Ultrastructural studies of spermatozoa in three bivalve species with notes on evolution of elongated sperm nucleus in primitive spermatozoa

Sperm ultrastructure and spermiogenesis of the three bivalve species Musculus discors, Nucula sulcata, and Dreissena polymorpha have been studied. During spermatid differentiation in Musculus discors and Nucula sulcata the nucleus attains an elongated rod-like shape. The spermatozoon from Nucula sulcata was found to have a cup-shaped acrosome and five mitochondria surrounding two centrioles in the middle piece. The spermatozoa from Musculus discors has a long complex acrosome. From the distal centriole striated processes extend and attach to the plasma membrane. The spermatozoon of the fresh water species Dreissena polymorpha agrees in all main features with those of other invertebrate groups with external fertilization. It is thus of the primitive type with barrel-shaped nucleus and four to five mitochondria1 spheres in the middle piece. The acrosome is a prominant, complex structure at the apex of the mature spermatozoon. A comparison of sperm ultrastructure among bivalves indicates that there is a certain correlation between the evolution of the elongated sperm nucleus and large, yolk-rich eggs. In species with an elongated sperm nucleus the increased egg size has often led to a lecithotrophic or direct development. The elongated nucleus is a slight modification of the primitive type. There is a great variation in acrosome structure among bivalve spermatozoa, reflecting diverging functional demands at fertilization of the eggs.     

Isolation of Plasma Membrane from Porcine Spermatozoa

A procedure is reported for isolating plasma membrane from porcine spermatozoa. Sperm were separated from gel particles and seminal plasma and subjected to low-intensity sonication that fragmented the plasma membrane, but minimized damage to the acrosome, nucleus and mitochondria. After cytoplasmic droplets and plasma membrane-depleted sperm were removed by differential centrifugation, the plasma membrane fragments were purified by flotation through a discontinuous sucrose gradient. During isolation, the effectiveness of each step was evaluated by light or electron microscopy. Plasma membrane fragments were identified using a stain specific for that membrane. Preparations were shown, by morphometry, to contain at least 70 per cent plasma membrane.     

Heritable paternal cytoplasmic organelles in alfalfa sperm cells: ultrastructural reconstruction and quantitative cytology.

Sperm cells within pollen grains and pollen tubes of alfalfa (Medicago sativa L.) were observed at the ultrastructural level, and their plastid DNA was detected by DAPI (4,6-diamidino-2-phenylindole) staining. One sperm pair within the pollen grain and three sperm pairs within pollen tubes were reconstructed in three-dimensions from serial ultrathin sections. The two sperm cells are linked by cytoplasmic bridges in both pollen grains and tubes, and the vegetative nucleus is closely associated with the sperm cells within the pollen tube. The number of plastids and plastid nucleoids (DNA aggregates) in the sperm cell pair, collectively, is not significantly different from that in the generative cell; however, over 60% of the sperm cell plastids contain no DNA detectable with DAPI. The mean number of mitochondria in sperm cells is reduced from that in the generative cell (from 54 to 17), which suggests that paternal mitochondrial inheritance probably does not occur in the genotype investigated. Sperm cells of a pair may vary in their shape within the pollen grain and tube, but the number of plastids and mitochondria is not significantly different between the sperm cells. Therefore, heterospermy is not a factor determining cytoplasmic inheritance patterns in this species.     

Comparative sperm ultrastructure and spermiogenesis in basal heterobranch gastropods (Valvatoidea, Architectonicoidea, Rissoelloidea, Omalogyroidea, Pyramidelloidea) (Mollusca)

Three distinct groups of basal heterobranch gastropods (='Allogastropoda/Heterostropha') can be distinguished on the basis o f sperm and spermiogenic features: (1) Valvatoidea; (2) Architectonicoidea; (3) Rissoelloidea + Omalogyroidea + Pyramidelloidea. Sperm of pentaganglionate heterobranchs (Opisthobranchia sensu stricto + Pulmonata) conform in all respects to the pattern shown by group (3). Heterobranchia are united, and differentiated from other gastropods, by a shared suite of sperm and spermiogenic features (rounded acrosomal vesicle, nucleus usually helical, highly modified mitochondrial derivative, spermatid acrosome associated with a dense nuclear plaque, formation of the mitochondrial derivative through fusion of numerous small mitochondria along the length of the axoneme). Sperm autapomorphies of the Architectonicoidea and the Valvatoidea suggest that these two superfamilies arc distinct but terminal offshoots from ancestral heterobranchs.     

The double sperm line in Isochaetides (Annelida,Clitellata, Tubificidae)

Sperm morphology and spermatogenesis were examined in the oligochaete annelid Isochaetides arenarius, a species belonging to the subfamily Tubificinae inhabiting the sediments of Lake Baikal. As all tubificines, Isochaetides produces two types of spermatozoa, named eusperm and parasperm. The eusperm are the fertilizing male gametes and consist, in sequence, of an acrosome, a nucleus, a mitochondrial mid-piece, and a tail. The parasperm have the same general architecture, but differ in cytological details: the acrosome is shorter, devoid of a perforatorium, and the acrosome vesicle has a different, simpler, shape. The nucleus is much shorter and rectilinear (the eusperm nucleus is twisted). The mid-piece mitochondria are less numerous but their overall volume is larger. The flagellum has a plasma membrane largely separated from the axoneme, and is devoid of glycogen granules. After mating, the two sperm types gather in the spermathecae to form spermatozeugmata; in these structures the parasperm form an external sheath involving the centrally located eusperm and their tails are connected by conspicuous septate junctions. Parasperm nuclei are produced through a process of fragmentation of the 'spermatocytes', whereas the flagellar basal bodies are produced by a process similar to that giving rise to basal bodies in ciliated epithelia.     

Quantitative cytology of the sperm cells of Brassica campestris and B. oleracea

Pollen grains of Brassica campestris L. var. acephala DC and B. oleracea L. were serially sectioned and examined using transmission electron microscopy to determine the three-dimensional organization of sperm cells within the microgametophyte and the quantity of membrane-bound organelles occurring within each cell. Sperm cells occur in pairs within each pollen grain, but are dimorphic, differing in size, morphology and mitochondrial content. The larger of the two sperm cells (S_vn) is distinguished by the presence of a blunt evagination, which in B. oleracea wraps around and lies within shallow furrows on the vegetative nucleus and in B. campestris can penetrate through internal enclaves of the vegetative nucleus. This sperm cell contains more mitochondria in both species than the second sperm cell (S_ua). This latter cell is linked to the first by a common cell junction with the S _vn, but is not associated with the vegetative nucleus and lacks a cellular evagination. Such differences are indicative of a system of cytoplasmic heterospermy in which sperm cells possess significantly different quantities of mitochondria.Abbreviations mtDNA mitochondrial DNA - S_ua sperm cell unassociated with the vegetative nucleus - S_vn Sperm cell physically associated with the vegetative nucleus     

Alteration of cytochrome C oxidase activity during spermatogenesis in Carcinus maenas

During spermatogenesis in the crab, Carcinus maenas, mitochondria in the developing spermatids degenerate. In close association with mitochondrial fragments in late spermatids, an elaborate lattice-like complex of fused membranes is formed and lies in a position adjacent to the acrosome. Mature sperm possess no mitochondria, but a whorl of membranes is present alongside the acrosome in the diffuse nucleus. To ascertain whether or not cytochrome c oxidase activity is lost as the mitochondria disintegrate, differentiating Carcinus maenas spermatids and mature sperm have been studied cytochemically. Cytochfome c oxidase activity was localised by means of the osmophilic compound 3,3'-diaminobenzidine (DAB). Cytochrome c oxidase activity is confined to the cristae of mitochondria in the testis. As spermatids mature most mitochondria are lost. A few mitochondrial fragments may be caught up within the lamellar complex. While they are recognisalbe as mitochondria they retain cytochrome c oxidase activity. The lamellar complex does not show this enzyme activity. These results therefore suggest that the mature sperm of Carcinus maenas do not contain the enzymes normally incorporated in the mitochondrial membrane, capable of oxidative phosphorylation.     

Antibody to a sperm surface glycoprotein inhibits the egg jelly-induced acrosome reaction of sea urchin sperm

When the surface of sea urchin (Strongylocentrotus purpuratus) sperm is radioiodinated, 75% of the protein-incorporated radioactivity is associated with two glycoproteins of M_r 84,000 (84K) 64,000 (64K) (Lopo and Vacquier 1980). Antibodies were prepared against these two components by separating a Triton X-100 extract of sperm on SDS-polyacrylamide gels, cutting out the band containing the glycoprotein and injecting the homogenized gel into rabbits. Both anti-84K and anti-64K sera agglutinate sperm. Light and EM immunoperoxidase localization show both antigens are distributed over the entire sperm surface. By the immunoperoxidase technique there is some degree of cross-reactivity of both antisera with sperm of other Strongylocentrotus species, but not with those of other genera. Living sperm incubated with anti-84K Fab fragments are completely inhibited from undergoing the egg jelly-induced acrosome reaction and fertilizing eggs. Anti-64K Fab fragments have no effect on the ability of the sperm to undergo the acrosome reaction or fertilize eggs. Sperm incubated in anti-84K or anti-64K Fab fragments undergo the acrosome reaction in response to the Ca²⁺ ionophore A23187, or when the extracellular pH is increased to 9.2 with NH₄OH, indicating that the inhibition of the egg jelly-induced acrosome reaction results from the binding of the anti-84K Fab to an external molecule involved in the initiation or propagation of the acrosome reaction. The 84K glycoprotein is the first sperm surface component identified that might have a role in the induction of the acrosome reaction.     

Spermatozoa of the deep-sea cephalopod Vampyroteuthis infernalis Chun: ultrastructure and possible phylogenetic significance

Sperm ultrastructure in the rare deep-sea cephalopod Vampyroteuthis infernalis is described, based on formalin-fixed material held in the Australian Museum (Sydney). The species is the sole member of the coleoidean order Vampyromorpha, which represents a level of organization intermediate between that of the Sepioidea-Teuthoidea and the Octopoda. Spermatozoa of Vampyroteuthis, the simplest observed in any cephalopod, exhibit the following features: (1) a spheroidal acrosome lacking any complex substructure; (2) a short (8.5 microns) fusiform nucleus with a deep (2.2-2.5 microns) basal invagination (containing an extensive plug of dense material); (3) two triplet centrioles arranged parallel to the sperm longitudinal axis; (4) a short (1 micron) midpiece composed of a triangular cluster of mitochondria surrounding the centrioles; and (5) a tail (length 130-135 microns) that is continuous with one of the centrioles (here considered as a 'distal' centriole). An annulus and membranous skirt are absent, though the coarse fibres do fuse into a ring at the tail-midpiece junction). These cells show some resemblance to sperm or spermatids of sepioids and teuthoids (spheroidal acrosome, short nucleus) but are also remarkably similar to mid-spermatids of Octopus (with the exception of the uncondensed nucleus in Octopus spermatids). Sperm morphology supports the current assignment of Vampyroteuthis to a separate coleoidean order--Vampyromorpha--and also suggests that a close link exists between the Vampyromorpha and Octopoda.     

The spermatogenesis and sperm structure of Acerentomon microrhinus (Protura, Hexapoda) with considerations on the phylogenetic position of the taxon

The spermatogenesis of the proturan Acerentomon microrhinus Berlese, (Redia 6:1–182, 1909) is described for the first time with the aim of comparing the ultrastructure of the flagellated sperm of members of this taxon with that of the supposedly related group, Collembola. The apical region of testes consists of a series of large cells with giant polymorphic nuclei and several centrosomes with 14 microtubule doublets, whose origin is likely a template of a conventional 9-doublet centriole. Beneath this region, there are spermatogonial cells, whose centrosome has two centrioles, both with 14 microtubule doublets; the daughter centriole of the pair has an axial cylinder. Slender parietal cells in the testes have centrioles with nine doublet microtubules. Spermatocytes produce short primary cilia with 14 microtubule doublets. Spermatids have a single basal body with 14 microtubule doublets. Anteriorly, a conical dense material is present, surrounded by a microtubular basket, which can be seen by using an α-anti-tubulin antibody. Behind this region, the basal body expresses a long axoneme of 14 microtubule doublets with only inner arms. An acrosome is lacking. The nucleus is twisted around the apical conical dense structure and the axoneme; this coiling seems to be due to the rotation of the axoneme on its longitudinal axis. The posterior part of the axoneme forms three turns within the spermatid cytoplasm. Few unchanged mitochondria are scattered in the cytoplasm. Sperm consist of encysted, globular cells that descend along the deferent duct lumen. Some of them are engulfed by the epithelial cells, which thus have a spermiophagic activity. Sperm placed in a proper medium extend their flagellar axonemes and start beating. Protura sperm structure is quite different from that of Collembola sperm; and on the basis of sperm characters, a close relationship between the two taxa is not supported.     

The male reproductive system,sperm, and spermatophores of the primitive,hermaphroditic, remipede crustacean Speleonectess benjamini

Summary

Speleonectes benjamini, a species of the primitive crustacean class Remipedia, is a simultaneous hermaphrodite. The male reproductive tract consists of paired testes and vas deferens. Sperm have an ovoid nucleus, acrosome, and a flagellum with a 9 + 2 microtubular arrangement. The spermatophores contain at least three sperm.     

Ultrastructure of sperm development and mature sperm morphology in three species of commensal bivalves (Mollusca: Galeommatoidea)

Ultrastructural features of the ovotestes, spermatogenesis, and the mature sperm are described for three galeommatid bivalves, Divariscintilla yoyo, Divariscintilla troglodytes, and Scintilla sp., from stomatopod burrows in eastern Florida. All three species yielded similar results except with respect to mature sperm dimensions. The ovotestis contains three types of somatic cells within the testicular portion: flattened myoepithelial cells defining the outer acinal wall; underlying pleomorphic follicle cells containing abundant glycogen deposits; and scattered, amoeboid cells containing lysosomal-like inclusions which are closely associated with developing sperm. Early spermatogenesis is typical of that reported from other bivalves. In contrast, the late stages of spermiogenesis involve the migration and gradual rotation of the acrosomal vesicle, resulting in a mature acrosome tilted about 70° from the long axis of the cell. The mature sperm possesses an elongated, slightly curved nucleus; a subterminal, concave acrosome with a nipple-like central projection; five spherical mitochondria and two centnoles in the middlepiece; and a long flagellum. The rotational asymmetry and the presence of perimitochondrial glycogen deposits in these sperm are unusual in the Bivalvia and may be associated with fertilization specializations and larval brooding common among galeommatoideans.     

Spermiogenesis in Psilochorus simoni (Berland, 1911) (Pholcidae, Araneae): evidence for considerable within-family variation in sperm structure and development

A large number of characters and considerable variation among taxa make animal sperm cells promising objects for phylogenetic studies. However, our knowledge about sperm structure and development in spiders is still rudimentary. In pholcids, previous studies of two species representing different subfamily level taxa have revealed conspicuous differences. Here, we report on a representative of a third subfamily level taxon, confirming substantial variation in sperm structure and development within the family. The male genital system in Psilochorus simoni (Berland, 1911) consists of paired testes and deferent ducts which lead into a common ejaculatory duct. The somatic cells of the testes show a high secretory activity, and produce at least two different kinds of secretion. The spermatozoa show features already known from other Pholcidae as well as unique characters. The acrosomal vacuole is tube-like with a narrow subacrosomal space. The axoneme migrates deep into the nucleus and is finally located near the acrosomal vacuole. Thus, the postcentriolar elongation of the nucleus is very long. A centriolar adjunct is not present and after the coiling process the implantation fossa is completely filled with glycogen which is also found in larger amounts within the cytoplasm of the sperm cell. After the coiling process, a vesicular area is present that becomes most prominent in the periphery of the sperm cell and surrounds the axoneme and parts of the nucleus. The secretion sheath surrounding the mature spermatozoon is already formed in the lumen of the testis, possibly by a secretion present in the testis but absent in the deferent duct. Sperm are transferred as cleistospermia. Results are compared with previous studies on pholcid spermiogenesis and sperm structure.     

平疣桑椹石磺精子结构观察

通过电光学显微镜和透射电子显微镜观察了平疣桑椹石磺精子的形态及其超微结构。平疣桑椹石磺成熟精子属于进化型,由头部、中段和末段组成。头部由顶体和精核构成,顶体长约0.7μm,呈细奶嘴状,内含物分布均匀,电子密度稍低于细胞核。顶体基部与精核前端紧密相连,无间隙。精核长约3.8μm,宽约1.0μm,核质高度浓缩,电子密度高,无核泡,纵切似辣椒状,核后端内凹形成核后窝。中段加长,结构复杂,线粒体演化成线粒体鞘,螺旋状包绕轴丝。精子末段由轴丝及包绕轴丝的质膜组成,轴丝为典型的“9＋2”结构。比较了平疣桑椹石磺精子与相关腹足类精子结构的异同,进一步证实了腹足纲贝类精子结构之间的区别主要在于顶体有无及形态,精核的长短与外形、中段线粒体的数目及其排列方式等。     

Ultrastructure of Sperm in <Emphasis Type="Italic">Mercenaria stimpsoni</Emphasis> and <Emphasis Type="Italic">Mactra chinensis</Emphasis> (Mollusca: Bivalvia) from the Sea of Japan

The ultrastructure of the sperm of the common bivalve species Mercenaria stimpsoni and Mactra chinensis from Peter the Great Bay is described. The sperm structure is typical for animals with external insemination. The sperm consists of a head, middle part, and flagellum. The sperm head of M. stimpsoni has a curved crescent form and includes the nucleus and acrosome; the head length is 9.8 μm. The acrosome is subdivided to the acrosome granule and the periacrosomal material. There are 4 mitochondria of about 0.8 μm in size in the middle part of the spermatozoon. The mitochondria surround the centriolar apparatus, which consists of proximal and distal centrioles located at a right angle. The axoneme originates from the distal centriole. The sperm of M. chinensis is barrel-shaped, with a head length of 3.2 μm. The acrosome is relatively larger, and its height is 1–1.2 μm. There are also 4 mitochondria 0.6–0.8 μm in the middle part of the spermatozoon. The sperm structure of the described species is typical of the families to which the mollusks belong, with insignificant variations.     

New findings on sperm ultrastructure in thrips (Thysanoptera, Insecta)

Sperm ultrastructure of several species in each of the two suborders of Thysanoptera Tubulifera and Terebrantia shows a distinctive and unusual architecture. Members of the whole order share a bizarre axoneme consisting of 27 microtubular elements derived from the amalgamation of 3 (9+0) axonemes present in each spermatid at the beginning of spermiogenesis. The reciprocal shifting of these axonemes along the length of the sperm, together with their possible shortening and overlapping for short distances, could explain why in some species it is never possible to observe the complete set of 27 microtubular elements in any one cross section. Tubuliferan sperm have a small elliptical (in cross section) acrosome extending the length of the sperm. In Bolothrips insularis and Compsothrips albosignatus this structure is larger and is associated with an external, flattened vesicle throughout its length. Terebrantian sperm lack an acrosome, but display for half their length a dense body running parallel to the nucleus. The sperm, in members of this suborder, are also characterized by possession of a small mitochondrion and by the unusual bilobed outline of cross sections through the anterior sperm region, with the nucleus located in one of the two lobes. Structures serving to anchor sperm to the inner surface of the cyst cell have been observed at their anterior tips in the testes of tubuliferans. In B. insularis, an anterior appendage is formed in immature sperm and is maintained in the mature spermatozoon parallel to its long axis in the most anterior region. Such an anchoring structure has not been observed in sperm of the terebrantian species examined, probably because the testis of terebrantians contains only a single cyst of developing gametes.     

Acrosome intact and acrosome-reacted human sperm can initiate binding to the zona pellucida

Mammalian sperm must be acrosome reacted before penetrating the zona pellucida. In some species the sperm undergo the acrosome reaction before binding to the zona pellucida and in other species only acrosome intact sperm can initiate binding to the zona. In this study we addressed the question of acrosomal status and sperm-zona binding with human gametes. Sperm acrosome reactions were induced by treatment with human follicular fluid or N-(6-amino-hexyl)-5-chloro-naphthalene sulfonamide (W-7). The sperm suspensions, containing various percentages of acrosome-reacted sperm, were then incubated with human oocytes for 1 min. The acrosomal status of the sperm population bound to the zona was similar to the acrosomal status of the population of sperm in suspension (R2 = 0.77), regardless of the treatment to induce acrosome reactions. Our interpretation of these results is that both acrosome intact and acrosome-reacted human sperm can initiate binding to the zona pellucida. However, we reported earlier (N. L. Cross, P. Morales, J. W. Overstreet, and F. W. Hanson, 1988, Biol. Reprod. 38, 235-244) that the human zona pellucida is able to induce acrosome reactions. Thus, to exclude the possibility that sperm had undergone the acrosome reaction on the zona within 1 min of binding, sperm were suspended in a nominally calcium-free Tyrode's medium (0 Ca-mTyr) before incubation with oocytes (this medium was supplemented with SrCl2 and spermine to support sperm motility and zona binding). In 0 Ca-mTyr, the proportion of acrosome-reacted sperm on the zona was still highly correlated with the proportion of reacted sperm in suspension, indicating that the sperm were reacted before binding. Evidence that 0 Ca-mTyr effectively inhibited acrosome reactions induced by the zona pellucida was derived from experiments in which sperm were treated with human follicular fluid or control medium and the suspensions were diluted with either 0 Ca-mTyr or control medium.4+ Human oocytes were added for 1 min (pulse) at which time some oocytes were fixed and other oocytes were transferred to sperm-free medium and incubated for 35 min (chase) before fixation. Sperm diluted in control medium, pretreated with either human follicular fluid or control medium, showed a similar increase (40%) in the percentage of acrosome reactions among the zona-bound sperm after the chase. Sperm diluted in 0 Ca-mTyr did not show an increase in the percentage of acrosome-reacted sperm on the zona pellucida after the chase.(ABSTRACT TRUNCATED AT 400 WORDS)     

Comparative sperm ultrastructure of<Emphasis Type="Italic"> Neodasys ciritus</Emphasis> and<Emphasis Type="Italic"> Musellifer delamarei</Emphasis>, two species considered to be basal among Chaetonotida (Gastrotricha)

The spermatozoa of two species supposed to be basal to Gastrotricha Chaetonotida, Neodasys ciritus and Musellifer delamarei, were studied in order to supply further elements to the understanding of sperm evolution in Chaetonotida, a group in which a fully parthenogenetic reproduction is dominant. Two considerably different sperm patterns were found: the spermatozoon of N. ciritus has a simple, conical acrosome, a short, condensed nucleus, few conventional mitochondria randomly arranged along the sperm head, and a 9×2+2 flagellum perpendicular to the sperm major axis. The spermatozoon of M. delamarei is a filiform cell with a simple acrosome, a partially condensed nucleus, four mitochondria at the nuclear base, and a flagellum with a 9×2+2 axoneme and large accessory fibers. Some sperm features of M. delamarei are comparable to those of Xenotrichulidae, the only other Chaetonotida producing conventional spermatozoa, whereas the sperm of N. ciritus appears different from all the other patterns known among Gastrotricha, thus knowledge of it does not help in solving the problem of the discussed phylogenetic position of the genus.     

Spermiogenesis in Polyplacophora,with special reference to acrosome formation (Mollusca)

Summary The present study examines spermiogenesis, and in particular the formation of the acrosome, in ten species of chitons belonging to four families. This study emphasizes the formation of the acrosome but brings to light several other structures that have received little or no mention in previous studies. The process of spermiogenesis is essentially similar in each species, although Chaetopleura exhibits some significant differences. In early spermiogenesis the Golgi body secretes numerous small pro-acrosomal vesicles that gradually migrate into the apical cytoplasm. The chromatin condenses from granules into fibres which become twisted within the nucleus. A small bundle of chromatin fibres projects from the main nuclear mass into the anterior filament; this coincides with the appearance of a developing manchette of microtubules around the nucleus that originates from the two centrioles. Radiating from the distal centriole is the centriolar satellite complex, which is attached to the plasma membrane by the annulus. The distal centriole produces the flagellum posteriorly and it exits eccentrically through a ring of folded membrane that houses the annulus. Extending from the annulus on one side of the flagellum, in all but one species, is a dense fibrous body that has not been previously reported. The proximal centriole lies perpendicular to the end of the distal centriole and is attached to it by fibro-granular material. Pro-acrosomal vesicles migrate anteriorly through the cytoplasm and move into the anterior filament to one side of the expanding nucleus. Eventually these vesicles migrate all the way to the tip of the sperm, where they fuse to form one of two granules in the acrosome. In mature sperm the nucleus is bullet-shaped with a long anterior filament and contains dense chromatin with occasional lacunae. The mitochondria vary in both number and position in the mature sperm of different species. Both centrioles are housed eccentrically in a posterior indentation of the nucleus, where the membranes are modified. The elongate flagellum tapers to a long filamentous end-piece that roughly corresponds to the anterior filament and may be important in sperm locomotion for hydrodynamic reasons. An acrosome is present in all ten species and stained positively for acid phosphatase in three species that were tested.