A M ERI C A N  M USE U M  N OV ITATES
Number 3993, 50 pp. December 13, 2022
Bundles of Sperm: Structural Diversity in Scorpion 
Sperm Packages Illuminates Evolution of Insemination 
in an Ancient Lineage
DAVID E. VRECH,1 ALFREDO V. PERETTI,1 LORENZO PRENDINI,2  
AND CAMILO I. MATTONI1
ABSTRACT
The spermatozoa of scorpions are often bundled together, forming a type of sperm conju-
gation known as a sperm package. Sperm packages may be found inside the testes and seminal 
vesicles but vanish in the female atrium, leaving free spermatozoa. Previous studies, based on 
a limited number of taxa, suggested a diversity of sperm package morphology across the order 
Scorpiones C.L. Koch, 1850. However, the sperm packages of most scorpion taxa remained 
unknown. The present study provides the first systematic survey of sperm package morphology 
across the order, covering 89 exemplar species in 66 genera and 19 families representing all 
suprafamilial ranks, with a more detailed investigation of the family Bothriuridae Simon, 1880. 
Whereas all exemplar species of scorpions exhibit sperm packages, Buthida Soleglad and Fet, 
2003, including Chaerilidae Pocock, 1893, and most Buthidae C.L. Koch, 1837, present unor-
ganized sperm or loosely organized bundles. Although the details vary, three main types of 
sperm packages may be recognized in all other families: single folded; straight; and multiple 
folded. Subtypes may be identified according to general shape and folding patterns, mainly 
among sperm packages that are folded multiple times. Single-folded sperm packages are the 
most common type observed in the order. Although most sperm packages lack a covering, a 
conspicuous secretion sheath may be evident, e.g., in some Chactidae Pocock, 1893. Sperm 
1  Laboratorio de Biología Reproductiva y Evolución, Instituto de Diversidad y Ecología Animal, CONICET – 
FCEFyN, Universidad Nacional de Córdoba, Córdoba, Argentina. 
2  Arachnology Lab and Scorpion Systematics Research Group, Division of Invertebrate Zoology, American 
Museum of Natural History, New York.
Copyright © American Museum of Natural History 2022 ISSN 0003-0082
2 AMERICAN MUSEUM NOVITATES NO. 3993
packages vary in length from 112–354 µm and bent sperm packages are not necessarily longer 
than straight sperm packages. Four exemplar species of Bothriuridae reveal that variation in 
sperm count within a single sperm package is consistent with the count derived in spermato-
genesis. The diversity of sperm packages suggests a path from free spermatozoa, via bent sperm 
packages, to other forms. Sperm packages may aid in the transport, cooperation, competition, 
and survival of spermatozoa. The diverse morphology, function, and evolution of sperm pack-
ages merit further investigation.
INTRODUCTION
The spermatozoa of scorpions are morphologically rather uniform (André, 1959, 1963; 
Hood et al., 1972; Cruz-Landim and Ferreira, 1971, 1973; Jespersen and Hartwick, 1973; Phil-
lips, 1974; Alberti, 1983). The spermatozoa are filiform and flagellate, comprising a head, mid-
dle piece, and flagellum (Jespersen and Hartwick, 1973; Alberti, 2000, 2005; Michalik and 
Mercati, 2010). Structural differences in the axoneme or the acrosomal complex, between 
Buthidae C.L. Koch, 1837, and other extant families, suggest variation in the morphology of 
scorpion sperm may be phylogenetically informative (Vignoli et al., 2008; Michalik and Mer-
cati, 2010; Peretti, 2010). 
Scorpion spermatozoa are often gathered, or bundled, forming sperm conjugations in 
which spermatozoa are held together during the final phase of spermatogenesis (Pitnick et al., 
2009; Higginson and Pitnick, 2011; Dallai, 2014). Sperm conjugates in scorpions are formed 
by grouping spermatozoa with an undetermined electrodense substance, lacking a secretion 
sheath (Vignoli et al., 2008; Michalik and Mercati, 2010; Vrech et al., 2011). Previous studies 
indicated that sperm conjugates may contain 70–250 spermatozoa per package (Peretti and 
Battán-Horenstein, 2003; Vignoli et al., 2008; Michalik and Mercati, 2010; Vrech et al., 2016). 
The terminology describing sperm conjugates in animals is heterogeneous and inconsis-
tently applied (Pitnick et al., 2009). In the present study, “sperm package” refers to the sperm 
conjugates of scorpions, following recent scorpion literature (Vignoli et al., 2008, Michalik and 
Mercati, 2010; Vrech et al., 2011, 2016) and is synonymous with “sperm bundle,” widely used 
for insects (e.g., Virkki, 1969; Mojica and Bruck, 1996; Sasakawa and Toki, 2008; Higginson 
and Pitnick, 2011; Hodgson et al., 2013) as well as in the older literature on scorpions (e.g., 
Jespersen and Hartwick, 1973; Alberti, 1983).
Many early studies of scorpion sperm were conducted on taxa of the family Buthidae, with 
detailed data presented on spermiogenesis and spermatozoa ultrastructure (Wilson, 1931; 
Cruz-Landim and Ferreira, 1971, 1973; Riess et al., 1978a, b; Alberti, 1983). Jespersen and 
Hartwick (1973) were the first to record the presence of sperm packages in four nonbuthid taxa 
from North America, i.e., Anuroctonus phaiodactylus (Wood, 1863), Hadrurus arizonensis 
Ewing, 1928, Uroctonus mordax Thorell, 1876, and Paravaejovis puritanus (Gertsch, 1958) (as 
Vejovis puritanus Gertsch, 1958), currently assigned to three chactoid families, Chactidae 
Pocock, 1893, Hadruridae Stahnke, 1974, and Vaejovidae Thorell, 1876. Unfortunately, Jes-
persen and Hartwick (1973) provided few data on the morphology of the sperm packages in 
these taxa. 
2022 VRECH ET AL.: SCORPION SPERM PACKAGES 3
The presence of sperm packages in four genera and eight species of another nonbuthid 
family, Bothriuridae Simon, 1880, was reported 30 years later (Peretti and Battán-Horenstein, 
2003). In addition to describing the male genitalia and measuring sperm packages, Peretti and 
Battán-Horenstein (2003) discussed sperm package dynamics inside the female genital tract 
for the first time. Sperm packages disaggregate inside the female genital atrium, spermatozoa 
then separate and are stored freely inside the female spermathecae. 
Vignoli et al. (2008) presented the first description of the sperm packages of the troglo-
morphic chactoid, Belisarius xambeui Simon, 1879, currently accommodated in Belisariidae 
Lourenço, 1998. The sperm of B. xambeui formed elongate, oval packages containing 150 sper-
matozoa and lacking a secretion sheath. 
Michalik and Mercati (2010) subsequently described the sperm packages of Opistophthalmus 
penrithorum Lamoral, 1979, the first such example for the family Scorpionidae Latreille, 1802, and 
superfamily Scorpionoidea Latreille, 1802. The sperm packages of O. penrithorum resembled those 
of B. xambeui described by Vignoli et al. (2008) but contained 250 spermatozoa. Additionally, 
Michalik and Mercati (2010) reviewed and summarized the appearance, shape, sperm arrangement, 
and number of sperm packages, together with ultrastructural characters of the spermatozoa, in 15 
species representing six families of scorpions. Building on the work of Peretti and Battán-Horenstein 
(2003), Michalik and Mercati (2010) discussed the evolution of sperm packages in scorpions, 
hypothesizing that more compact sperm packages may have been selectively advantageous.
Bent sperm packages were later described in Euscorpius italicus (Herbst, 1800), represent-
ing another chactoid family, Euscorpiidae Laurie 1896, by Althaus et al. (2010). Vrech et al. 
(2011) updated previous studies with the addition of more species, focusing on Bothriuridae. 
For the first time, Vrech et al. (2011) analyzed various measurements of individual sperm pack-
ages, investigated intraspecific variation, and discussed the utility of sperm packages as char-
acters for scorpion systematics. Based in part on differences in sperm package morphology, 
Vrech et al. (2011) recommended elevating the subgenus Andibothriurus Maury, 1975, long 
recognized based on other characters (Mattoni, 2003; Peretti, 2010), to the rank of genus. Vrech 
et al. (2011, 2016) also described abnormalities in the shape of sperm packages and the number 
of spermatozoa inside male ejaculates.
The above-mentioned studies demonstrated that sperm packages are widely distributed 
across the order Scorpiones C.L. Koch, 1850 (Mattoni, 2003; Michalik and Mercati, 2010; Vrech 
et al., 2011), to date reported in 54 species, representing 32 genera, seven families, and three 
superfamilies of Iurida Soleglad and Fet, 2003: Belisariidae (Vignoli et al., 2008); Bothriuridae 
(Peretti and Battán-Horenstein, 2003; Vrech et al., 2011); Chactidae (Jespersen and Hartwick, 
1973); Euscorpiidae (Althaus et al., 2010), Hadruridae (Jespersen and Hartwick, 1973); Scor-
pionidae (Michalik and Mercati, 2010); and Vaejovidae (Jespersen and Hartwick, 1973). 
At present, sperm packages have not yet been reported in Buthidae (Cruz-Landim and Fer-
reira, 1973; Peretti and Battán-Horenstein, 2003; Vrech et al., 2011) or Chaerilidae Pocock, 1893 
(Vrech et al., 2011), both assigned to the suborder Buthida Soleglad and Fet, 2003, an early branch 
of the order (Lamoral, 1980; Stockwell, 1989; Sissom, 1990; Prendini, 2000, 2003; Coddington et 
al., 2004; Prendini et al., 2006; Volschenk et al., 2008). Alberti (1983) suggested that the loosely 
4 AMERICAN MUSEUM NOVITATES NO. 3993
aggregated spermatozoa of the buthid, Buthus occitanus (Amoreux, 1789), represent sperm bun-
dles. The presence of sperm packages also remains unknown in Pseudochactidae Gromov, 1998, 
considered closely related to Chaerilidae, in superfamily Chaeriloidea Pocock, 1893 (Prendini et 
al., 2006, 2021). Data on sperm packages are also lacking for another 12 families, notably the basal 
nonbuthid family Iuridae Thorell, 1876, of superfamily Iuroidea Thorell, 1876; five chactoid fami-
lies, Caraboctonidae Kraepelin, 1905, Scorpiopidae Kraepelin, 1905, Superstitioniidae Stahnke, 
1940, Troglotayosicidae Lourenço, 1998, and Typhlochactidae Mitchell, 1971; and six scorpionoid 
families, Diplocentridae Karsch, 1880, Hemiscorpiidae Pocock, 1893, Heteroscorpionidae Krae-
pelin, 1905, Hormuridae Laurie, 1896, Rugodentidae Bastawade et al., 2005, and Urodacidae 
Kraepelin, 1905. 
The precise function of sperm packages in scorpions is unclear. The aggregation of sperm may 
aid their protection during sperm transfer (Peretti and Battán-Horenstein, 2003; Peretti, 2010). 
Comparisons among exemplar species of Buthidae and Bothriuridae revealed that male buthids, 
with bundles of loosely aggregated spermatozoa, inseminate females rapidly, usually within a few 
seconds, whereas insemination takes longer in bothriurids, which possess sperm packages. Further-
more, compact sperm may be delivered more easily and in greater quantity, without substantial loss 
(Peretti, 2010; Vrech et al., 2011). Althaus et al. (2010) demonstrated that sperm packages play a 
role in forming a temporary sperm plug in the female genital opening, after sperm transfer. 
Despite an accumulation of observations and hypotheses concerning the sperm packages of 
scorpions in recent decades, knowledge of their diversity, function, and evolution remains limited, 
in part due to an absence of data for many scorpion taxa (Vignoli et al., 2008; Vrech et al., 2011). 
The present study provides the first systematic survey of sperm package morphology across the 
order, covering 89 exemplar species in 66 genera and 19 families representing all suprafamilial 
ranks, with a more detailed investigation of the family Bothriuridae, in which the greatest diver-
sity of sperm packages is observed (Vrech et al., 2011). The general morphology of sperm pack-
ages is described and illustrated, sperm package length is measured and analyzed statistically, and 
sperm counts are presented for four exemplar species of Bothriuridae. Comparison of the diver-
sity in sperm package morphology across the order provides new insights into the evolution of 
sperm packages in scorpions, and their potential utility as characters for scorpion systematics.
Material and Methods
Taxon Sampling and Material Examined: Adult males of 89 exemplar species, repre-
senting 66 genera and 19 families, were examined (table 1). Buthida were represented by 17 
species in 16 genera and three families, representing both superfamilies Buthoidea C.L. Koch, 
1837, and Chaeriloidea. Iurida were represented by 72 species in 50 genera and 16 families, 
representing all superfamilies (Bothriuroidea Simon, 1880; Chactoidea Pocock, 1893; Iuroidea; 
Scorpionoidea). Three families were omitted: Belisariidae, for which the sperm packages of B. 
xambeui were described by Vignoli et al. (2008); Microcharmidae Lourenço, 1996, synony-
mized with Buthidae by Volschenk et al. (2008) and considered a junior synonym thereof, in 
the present investigation; and Rugodentidae, for which material was unavailable for study. 
2022 VRECH ET AL.: SCORPION SPERM PACKAGES 5
The greatest sample of genera (13) and species (33) was examined in Bothriuridae (table 1), 
and Bothriurus Peters, 1861, in particular (16 species), on account of the diversity of sperm pack-
age morphology in these taxa (Mattoni, 2003; Ojanguren-Affilastro, 2005; Vrech et al., 2011).
Sperm packages were dissected from adult males deposited in the following collections 
(appendix 1): AMNH, American Museum of Natural History, New York; AVP, Alfredo V. Per-
etti Private Collection, Universidad Nacional de Córdoba, Argentina; CAS, California Academy 
of Sciences, San Francisco; CIM, Camilo I. Mattoni Private Collection, Universidad Nacional 
de Córdoba, Argentina; DEV, David E. Vrech Private Collection, Universidad Nacional de 
Córdoba, Argentina; IBSP, Instituto Butantan, São Paulo, Brazil; MACN, Museo Argentino de 
Ciencias Naturales Bernardino Rivadavia, Buenos Aires, Argentina; MCZ, Museum of Com-
parative Zoology, Harvard University, Cambridge, MA; MPUJ, Museo Javeriano de Historia 
Natural “Lorenzo Uribe S.J.,” Pontificia Universidad Javeriana, Bogotá, Colombia; MZUSP, 
Museu de Zoología da Universidade de São Paulo, Brazil; MZUC, Museo de Zoología, Univer-
sidad de Concepción, Chile; UFBA, Universidade Federal da Bahía, Salvador da Bahía, Brazil; 
ZMB, Museum für Naturkunde, Berlin, Germany. 
The scarcity of material prevented the examination of more than one male for most taxa. 
However, intraspecific variation in sperm package morphology was assessed in a few species by 
observations within one or more individuals from the same or different populations. Polymor-
phism in sperm packages from a single individual was investigated by Vrech et al. (2016).
Dissection, Microscopy, and Imaging: Incisions were made in the pleural membrane 
of each specimen, and the sinistral paraxial organ removed using fine forceps. Sperm packages 
were extracted for light microscopy by dissecting the seminal vesicle over a microscope slide. 
Twenty-five exemplar species were examined with scanning electron microscopy (SEM) and 
the rest with light microscopy. 
Seminal vesicles containing sperm packages used for SEM were dehydrated in progressively 
increasing concentrations of ethanol, from 70% to 100%. Two desiccation techniques, critical-
point drying (CPD) and Hexamethyldisilazane (HMDS) (Nation, 1983), were investigated and 
neither was found to affect the morphology of the sperm packages (Bray et al., 1993). Desiccated 
samples were mounted and coated with gold (Au) and palladium (Pd) in a DENTON Desk II 
Sputter Coater (Moorestown, NJ). Samples were then analyzed using a Hitachi S-4700 Field Emis-
sion SEM (Tokyo, Japan). Sample processing and imaging was conducted at the AMNH Micros-
copy and Imaging Facility and the Laboratorio de Análisis de Materiales por Espectometría de 
Rayos X (LAMARX-FaMAF), Universidad Nacional de Córdoba (UNC), Argentina.
A sample of sperm packages was mixed in liquid glycerin and scattered in an Improved 
Neubauer counting chamber (Boeco, Wuppertal, Germany) to enable posterior measurements 
using the chamber’s grid. Digital images were taken using a Nikon DIGITAL SIGHT DS-fi1 
camera (Tokyo, Japan) attached to a Nikon eclipse50i phase contrast light microscope. Exposure 
to ethanol and glycerin did not affect the sperm packages, which maintained their integrity 
after a year in glycerin. Sperm packages were found to be generally well preserved by standard 
methods of scorpion specimen preservation, allowing their extraction and examination from 
museum material. 
6 AMERICAN MUSEUM NOVITATES NO. 3993
TABLE 1. Count of exemplar species representing major groups of scorpions in which sperm packages were 
examined.
Suborder Superfamily Family Genera Species
Buthida Soleglad and Fet, 2003 Buthoidea C.L. Koch, 1837 Buthidae C.L. Koch, 1837 14 14
Chaeriloidea Pocock, 1893 Chaerilidae Pocock, 1893 1 2
Pseudochactidae Gromov, 1998 1 1
Iurida Soleglad and Fet, 2003 Bothriuroidea Simon, 1880 Bothriuridae Simon, 1880 13 33
Chactoidea Pocock, 1893 Caraboctonidae Kraepelin, 1905 2 2
Chactidae Pocock, 1893 7 7
Euscorpiidae Laurie, 1896 2 3
Scorpiopidae Kraepelin, 1905 3 3
Superstitioniidae Stahnke, 1940 1 1
Troglotayosicidae Lourenço, 1998 1 1
Typhlochactidae Mitchell, 1971 2 2
Vaejovidae Thorell, 1876 7 7
Iuroidea Thorell, 1879 Iuridae Thorell, 1876 1 1
Scorpionoidea Latreille, 1802 Diplocentridae Karsch, 1880 2 2
Hemiscorpiidae Pocock, 1893 1 1
Heteroscorpionidae Kraepelin, 1905 1 1
Hormuridae Laurie, 1896 4 4
Scorpionidae Latreille, 1802 2 2
    Urodacidae Pocock, 1893 1 2
Total   19 66 89
Analysis of Shape and Length: The diversity in shape of sperm packages was assessed 
from images obtained with light microscopy and SEM. The structure of the sperm packages 
observed in each family was compared and described, allowing general patterns to be observed 
and different types of sperm packages to be identified across the order. Type describes the 
general pattern. Shape describes the form observed, for example in sperm packages with many 
folds, the shape may be a slender bar or an ellipsoid. The term spherical was applied if the 
ellipsoid resembled a sphere. Where possible, patterns of sperm package folding were also 
described. Sometimes, folding was obscured by secretions. Folding terminology was adopted 
from the brochure and leaflet industry (ALPHA2OMEGA, n.d.; APS, 2022). Images that exem-
plified the major types were presented. Descriptions of sperm packages from species of the 
family Bothriuridae follow Vrech et al. (2011). 
When comparing sperm packages, the main type is described first, followed by variation 
in shape, and finally, when possible, the manner in which the sperm was folded within (type, 
shape, and folding; table 2). For example, a sperm package that is folded multiple times may 
present an ellipsoidal shape, and the sperm within presenting an open gatefold folding, in 
which the tips of the sperm package arms bend inward.
2022 VRECH ET AL.: SCORPION SPERM PACKAGES 7
Where possible, the length and area of the sperm packages were calculated from the images 
using Image J 64-bit image-processing software (Schneider et al., 2012). Length was assessed 
to be a more precise measurement than area, as it was less affected by the state of preservation 
of the material. Length was measured with the straight tool, along the midline of the sperm 
package from the anterior part, which contains the nuclei of the spermatozoa, to the posterior 
part, which contains the flagella of the spermatozoa. 
When the sperm package was not entirely straight or presented folds, the number of folds 
were counted, and the length estimated by multiplying the length measured by the number of 
branches produced by the folds (fig. 1A, C). For example, if a bend in the middle of the sperm 
package produced a single fold, the length measured was multiplied by two because a single 
fold produces two branches (fig. 1A). When two folds were observed, as in round sperm pack-
ages, the length measured was multiplied by four. Length was not estimated in sperm packages 
with other types of folds, which were difficult to quantify. 
A one-way ANOVA with a Tukey post hoc test (α = 5%) was performed to compare length 
among sperm packages with a single fold, the most common type among the taxa examined. 
Counts of Spermatozoa in Bothriuridae: Four species of Bothriuridae, Bothriurus 
bonariensis (C.L. Koch, 1842), Brachistosternus ferrugineus (Thorell, 1876), Timogenes elegans 
(Mello-Leitão, 1931), and Urophonius brachycentrus (Thorell, 1876), were investigated in more 
detail. The reproductive biology of these species has been extensively studied (Vrech, 2013; 
Vrech et al., 2014, 2018, 2019; Romero-Lebrón et al., 2019; Oviedo-Diego et al., 2019, 2020; 
Olivero et al., 2015, 2019, 2021) and fresh material was more readily available compared to 
other taxa. 
One seminal vesicle of each species was fixed in 4% formaldehyde 2% glutaraldehyde in caco-
dylate buffer (pH 7.3, 0.1 M) for 2 hours, and then transferred to 1% osmium tetroxide in the 
same buffer. After dehydration in progressively increasing concentrations of acetone, samples 
were embedded in Araldite and polymerized at 60° C. Transverse thin sections of sperm packages 
were prepared with a diamond knife on a JEOL JUM-7 ultramicrotome (Tokyo, Japan) and 
imaged with a Zeiss LEO 906E (Jena, Germany) transmission electron microscope (TEM). Sper-
matozoa were counted from the TEM images (n = 15 sperm packages per species). For consis-
tency, spermatozoa were counted from sperm packages only in the medial zone of the image, as 
spermatozoa at the periphery could be slightly out of phase. The number of mitochondria and 
the form of the axoneme were also examined. Sample processing and imaging was conducted in 
the Centro de Microscopía Electrónica, Facultad de Ciencias Médicas, UNC.
RESULTS
Major Types of Sperm Packages in Scorpions: Sperm packages were present in 17 
(89%) of the 19 families studied (table 2). Except for three exemplar species of Buthidae, all 
Buthida lacked sperm conjugation, possessing free, disordered spermatozoa. 
The sperm packages of Iurida were highly variable. Three major types were recognized 
(figs. 1A–F): straight sperm packages; single-folded sperm packages; and multiple-folded sperm 
8 AMERICAN MUSEUM NOVITATES NO. 3993
TABLE 2. Presence and qualitative differences in structure of sperm packages among exemplar species representing major groups of scorpions. 
Sources: [1] Jespersen and Hartwick (1973), refers to “bundles”; [2] Alberti (1983), refers to “sperm bundles”; [3] Peretti and Battán-Horenstein 
(2003); [4] Vignoli et al. (2008); [5] Michalik and Mercati (2010); [6] Althaus et al. (2010); [7] Vrech et al. (2011); [8] this study. Mt = mitochondria.
Classification Species Type Shape Folding Sheath Mt Axoneme Source
Buthida
Buthoidea
Buthidae Ananteris arcadioi absent1 (block) [8]
Babycurus jacksoni absent free/loosely aggregated sperm [8]
Buthus occitanus absent free/loosely aggregated sperm 2 9 + 2 [2]
Buthus paris absent free/loosely aggregated sperm 2 [8]
Hottentotta conspersus absent free/loosely aggregated sperm [8]
Isometrus maculatus absent free/loosely aggregated sperm [8]
Lychas obsti absent free/loosely aggregated sperm [8]
Mesobuthus eupeus thersites absent free/loosely aggregated sperm [8]
Microtityus waeringi absent free/loosely aggregated sperm [8]
Parabuthus granulatus fusiform1 (fusiform) [8]
Pseudolychas ochraceus folded1  (folded) [8]
Reddyanus assamensis absent free/loosely aggregated sperm [8]
Teruelius ankarana absent free/loosely aggregated sperm [8]
Tityus elii absent free/loosely aggregated sperm [8]
Zabius fuscus absent free/loosely aggregated sperm [3, 7]
Chaeriloidea
Chaerilidae Chaerilus julietteae absent free/loosely aggregated sperm [8]
Chaerilus variegatus absent free/loosely aggregated sperm [6]
Pseudochactidae Troglokhammouanus steineri absent (?)2 N/A [8]
2022 VRECH ET AL.: SCORPION SPERM PACKAGES 9
TABLE 2 continued
Classification Species Type Shape Folding Sheath Mt Axoneme Source
Iurida
Bothriuroidea
Bothriuridae Bothriurus araguayae straight straight absent [7, 8]
Bothriurus asper straight/single folded straight/bent half fold absent [7, 8]
Bothriurus bocki single folded/straight bent/straight half fold absent [7, 8]
Bothriurus bonariensis straight sraight absent 9 + 0 [3, 7, 8]
Bothriurus burmeisteri straight canelike absent [7, 8]
Bothriurus chacoensis straight Straight absent [3, 7, 8]
Bothriurus cordubensis straight canelike absent [3, 7, 8]
Bothriurus coriaceus straight canelike absent [7, 8]
Bothriurus flavidus straight canelike absent [3, 7, 8]
Bothriurus inermis straight canelike absent [7, 8]
Bothriurus keyserlingi straight canelike absent [7, 8]
Bothriurus noa straight canelike absent [7, 8]
Bothriurus olaen straight canelike absent [7, 8]
Bothriurus rochai straight canelike absent [7, 8]
Bothriurus rochensis straight canelike absent [7, 8]
Bothriurus sp. straight straight absent [7, 8]
Brachistosternus angustimanus straight canelike absent [7, 8]
Brachistosternus ferrugineus straight canelike absent 3 9 + 0 [3, 7, 8]
Brachistosternus pentheri straight canelike absent [7, 8]
Centromachetes obscurus straight canelike absent [7, 8]
Centromachetes pocockii straight canelike absent [7, 8]
Cercophonius squama single folded/ bent/straight half fold absent [7, 8]
straight canelike
Lisposoma josehermana straight straight absent [7, 8]
Orobothriurus tamarugal straight straight absent [7, 8]
Phoniocercus pictus straight canelike absent [7, 8]
Rumikiru lourencoi straight straight absent [7, 8]
Tehuankea moyanoi straight canelike absent [7, 8]
10 AMERICAN MUSEUM NOVITATES NO. 3993
TABLE 2 continued
Classification Species Type Shape Folding Sheath Mt Axoneme Source
Iurida
Bothriuroidea
Bothriuridae Thestylus aurantiurus straight straight absent [7, 8]
Timogenes dorbignyi single folded bent half fold absent [3, 7, 8]
Timogenes elegans single folded bent half fold absent 3 9 + 0 [3, 7, 8]
Urophonius brachycentrus straight canelike absent 3 9 + 0 [3, 7, 8]
Urophonius tregualemuensis straight canelike absent [7, 8]
Vachonia martinezi single folded bent half fold absent [7, 8]
Chactoidea
Belisariidae Belisarius xambeui single folded bent half fold absent 3, 4, 6 9 + 0 [4]
Caraboctonidae Caraboctonus keyserlingi straight straight absent [7, 8]
Hadruroides lunatus straight straight absent [8]
Chactidae Anuroctonus phaiodactylus single folded bent half fold absent 4, 7 9 + 0 [1, 5]
Brotheas sp. multiple folded ellipsoidal/double bent open/closed present [8]
gatefold
Broteochactas nitidus multiple folded double bent open gatefold present [8]
Chactas aequinoctialis multiple folded ellipsoidal/spherical open gatefold/ present [7, 8]
roll fold?
Chactopsoides anduzei multiple folded ellipsoidal open gatefold? present [8]
Nullibrotheas allenii multiple folded ellipsoidal open gatefold? present [8]
Teuthraustes sp. multiple folded spherical/ellipsoidal open/closed present [8]
gatefold?
Uroctonus mordax single folded bent half fold absent 4, 5, 6, 7 9 + 0 [1, 5, 8]
2022 VRECH ET AL.: SCORPION SPERM PACKAGES 11
TABLE 2 continued
Classification Species Type Shape Folding Sheath Mt Axoneme Source
Iurida
Chactoidea
Euscorpiidae Megacormus gertschi multiple folded spherical/ellipsoidal closed gatefold/ present [7, 8]
roll fold
Megacormus sp. ellipsoidal spherical/ellipsoidal closed gatefold/ present [7, 8]
roll fold
Euscorpius italicus single folded bent half fold present [6]
Euscorpius sicanus single folded bent half fold present 6, 7, 8 9 + 0 [5]
Tetratrichobothrius flavicaudis multiple folded ellipsoidal/bent open gatefold/ present [7, 8]
annular 
twisted/closed 
gatefold
Hadruridae Hadrurus arizonensis straight? straight? absent 5 9 + 0 [1, 5]
Scorpiopidae Euscorpiops longimanus multiple folded ellipsoidal roll fold present [8]
Scorpiops zubairi single folded bent half fold absent [8]
Troglocormus ciego multiple folded ellipsoidal roll fold absent [8]
Superstitioniidae Superstitionia donensis straight straight absent [8]
Troglotayosicidae Troglotayosicus humiculum single folded bent half fold absent [8]
Typhlochactidae Alacran tartarus single folded bent half fold absent [8]
Typhlochactas mitchelli single folded bent half fold absent [8]
Vaejovidae Graemeloweus glimmei single folded bent half fold absent [8]
Mesomexovis variegatus single folded bent half fold absent [8]
Paravaejovis puritanus single folded bent half fold absent 4, 5, 6, 7 9 + 0 [1, 5]
Paravaejovis spinigerus single folded bent half fold absent [5, 8] 
Smeringurus grandis single folded bent half fold absent [8]
Syntropis williamsi single folded bent half fold absent [8]
Vaejovis mexicanus single folded bent half fold absent [8]
Vejovoidus longiunguis single folded bent half fold absent [8]
Iuroidea
Iuridae Protoiurus asiaticus straight straight absent [8]
12 AMERICAN MUSEUM NOVITATES NO. 3993
TABLE 2 continued
Classification Species Type Shape Folding Sheath Mt Axoneme Source
Iurida
Scorpionoidea
Diplocentridae Diplocentrus lindo multiple/single folded ellipsoidal/bent roll fold?/half absent [8]
fold
Nebo hierichonticus single folded bent half fold absent [8]
Hemiscorpiidae Hemiscorpius lepturus single folded bent half fold absent [8]
Heteroscorpionidae Heteroscorpion goodmani single/multiple folded bent/double bent half fold/open present [8]
gatefold
Hormuridae Hadogenes troglodytes multiple folded annular/ellipsoidal annular/roll absent [8]
fold
Hormurus sp. multiple folded annular/annular twisted/ annular absent [7, 8]
double bent twisted
Opisthacanthus capensis multiple folded ellipsoidal roll fold absent [7, 8]
Opisthacanthus valerioi multiple folded ellipsoidal roll fold absent [7, 8]
Scorpionidae Opistophthalmus penrithorum single folded bent half fold absent 5, 6 9 + 0 [5]
Pandinus imperator single folded/straight bent/canelike half fold absent [7, 8]
Scorpio fuliginosus multiple folded ellipsoidal/spherical double parallel absent [7, 8]
fold/roll fold
Urodacidae Urodacus butleri multiple folded ellipsoidal/spherical double parallel present [8]
fold/roll fold
  Urodacus planimanus multiple folded ellipsoidal/spherical double parallel present [8]
fold/roll fold
1 May exhibit some form of sperm conjugation, see text.
2 Not analyzed.
2022 VRECH ET AL.: SCORPION SPERM PACKAGES 13
packages. The third category included sperm packages with annular, double-folded, or ellip-
soidal shapes (fig. 1C, D). In many sperm packages, the folding was difficult to describe either 
because of its intricate configuration or because a sheath obscured the coiling of the sperm 
inside. A sheath was observed in Chactidae, Euscorpiidae, Heteroscorpionidae, Scorpiopidae, 
and Urodacidae but appears to be uncommon in the order. 
Sperm packages folded once only were termed bent sperm packages. Bent sperm packages 
presented limited variation except, occasionally, in the symmetry of their arms. Variation was 
common among straight sperm packages and sperm packages with multiple folds, however. 
Straight sperm packages presented different widths (e.g., some bothriurids) and angles in the 
anterior part (fig. 1F). Among the sperm packages with multiple folds, some sperm packages 
were folded medially, resembling bent sperm packages, but were also folded in one or both tips 
of their arms (fig. 1C, bottom). These were termed double-bent sperm packages as they were 
longer than ellipsoidal sperm packages and differed from bent sperm packages. 
The bent sperm package, characterized by a single fold that bends the package medially 
(fig. 1A, E) was the most abundant type, observed in 11 (58%) of the families and 35% of 
the exemplar species. Although observed in 38% of the exemplar species, straight sperm 
packages (fig. 1B, E, F) were concentrated in four (21%) families (Bothriuridae, Caraboc-
tonidae, Iuridae, and Superstitioniidae). Sperm packages that folded multiple times, includ-
ing different shapes such as annular, ellipsoidal, and double-bent sperm packages (fig. 1C, 
D), were observed in seven (37%) of the families and 21% of the exemplar species. In some 
cases, different shapes occurred in the same taxon. For example, annular sperm packages 
were commonly associated with bent sperm packages (fig. 1D), and sometimes also with 
straight sperm packages in a sample extracted from a single male of Timogenes elegans. Simi-
larly, straight sperm packages were sometimes present together with bent sperm packages 
(fig. 1E; table 2). There was great variation in sperm package morphology within the family 
Bothriuridae, representing all three main categories of sperm packages (single folded, 
straight, and multiple folded; fig. 1D–F).
In general, the spermatozoa forming sperm packages were usually twisted along the entire 
length of the sperm package, resembling the inside of a copper-wire cable, an arrangement 
which appears to provide structural cohesion to the sperm package.
Comparison of Sperm Packages among Scorpion Families: Sperm packages were 
examined in 14 exemplar species of Buthidae. Eleven (79%) species exhibited free spermatozoa 
with no apparent aggregation inside the seminal vesicle (figs. 1G–L, 2A, B). There were three 
exceptions to this general pattern, however (fig. 2C–E). Parabuthus granulatus (Ehrenberg, 
1831) possessed loosely aggregated sperm packages, approximately 150–200 µm in length, with 
a fusiform shape, resembling the sperm packages of Iurida (fig. 2C). Spermatozoa in these 
arrangements were aligned, but not densely packed as in other families (see below). Similarly, 
Pseudolychas ochraceus (Hirst, 1911) exhibited sperm arrangements of 100 µm length (fig. 2D) 
ellipsoidal in shape, but it is unclear whether this is comparable to the ellipsoidal sperm pack-
ages of Iurida. Finally, Ananteris arcadioi Botero-Trujillo, 2008, exhibited large sperm masses 
resembling blocks of spermatozoa (fig. 2E). 
14 AMERICAN MUSEUM NOVITATES NO. 3993
Chaerilidae exhibited the same general organization of free, irregularly dispersed sperma-
tozoa observed in most buthid taxa. Both exemplar species, Chaerilus julietteae Lourenço, 2011, 
and Chaerilus variegatus Simon, 1877, lacked identifiable sperm packages, the spermatozoa 
instead forming a loose, disordered mass inside the seminal vesicle (fig. 2F).
Sperm packages also appear to be absent in Pseudochactidae, but this could not be defini-
tively confirmed in the material examined of the exemplar species, Troglokhammouanus steineri 
Lourenço, 2007.
Protoiurus asiaticus (Birula, 1903), the sole exemplar species of Iuridae, possessed straight, 
slender sperm packages that may be curved anteriorly in the first third of the sperm package, in 
the area where the nuclei of the spermatozoa are clustered (fig. 2G). This anterior part is curved 
and appears aligned and attached to the rest of the sperm package and twisted around it. 
The sperm packages of Euscorpiidae and the related Scorpiopidae are folded multiple times 
and highly variable in shape (fig. 2H–L). This variation is complex due to the number and 
position of folds along the body of the sperm package, resembling a straight sperm package 
bent at the extremes of its length like an office staple (double bent), and termed open gatefold-
ing. This kind of folding may resemble single folded sperm packages (fig. 2H, lower left corner). 
The sperm package may exhibit an annular twisted or lemniscate shape, resembling an infinity 
sign, ∞ (fig. 2H, lower right corner). This twisted ring may bend again medially, becoming 
smaller, more compact, and rounded, resembling a sphere or ellipsoid (fig. 1C, 2I). This folding 
is termed a double parallel fold. 
The euscorpiid, Tetratrichobothrius flavicaudis (DeGeer, 1778), presents ellipsoidal sperm 
packages with various types of folding, e.g., an open gatefold, double parallel fold, roll fold (simi-
lar to a spiral coiling), and annular twisting (figs. 1C, 2H). Sometimes, this species presents sperm 
packages like the typical folded packages of Bothriuridae and some Vaejovidae (see below), with 
a long slender ellipsoidal appearance (fig. 2H, lower left corner), however, these are not folded 
once only as in the latter families. The sperm package of T. flavicaudis may also exhibit a second 
fold in one of the two branches (fig. 1C: lower sperm package, denoted by the number 1). 
A more compact type of folding is observed in Megacormus gertschi Diaz Nájera, 1966, and 
Megacormus sp., and also appears in T. flavicaudis (fig. 1C: upper sperm package). Megacormus 
Karsch, 1881, possess ellipsoidal, almost spherical sperm packages in which the spermatozoa 
appear to be folded many times, the single fold packages arcing again medially (double parallel 
fold), or folding spirally, to produce a short, roundish sperm package (fig. 2I). This spherical 
shape and compactness resembles that of the chactid, Nullibrotheas allenii (Wood, 1863) (see 
below). A covering or sheath over the spermatozoa was not observed in Megacormus, although 
the sperm packages of this genus resemble those of other taxa, in which a sheath is present 
(table 2), e.g., Chactidae and the euscorpiids Euscorpius italicus and Euscorpius sicanus (C.L. 
Koch, 1837).
Slightly ellipsoidal sperm packages with multiple folds are evident in the scorpiopid, Tro-
glocormus ciego Francke, 1981 (fig. 2J). The sperm packages of T. ciego are very similar to those 
of Megacormus, similarly lacking evidence of a sheath covering the spermatozoa. Scorpiops 
zubairi Kovařík, 2020, possessed a single-folded sperm package, bent medially (fig. 2K). The 
2022 VRECH ET AL.: SCORPION SPERM PACKAGES 15
ellipsoidal sperm packages of Euscorpiops longimanus (Pocock, 1893) were wrinkled anteriorly 
(fig. 2L), the entire sperm conjugation coiled spirally. Unlike other exemplar species of Scor-
piopidae, a sheath covered the spermatozoa of the entire sperm package in E. longimanus (fig. 
2L). This character was also observed in Chactidae, Euscorpiidae, and Urodacidae (see below), 
but appears to be uncommon in the order.
The caraboctonid, Caraboctonus keyserlingi Pocock, 1893, possessed broad, thick, straight 
sperm packages (fig. 3A). The anterior part of the sperm package, approximately one-third of its 
length, appeared to be folded toward the posterior part, creating a rounded appearance. This part 
was also attached to the main body of the package and twisted around it, resembling the sperm 
package of the iurid, P. asiaticus (fig. 2G). Sperm packages of another caraboctonid, Hadruroides 
lunatus (L. Koch, 1867) (fig. 3B), were straight and slender, also resembling those of P. asiaticus. 
Similar slender sperm packages were also observed in C. keyserlingi, but in far lower numbers.
Superstitionia donensis Stahnke, 1940, the only species of Superstitioniidae, exhibited 
straight sperm packages (fig. 3C), differing from those observed in Iuridae and all exemplar 
species of Bothriuridae, except Lisposoma josehermana Lamoral, 1979, in widening anteriorly 
where the nuclei of the spermatozoa are gathered, and narrowing posteriorly where the flagella 
of the spermatozoa occur. 
Although the sperm was poorly preserved in the exemplar species of Typhlochactidae, 
Alacran tartarus Francke, 1982, and Typhlochactas mitchelli Sissom, 1988, and no further mate-
rial was available, the images suggest the sperm packages are folded in these taxa. 
Species of Chactidae possess sperm packages that are folded many times. The general shapes 
range from ellipsoidal to almost spherical (fig. 3D–K). Nullibrotheas allenii possessed an almost 
spherical and ellipsoidal sperm package (fig. 3D, E) that appeared to be folded more than once 
and also twisted (fig. 3E), but it was difficult to determine the folding pattern. A thin sheath 
appeared to cover the entire sperm package of N. allenii, but the undulations of individual sper-
matozoa could be identified (fig. 3E). The multiple-folded sperm package of Brotheas sp. exhibited 
different shapes in the same sample, including ellipsoidal (fig. 3F), double-bent (fig. 3G), and 
almost spherical sperm packages with a spiral or double gatefold; a clear smooth sheath was also 
noticeable (fig. 3F, G). The sperm packages of Broteochactas nitidus Pocock, 1893, also appeared 
to be folded multiple times (fig. 3H) and were similar in shape to the double-bent sperm package 
with open gatefold of Brotheas sp. (fig. 3G). The sperm packages of Chactopsoides anduzei 
(González-Sponga, 1982) resembled those of B. nitidus, exhibiting a double-bent shape with pat-
terns of lines medially (fig. 3I). The unusual shape of the sperm package of this species prevented 
assessment of how the sperm folds inside, but it is assumed to be an open gatefolding, similar to 
B. nitidus. The covering sheath of these latter species was difficult to identify under light micros-
copy but is assumed to be present (fig. 3G). The sperm packages of Chactas aequinoctialis (Karsch, 
1879) were ellipsoidal to almost spherical (fig. 3J), sometimes resembling the spherical sperm 
packages of Brotheas sp. and the euscorpiid, Megacormus (fig. 2I). As in other chactids, C. aequi-
noctialis presented a secretion sheath. An ellipsoidal sperm package was also observed in Teuth-
raustes sp., but its shape and size were more variable than in C. aequinoctialis, and a sheath 
covered the entire sperm package (fig. 3K).
16 AMERICAN MUSEUM NOVITATES NO. 3993
A B C 3
1 2
straight 3 ellipsoidal 1bent
1
double bent
2
D E F
straight
canelike
bent
annular bent
G H I
J K L
FIGURE 1. Sperm packages of Bothriuridae Simon, 1880 (A, D, E, F), Superstitioniidae Stahnke, 1940 (B), 
Euscorpiidae Pocock, 1893 (C), and Buthidae C.L. Koch, 1837 (G–L), imaged with light microscopy (A–F) 
or scanning electron microscopy (G–L). A, D, E. Timogenes elegans (Mello-Leitão, 1931): bent, annular, 
straight. B. Superstitionia donensis Stahnke, 1940: straight. C. Tetratrichobothrius flavicaudis (De Geer, 1778): 
double bent/ellipsoidal; numbers represent folding that causes differences in shape. F. Brachistosternus fer-
rugineus (Thorell, 1876): straight. G. Zabius fuscus (Thorell, 1876): absent. H. Buthus paris (C.L. Koch, 1839): 
absent. I. Teruelius ankarana (Lourenço and Goodman, 2003): absent. J. Hottentotta conspersus (Thorell, 
1876): absent. K. Babycurus jacksoni (Pocock, 1890): absent. L. Lychas obsti Kraepelin, 1913: absent. Arrows 
indicate folding of sperm packages described in text, including variations in conspecifics. Scale bars: 25 µm.
2022 VRECH ET AL.: SCORPION SPERM PACKAGES 17
A B C
D E F
G H I
J K L
FIGURE 2. Sperm packages of Buthidae C.L. Koch, 1837 (A–E), Chaerilidae Pocock, 1893 (F), Iuridae Thorell, 
1876 (G), Euscorpiidae Laurie, 1896 (H, I), and Scorpiopidae Kraepelin, 1905 (J–L), imaged with scanning 
electron microscopy (A–G, J–L) or light microscopy (H, I). A. Tityus elii Armas and Marcano Fondeur, 1992: 
absent. B. Isometrus maculatus (DeGeer, 1778): folded. C. Parabuthus granulatus (Ehrenberg, 1831): fusiform. 
D. Pseudolychas ochraceus (Hirst, 1911): folded. E. Ananteris arcadioi Botero-Trujillo, 2008: block. F. Chaerilus 
julietteae Lourenço, 2011: absent. G. Protoiurus asiaticus (Birula, 1903): straight. H. Tetratrichobothrius flavi-
caudis (De Geer, 1778): double bent. I. Megacormus sp., Veracruz, Mexico: spherical. J. Troglocormus ciego 
Francke, 1981: spherical. K. Scorpiops zubairi Kovařík, 2020: bent. L. Euscorpiops longimanus (Pocock, 1893): 
spiral. Scale bars: 25 µm.
18 AMERICAN MUSEUM NOVITATES NO. 3993
Scanning electron micrographs of Brotheas sp., N. allenii, and Teuthraustes sp. revealed the 
presence of a sheath that covered the spermatozoa, providing a smooth appearance to the 
sperm package (fig. 3F, G, K). The different zones of the sperm package (head, middle zone, 
and flagellar zone) were difficult to differentiate, however, due to the bending and sheath (when 
present). The covering sheath appeared to be transparent under light microscopy, revealing the 
sperm inside. A similar pattern was evident in Euscorpiidae (see above). 
The sperm obtained from the exemplar species of Troglotayosicidae, Troglotayosicus humic-
ulum Botero-Trujillo and Francke, 2009, was also in poor state of preservation. The images 
available and previous literature suggest this species possesses folded sperm packages (fig. 3L). 
All exemplar species of Vaejovidae exhibited bent single folded sperm packages (fig. 4A–F), 
lacking a covering sheath and with few other differences (any differences observed appear to 
be related to the state of preservation). The sperm packages of vaejovids were the typical folded 
type, bent medially but also twisted along the length of the branches delimited by the anterior 
and posterior ends of the package (e.g., fig. 4D, E). 
Four subtypes of sperm package were observed in Bothriuridae: typical bent (single folded) 
(fig. 1A, D, E); among straight sperm packages there were straight (fig. 1E) and canelike shapes 
(fig. 1F); multiple-folded sperm packages were represented by annular or ringlike shapes (fig. 
1D). The canelike shape (fig. 1F) resembled the straight shape (fig. 1B) but with its anterior 
part bent 45°–90°. This was the most common type, observed in 35% of the exemplar species 
analyzed. Bent sperm packages were observed in 26% of the exemplar species, i.e., both species 
of Timogenes Simon, 1880, Vachonia martinezi Abalos, 1954, and some species of the nominal 
subgenus of Bothriurus. Annular sperm packages were also observed in the same taxa, but 
appeared to be more common in some species, e.g., Bothriurus inermis Maury, 1981, than 
others. 
Heteroscorpion goodmani Lourenço, 1996, the sole exemplar species of Heteroscorpionidae, 
possessed typical bent sperm packages. A few double-bent sperm packages were also observed 
in this species and appeared to be covered by a thin sheath (fig. 4G, H), as in the chactid, N. 
allenii (fig. 3E, F). 
Hemiscorpius lepturus Peters, 1861, the sole exemplar species of Hemiscorpiidae, was 
poorly preserved but possessed bent sperm packages and some double-bent and ellipsoidal 
sperm packages. The sperm packages appear to lack a covering sheath (fig. 4I). 
Mostly annular sperm packages were observed among the exemplar species of Hormuridae 
(fig. 4J–L). The annular sperm package appears to be achieved by coiling the straight package, 
and sometimes further twisting the ring into a lemniscate shape (fig. 4L). Exemplar species of 
Opisthacanthus Peters, 1861, also possessed ellipsoidal sperm packages, but the poor preserva-
tion of the material prevented their structure from being properly determined. 
The sperm packages of the two exemplar species of Urodacidae were ellipsoidal to almost 
spherical with a sheath (fig. 5A, B) that appeared to be much thicker than observed in Chacti-
dae (fig. 3E–K). 
Among the exemplar species of Diplocentridae, both bent and ellipsoidal sperm packages 
were observed in Diplocentrus lindo Stockwell, 2001 (fig. 5C) whereas only bent sperm pack-
2022 VRECH ET AL.: SCORPION SPERM PACKAGES 19
ages were observed in Nebo hierichonticus (Simon, 1872) (fig. 5D). The ellipsoidal shape of the 
sperm packages of D. lindo appears to be achieved by spiral coiling of the sperm package (fig. 
5C). No sheath was observed covering the spermatozoa in either of the diplocentrid 
exemplars. 
Among the exemplar species of Scorpionidae, Pandinus imperator (C.L. Koch, 1841) exhib-
ited straight (fig. 5E), and bent sperm packages (table 1), whereas Scorpio fuliginosus (Pallary, 
1928) exhibited ellipsoidal sperm packages (fig. 5F), along with some folded sperm packages. 
The material, particularly for P. imperator, was not well preserved. 
Diversity of Sperm Packages in Bothriuridae: All three exemplar species of Brachis-
tosternus Pocock, 1893, possessed straight sperm packages with a canelike shape (fig. 5G, H). 
The sperm packages of Brachistosternus angustimanus Ojanguren Affilastro and Roig Alsina, 
2001, were longer than those of the other two species (table 3). Narrower sperm packages were 
observed in some samples of B. ferrugineus. The same pattern was evident in the caraboctonid, 
Caraboctonus keyserlingi.
Lisposoma josehermana exhibited thick, straight sperm packages with a straight, pointed 
head (fig. 5I), unusually long, relative to the length of the sperm package. In most of the sperm 
packages, the anterior zone always appeared swollen, with the spermatozoa loosely arranged 
and separated from each other. The shape of this sperm package resembled that of the super-
stitioniid, Superstitionia donensis (fig. 3C). 
The sperm packages of Orobothriurus tamarugal Ochoa et al., 2011, were short, straight, 
and uniform from the head to the medial zone, tapering terminally (fig. 5J). These were the 
narrowest sperm packages of the family and, together with those of Phoniocercus pictus Pocock, 
1893, Rumikiru lourencoi (Ojanguren Affilastro, 2003), and Thestylus aurantiurus Yamaguti and 
Pinto-da-Rocha, 2003, among the shortest (table 3). The sperm packages of R. lourencoi were 
short and slender, with a long head relative to the length, tapering terminally (fig. 5K), as in 
O. tamarugal. The short, narrow sperm packages of T. aurantiurus were more uniform along 
their length than those of O. tamarugal and R. lourencoi, and not tapering as abruptly termi-
nally (fig. 5L). 
In all exemplar species of Urophonius Pocock, 1893, the head of the sperm package was angled 
45°–90° to the body (fig. 6A, B). The body of the sperm package tapered terminally. An undulated 
area was sometimes evident medially on the sperm package of U. brachycentrus (fig. 6B). 
The sperm packages of Cercophonius squama (Gervais, 1843) resembled those of P. pictus 
and Urophonius. The head zone was short and the head-body angle gentle (fig. 6C). Some 
sperm packages appeared to be single folded medially (table 2). The bending resembled that 
observed in other families, e.g., Vaejovidae, but the general shape was different as the sperm 
package was not uniform in width, and the head was angled approximately 90°, differing from 
the straight head zone associated with the folded sperm packages of other species in the 
family.
The general form of the sperm packages of P. pictus resembled those of C. squama and 
Urophonius, but the sperm packages of P. pictus were shorter (table 3), and the tips usually 
sharper (fig. 6D). 
20 AMERICAN MUSEUM NOVITATES NO. 3993
A B C
D E F
G H I
J K L
FIGURE 3. Sperm packages of Caraboctonidae Kraepelin, 1905 (A, B), Superstitioniidae Stahnke, 1940 (C), 
Chactidae Pocock, 1893 (D–K), and Troglotayosicidae Lourenco, 1998 (L) imaged with scanning electron 
microscopy (A–C, E–G, K) or light microscopy (D, H–J, L). A. Caraboctonus keyserlingi Pocock, 1893: 
straight. B. Hadruroides lunatus (L. Koch, 1867): straight. C. Superstitionia donensis Stahnke, 1940: straight. 
D, E. Nullibrotheas allenii (Wood, 1863): ellipsoidal, double bent. F, G. Brotheas sp., Bartica District, Guyana: 
ellipsoidal, double bent. H. Broteochactas nitidus Pocock, 1893: double bent. I. Chactopsoides anduzei 
(González-Sponga, 1982): double bent. J. Chactas aequinoctialis (Karsch, 1879): ellipsoidal, spherical. K. Teu-
thraustes sp., Aguay Province, Ecuador: ellipsoidal. L. Troglotayosicus humiculum Botero-Trujillo and Francke, 
2009: bent. Scale bars: 25 µm.
2022 VRECH ET AL.: SCORPION SPERM PACKAGES 21
A B C
D E F
G H I
J K L
FIGURE 4. Sperm packages of Chactidae Pocock, 1893 (A, B), Vaejovidae Thorell, 1876 (C–F), Heteroscor-
pionidae Kraepelin, 1905 (G, H), Hemiscorpiidae Pocock, 1893 (I), and Hormuridae Laurie, 1896 (J–L) 
imaged with scanning electron microscopy (A–J) or light microscopy (K, L). A, B. Uroctonus mordax Thorell, 
1876: bent. C, D. Paravaejovis spinigerus (Wood, 1863): bent. E. Graemeloweus glimmei (Hjelle, 1972): bent. 
F. Vejovoidus longiunguis (Williams, 1969): bent. G, H. Heteroscorpion goodmani Lourenco, 1996: bent/double 
bent. I. Hemiscorpius lepturus Peters, 1861: bent. J. Hadogenes troglodytes (Peters, 1861): annular. K, L. Hor-
murus sp., Queensland, Australia: annular, double bent. Scale bars: 25 µm.
22 AMERICAN MUSEUM NOVITATES NO. 3993
TABLE 3. Length (mean ± standard deviation, in µm) of sperm packages among exemplar species repre-
senting major groups of scorpions.
Suborder Superfamily Family Species Length
Buthida Buthoidea Buthidae Ananteris arcadioi 152 ± 19
Parabuthus granulatus 230 ± 28
Iurida Bothriuroidea Bothriuridae Bothriurus araguayae 199 ± 5
Bothriurus bocki 159 ± 5
Bothriurus bonariensis 249 ± 11
Bothriurus burmeisteri 287 ± 19
Bothriurus chacoensis 226 ± 11
Bothriurus cordubensis 302 ± 3
Bothriurus coriaceus 329 ± 7
Bothriurus flavidus 212 ± 23
Bothriurus keyserlingi 300 ± 14
Bothriurus noa 332 ± 16
Bothriurus olaen 328 ± 9
Bothriurus rochai 201 ± 33
Bothriurus rochensis 269 ± 15
Brachistosternus angustimanus 253 ± 1
Brachistosternus ferrugineus 233 ± 8
Brachistosternus pentheri 205 ± 13
Centromachetes obscurus 354 ± 10
Cercophonius squama 227 ± 20
Lisposoma josehermana 288 ± 8
Orobothriurus tamarugal 193 ± 5
Phoniocercus pictus 165 ± 6
Rumikiru lourencoi 158 ± 3
Tehuankea moyanoi 324 ± 6
Thestylus aurantiurus 162 ± 7
Timogenes dorbignyi 227 ± 14
Timogenes elegans 240 ± 17
Urophonius brachycentrus 311 ± 7
Urophonius tregualemuensis 264 ± 4
Vachonia martinezi 200 ± 9
Chactoidea Caraboctonidae Caraboctonus keyserlingi 323 ± 6
Chactidae Brotheas sp. 210 ± 8
Chactas aequinoctialis 144 ± 4
Chactopsoides anduzei 244 ± 6
Nullibrotheas allenii 231 ± 3
Teuthraustes sp. 246 ± 27
Uroctonus mordax 203 ± 9
2022 VRECH ET AL.: SCORPION SPERM PACKAGES 23
TABLE 3 continued
Suborder Superfamily Family Species Length
Iurida Chactoidea Euscorpiidae Megacormus gertschi 230 ± 2
Megacormus sp. 217 ± 4
Tetratrichobothrius flavicaudis 112 ± 5
Scorpiopidae Euscorpiops longimanus 166 ± 3
Scorpiops zubairi 193 ± 19
Troglocormus ciego 130 ± 17
Superstitioniidae Superstitionia donensis 231 ± 46
Troglotayosicidae Troglotayosicus humiculum 145 ± 3
Typhlochactidae Alacran tartarus 177 ± 21
Urodacidae Urodacus planimanus 282 ± 35
Vaejovidae Vaejovis mexicanus 160 ± 7
Vejovoidus longiunguis 187 ± 4
Iuroidea Iuridae Iurus dufoureius 335 ± 14
Scorpionoidea Diplocentridae Diplocentrus lindo 192 ± 7
Hemiscorpiidae Hemiscorpius lepturus 195 ± 12
Heteroscorpionidae Heteroscorpion goodmani 171 ± 14
Hormuridae Hormurus sp. 146 ± 4
Opisthacanthus capensis 151 ± 8
Scorpionidae Pandinus imperator 158 ± 8
      Scorpio fuliginosus 149 ± 4
The sperm packages of Tehuankea moyanoi Cekalovic, 1973, were longer than similar 
sperm packages in other bothriurids, gradually tapering terminally (fig. 6E). The heads of the 
sperm package were very short compared with the length, and a conspicuous angle was evident 
between the head and the body of the sperm package (fig. 6E). 
The sperm packages of the two exemplar species of Centromachetes Lönnberg, 1897, were 
long and uniformly straight, with a short head zone (fig. 6F). 
Among the 16 exemplar species of Bothriurus, the shapes of the sperm packages were 
diverse in some species groups and uniform in others. A marked difference was evident 
between the two subgenera. Straight sperm packages, taking the form of a cane, were common 
in subgenus Andibothriurus, comprising 50% of the exemplar species (table 2). Canelike sperm 
packages are straight, with the frontal part slightly bent at an angle greater than 90° from the 
body of the sperm package (fig. 1F). Sometimes, however, the anterior zone may also be straight 
(e.g., fig. 6G). This zone is wide and tapers terminally in the zone bearing the spermatozoa 
flagella. This canelike subtype of sperm package was observed only in Bothriuridae and mostly 
among exemplar species of Andibothriurus. Minor variation was observed in the length of 
canelike sperm packages, but the shape was generally similar among species. 
Exemplar species of the nominal subgenus Bothriurus displayed a wider variety of sperm 
packages than observed in Andibothriurus (e.g., fig. 6H, I). The sperm packages observed in 
24 AMERICAN MUSEUM NOVITATES NO. 3993
exemplar species of subgenus Bothriurus were straight and uniform in width along the entire 
length. These packages appeared annular or single folded in some species (fig. 6I). However, 
the packages of Bothriurus araguayae Vellard, 1934, were straight, with the zone of sperm heads 
long and markedly defined, compared with other species. Similarly, both Bothriurus bonariensis 
and Bothriurus chacoensis Maury and Acosta, 1993, possessed straight sperm packages (fig. 
6H), like those of B. araguayae, but slightly slenderer in B. chacoensis. Bothriurus bocki Krae-
pelin, 1911, and B. inermis displayed bent sperm packages, resembling those of other families 
(table 2; fig. 6I), together with some annular sperm packages, and straight sperm packages, as 
in B. araguayae. All three types of sperm packages (single folded, straight, and multiple folded) 
are commonly observed together in many species in which the single-folded sperm package is 
the most common type. Annular sperm packages, formed from multiple-folded sperm pack-
ages, were more abundant in B. inermis than other species in which both folding types were 
observed, and exhibited variation within individuals. 
The sperm packages of exemplar species of subgenus Bothriurus, i.e., Bothriurus asper 
Pocock, 1893, and Bothriurus rochai Mello-Leitão, 1932, were difficult to interpret due to poor 
preservation. These species appear to possess straight sperm packages, uniform in width along 
the entire length, like B. araguayae and B. bonariensis. The zone of the head of these sperm 
packages appeared to be short compared to the sperm packages of B. araguayae and B. bocki. 
Bothriurus asper exhibited aggregations that resemble straight sperm packages. The sperm 
packages of B. rochai were wider anteriorly than posteriorly, but the sperm heads could not be 
easily identified. 
The typical bent sperm package was abundant in both exemplar species of Timogenes (fig. 
6J). The width of the sperm package was uniform, and its head appeared to be long, as in 
Bothriurus araguayae. Two other types of sperm packages were also observed in Timogenes but 
were far less abundant than the typical folded sperm packages: annular sperm packages (fig. 
6K), resembling those of Bothriurus inermis, and straight sperm packages, resembling those of 
B. araguayae or the bonariensis group of Bothriurus. The sperm packages of Vachonia martinezi 
closely resembled the single-folded, bent sperm packages of Timogenes (fig. 6L). 
Analysis of Sperm Package Length across Scorpions: The mean length of the sperm 
packages of all exemplar species was 203.95 ± 56.54 µm. Species values are summarized in table 
3. The shortest sperm packages were observed among Euscorpiidae, e.g., Tetratrichobothrius 
flavicaudis (112 ± 5 µm), and Scorpiopidae, e.g., Troglocormus ciego (130 ± 17 µm). The longest 
sperm packages, observed in Bothriuridae, e.g., Centromachetes pocockii (Kraepelin, 1894) (354 
± 10 µm), were almost three times greater. 
Among all sampled species, straight sperm packages were longer than bent sperm pack-
ages, the only exception being the urodacid, Urodacus planimanus Pocock, 1893, the bent 
sperm package of which was similar in length to the straight sperm package of, e.g., Iuridae. 
Variation in the length of sperm packages, ranging from 143 µm to 223 µm (183 ± 40 µm), was 
observed among families with bent sperm packages (table 3). A one-way ANOVA confirmed 
a statistical difference in length among the species (F (11; 54) = 13.71, p << 0.001). Three groups 
were identified by the Tukey HSD test (fig. 7): U. planimanus (Urodacidae) with the greatest 
2022 VRECH ET AL.: SCORPION SPERM PACKAGES 25
mean value; an intermediate group including Alacran tartarus (Typhlochactidae); the smallest 
mean value in T. flavicaudis (Euscorpiidae). The longest sperm packages in the dataset, 
observed in Iuridae, were straight (table 3). 
Among Bothriuridae, straight, canelike sperm packages varied in length from 212 ± 2 µm 
(Bothriurus flavidus Kraepelin, 1911) to 332 ± 7 µm (Bothriurus noa Maury, 1984), and across 
the entire family, straight packages varied in length from 158 ± 3 µm (Rumikiru lourencoi) to 
354 ± 10 µm (Centromachetes obscurus Mello-Leitao, 1932) (table 3). Among straight sperm 
packages, the mean value of the exemplar species of this family was 254 ± 52 μm.
Counts of Spermatozoa per Sperm Package in Bothriuridae: Transmission electron 
microscopy of four species of Bothriuridae revealed that spermatozoa were clustered adjacent 
to one another and surrounded by an electrodense substance without a covering sheath (fig. 
8A–H). Sections at different levels along the sperm package indicated distinctive parts of indi-
vidual spermatozoa (fig. 8A–D). A section across the anterior part of the sperm package, the 
zone corresponding to the spermatozoa nucleus, appeared electrodense (fig. 8A, B). The 
arrangement of the mitochondria and disposition of the microtubules in the axoneme can be 
identified in the medial zone of the spermatozoa (fig. 8C). The flagellar zone reveals the 9 + 0 
arrangement of microtubules without a central pair (fig. 8D). 
Although spermatozoa are aligned in the sperm package, the alignment is imperfect at the 
ends, i.e., the zone of the nuclei and the zone bearing the flagella, where the sperm counts are 
always lower than the counts in the medial zone. This mismatch is consistent with the tapering 
of the sperm packages at either end (fig. 1). It is evident that only two mitochondria are present 
on either side of the axoneme in Bothriurus bonariensis (fig. 8E), unlike the other three species 
studied, in which three mitochondria are present (fig. 8F–H). 
The lowest count of spermatozoa, fewer than 100 spermatozoa per sperm package (96 ± 
16 spermatozoa), was observed in B. bonariensis (fig. 8E), compared with 244 ± 35 spermatozoa 
per sperm package in Timogenes elegans (fig. 8F), 260 ± 25 spermatozoa in Brachistosternus 
ferrugineus (fig. 8G), and 169 ± 19 spermatozoa in Urophonius brachycentrus (fig. 8H). Several 
electrodense drops, noticeable with optical microscopy and TEM, accompanied the sperm 
packages of U. brachycentrus (fig. 8H, I) but were not consistently observed in the other species. 
The droplets appear somewhat transparent and refringent using optical microscopy, suggesting 
a lipid, but their chemical composition is unknown.
In the four species assessed, the width of the sperm package is a function of the number 
of spermatozoa rather than their width, which is quite uniform. When comparing the numbers 
of spermatozoa and the size of the sperm package, there is a slight tendency for short sperm 
packages to contain more spermatozoa among the four species studied. However, this could 
not be tested statistically because of the small sample size.
DISCUSSION
Sperm Package Morphology: The general absence of sperm packages in Buthidae is well 
known (Cruz-Landim and Ferreira, 1973; Peretti and Battán-Horenstein, 2003; Michalik and 
26 AMERICAN MUSEUM NOVITATES NO. 3993
A B C
D E F
G H I
J         K L
FIGURE 5. Sperm packages of Urodacidae Pocock, 1893 (A, B), Diplocentridae Karsch, 1880 (C, D), Scorpi-
onidae Latreille, 1802 (E, F), and Bothriuridae Simon, 1880 (G–L) imaged with scanning electron microscopy 
(A–C, G, J) or light microscopy (D–F, H, I, K, L). A, B. Urodacus planimanus Pocock, 1893: ellipsoidal/
spherical. C. Diplocentrus lindo Stockwell and Baldwin, 2001: spiral/spherical. D. Nebo hierichonticus (Simon, 
1872): bent. E. Pandinus imperator (C.L. Koch, 1841): straight. F. Scorpio fuliginosus (Pallary, 1928): ellipsoidal. 
G. Brachistosternus ferrugineus (Thorell, 1876): canelike. H. Brachistosternus pentheri Mello-Leitão, 1931: cane-
like. I. Lisposoma josehermana Lamoral, 1979: straight. J. Orobothriurus tamarugal Ochoa et al., 2011: straight. 
K. Rumikiru lourencoi (Ojanguren Affilastro, 2003): straight. L. Thestylus aurantiurus Yamaguti and Pinto-da-
Rocha, 2003: straight. Scale bars: 25 µm.
2022 VRECH ET AL.: SCORPION SPERM PACKAGES 27
A B C
D E F
G H I
J K L
FIGURE 6. Sperm packages of Bothriuridae Simon, 1880 imaged with light microscopy (A–C, H, I, L) and 
scanning electron microscopy (D–G, K). A. Urophonius tregualemuensis Cekalovic, 1981: canelike. B. Uro-
phonius brachycentrus (Thorell, 1876): canelike. C. Cercophonius squama (Gervais, 1843): canelike. D. Pho-
niocercus pictus Pocock, 1893: canelike. E. Tehuankea moyanoi Cekalovic, 1973: canelike. F. Centromachetes 
pocockii (Kraepelin, 1894): straight. G. Bothriurus cordubensis Acosta, 1995: canelike. H. Bothriurus bonarien-
sis (C.L. Koch, 1842): canelike. I. Bothriurus bocki Kraepelin, 1911: bent. J, K. Timogenes elegans (Mello-Leitão, 
1931): bent, annular. L. Vachonia martinezi Abalos, 1954: bent. Scale bars: 25 µm.
28 AMERICAN MUSEUM NOVITATES NO. 3993
d
350
300
c, d
250 b, c
b, c
b b, c a, b
200 a, b
a, b a, b
a, b
150
a
100
 .
us do is us ni sp or iri ns m s us
tarr s l
in au
d ur a s rat
u
pt m u b
a a lu n n
ta ru ic  le od u
r pe  zu  el
eg icu a ica
n nt lav s go rm  im ps
m
a e f iu  o s o es  hu
m nia e
x
r c  p n H i n l  m
lac ipl
o
riu
s
co
r
rpi
o
din
u rp e s  p is
A D is o n c
o og icu us jovs c e
bo
th
em s
c Pa S Tim o
H ro ota
y od
a Va
hoc et
e gl Ur
atr
i H Tro
tr
Te
Exemplar Species with Bent Sperm Packages
FIGURE 7. Boxplot of Tukey HSD test illustrating three major length types (a–c) of single folded sperm pack-
ages in Scorpiones. Representatives of the three groups in boldface (see text).
Mercati, 2010; Peretti, 2010; Vrech et al., 2011; but see Alberti, 1983). For example, Peretti and 
Battán-Horenstein (2003) reported the absence of sperm conjugation in Zabius fuscus (Thorell, 
1876) and suggested a hypothesis, concerning a difference in sperm transfer between Buthidae 
and Bothriuridae, which could account for the absence or presence of sperm packages, respec-
tively. Insemination is faster in buthids than bothriurids, hence sperm do not need to be 
grouped together, suggesting that the purpose of sperm conjugation in scorpions is to maintain 
the viability of spermatozoa during sperm transfer. Although Vignoli et al. (2008) and Michalik 
and Mercati (2010) described the sperm packages of Buthidae as loosely clustered sperm cells 
or loose bundles, Vrech et al. (2011) formalized the character state of Buthidae as the absence 
of sperm packages and reported it also in Chaerilidae. The general absence of sperm conjuga-
tion in both families was confirmed in the present investigation (table 2). The basal phyloge-
netic position of these families (Prendini and Wheeler, 2005; Prendini et al. 2006) supports the 
hypothesis that free spermatozoa represent the plesiomorphic state in scorpions (Vignoli et al., 
2008; Michalik and Mercati, 2010; Vrech et al., 2011). This claim is also supported by the fact 
Sperm Package Total Length (μm)
2022 VRECH ET AL.: SCORPION SPERM PACKAGES 29
that there are no sperm packages or bundles of spermatozoa in arachnid orders closely related 
to the order Scorpiones (Lozano-Fernandez et al., 2019; Howard et al., 2020).
Nevertheless, it is important to note that some kind of sperm gathering, or conjugation, 
was observed in three exemplar species of Buthidae in the present study: Ananteris arcadioi, 
Parabuthus granulatus, and Pseudolychas ochraceus. The spermatozoa of these taxa appeared to 
be loosely aggregated, creating the appearance of sperm packages less tightly grouped than in 
other, nonbuthid taxa. Although it is possible that these cases are artifactual, this seems unlikely, 
especially as the two African taxa are known to be phylogenetically related, and some recon-
structions have suggested a relationship to the South American genus Ananteris Thorell, 1891 
(Coddington et al., 2004; Prendini, 2004). It is important to note that ordered structures, i.e., 
conjugated spermatozoa, are seldom observed in Buthidae, and such structures are unlikely to 
arise by chance. Besides, sperm conjugation was already reported in another buthid, Buthus 
occitanus, using the more general term, sperm bundle, with sperm heads embedded in an 
electrodense substance that may give consistency to the structure (Alberti, 1983). Unfortu-
nately, sperm conjugates were not described in more detail, nor was an illustration of the sperm 
package or bundle provided, preventing a determination as to whether the conjugation noted 
by Alberti (1983) resembles those observed in the present study. In conclusion, whereas the 
absence of sperm conjugation is typical in Buthida, at least based on the exemplar species of 
Buthidae and Chaerilidae studied to date (table 2), the presence of conjugation in some taxa 
should not be disregarded. Further investigation, including a broader sample of taxa in both 
families, may reveal additional examples of conjugation in Buthida. 
Conjugation is assumed to be absent in Pseudochactidae, given its close phylogenetic relation-
ship to Chaerilidae (Prendini et al., 2006, 2021). Unfortunately, this could not be verified in the 
pseudochactid exemplar species, Troglokhammouanus steineri, as the seminal vesicle could not be 
located in its greatly reduced genitalia, which are markedly different from those of other scorpions 
(Prendini et al., 2006, 2021). Further investigation of the genitalia and sperm structure of this family 
are important to formulate a more precise hypothesis of sperm package evolution in scorpions. 
The present study revealed that sperm conjugation is ubiquitous in Iurida, the group com-
prising all other nonbuthid scorpion families, although marked differences are evident among 
some. Bent sperm packages were observed in most families (table 2), consistent with the obser-
vations of Michalik and Mercati (2010). The present investigation also supports the evolution-
ary transformation from free spermatozoa via straight sperm packages to single-folded and 
ultimately multiple-folded sperm packages, following successive folding events (Vignoli et al., 
2008; Vrech et al., 2011). 
The first conclusive evidence is presented of sperm packages that evolved a sheath or cap-
sule covering the entire conjugate. Previous studies suggested sperm packages generally lack a 
sheath (Vignoli et al., 2008; Michalik and Mercati, 2010; Vrech et al., 2011), the only exceptions 
being an observation in the euscorpiid Euscorpius sicanus (Michalik and Mercati, 2010) and 
the bothriurid taxa studied by Peretti and Battán-Horenstein (2003). The present study revealed 
the absence of any kind of sheath in Bothriuridae and the presence of a true sheath in five 
families (Chactidae, Euscorpiidae, Heteroscorpionidae, Scorpiopidae, and Urodacidae) from 
30 AMERICAN MUSEUM NOVITATES NO. 3993
A B C
axo
h
f miit
n
mp
D E F
axo
G H I
FIGURE 8. Transmission electron micrographs of spermatozoa from sperm packages of the bothriurid, Both-
riurus bonariensis (C.L. Koch, 1842), sectioned at different points along an axis (A–D), and of sperm packages 
of four species of Bothriuridae Simon, 1880 sectioned in the middle (E–H). A. Head, middle piece, and flagella 
of different sperm packages. B. Nuclei of heads from different spermatozoa. C. Middle piece of different 
spermatozoa with paired mitochondria. D. Flagella of different spermatozoa. E. Bothriurus bonariensis. F. 
Timogenes elegans (Mello-Leitão, 1931). G. Brachistosternus ferrugineus (Thorell, 1876). H, I. Urophonius 
brachycentrus (Thorell, 1876). Inset in E–H illustrates details of axoneme. Abbreviations: axo, axoneme; f, 
flagellum; h, head; mit, mitochondria; mp, middle piece; n, nucleus. Scale bars: 0.5 µm (A–D); 2.5 µm (E–H).
two superfamilies, suggesting this character arose independently on multiple occasions. This 
may also be suggested for the single-folded sperm packages, which appear to have evolved 
independently in different taxa. For example, the bent shape observed in some Bothriurus, 
Timogenes, and Vachonia, relatively distal taxa within Bothriuridae (Prendini, 2003; Mattoni 
and Prendini, 2007), is very similar to the shapes observed in other distantly related families 
like Scorpionidae and Vaejovidae. 
Despite the apparently high levels of convergence, sperm package morphology is poten-
tially informative for scorpion systematics, as noted by others (Vignoli et al., 2008; Michalik 
and Mercati, 2010; Vrech et al., 2011). For example, sperm packages suggest that Bothriurus 
may not be monophyletic (Vrech et al., 2011), in agreement with previous studies based on 
2022 VRECH ET AL.: SCORPION SPERM PACKAGES 31
other characters (Prendini, 2000, 2003; Mattoni, 2003; Mattoni and Prendini, 2007). Three 
species groups are identified in Bothriurus based on sperm package morphology. The first 
group includes species of the nominal subgenus with straight sperm packages, such as B. ara-
guayae, B. bonariensis, and B. chacoensis; the second includes species of the nominal subgenus 
with folded sperm packages similar to Timogenes and Vachonia, such as B. bocki, and B. iner-
mis; and the third includes the species of subgenus Andibothriurus, characterized by canelike 
sperm packages. Preliminary analyses by Vrech et al. (2011) suggested the absence of sperm 
packages in some Bothriurus species, i.e., B. asper and species of the rochai group. During the 
present investigation, however, the presence of sperm packages was verified in these species 
(table 2), albeit with difficulty due to poor preservation of the material examined. Preservation 
is evidently important for the successful study of sperm packages. 
Sperm Package Metrics: Considerable variation in the length of the sperm packages was 
observed across the order and in the family Bothriuridae. Bent sperm packages were not neces-
sarily longer than straight sperm packages, suggesting that folding of the sperm package is 
independent of length, and that long sperm packages can be successfully transferred without 
folding. Chactidae and Urodacidae, in which long sperm packages were folded at least once, 
sometimes with the presence of a sheath rendering them even more compact, were notable 
exceptions. An overestimation of the total length of the sperm packages of Chactidae could not 
be disregarded due to the complexity of the folding, however. Although the length of a sperm 
package does not appear to induce folding, as some of the longest sperm packages were 
observed in taxa with straight sperm packages, folded sperm packages appear to be more easily 
transferred through the male genital tract (Vrech et al., 2011). Similarly, some insects, including 
fruit flies of the genus Drosophila Fallén, 1823, produce coiled sperm bundles that facilitate 
sperm transport through the testes (Mojica and Bruck, 1996). Sperm package length resembles 
sperm length except in extremely coiled structures. Sperm length in insects may be related 
either to sexual selection (Gage, 1994; Morrow and Gage, 2000; Pitnick et al., 2009) or to 
allometry and its relationship with male body size (Gage, 1994; Pitnick, 1996; Pitnick et al., 
2009; Vrech et al., 2014). Also, sperm length is highly correlated with the female inner repro-
ductive structures in some insect taxa (Pitnick et al., 2009; Higginson and Pitnick, 2011). 
Several studies of insects suggest a correlation between sperm length or sperm bundles and 
sperm storage or associated structures of the female (Sasakawa, 2007; Pitnick et al., 2009). Although 
such relationships have not yet been investigated in scorpions, it is noteworthy that sperm packages 
disaggregate inside the female genital tract, hence interactions with the female reproductive struc-
tures would involve only individual spermatozoa (Peretti and Battán-Horenstein, 2003). 
Transmission electron microscopy indicated material of unknown chemical composition, 
binding the spermatozoa together (fig. 8). The spatial organization of the spermatozoa revealed 
that individual spermatozoa were aligned in the same direction. Although imperfect, the align-
ment allowed the length of the spermatozoa to be estimated precisely from the length of the 
sperm package (Peretti, 2010). 
Axonemal organization in four exemplar species of Bothriuridae, Bothriurus bonariensis, Bra-
chistosternus ferrugineus, Timogenes elegans, and Urophonius brachycentrus, was consistent with the 
32 AMERICAN MUSEUM NOVITATES NO. 3993
9 + 0 pattern described for other Iurida by Michalik and Mercati (2010). This pattern differs from 
the 9 + 2 axonemal pattern observed in Buthidae (Michalik and Mercati, 2010; but see Hood et al., 
1972), which is the most common pattern among animals (Mitchell, 2004; Pitnick et al., 2009), and 
is therefore assumed to be the plesiomorphic state in scorpions (Michalik and Mercati, 2010).
Counts of spermatozoa in the sperm packages were generally consistent with the 2n × 4 for-
mula where n is the number of premeiotic mitotic divisions (Higginson and Pitnick, 2011) or any 
of its modifications (Virkki, 1969; Phillips, 1970; Sivinski, 1980; Jurečić, 1988; Schiff et al., 2001; 
Dias et al., 2013). Brachistosternus ferrugineus and Timogenes elegans appear to conform with 
counts close to 256, implying almost six premeiotic mitotic divisions to form the sperm package 
(26 × 4 = 256). However, the counts were less precise in other species, e.g., Bothriurus bonariensis, 
with close to 128 spermatozoa, implying approximately five mitotic and two meiotic processes 
(27 = 128), but usually fewer than 100 spermatozoa, and Urophonius brachycentrus, with counts 
between 128 and 256 spermatozoa. It is not uncommon for some species to present an intermedi-
ate or slightly variable count of spermatozoa (Nur, 1962; Schärer et al., 2008; Higginson and 
Pitnick, 2011). The counts of spermatozoa for bothriurids obtained in the present study were 
generally greater than those for bothriurids cited by Peretti and Battán-Horenstein (2003) but 
similar to those for scorpionids cited by Michalik and Mercati (2010). 
Hypotheses for the Evolution and Function of Sperm Conjugation: A new 
hypothesis is proposed herein for the origin of sperm packages. Based on the arachnid phy-
logeny (Lozano-Fernandez et al., 2019; Howard et al., 2020), free sperm would be the plesio-
morphic state in scorpions. A change in spermiogenesis would have caused individual 
spermatozoa to cluster together as conjugated sperm instead of separating into free spermato-
zoa as in the families of Buthida (Buthidae, Chaerilidae, and presumably, Pseudochactidae). 
Sperm would have become loosely aggregated into bundles in some Buthidae. Apparent con-
jugation of sperm in buthids like Parabuthus granulatus would represent convergence, assum-
ing it represents true conjugation. Conjugation of spermatozoa would have initially produced 
single-folded bent sperm packages instead of straight sperm packages, accounting for their 
widespread presence in Iurida. These bent sperm packages could subsequently evolve in two 
directions, either unfolding to produce straight sperm packages or continuing to fold multiple 
times, producing ellipsoidal, spherical, or annular sperm packages. Straight sperm packages 
appear to have evolved independently at least four times, in Iuridae, Caraboctonidae, Bothri-
uridae, and Superstitioniidae. The canelike sperm packages of some Bothriurus are presumably 
derived from straight sperm packages, which appears to be the plesiomorphic state in Bothri-
uridae. The annular and multiple-folded sperm packages appear to be autapomorphic or syn-
apomorphic for particular taxa, e.g., annular in Bothriurus inermis and Hormurus sp., or 
multiple folded in Megacormus, Troglocormus and some Chactidae. The hypothesized evolu-
tionary transformation series of sperm package shape is summarized in figure 9. 
The change in spermiogenesis that allowed individual spermatozoa to remain together 
could have been adaptive or nonadaptive, derived from cyst cells failing to individualize their 
products (Higginson and Pitnick, 2011; Burnett and Heinze, 2014), raising the question as to 
why sperm conjugation arose? This question has been repeatedly asked, and some current 
2022 VRECH ET AL.: SCORPION SPERM PACKAGES 33
hypotheses were reviewed by Pitnick et al. (2009) and Higginson and Pitnick (2011). Although 
data remain limited, three hypotheses may be suggested to account for the occurrence of sperm 
conjugation in scorpions:
(1) Sperm transport and movement: According to the classical hypothesis, sperm conjuga-
tion facilitates sperm transport (Mojica and Bruck, 1996, Pitnick et al., 2009; Higginson, 2011; 
Higginson and Pitnick, 2011; Gage, 2012; Higginson and Henn, 2012). This may be true in 
scorpions as spermatozoa are long and conjugation may aid transport. Perhaps the widespread 
presence of single-folded sperm packages and the appearance of multiple folded sperm pack-
ages resulted from a selective advantage to enhancing sperm transfer by males (Vrech, 2011), 
facilitating insemination and avoiding stagnation. It has been suggested that sperm packages 
with increased compression, caused by folding, would be easier to transfer (Michalik and Mer-
cati, 2010; Vrech et al., 2011). Studies of insects suggest the interaction between spermatozoa 
and the male genital tract favors bending in sperm aggregates (Mojica and Bruck, 1996, 2003; 
Joly et al., 2003; Joly et al., 2008), especially for the transport of long sperm groups (sperm 
bundles) through the testes, a hypothesis supported by Bruck (1978) and Virkki and Bruck 
(1994). The present study suggests that folding is maximized in ellipsoidal sperm packages, 
with the compression reinforced by the addition of a sheath covering the spermatozoa. 
It has also been suggested that sperm packages could be related to the type of spermato-
phore (Peretti and Battán-Horenstein, 2003), the structure used by scorpions to indirectly 
transfer sperm to the female (Francke, 1979). Sperm packages are mostly absent in Buthida 
(Buthidae, Chaerilidae and Pseudochactidae), in which the spermatophores are rather simple, 
whereas sperm packages are present in Iurida, in which the spermatophores are more complex 
(Francke, 1979; Monod et al., 2017). The simple flagelliform spermatophores of Buthidae trans-
fer sperm more rapidly than the complex lamelliform spermatophores of Bothriuridae (Peretti 
and Battán-Horenstein, 2003). As such, the correlation between the presence or absence of 
sperm packages and the complexity of the spermatophore may be related to the time required 
for insemination. Sperm packages may provide a measure of protection for sperm during the 
additional time required for transfer to the female genital atrium. 
Related to sperm transport is the hypothesis of sperm cooperation in which the sperma-
tozoa work together to enhance motility and strength of movement (Pitnick et al., 2009). Both-
riurid spermatozoa show movement that allows separation from one another on contact with 
saline solution (Peretti and Battán-Horenstein, 2003), but there is no direct evidence for active 
directional movement of sperm packages, at least in vitro. Indeed, movement to the female 
genital tract is passive, aided by spermatophore action. The sperm package could be viewed as 
a mechanism for transporting spermatozoa in an inactive state (Alberti, 1983), preventing the 
active movement of spermatozoa across the walls of the male genital tract as happens in some 
insects (Werner and Simmons, 2008) and resembling the sperm bundles of others (Robison, 
1966; Ross and Robison, 1969; Nur, 1962). There is no evidence of spermatozoa cooperation 
to enhance swimming in scorpions, as suggested for insects (Werner and Simmons, 2008; 
Pitnick et al., 2009). Spermatozoa grouped inside a sperm conjugation could dissociate inside 
the female’s storage or fertilization tracts (Higginson and Pitnick, 2011) but there is evidence 
34 AMERICAN MUSEUM NOVITATES NO. 3993
that sperm dissociate before entry in some taxa (Buckland-Nicks et al., 1999; Hayashi and 
Kamimura, 2002a, 2002b). Studies of scorpions suggest this may be the mechanism as the 
spermatozoa appear to be dissociated prior to entering the female spermathecae (Peretti and 
Battán-Horenstein, 2003; Althaus et al., 2010). Perhaps the spermatozoa become active once 
freed inside the female genital tract, as suggested by Alberti (1983) and Althaus et al. (2010). 
(2) Sexual selection: Sperm conjugation may also enhance fertilization success. By enhanc-
ing the swimming capabilities of individual spermatozoa, sperm conjugation may aid sperm 
competition (Simmons, 2001; Pitnick et al., 2009). This may not be the only benefit of sperm 
conjugation, which is sexually selected, however. Females may evaluate and favor some males 
by exerting cryptic female choice on their sperm packages (Eberhard, 1996; Peretti and Aisen-
berg, 2015). Sperm length correlates with the length of the female genital tract in many taxa 
of vertebrates and invertebrates (Cummins and Woodall, 1985; Briskie and Montgomerie, 1992, 
1993, Simmons, 2001; Pitnick et al., 2009). Females may also favor larger sperm packages (Hig-
ginson and Pitnick, 2011). For example, in carabid beetles, sperm conjugate size correlates 
positively with spermathecal length (Sasakawa, 2007). Sperm conjugation could represent a 
mechanism to increase size with minimal energy expenditure (Higginson and Pitnick, 2011). 
Besides, males may use conjugation to compactly transfer more sperm in an environment with 
sperm competition. As such, sperm packages may offer a means to transfer more sperm with-
out producing larger sperm (Higginson and Pitnick, 2011). 
Males of the caraboctonid, Caraboctonus keyserlingi, produce large sperm packages stored 
inside seminal vesicles, so large that the hemispermatophores are sometimes difficult to find 
(unpubl. data); the spermathecae of females are similarly enormous compared to other scorpion 
taxa (Volschenk et al., 2008). The almost negligible volume of sperm contained in the spermato-
phore compared to what is stored in the seminal vesicle suggests male C. keyserlingi may copulate 
repeatedly which, together with the presence of large sperm packages, and polymorphism, with 
broad and slender packages in the same individual (Vrech et al., 2011, 2014), are indicative of 
alternative strategies related to high levels of sperm competition as observed in insects (Simmons, 
2001; Shuker and Simmons, 2014; Pitnick et al., 2009; Higginson and Pitnick, 2011).
Data presented herein demonstrate that short sperm packages tend to contain more sper-
matozoa among four exemplar species of Bothriuridae. Although only a few species were com-
pared, this observation suggests a direct trade-off between the length of spermatozoa and the 
number of spermatozoa contained in a sperm package (Pitnick, 1996; Oppliger et al., 1998; 
Gage and Morrow, 2003; Pitnick et al., 2009). Assuming sperm packages are affected by sperm 
competition, such a trade-off might be expected as suggested by classical models (Parker et al., 
2010). Some studies on insects assessed the relationship between the count of spermatozoa per 
sperm bundle and the phylogenetic position of the taxon (White, 1955; Virkki, 1969; Jurečić, 
1988; Schiff et al., 2001). These studies suggest that species placed relatively basal in the phy-
logeny possessed a greater number of spermatozoa per sperm bundle. The few scorpion species 
assessed in the present study are consistent with this pattern, except for Timogenes elegans. 
However, further investigation with more exemplar species is needed to test this hypothesis 
more rigorously in scorpions. 
2022 VRECH ET AL.: SCORPION SPERM PACKAGES 35
free or loosely 
aggregated sperm
straight single folded
A B
bent
fusiform
half fold
straight
multiple folds
C
ellipsoidal double bent annular
canelike
double parallel roll fold/ open gatefold twisted ringlike
fold spiral
FIGURE 9. Schematic illustration summarizing the major types, shapes, and folding of sperm packages in 
Scorpiones with hypothesized evolutionary transformation from absence (free sperm), e.g., Buthida Soleglad 
and Fet 2003: A. Straight: fusiform, e.g., Parabuthus granulatus (Ehrenberg, 1831) (Buthidae C.L. Koch, 1837); 
straight, e.g., Iuridae Thorell, 1876, and Superstitioniidae Stahnke, 1940; or canelike, e.g., Bothriuridae Simon, 
1880. B. Single fold: bent in half, e.g., Vaejovidae Thorell, 1876, Timogenes and Vachonia Abalos, 1954 (Both-
riuridae). C. Multiple folds: ellipsoidal: double parallel fold, e.g., Tetratrichobothrius flavicaudis (De Geer, 
1778), Nullibrotheas allenii (Wood, 1863); spiral, e.g., Euscorpiops longimanus (Pocock, 1893); double bent 
open gatefold, e.g., Broteochactas Pocock, 1893; annular: twisted, e.g., Hormuridae Laurie, 1896; or ringlike, 
e.g., Bothriurus Peters, 1861, and Timogenes Simon, 1880 (Bothriuridae). 
36 AMERICAN MUSEUM NOVITATES NO. 3993
Sperm packages may also assist with avoiding sperm competition in some scorpion taxa. 
For example, sperm packages serve two functions in the euscorpiid Euscorpius italicus (Althaus 
et al., 2010). In addition to their primary function in assisting with fertilization, sperm pack-
ages, together with ejaculate coagulates, form a genital plug in the female genital orifice. Genital 
plugs are structures of variable composition that reduce sperm competition by preventing the 
female from remating (Chapman et al., 2003; Shuker and Simmons, 2014). Although wide-
spread among animals (Shine et al., 2000), genital plugs are rarely composed mainly of sperm. 
The genital plugs of scorpions may comprise spermatophore structures (Mattoni and Peretti, 
2004; Contreras-Garduño et al., 2006), ejaculate substances (Castelvetri and Peretti, 1999), a 
mixture of both (Mattoni and Peretti, 2004), or a combination of substances from the male and 
female (Oviedo-Diego et al., 2020). In E. italicus, however, sperm forms a permanent hard 
structure (Althaus et al., 2010) that appears to be effective in restraining female mating, as 
females appear to mate only once (Benton, 1992). 
(3) Protection from harsh environments: Sperm conjugation may provide physical pro-
tection against unfavorable environments and may assist molecular exchange among sperm 
cells. Preliminary observations of sperm viability in scorpions suggest that grouping may 
aid in retaining the viability of spermatozoa for a longer period (unpubl. data). Spermato-
zoa on the external surface of the sperm package may shield spermatozoa inside, helping 
the great majority of spermatozoa to remain viable until reaching the female genital tract 
or specific sites inside it. Such sperm cooperation or altruism has been described in other 
taxa such as insects, rodents, or mollusks (Pizzari and Parker, 2009). Sperm conjugation 
may also assist in avoiding premature acrosome reactions and maintain the integrity of 
most of the spermatozoa (Pitnick et al., 2009; Higginson and Pitnick, 2011). Additionally, 
the impact of forces associated with the mechanical action of a lamelliform spermatophore, 
which could be detrimental to isolated spermatozoa, may be lessened by their occurrence 
within the supportive framework of a sperm package. This hypothesis also awaits more 
rigorous scrutiny. 
In addition to potentially improving sperm transfer, the presence of a covering sheath gives 
the sperm package additional protection against potentially harmful agents, which spermato-
zoa could encounter immediately upon immediate entry to the female genital tract after insem-
ination (Pitnick et al., 2009). The presence of a protective cover to encapsulate sperm is common 
in other arachnids such as spiders, mites, and solifuges (Alberti, 2000; Klann et al., 2005; 
Michalik and Ramírez, 2014). Sperm conjugation in spiders is characterized by capsules that 
protect the sperm inside. Such capsules, also observed in some solifuges, such as Galeodidae 
Sundevall, 1833, are termed coenospermia (Klann et al., 2005; Michalik and Ramírez, 2014). 
The female genital tract of spiders is considered unfavorable for sperm viability, so the protec-
tion of a capsule is a useful protective trait (Michalik and Lipke, 2013). From this point of view, 
sperm protection appears to avoid sexual conflict (Birkhead et al. 1993; Birkhead and Møller, 
1993). Little is known about this aspect in scorpions, however. 
Finally, the presence of a sheath could confer auxiliary protection from environmental 
factors other than those directly related to sexual conflict that also decrease the viability of 
2022 VRECH ET AL.: SCORPION SPERM PACKAGES 37
spermatozoa, such as water loss during deposition inside the spermatophore, indirect transfer, 
or similar factors (Peretti and Battán-Horenstein, 2003; Peretti, 2010; Michalik and Ramírez, 
2014; Cargnelutti et al., 2019). Further investigation is needed into the mechanisms by means 
of which sperm packages may confer protection to spermatozoa.
CONCLUSIONS
The present study surveyed sperm packages in the largest taxon sample of scorpions to 
date, along with a comprehensive sample representing most genera of Bothriuridae. Data from 
classical morphometry were combined with qualitative assessments of shape to enable the 
identification of general patterns across the order. Despite the morphological diversity of sperm 
packages, single-folded sperm packages are the most common form. Basal scorpion lineages 
lack sperm packages or present loosely aggregated forms, and some taxa independently devel-
oped sheaths covering the sperm packages. In addition to being phylogenetically informative, 
sperm packages enhance the understanding of spermatozoa production, storage, and transfer 
in scorpions. Future research should investigate and describe the sperm packages of additional 
taxa, analyze the ultrastructure of sperm packages, and further investigate the evolutionary role 
of sperm packages from the perspectives of reproductive strategies and sexual selection. 
ACKNOWLEDGMENTS
D.E.V. thanks FONCyT (Argentina) for financial support; the AMNH Richard Gilder 
Graduate School for a Collections Study Grant to visit the AMNH; Martín Ramírez and Matías 
Izquierdo for assistance with a preliminary SEM analysis at the MACN; Ruth Salas and the 
team at the AMNH Microscopy and Imaging Facility for assistance with fixing material, SEM, 
and optical microscopy; Edmundo González-Santillán and Ofelia Delgado-Hernández for 
assistance and support in New York; Cristina Maldonado, Jorge Mukdsi, and their staff for 
helping with TEM analysis in the Centro de Microscopía Electrónica (FCM, UNC) imaging 
facility; Ricardo Botero-Trujillo, Stephanie F. Loria and two anonymous reviewers for critical 
comments on the manuscript. Aspects of this research were supported by the following grants 
from the U.S. National Science Foundation to L.P.: EAR 0228699, DEB 0413453 and DEB 
1655050. Further support to D.E.V., A.V.P. and C.I.M. was provided by SECyT-UNC, FONCyT, 
PIP CONICET (Argentina). 
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44 AMERICAN MUSEUM NOVITATES NO. 3993
APPENDIX 1
Material Examined for Study of Sperm Packages in the Order 
Scorpiones C.L. Koch, 1850
Abbreviations for natural history collections as follows: AMNH, American Museum of 
Natural History, New York; AVP, Alfredo V. Peretti Private Collection, Universidad de Cór-
doba, Argentina; CAS, California Academy of Sciences, San Francisco, CA; CIM, Camilo I. 
Mattoni Private Collection, Universidad de Córdoba, Argentina; DEV, David E. Vrech Private 
Collection, Universidad de Córdoba, Argentina; IBSP, Instituto Butantan, São Paulo, Brazil; 
MACN, Museo Argentino de Ciencias Naturales Bernardino Rivadavia, Buenos Aires, Argen-
tina; MCZ, Museum of Comparative Zoology, Harvard University, Cambridge, MA; MPUJ, 
Museo Javeriano de Historia Natural “Lorenzo Uribe S. J.,” Pontificia Universidad Javeriana, 
Bogotá, Colombia; MZUSP, Museu de Zoología da Universidade de São Paulo, Brazil; MZUC, 
Museo de Zoología, Universidad de Concepción, Chile; UFBA, Universidade Federal da Bahía, 
Salvador da Bahía, Brazil; ZMB, Museum für Naturkunde, Berlin, Germany.
Family Bothriuridae Simon, 1880
Bothriurus araguayae Vellard, 1934: BRAZIL: São Paulo: Estaçao Ecológica de Itirapina, Itirapina, 12.
ix.2000, G. Machado, 10 ♂ (CIM). 
Bothriurus asper Pocock, 1893: BRAZIL: Bahía: 5 ♂ (UFBA).
Bothriurus bocki Kraepelin, 1911: BOLIVIA: Potosí Department: Mojotorillo, 5 km E of Betanzos, 
19°34′40.9″S 65°24′57.9″W, 3217 m, 9.i.2005, C. Mattoni, A. Ojanguren and J. Ochoa, 1 ♂ (CIM).
Bothriurus bonariensis (C.L. Koch, 1842): ARGENTINA: Córdoba Province: Córdoba, 2 ♂ (AVP), Men-
diolaza, 1 ♂ (DEV). URUGUAY: Rivera Department: Route 30 km 233, ca. 100 km SE of Artigas, 
01°08′25.629″S 55°55′11.28″W, 345 m, 13.xii.2005, C. Mattoni, A. Ojanguren and F. Labarque, 2 
♂(CIM). 
Bothriurus burmeisteri Kraepelin, 1894: ARGENTINA: 1 ♂ (AVP). Mendoza Province: Reserva Natural 
Bosque Telteca, 32°22.967′S 68°03.309′W, 580 m, 19.xi.2003, C. Mattoni, J. Ochoa and L. Prendini, 
3 ♂ (CIM). 
Bothriurus chacoensis Maury and Acosta, 1993: ARGENTINA: Córdoba Province: Córdoba, 3 ♂ (AVP). 
Bothriurus cordubensis Acosta, 1995: ARGENTINA: Córdoba Province: Córdoba, 4 ♂ (AVP).
Bothriurus coriaceus Pocock, 1893: CHILE: Región IV (Coquimbo): Limarí Province: Parque Nacional 
Fray Jorge, hillside below Bosque Fray Jorge, 30°39.124′S 71°40.645′W, 500 m, 4.xi.2003, L. Pren-
dini, C. Mattoni and J. Ochoa, 4 ♂ (CIM).
Bothriurus flavidus Kraepelin, 1911: ARGENTINA: Córdoba Province: Córdoba, 2 ♂ (AVP); Pampa de 
Olaen, Capilla de Olaen, ca. 11 km W of Molinari, 31°09′44.46″S 64°36′24.336″W, 1096 m, 29.
xii.2005, C. Mattoni, A. Peretti, P. Carreras, M. Zerda and D. Vrech, 4 ♂ (AVP).
Bothriurus inermis Maury, 1981: BRAZIL: Rondônia: Km 53 on BR 364, 8.xi.1985, 1 ♂ (MZUSP 18995).
Bothriurus keyserlingi Pocock, 1893: CHILE: Región V (Valparaíso): Quillota Province: Parque Nacional 
La Campana, Palmas de Ocoa, Sendero Quillay trail from campsite, 32°56.048′S 71°04.562′W, 494 
m, L. Prendini, C. Mattoni and J. Ochoa, 12.xi.2003, 1 ♂ (CIM). 
2022 VRECH ET AL.: SCORPION SPERM PACKAGES 45
Bothriurus noa Maury, 1984: ARGENTINA: La Rioja: El Cantadero, 16 km from La Rioja, 27.xi.1994, 
A. Peretti, L. Acosta, C. Mattoni and A. Martínez, 1 ♂ (AVP).
Bothriurus olaen Acosta, 1997: ARGENTINA: Córdoba Province: Vaquerías, 21.xii.1994, A. Peretti and 
A. Martínez, 2 ♂ (AVP).
Bothriurus rochai Mello-Leitão, 1932: BRAZIL: Piauí: Estação Ecológica Uruçui, Una, 08°52′S 44°57′W, 
19–29.i.2001, C.G. Martingelli, 5 ♂ (MZUSP 18999).
Bothriurus rochensis San Martín, 1965: URUGUAY: 2 ♂ (AVP). Rocha Department: Santa Teresa Park, 
road to camping close to Picada de los Cuervos, 34°00′36.072″S 53°33′20.772″ W, 48 m, 11.xii.2005, 
C. Mattoni, A. Ojanguren and F. Labarque, 1 ♂ (CIM).
Bothriurus sp.: BRAZIL: Bahía: Ceraíma Municipality: Guanambí, 7 km S, 14°17′05.6″S 42°47′02.2″W, 
533 m, 24.i.2007, C. Mattoni, R. Pinto-da-Rocha and H. Yamaguti, 3 ♂ (CIM).
Brachistosternus angustimanus Ojanguren Affilastro and Roig Alsina, 2001: ARGENTINA: Neuquén 
Province: Picún Leufú, 25.i.2005, M. Magnanelli and G. López, 3 ♂ (CIM). 
Brachistosternus ferrugineus (Thorell, 1876): ARGENTINA: Córdoba Province: Parque Provincial Chan-
caní, 20 and 23.xi.2001, C. Mattoni and J. Ochoa, 10 ♂ (CIM).
Brachistosternus pentheri Mello-Leitão, 1931: ARGENTINA: Mendoza Province: Reserva Ecológia de Bios-
fera Ñacuñan, 20.xi.2003, C. Mattoni, J. Ochoa and L. Prendini, 5 ♂ (CIM); Reserva Natural Bosque 
Telteca, 32°22.967′S 68°03.309′W, 580 m, 19.xi.2003, C. Mattoni, J. Ochoa and L. Prendini, 5 ♂ (CIM).
Centromachetes obscurus Mello-Leitao, 1932: CHILE: Region IX (La Araucanía): Malleco Province: 
Parque Nacional Nahuelbuta, near campsite, 37°49.744′S 73°00.418′W, 1126 m, 14.xi.2003, C. Mat-
toni, L. Prendini and J. Ochoa, 5 ♂ (CIM).
Centromachetes pocockii (Kraepelin, 1894): CHILE: Region VII (Maule): Malleco Province: Trail to Salto 
Rayén, next to Monumento Natural Contulmo, 38°01′07.896″S 73°09′54.720″W, 210 m, 10–11.i.2006, 
C. Mattoni and M. Vivanco, 1 ♂ (CIM).
Cercophonius squama (Gervais, 1843): AUSTRALIA: Tasmania: Mt. Barrow, 570 m, 15–17.ii.1980, A. 
Newton and M. Thayer, 3 ♂ (AMNH).
Lisposoma josehermana Lamoral, 1979: NAMIBIA: Oshikoto Region: Tsumeb District: Farm Varianto on 
Elandshoek 771, 19°22.773′S 17°44.456′E, 1500 m, 4.i.2004, L. Prendini, E. Scott, T. and C. Bird, Q. 
and N. Martins, 1 ♂ (CIM). 
Orobothriurus tamarugal Ochoa et al., 2011: CHILE: Region I (Tarapacá): Tarapacá Province: La Tirana, 
2 km W, 20°19′59.8″S 69°40′07.6″W, 999 m, 18. i.2005, C. Mattoni, A. Ojanguren and J. Ochoa, 2 
♂ (AMNH, MACN). 
Phoniocercus pictus Pocock, 1893: CHILE: Region La Araucanía: Cautín Province: Fundo las Selva, N of 
Temuco and NW of Nueva Imperial, 750 m, 16–20.ii.1981, L.E. Peña, 1 ♂ (AMNH).
Rumikiru lourencoi (Ojanguren Affilastro, 2003): CHILE: Region III (Atacama): Huasco Province: Parque 
Nacional Llanos de Challe, near ‘Administración’, 28°09′39.8″S 71°03′20″W, 205 m, 25.i.2005, C. 
Mattoni and A. Ojanguren, UV full moon, 1 ♂ (CIM). 
Tehuankea moyanoi Cekalovic, 1973: CHILE: Región VIII (Bio Bío): Arauco Province: Ramadilla, 
18.i.1971, R. Donoso Barros, holotype ♂ (MZUC 567).
Thestylus aurantiurus Yamaguti and Pinto-da-Rocha, 2003: BRAZIL: São Paulo: Parque Estadual da Serra 
da Cantareira, 22–30.xi.2004, S. Favorito et al., 1 ♂ (MZUSP).
Timogenes dorbignyi (Guérin Méneville, 1843): ARGENTINA: Córdoba Province: Parque Provincial 
Chancaní, 20–23.xi.2001, C. Mattoni and J. Ochoa, 6 ♂ (CIM); Salinas Grandes, iii.2007, C. Mattoni, 
A. Peretti and D. Vrech, 4 ♂ (CIM). 
46 AMERICAN MUSEUM NOVITATES NO. 3993
Timogenes elegans (Mello-Leitao, 1931): ARGENTINA: Córdoba Province: Parque Provincial Chancaní, 
1–25.iii.1994, C. Mattoni, 5 ♂ (CIM), 2004, M. Izquierdo, 3 ♂ (CIM).
Urophonius brachycentrus (Thorell, 1876): ARGENTINA: 13.vi.1993, S. Castelvetri, 2 ♂ (AVP).
Urophonius tregualemuensis Cekalovic, 1981: CHILE: Region VII (Maule): Cauquenes Province: Reserva 
Nacional Los Ruiles, NW of Cauquenes, 37°49.744′S 73°00.418′W, 146 m, 13.xi.2003, C. Mattoni, 
J. Ochoa and L. Prendini, 5 ♂ (CIM).
Vachonia martinezi Abalos, 1954: ARGENTINA: Río Negro Province: Balneario el Cóndor, S of Viedma, 
5.v.2003, M. Magnanelli, 4 ♂ (CIM).
Family Buthidae C.L. Koch, 1837
Ananteris arcadioi Botero-Trujillo, 2008: COLOMBIA: Meta Department: Hacienda Con Esto Tengo, 
between Villavicencio and Restrepo, 04°11.855′N 73°35.620′W, 407 m, 7.ix.2008, R. Botero-Trujillo 
and J.A. Ochoa, 3 ♂ (AMNH).
Babycurus jacksoni (Pocock, 1890): TANZANIA: Rufiji District: Kichi Hills Forest Reserve, 08°14.333′S 
38°39.014′E, 7.iii.2008, P. Hawkes, 1 ♂ (AMNH). 
Buthus paris (C.L. Koch, 1839): ALGERIA: El Guetna, NW of Mascara, 550 m, 24.v.1981, E.S. Ross, 1 ♂ 
(CAS).
Hottentotta conspersus (Thorell, 1876): NAMIBIA: Kunene Region: Opuwo District: Blue Drum, 5 km SE 
on S bank of Ondondujengo River, 17°48.894′S 12°25.626′E, 841 m, 15.i.2004, L. Prendini, E. Scott, 
T. and C. Bird, Q. and N. Martins, 3 ♂ (AMNH).
Isometrus maculatus (DeGeer, 1778): KENYA: Coast Province: Kilifi District: Watamu Beach, 25.vii/8.
viii.2008, S. Mwangi, 1 ♂ (AMNH).
Lychas obsti Kraepelin, 1913: KENYA: Eastern Province: Kibwezi County: Mtito Andei Division, near 
Tsavo National Park, 25.vii/8.viii.2008, S. Mwangi, 1 ♂ (AMNH). 
Mesobuthus eupeus thersites (C.L. Koch, 1839): UZBEKISTAN: Bukhara Area: Gizhduvan District: SW 
foothills of Karatau Mountain Range, 14.5 km N of Kanimekh, 40°24.851′N 65°08.955′E, 396 m, 
5.vi.2003. L. Prendini and A.V. Gromov, 1 ♂ (AMNH). 
Microtityus waeringi Francke and Sissom, 1980: U.S.A.: U.S. Virgin Islands: St. John, Virgin Islands 
National Park, Lameshur Bay trail, parking lot and first few hundred meters of trail, 18°19.242′N 
64°43.641′W, 22 m, L. Prendini and J. Huff, 17.x.2009, 1 ♂ (AMNH)
Parabuthus granulatus (Ehrenberg, 1831): SOUTH AFRICA: Northern Cape Province: Gordonia District: 
Farm Boksputs 462, 25 km SE Lutsputz on road to Keimoes, 28°33.368′S 20°50.427′E, 869 m, 8.i. 
2004, I. Engelbrecht and B. Watkins, 1 ♂ (AMNH). 
Pseudolychas ochraceus (Hirst, 1911): SOUTH AFRICA: Limpopo Province: Potgietersrus District: Maka-
pansgat, 1981, A. Harington, 1 ♂ (AMNH [AH 2263]).
Reddyanus assamensis (Oates, 1888): INDIA: West Bengal: 25 mi. from Calcutta, 11.vi.1966, N.K. Paul, 
1 ♂ (CAS [Stahnke coll. 66-862]).
Teruelius ankarana (Lourenço and Goodman, 2003): MADAGASCAR: Antsiranana Province: Andrafi-
abe, 2.6 km E, 12°57.523′S 49°07.189′E, 4/6.i.2007, A.H. Kirk-Springs, 3 ♂ (AMNH).
Tityus elii Armas and Marcano Fondeur, 1992: DOMINICAN REPUBLIC: La Vega Province: Loma 
Casabito, Reserva Científica Ébano Verde, along road to transmitter station, 19°02′15.3″W 
70°31′06.5″W, 1478 m, 18.vii.2004, E.S. Volschenk and J. Huff, 3 ♂ (AMNH).
Zabius fuscus (Thorell, 1876): ARGENTINA: Córdoba Province: Cuesta Blanca, 3 ♂ (AVP).
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Family Caraboctonidae Kraepelin, 1905
Caraboctonus keyserlingi Pocock, 1893: CHILE: Region IV (Coquimbo): Elqui Province: Monte Grande, 
Elqui Valley, 27.ii.2004, J. Pizarro, J. Ochoa and C. Mattoni, 1 ♂ (AVP), 2 ♂ (CIM).
Hadruroides lunatus (L. Koch, 1867): PERU: Lima Department: Lima Province: Cieneguilla, 6 km W, ca. 
400 m, 30.xii.1975, O.F. Francke, 4 ♂ (AMNH).
Family Chactidae Pocock, 1893
Brotheas sp.: GUYANA: Bartica District: Kartabo, 1922, 1 ♂ (AMNH).
Broteochactas nitidus Pocock, 1893: TRINIDAD AND TOBAGO: Blanchisseuse valley, northern Trini-
dad, 1.xi.1979, R. Mendez and J. Boos, 1 ♂ (AMNH).
Chactas aequinoctialis (Karsch, 1879): COLOMBIA: Sierra Nevada de Santa Marta, San Sebastián de 
Rabago, 2000 m, 1–10.iv.1968, B. Malkin, 1 ♂ (AMNH). 
Chactopsoides anduzei (González-Sponga, 1982): VENEZUELA: Amazonas: Autana Municipality: Isla 
Ratón (S part), Orinoco River, 05°03.882′N 67°49.000′W, 81 m, 7.viii.2009, F. Rojas-Runjaic, A. 
Ferrer and J.A. Ochoa, 1 ♂ (AMNH).
Nullibrotheas allenii (Wood, 1863): MEXICO: Baja California Sur: Sierra de la Laguna nucleus zone, 
23°33′16″N 109°59′27.4″W, 1800 m, 20.vii.2004, E. González, A. Valdez, W. Savary and O. Francke, 
♂ (AMNH).
Teuthraustes sp.: ECUADOR: Aguay Province: Susudel, ca. San Felipe de Oria, 03°24.339′S 79°10.581′W, 
2324 m, 11.ii.2008, 1 ♂ (AMNH).
Uroctonus mordax Thorell, 1876: U.S.A.: Oregon: Douglas County: Canyonville, 4 mi. S, 4.v.1936, G. 
Ferguson, 1 ♂ (AMNH). 
Family Chaerilidae Pocock, 1893
Chaerilus julietteae Lourenço, 2011: VIETNAM: Binh Thuan Province: Ham Thuan Nam District: Ta Cu/
Ta Kou Mountain Nature Reserve, Nui Ta Cu/Ta Kou below summit, above reclining Buddha, 
10°48′58″N 107°53′46.1″E, ca. 500 m, 17.xi.2012, L Prendini, 1 ♂ (AMNH).
Chaerilus variegatus Simon, 1877: INDONESIA: Java, 1 ♂ (MACN). 
Family Diplocentridae Karsch, 1880
Cazierus garridoi Armas, 2005: U.S.A.: Puerto Rico: Isla Mona, Trail #1 to Punta Capitan from Sardiniera, 
18.08823°N 67.93815°W, L. Esposito and H. Yamaguti, 19.x.2008, 1 ♂ (AMNH).
Diplocentrus lindo Stockwell, 2001: U.S.A.: Texas: Jeff Davis County: David Mountains State Park, 
Limpia Canyon Campground, 5.vi.1974, L. Draper, M.A. Cazier and O.F. Francke, 1 ♂ 
(AMNH).
Nebo hierichonticus (Simon, 1872): ISRAEL: Haifa District (Mehoz): Mount Carmel National Park, 
Ha’Agam Campsite, upper Nahal Oren, 32°43′24″N 35°00′33″E, 219 m, 22.viii.2011. L. Prendini, 
T.L. Bird and E. Gefen, 1 ♂ (AMNH).
48 AMERICAN MUSEUM NOVITATES NO. 3993
Family Euscorpiidae Laurie, 1896
Megacormus gertschi Diaz Nájera, 1966: MEXICO: 1 ♂ (AMNH).
Megacormus sp.: MEXICO: Veracruz: road to Tlaquilpan, 18°38.507′N 97°06.425′W, 2125 m, 19.vii.2002, 
L. Prendini and O.F. Francke, 1 ♂ (AMNH).
Tetratrichobothrius flavicaudis (DeGeer, 1778): FRANCE: Hérault: Lodève, 1969, B. Monroy, 1 ♂ 
(MACN).
Family Hemiscorpiidae Pocock, 1893
Hemiscorpius lepturus Peters, 1861: IRAN: Khoozestan Province: Baghmalek, Karbalai Ghasem village, 
31°27′24″N 49°57′37″E, 285 m, vii.2007, Salari, 1 ♂ (AMNH [LP 9711]).
Family Heteroscorpionidae Kraepelin, 1905
Heteroscorpion goodmani Lourenço, 1996: MADAGASCAR: Toliara Province: Parc National Andohahela, 
Tonatana, 33.3 km NW Tolagnaro, 24°45′31″S 46°51′13″E, 275 m, 22.xi.2006, B.L. Fisher, BLF 
15101, 1 ♂ (CAS ENT 9026922).
Family Hormuridae Laurie, 1896
Hadogenes troglodytes (Peters, 1861): MOZAMBIQUE: Tete Region: Moatize District: Kapanga, hills 
overlooking village on S bank Rovubwe River, 06°07′15″S 33°39′48″E, 212 m, 10.xii.2007, L. Pren-
dini and W.R. Schmidt, 1 ♂ (AMNH).
Hormurus sp.: AUSTRALIA: Queensland: Mt. Tozer Range, northern foot, 1 ♂ (MACN). 
Opisthacanthus capensis Thorell, 1876: SOUTH AFRICA: Western Cape Province: 1 ♂ (CIM). 
Opisthacanthus valerioi Lourenço, 1980: COSTA RICA: Isla de Coco, 4.iii.2002, A. Peretti, 1 ♂ 
(AVP).
Family Iuridae Thorell, 1876
Protoiurus asiaticus (Birula, 1903): 1 ♂ (ZMB).
Family Pseudochactidae Gromov, 1998
Troglokhammouanus steineri Lourenço, 2007: LAOS: Khammouane Province: Boualapha District: 
Hin Namno National Biodiversity Conservation Area, Tham Xe Bang Fai (Xe Bang Fai River 
Cave), left bank of Xe Bang Fai River (coming from downstream entrance), 17°22′23.6″N 
105°50′11.8″E, 159 m, 19–21.ii.2012, L. Prendini, P. Kanyavong and W. Phimmathong, 1 ♂ 
(AMNH).
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Family Scorpionidae Latreille, 1802
Pandinus imperator (C.L. Koch, 1841): pet trade, 1 ♂ (AVP). 
Scorpio fuliginosus (Pallary, 1928): MOROCCO: Marrakech Province: Arbalow Ourika, 1000 m, 
14–18.v.1975, B. Malkin, 1 ♂ (AMNH). 
Family Scorpiopidae Kraepelin, 1905
Euscorpiops longimanus (Pocock, 1893): 1 ♂ (AMNH).
Scorpiops zubairi Kovařík, 2020: (Gervais, 1843): PAKISTAN: Murree, 33°55′N 73°726′E, 7500 ft, 29.
vi.1967, B.L. Haines, 1 ♂ (MCZ)
Troglocormus ciego Francke, 1981: MEXICO: San Luis Potosí: Cueva de Elias, 13 km N Agua Buena, 
3.viii.1975, D. McKenzie, holotype ♂ (AMNH).
Family Superstitioniidae Stahnke, 1940
Superstitionia donensis Stahnke, 1940: U.S.A.: Nevada: Clark County: 8.7 mi. SW Hwy 95 on Hwy 156, 
on E slopes of Spring Mountains, 1800 m, 14.viii.1991, S.C. Williams, V.F. Lee and R.C. Bechtel, UV, 
1 ♂ (CAS). 
Family Troglotayosicidae Lourenço, 1998
Troglotayosicus humiculum Botero-Trujillo and Francke, 2009: COLOMBIA: Nariño Department: Ricaurte 
Muncipality: Vereda Alto Cartagena, Finca Nueva Estrella, 01°13′15.7″N 77°58′08.6″W, 1617 m, 
12.ix.2008, R. Botero-Trujillo, J.P. Botero, and J.A. Ochoa, 1 ♂ (MPUJ ENT 46835 old SCO 399).
Family Typhlochactidae Mitchell, 1971
Alacran tartarus Francke, 1982: MEXICO: Oaxaca: Sotano Li Nita, Huautla de Jimenez, 812 m, 29.
iii.1980, B. Steele and S. Zeman, 1 ♂ (AMNH).
Typhlochactas mitchelli Sissom, 1988: MEXICO: Oaxaca: Município de San José Tenango: Cerro Ocote 
[18°08′57.5″N 96°43′59.1″W], 5 mi. S San José de Tenango, iv.1987, A. Grubbs, A. Cressler and P. 
Smith, holotype ♂, paratype ♂ (AMNH).
Family Urodacidae Pocock, 1893
Urodacus butleri Volschenk et al., 2012: AUSTRALIA: Western Australia: Barrow Island, 20°46′S 
115°24′E, 9.ii.1977, W.H. Butler, K. Edwards and N. Gunawardene, paratype ♂ (AMNH). 
Urodacus planimanus Pocock, 1893: AUSTRALIA: Western Australia: Jarrahdale, 20.iii.1998, E.S. 
Volschenk, under stone, 1 ♂ (AMNH).
50 AMERICAN MUSEUM NOVITATES NO. 3993
Family Vaejovidae Thorell, 1876
Graemeloweus glimmei (Hjelle, 1972): U.S.A.: California: Lake County: ca. 5 mi. N Rayhouse Rd, at junc-
tion of David and Cacje Creeks, 900 m, 15.vi.1969, J.T. Hjelle and M. Bolander, 1 ♂ (CAS).
Mesomexovis variegatus (Pocock, 1898): MEXICO: Morelos: Xochitepec, 20.x.1974, O. Martínez, 1 ♂ 
(MACN).
Paravaejovis spinigerus (Wood, 1863): U.S.A.: Arizona: Pima County: Madera Canyon, Santa Rita Moun-
tains, 14.vii, M.A. Cazier and J. Bigelow, roadcuts, 1 ♂ (AMNH). 
Smeringurus grandis (Williams, 1970): MEXICO: Baja California: Okies Landing, 27 mi. S Pantocitos, 
12.vi.1968, W.K. Fox, 1 ♂ (CAS).
Syntropis williamsi Soleglad et al., 2007: MEXICO: Baja California Sur: La Paz, El Pilar, ca. 20 km NE of 
Las Pocitas, 24°28.762′N 111°01.125′W, 92 m, 25.vi.2008, H. Montaño and E. González, oasis carved 
walls of compacted sand and granitic walls, stones and boulders, UV detection at night, 1 ♂ 
(AMNH).
Vaejovis mexicanus C.L. Koch, 1836: MEXICO: Distrito Federal: Pedregal de San Nicolas, ladera NE 
Cerro Ajosco del Tlalpan, 1999, M. Souop, 1 ♂ (AMNH). 
Vejovoidus longiunguis (Williams, 1969): MEXICO: Baja California Sur: Guerrero Negro, 12 km S, 
27°56′5.8″N 113°54′23.1″W, 25 m, 15.vii.2004, O.F. Francke, W. Savary, A. Valdéz and E. Gonzalez, 
UV light detection at night, 1 ♂ (AMNH).

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