Ultrastructural observations of spermatozoa and spermiogenesis in Wandella orana Gray, 1994 (Araneae: Filistatidae) with notes on their phylogenetic implications

Spermatozoa and spermiogenesis of the prithine filistatid spider Wandella orana are described. The spider produces coenospermia, i.e. sperm aggregations that include several single sperm cells commonly surrounded by a secretion sheath. One sectioned coenospermium in W. orana contains at least five spermatozoa. During copulation many coenospermia are transferred into the female. Coenospermia are regarded as a peculiar transfer form of sperm which occurs in early derivative spiders such as Liphistiomorphae and Mygalomorphae. The only exception which was found in Araneomorphae until now was the filistatine spider Filistata insidiatrix. Our observation is the second case and supports the view that Filistatidae represent an early derivative taxon. Furthermore, the individual sperm cells show characteristics which also may be regarded as being plesiomorphic. There is a cone-shaped acrosomal vacuole, a very long acrosomal filament, a rather stout nucleus and a small implantation fossa. The axoneme shows the 9x2+3 pattern of microtubules which is synapomorphic in Megoperculata (Uropygi, Amblypygi and Araneae). The finding of coenospermia in two distant taxa of Filistatidae may have consequences for phylogenetic and systematic considerations.     

Spermatozoa and spermiogenesis of Liphistius cf. phuketensis (Mesothelae, Araneae, Arachnida) with notes on phylogenetic implications

The present study deals with the spermatozoa and spermiogenesis of Liphistius cf. phuketensis, a representative of the most primitive and enigmatic spider group Mesothelae. The general organization of the spermatozoa is very similar to the condition known from Amblypygi supporting a sister-group relationship between Araneae and Amblypygi. Besides plesiomorphic characters such as, e.g., an elongated and corkscrew shaped nucleus, the sperm cells are characterized by several apomorphic characters, e.g., the giant body and conspicuous membranous areas which are formed at the end of spermiogenesis. As the transfer form, coenospermia are formed at the end of spermiogenesis, which strongly supports the idea that this type of sperm aggregation is the primitive transfer form within spiders. A very remarkable character of the spermatozoa of some groups of arachnids is the coiling of the main cell organelles at the end of spermiogenesis. Previously, the Mesothelae were believed to be the only spider group which does not show a complete coiling of the main cell organelles. With the present study the first evidence of a complete coiling of spermatozoa within this primitive spider group could be documented, indicating that this character is part of the ground pattern of spider spermatozoa. Consequently, the incomplete coiling seems to be a synapomorphy of certain species of Mesothelae, which sheds new light on the discussion of the phylogenetic relationships of this group.     

Formation of primary sperm conjugates in a haplogyne spider (Caponiidae,Araneae) with remarks on the evolution of sperm conjugation in spiders

Sperm conjugation, where two or more sperm are physically united, is a rare but widespread pheno-menon across the animal kingdom. One group well known for its different types of sperm conjugation are spiders. Particularly, haplogyne spiders show a high diversity of sperm traits. Besides individual cleistospermia, primary (synspermia) and secondary (coenospermia, “spermatophore”) sperm conjugation occurs. However, the evolution of sperm conjugates and sperm is not understood in this group. Here, we look at how sperm are transferred in Caponiidae (Haplogynae) in pursuit of additional information about the evolution of sperm transfer forms in spiders. Additionally, we investigated the male reproductive system and spermatozoa using light- and transmission electron-microscopy and provide a 3D reconstruction of individual as of well as conjugated spermatozoa. Mature spermatozoa are characterized by an extremely elongated, helical nucleus resulting in the longest spider sperm known to date. At the end of spermiogenesis, synspermia are formed by complete fusion of four spermatids. Thus, synspermia might have evolved early within ecribellate Haplogynae. The fused sperm cells are surrounded by a prominent vesicular area. The function of the vesicular area remains still unknown but might be correlated with the capacitation process inside the female. Further phylogenetic and functional implications of the spermatozoa and sperm conjugation are discussed.     

The ultrastructure of the peculiar synspermia of some Dysderidae (Araneae, Arachnida)

The present study reports on the ultrastructure features of spermatozoa and spermatogenesis of several species of Dysderidae (Dysdera crocata, Dysdera erythrina, Dysdera ninnii, Harpactea arguta, Harpactea piligera, Dasumia taeniifera). Dysderid spiders are known to possess a peculiar sperm transfer form known as synspermia, characterized by fused spermatozoa surrounded by a secreted sheath. Until now the exact mode of formation of the synspermia is unknown. The present study demonstrates that the spermatids are connected via narrow cell bridges during the entire spermiogenesis as is usual, although in Dysderidae they do not separate at end of the spermiogenesis. Instead, they fuse completely within the testes shortly after the spermatid has coiled to get a spherical shape. The number of fusing sperm cells is different in the different observed species. The species of the genus Harpactea thus have synspermia consisting of two fused spermatozoa; whereas in the species of the genus Dysdera four sperm cells are fused and in D. taeniifera at least three spermatozoa are fused. In contrast with other known families with this peculiar form transfer of sperm, the synspermia in Dysderidae are mainly characterized by a conspicuous vesicular area which extends through the entire synspermium surrounding the cell organelles. Thus, all main cell components (e.g., nucleus, acrosomal vacuole, and axoneme) are covered by the vesicular membrane. The vesicular area seems to be functional and probably it is important during sperm activation in female genital system. Simultaneously to the extension of the vesicular area, the synspermium accumulates large amounts of glycogen. The glycogen is mainly located around the centriolar adjunct and along the axoneme accompanying the postcentriolar elongation of the nucleus. A further peculiar feature is the extremely elongated acrosomal vacuole, which seems to be synapomorphic trait for sperm cells of dysderids. Interestingly, spermatogenesis, including the fusion, exclusively occurs within the testes (in contrast to the formation of coenospermia). In the vas deferens only synspermia were found. The secreted sheath surrounding the spermatozoa is finally synthesized in the parts of the vasa deferentia, which are close to the genital opening where numerous vacuoles and microvilli are seen in the epithelial cells.     

Ultrastructure of spermatozoa of orsolobidae (Haplogynae,Araneae) with implications on the evolution of sperm transfer forms in Dysderoidea

Haplogynae are highly diverse with respect to the primary male genital system and sperm characteristics. Additionally, all sperm transfer forms (STF) known for spiders are present. Besides individually transferred sperm (cleistospermia), sperm are transferred as conjugates, both primary (synspermia) and secondary sperm conjugates (coenospermia, rouleaux) occur. Nevertheless, the ultrastructure of spermatozoa and STF are described for few Haplogynae and often only one representative species was studied, resulting in a superficial insight in the evolution of these traits. To elucidate the evolution of STF within Haplogynae we investigated representatives of four genera of the dysderoid family Orsolobidae. Our data show the presence of synspermia (Orsolobus, Osornolobus, Hickmanolobus, and Tasmanoonops) and also cleistospermia (Osornolobus). The occurrence of different STF within one family or even genus has not been described for any other spider taxon so far. Moreover, the synspermia of species of Tasmanoonops and Hickmanolobus were not covered by a secretion sheath suggesting a previously unknown strategy of transferring sperm that is possibly related to sperm residency time or female triggered processes after copulation. Based on serial ultrathin sectioning and subsequent 3D‐reconstruction, we obtained detailed measurements revealing remarkable size differences of STF. To evaluate the previously suggested correlation with the most distal region of the spermophor inside the embolus (intromittent part of the copulatory organ) we measured the diameter of the spermophor using micro‐computed X‐ray tomography data to obtain corresponding morphometric parameters. Based on these data only two species show similarity in STF and spermophor diameter. J. Morphol. 275:1238–1257, 2014. © 2014 Wiley Periodicals, Inc.     

Sperm storage secretion of female cellar spiders (Pholcus phalangioides; Araneae): a gel-electrophoretic analysis

Glandular secretion in the genital cavity of female Pholcus phalangioides was removed and investigated gel-electrophoretically. Different staining techniques indicate that the secretion contains proteinaceous substances. Some protein fragments show a clear reaction to glyco- and lipoprotein staining procedures.
After copulation, female P. phalangioides keep the spermatozoa embedded in the secretion in the genital cavity. Since the spermatozoa are immobile, i.e. coiled and encapsulated, until shortly before oviposition, a nutritive function of the secretion during sperm storage is unlikely. The viscous quality of the material probably serves to retain the sperm mass in the sperm storage site. Lipoproteinaceous components are assumed to prevent desiccation of the sperm mass. Retaining the spermatozoa and maintaining them in a favourable environment are the most plausible functions of the secretion of female P. phalangioides. In spider species which possess receptacula seminis other functions can be attributed to sperm storage secretions.     

Structure of spermatodesms of Orthoptera Tettigonioidea

Examination of spermatodesms collected from the male and female genital tracts of numerous Orthoptera Tettigonioidea revealed an overall morphological and ultrastructural organization that is generally similar in individuals of the same sex but considerably different between males and females of even the same species. In the male genital tracts each spermatodesm is composed of a limited number of spermatozoa whose nuclei and acrosomes are covered by a mucous cap. The spermatozoa inside each bundle are mainly arranged in parallel rows and are always distinctly separate. The number of spermatozoa per spermatodesm may vary within the same individual although it does not seem to exceed a maximum value that we could only determine exactly in Tettigoniidae species. The most characteristic feature of spermatozoa of all the species examined is a conspicuous elongation of the plasma membrane in the acrosomal region that is not present in the female genital tracts. In addition, spermatodesms from females are composed of highly numerous tightly packed spermatozoa that are linked together via the acrosomal region. This characteristic of spermatodesms, never previously reported in other insect species, would involve their reorganization during transfer from the male to the female genital tracts and would seem to take place in the spermatophore. The probable role of spermatodesms in the reproductive physiology of Tettigonioidea might be related to the degree of maturity of the sex cells transferred to the female; the reorganization of the spermatozoa out of the male genital tracts seems to support this hypothesis.     

Evolutionary morphology of the male reproductive system,spermatozoa and seminal fluid of spiders (Araneae,Arachnida) – Current knowledge and future directions

The male reproductive system and spermatozoa of spiders are known for their high structural diversity. Spider spermatozoa are flagellate and males transfer them to females in a coiled and encapsulated state using their modified pedipalps. Here, we provide a detailed overview of the present state of knowledge of the primary male reproductive system, sperm morphology and the structural diversity of seminal fluids with a focus on functional and evolutionary implications. Secondly, we conceptualized characters for the male genital system, spermiogenesis and spermatozoa for the first time based on published and new data. In total, we scored 40 characters for 129 species from 56 families representing all main spider clades. We obtained synapomorphies for several taxa including Opisthothelae, Araneomorphae, Dysderoidea, Scytodoidea, Telemidae, Linyphioidea, Mimetidae, Synotaxidae and the Divided Cribellum Clade. Furthermore, we recovered synspermia as a synapomorphy for ecribellate Haplogynae and thus propose Synspermiata as new name for this clade. We hope that these data will not only contribute to future phylogenetic studies but will also stimulate much needed evolutionary studies of reproductive systems in spiders.     

大茂山国家森林公园蜘蛛群落结构及多样性研究

2007年5月对河北唐县大茂山国家森林公园蜘蛛的物种多样性和群落结构进行了调查,采用样方与随机扫网相结合的方法,共采集标本728头,隶属25科63种(属)。运用群落多样性指数对其进行分析,研究结果显示:大茂山地区蜘蛛物种多样性丰富,不同生境中蜘蛛群落的种类和结构差别较大。落叶层的蜘蛛种类最多,个体密度最高,群落结构稳定;灌木丛的蜘蛛均匀度最高,结构比较稳定;而草丛中的蜘蛛种类少,个体密度较低,优势种明显。     

Ultrastructure of spermatozoa of Solifuges (Arachnida, Solifugae): possible characters for their phylogeny?

The ultrastructure of spermatozoa is a widely accepted source of characters for phylogenetic studies. In this study the fine structure of sperm cells of representatives of six different New and Old World families (Ammotrechidae, Daesiidae, Eremobatidae, Galeodidae, Karschiidae, Solpugidae) of solifuges (Arachnida, Solifugae) were investigated in order to reveal putative characters suitable for subsequent systematic and phylogenetic analyses. The spermatozoa of solifuges represent a relatively simple type of sperm cells. In general, their spermatozoa are roundish, oval shaped (Ammotrechidae, Daesiidae, Eremobatidae, Solpugidae) or plate-shaped (Karschiidae) with or without membrane protuberances and devoid of a flagellum. Only in Galeodidae, very conspicuous thin and elongated sperm cells occur. The spermatozoa either occur as single cells (Eremobatidae, Solpugidae) or in groups of loose knit cells (Ammotrechidae) or in highly ordered groups (Karschiidae). In contrast to the other families studied here, within the Galeodidae and in the genus Blossia (Daesiidae) sperm cells surrounded by a secretion sheath, clearly representing coenospermia, could be observed.     

Diversity of grass-dwelling spiders (Arachnida: Araneae) in calcareous fens of the Coastal Lowland,Latvia

Calcareous fens have a high conservation priority in the European Union. They are very unique, very sensitive and very rare habitats in Latvia as well as in many other European countries. Because of their rarity, many organisms living in calcareous fens are nowadays considered threatened. The same is applied to spiders. Spiders have been suggested as good biodiversity indicators because they have numerous direct and indirect relationships with other organisms. Only few investigations have been carried out on fen inhabiting spiders. The knowledge of grass-dwelling spiders is especially lacking. Thus the aim of this study was to evaluate grass-dwelling spider diversity in several calcareous fens of Latvia, compare these fens and to find out the habitat features that might affect grass-layer inhabiting spiders. The research was carried out in eight calcareous fens located in the Coastal Lowland of Latvia. A total of 760 spiders from nine families and 20 species were collected with a sweep net. Two of the most abundant spider species were Dolomedes fimbriatus (Clerck, 1757) and Tibellus maritimus (Menge, 1875). Diversity indices suggested that the grass-dwelling spider community consists of few abundant species and numerous rare species. Correlation analysis as well as DCA showed that plant species diversity did not significantly affect spider species richness and diversity, although at the same time there were a lot of significant associations between spiders and individual plant species. It was shown that various spider species responded very differently to the presence of particular plant species, and thus habitat structural heterogeneity emerges to be an important factor influencing the grass-dwelling spider diversity and community structure. Correlation analysis also revealed that spider abundance was negatively affected by the vegetation height and wind speed.     

Copulatory mechanism in a sexually cannibalistic spider with genital mutilation (Araneae: Araneidae: Argiope bruennichi)

Genitalia are among the fastest evolving morphological traits as evidenced by their common function as diagnostic traits in species identification. Even though the main function of genitalia is the successful transfer of spermatozoa, the presence of diverse structures that are obviously not necessary for this suggests that genitalia are a target of sexual selection. The male genitalia of many spider species are extremely complex and equipped with numerous sclerites, plates and spines whose functions are largely unknown. Selection on male genitalia may be particularly strong in sexually cannibalistic spiders, where mating success of males is restricted to a single female. We investigated the copulatory mechanism of the sexually cannibalistic orb weaving spider Argiope bruennichi by shock freezing mating pairs and revealed a complicated interaction between the appendices and sclerites that make up the male gonopods (paired pedipalps). The plate that covers the female genital opening (scape) is secured between two appendices of the male genital bulb, while three sclerites that bear the sperm duct are unfolded and extended into the female copulatory opening. During copulation, females attack and cannibalise the male and males mutilate their genitalia in about 80% of cases. Our study demonstrates that (i) genital coupling is largely accomplished on the external part of the female genitalia, (ii) that the mechanism requires an interaction between several non-sperm-transferring structures and (iii) that there are two predetermined breaking points in the male genitalia. Further comparative work on the genus Argiope will test if the copulatory mechanism with genital mutilation indeed is an adaptation to sexual cannibalism or if cannibalism is a female counter adaptation to male monopolisation through genital plugging.     

Test for predation effects of single versus multiple species of generalist predators: spiders and their insect prey

The prediction that single spider species (as exemplary generalist predators) limit associated prey populations to the same extent that species assemblages do was tested in a well controlled and replicated old field experiment involving the following treatments: (1) the natural spider assemblage (2) a numerically prominent web building spider, (3) a numerically prominent wandering spider, (4) a biomass prominent web-builder, and (5) a biomass prominent wandering spider. Pest insect numbers were significantly higher in spider removal controls than in any spider treament over the four month period of the study, both in terms of total numbers and per spider effects. The individual spider species, in general, showed reduced prey limitation effects relative to that of the spider assemblage, though the magnitudes of these differences were small when compared to those exhibited between the various treatments and the spider removal control. When insect numbers were partitioned according to taxa, no treatment was found to have limited the predaceous insects nor the phytophagous hemipterans. All treatments, however, showed significant limiting effects on the phytophagous homopterans, coleopterans, and dipterans in the old field system, and other taxa were significantly reduced in at least one treatment in addition to the spider assemblage as a whole.     

An ultrastructural study of spermatogenesis and sperm morula breakdown inArenicola marina (L.) (Annelida: Polychaeta)

Spermatogenesis in the lugwormArenicola marina, in common with other members of Arenicolidae, occurs in the coelomic fluid and results in the formation of discs of mature spermatozoa known as a morulae. Within a morula, individual spermatozoa are connected by a common mass of cytoplasm called the cytophore and therefore make up a syncitium. Immediately prior to spawning, and in response to an endocrine substance known as “Sperm Maturation Factor” (SMF), the structure of the sperm morulae breaks down and free spermatozoa are liberated. These are subsequently spawned from the body cavity. The investigation described here uses transmission electron microscopy to investigate the ultrastructural changes, which accompany spermatogenesis and the breakdown of sperm morulae in response to SMF in vitro. The study demonstrates that the cytophore appears to have a key role both during spermatogenesis and during sperm morula breakdown. The ultrastructure of sperm morulae and of mature spermatozoa is described. The structure of spermatozoa is shown to be primitive with a single flagellum which appears to be coiled at its distal end. The phagocytosis of free spermatozoa by coelomocytes is also described and it is suggested that these may play a role in the resorption of unspawned gametes in vivo.     

Spermatozoa of an Old World Ricinulei (Ricinoides karschii, Ricinoidae) with notes about the relationships of Ricinulei within the Arachnida

The ultrastructure of spermatozoa is a valuable tool for phylogenetic and systematic studies. Ricinulei are enigmatic and poorly studied arachnids. So far, spermatozoa are only known from New World ricinuleids. The goals were to study, by means of light and transmission electron microcopy, the spermatozoa of an Old World species with regard to their phylogenetic implications, e.g., does the sperm structure contribute to the debated sister-group relationship of Acari and Ricinulei. The spermatozoa are coiled-flagellate and characterized by a cap-like acrosomal vacuole covered by electron-dense material, an elongated nucleus covered by a manchette of microtubules during spermiogenesis, an axoneme with a 9+2 microtubular pattern, a nuclear tube and axonemal basis which both originate underneath the acrosomal vacuole and cleistospermia as transfer form equipped with three intracellular plates. The data of the present study did not support a close relationship of Ricinulei and Acari which have aflagellate sperm with various synapomorphies as e.g., lacking nuclear envelopes/membranes in Actinotrichida (very similar to Solifugae) or vacuolated spermatozoa in Anactinotrichida. Affinities of Ricinulei are discussed in the light of the ultrastructure of arachnid spermatozoa.     

Copulation duration in the spiderPhilodromus vulgaris (Hentz) (Araneae: Philodromidae) and its influence on the evolution of host transfer behavior during cannibalism byMantispa uhleri banks (Neuroptera: Mantispidae)

Matings and acts of cannibalism were observed in the crab spiderPhilodromus vulgaris, some of which were carrying a first-instar larva of the mantispidMantispa uhleri. Larval mantispids did not transfer during the copulation of their spider hosts but did switch from spider to spider during cannibalism. Twenty-three of 27 total cannibalisms in which the cannibalized spider carried a larva resulted in larval transfers, for a transfer rate of 85%. Copulation times inP. vulgaris were found to be extremely short in comparison to lycosids such asSchizocosa ocreata, whose long copulation time supports the larval transfer ofClimaciella brunnea. The time required for larval transfer during cannibalism inP. vulgaris was measured. Cannibalisms were much longer than copulations but larvae transferred to the cannibalizing spider in a comparatively short period of time.     

Comparative studies of epididymal morphology and sperm distribution in dasyurid marsupials during the breeding season

The structural features of the epididymis and the number and distribution of spermatozoa along the duct, during the breeding season, were examined in two semelparous and three iteroparous dasyurid marsupials. Total numbers of epididymal spermatozoa were extremely low in all of these species when compared with epididymal sperm numbers in most other marsupials and eutherian mammals. Although semelparous dasyurids had significantly more epididymal spermatozoa than itcroparous species, very few spermatozoa were seen in the distal cauda epididymidis of any of the species examined. This coincided with distinct changes in duct shape and the surface area of the lumen in caudal regions which resulted in a reduced sperm storage capacity in the cauda epididymidis of these species. The data suggest that, like Antechinus stuartii (Taggart & Temple-Smith, 1990a), sperm content of the ejaculates in these species will be extremely low, and that sperm motility and/or transport in the female tract is highly efficient. The functional and evolutionary significance of the reproductive strategies of semelparous and iteroparous dasyurid marsupials is still obscure and further study is needed to determine if the length of sperm storage in the female and sperm competition for storage sites is related to sperm distribution in the male and mating activities. This study does, however, clearly indicate that large numbers of spermatozoa are not required to ensure successful fertilization in either semelparous or iteroparous members of the family Dasyuridae.     

Motility and dynamics of eupyrene and apyrene sperm in the spermatheca of the monandrous swallowtail butterfly Byasa alcinous

Lepidopteran males produce two sperm types: nucleated eupyrene sperm and non‐nucleated apyrene sperm. Although apyrene sperm are infertile, both sperm types migrate from the spermatophore to the spermathecal after copulation. As a dominant adaptive explanation for migration of apyrene sperm in polyandrous species, the cheap filler hypothesis suggests that the presence of a large number of motile apyrene sperm in the spermatheca reduces female receptivity to re‐mating. However, apyrene sperm are also produced in males of the monandrous swallowtail butterfly Byasa alcinous Klug. To identify the role of apyrene sperm in these males, the present study examines the number of spermatozoa produced and transferred and the dynamics and motility of spermatozoa in the spermatheca for each type of sperm. Apyrene sperm represents approximatey 89% of the sperm produced and transferred, which is comparable to polyandrous species. Two‐day‐old males transfer approximately 17 000 eupyrene and 230 000 apyrene spermatozoa to a spermatophore; approximately 5000 eupyrene and 47 000 apyrene spermatozoa arrive at the spermatheca. Eight days after copulation, most eupyrene spermatozoa remain in the spermatheca and a quarter of them are still active. However, the number of apyrene spermatozoa decreases and those remaining lose their motility after the arriving at the spermatheca. Consequently, 8 days after copulation, no motile apyrene sperm are found. The high proportion of apyrene sperm in the spermatophore, as well as in sperm migration, suggests that the production and migration of apyrene sperm is not simply an evolutionary vestigial trait. The possible functions of apyrene sperm in monandrous species are discussed.     

Fundamental aspects of sperm cryobiology: the importance of species and individual differences

While semen cryopreservation is successfully used for a few species, application to other species can be problematic. Here, I argue that species differences in female tract anatomy, subtle differences in sperm transport mechanisms, ability to time inseminations and deliver spermatozoa effectively are powerful determinants of fertility with cryopreserved spermatozoa. Poor sperm survival represents one major aspects of the problem and determining biophysical characteristics of the sperm plasma membrane is an established approach to solving it. However, this approach is unable to account for the consistent differences in post-cryopreservation sperm quality between individual males, an effect that is recognized is many species although only documented in a few. Searching for genetic differences between these individuals might offer a genomically-based direction in semen cryopreservation research. Cryopreservation of spermatozoa and spermatogenic cells for intracytoplasmic sperm injection has been developed primarily to deliver an intact genome and presents a very different set of technical problems.     

Production of reactive oxygen species by spermatozoa undergoing cooling, freezing, and thawing

In the present study, we provide evidence for the production of reactive oxygen species (ROS) during cryopreservation of bovine spermatozoa. Cooling and thawing of spermatozoa cause an increase in the generation of superoxide radicals. Although nitric oxide production remains unaltered during sperm cooling from 22-4 degrees C, a sudden burst of nitric oxide radicals is observed during thawing. Increase in lipid peroxidation levels have been observed in frozen/thawed spermatozoa and appears to be associated with a reduction in sperm membrane fluidity as detected by spin labeling studies. The data presented provide strong evidence that oxygen free radicals are produced during freezing and thawing of bovine spermatozoa and suggest that these reactive oxygen species may be a cause for the decrease in sperm function following cryopreservation. Mol. Reprod. Dev. 59: 451-458, 2001.