How is the flagellar length of mature sperm determined? : II. Comparison of tubulin synthesis in spermatids between newt and Xenopus in vitro

In order to elucidate mechanisms that control flagellar length of mature sperm, we studied in synchronous cell suspension cultures flagellar growth, tubulin pool, and tubulin synthesis in round spermatids of Xenopus laevis and the newt Cynops pyrrhogaster. The average final length of flagella in Xenopus round spermatids was 35 μm, almost the same length as that in mature sperm, whereas in the newt round spermatids, the length was 210 μm, almost half that of mature sperm. Kinetics of flagellar growth showed that the rate and period of flagellar growth in the newt spermatids were two to threefold those in Xenopus spermatids. The tubulin pool size in newt spermatids was estimated to be about 10-fold greater than that in Xenopus spermatids. But even if all of the pool was used for flagellar growth, it could support only about a seventh to a tenth of the flagellar length in mature sperm in either species. Thus, the possibility that the tubulin pool primarily determines flagellar length was excluded. Since the tubulin pool size did not change throughout the culture period, the possibility that the termination of flagellar growth is due to the exhaustion of the tubulin pool was also excluded. Tubulin synthesis declined over the culture period but continued in newt spermatids longer than in Xenopus spermatids. The period of flagellar elongation almost coincided with the period of tubulin synthesis. The amount of rRNA did not decrease, excluding the possibility that the decline of tubulin synthesis was due to cytoplasmic shedding which might result in the loss of ribosomes. Tubulin synthesis and the amount of rRNA in newt spermatids was more than threefold greater than that in Xenopus spermatids, which may explain the difference in growth rates of their flagella.     

Spermatogenesis and sperm structure of Acerella muscorum, (Ionescu, 1930) (Hexapoda, Protura)

The general organization of the male genital system, the spermatogenesis and the sperm structure of the proturan Acerella muscorum have been described. At the apex of testis apical huge cells are present; their cytoplasm contains a conventional centriole, a large amount of dense material and several less electron-dense masses surrounded by mitochondria. Spermatocytes have normal centrioles and are interconnected by cytoplasmic bridges. Such bridges seem to be absent between spermatid cells and justify the lack of synchronization of cell maturation. Spermatids are almost globular cells with a spheroidal nucleus and a large mass of dense material corresponding to the centriole adjunct. Within this mass a centriole is preserved. Mitochondria of normal structure are located between the nucleus and the plasma membrane. The spermatids are surrounded by a thick membrane. No flagellar structure is formed. Sperm have a compact spheroidal nucleus, a large cap of centriole adjunct material within which a centriole is still visible. A layer of mitochondria is located over the nucleus. The cytoplasm is reduced in comparison to spermatids; many dense bodies are interspersed with sperm in the testicular lumen. The sperm are small, immotile cells of about 2.5-3 μm in diameter.     

ZYGOTE FORMATION IN ASCARIS LUMBRICOIDES (NEMATODA)

Ultrastructural observations of the in utero sperm of Ascaris lumbricoides reveal that it consists of a relatively clear, ameboid anterior region and a conical posterior region containing numerous surface membrane specializations, dense mitochondria, a lipid-like refringent body of variable size, and a dense nucleus which lacks an apparent nuclear envelope. No acrosomal complex was observed. Pseudopods emanating from the anterior cytoplasm make first contact with the primary oocytes and appear to be responsible for the localized removal of the extraneous coat covering the oolemma. Subsequently the gamete membranes interdigitate and finally fuse. Because this pseudopodial action appears similar to that reported for the acrosomal filaments in flagellated sperm, the anterior region of the Ascaris sperm is thought to serve an acrosomal function. Following gamete-membrane fusion, the sperm nucleus acquires a particulate appearance and becomes disorganized. Once inside the oocyte, the sperm cytoplasm consists of dense mitochondria, ribosomes, and vesicles derived from the surface membrane specializations. The refringent body, whose contents possibly contribute to the synthesis of ribosomes, is usually absent by the time the sperm cytoplasm attains a central position in the egg.     

Somatic tissue–male germ cell barrier in Hydra viridis (hydrozoa,coelenterata)

In Hydra viridis, cordons of male germ cells lie in gonadal compartments, which are enlarged spaces between the elongated and “spongy” epidermal cells. The germ cells are surrounded by these cells, except for small areas where the interstitial cells and spermatogonia are in direct contact with the mesoglea. Cells from both epidermis and gastrodermis project cytoplasm into the mesoglea, where they contact each other and form trans-mesogleal bridges. The latter exhibit gap junctions, which are particularly abundant at the spermary region. Here, the mesoglea is thinner then elsewhere in the body. Both epithelia are joined by septate junctions toward their apical ends, which are totally impermeable to horseradish peroxidase (HRP). HRP gained entry to the cells of both epithelia by pinocytosis. Incorporation into the cells was high at the basal disk, in the tentacles, and in the mesoglea in the lower part of the body stalk. The tracer was never found within the gonadal space of the testis during spermatogenesis. In mature spermaries during spermiation, tracer-filled intracellular vacuoles fused with the gonadal spaces as the thin cytoplasmic columns of the epidermal cells ruptured; HRP thus gained access to the germ cells. During spermatogenesis, germ cells of Hydra viridis are in a closed compartment. The barrier that controls the access of metabolites to the germ cells is formed by epidermal cells, thinned-out mesoglea, and numerous transmesogleal interepithelial bridges. The presumed role of the barrier is the control of the environment (1) where interstitial cells are differentiating into spermatogonia and meiosis occurs and (2) in which ripe spermatozoa are kept immotile until spermiation.     

Temporal pattern of the double sperm line production in Tubifex tubifex (Annelida,Oligochaeta)

Laboratory cohort cultures of the tubificid Tubifex tubifexwere carried out at 21 °C in homogeneous conditions. Our aim was to study the temporal pattern of spermatogenesis of the two sperm lines which characterise this species. Starting from the second week after cocoon laying, we analysed the seminal vesicle content. We counted the cysts in the vesicles and arranged them into three classes: premeiotic, paraspermatids and euspermatids. Our results show that spermatogenesis begins early, at week 3, but cysts of spermatids are not found until week 5 for the parasperm line and week 6 for the eusperm line. These data are derived from a preliminary study of complex population dynamics. Nonetheless, they allow us to formulate some hypothesis regarding the mechanism which regulate the production of the two types of sperm.     

How is the flagellar length of mature sperm determined? II. Comparison of tubulin synthesis in spermatids between newt and Xenopus in vitro

In order to elucidate mechanisms that control flagellar length of mature sperm, we studied in synchronous cell suspension cultures flagellar growth, tubulin pool, and tubulin synthesis in round spermatids of Xenopus laevis and the newt Cynops pyrrhogaster. The average final length of flagella in Xenopus round spermatids was 35 mum, almost the same length as that in mature sperm, whereas in the newt round spermatids, the length was 210 mum, almost half that of mature sperm. Kinetics of flagellar growth showed that the rate and period of flagellar growth in the newt spermatids were two to threefold those in Xenopus spermatids. The tubulin pool size in newt spermatids was estimated to be about 10-fold greater than that in Xenopus spermatids. But even if all of the pool was used for flagellar growth, it could support only about a seventh to a tenth of the flagellar length in mature sperm in either species. Thus, the possibility that the tubulin pool primarily determines flagellar length was excluded. Since the tubulin pool size did not change throughout the culture period, the possibility that the termination of flagellar growth is due to the exhaustion of the tubulin pool was also excluded. Tubulin synthesis declined over the culture period but continued in newt spermatids longer than in Xenopus spermatids. The period of flagellar elongation almost coincided with the period of tubulin synthesis. The amount of rRNA did not decrease, excluding the possibility that the decline of tubulin synthesis was due to cytoplasmic shedding which might result in the loss of ribosomes. Tubulin synthesis and the amount of rRNA in newt spermatids was more than threefold greater than that in Xenopus spermatids, which may explain the difference in growth rates of their flagella.     

Fine structure of the male genital system of the predatory mite Rhagidia halophila (Rhagidiidae,Prostigmata, Actinotrichida)

The male genital system of the actinotrichid mite Rhagidia halophila is described and compared with other mites and arachnids. The large testes are composed of germinal and glandular parts and produce numerous small sperm cells. The glandular parts are connected via a testicular bridge. Spermiogenesis occurs in cysts containing spermatids in equal stages of development. Cysts of spermatids are embedded in huge somatic cells. The nuclei of the spermatids loose their envelope. Mature sperm cells are simple exhibiting a ring‐shaped chromatin body and lacking an acrosomal complex. They are most similar to the sperm cells of the related mite Linopodes motatorius. The spermatopositor contains the ejaculatory duct divided into a dorsal channel and a ventral channel that are connected via a narrow passage. At its distal end, the spermatopositor is divided into three eugenital lips. The function of the spermatopositor during deposition of the peculiar thread‐like spermatophores is discussed. Details of the sensilla of the spermatopositor and the progenital lips are reported. The genital papillae located on the inner side of the progenital lips exhibit characteristics of cells performing transport of ions and/or water. The results confirm the overall similarity of actinotrichid genital systems, which is profoundly different from that of anactinotrichid mites. With reference to other Arachnida it is corroborated that testes and sperm structure of Actinotrichida are most similar to that of Solifugae. However, synapomorphies between sperm cells of Rhagidia and Solifugae that could suggest a closer relationship between these two taxa as was suggested in earlier studies were not recognizable. On the contrary, the sperm cells of Rh. halophila being devoid of an acrosomal complex appeared to be more apomorphic than those of many other actinotrichid mites as well as Solifugae. J. Morphol. 276:832–859, 2015. © 2015 Wiley Periodicals, Inc.     

TRANSFER OF THE GASTROPOD FAMILY PLESIOTROCHIDAE TO THE CAMPANILOIDEA BASED ON SPERM ULTRASTRUCTURAL EVIDENCE

Using sperm ultrastructure the systematic placement and affinitiesof the caenogastropod family Plesiotrochidae are re-examined.The simultaneous hermaphrodite, Plesiotrochus crinitus Thiele,1930, produces both euspermatozoa (uniflagellate, fertile sperm)and paraspermatozoa (bi- or triflagellate, infertile sperm).Features of each type of sperm clearly indicate that the Plesiotrochidaeare closely related to the Campanilidae (Campaniloidea) andare not, as previously believed, referable to the superfamilyCerithioidea. Significant sperm synapomorphies of Plesiotrochus(Plesiotrochidae) and Campanile (Campanilidae) include the morphologyof the eusperm midpiece (seven to nine straight mitochondriasurrounded by a segmented, accessory sheath of membrane-boundvesicles) and morphology of the anucleate parasperm head (axialcore of mitochondria surrounded by a bilaterally symmetricalarrangement of axonemes and dense vesicles). The characteristicsubstructure of the cerithioidean eusperm midpiece (four straightmitochondria each containing parallel, cristal plates) is notobserved in Plesiotrochus or Campanile. Euspermatozoa of Plesiotrochusdiffer from Campanile principally in details of the acrosomalcomplex (Plesiotrochus with apical bleb, probable absence ofan accessory membrane; Campanile without apical bleb, accessorymembrane well developed), the transverse profile of all midpiecemitochondria (thin in Plesiotrochus; thick in Campanile), andmorphology of the annulus (double ring in Plesiotrochus; singlering in Campanile). In addition, all observed paraspermatozoaof Plesiotrochus are anucleate, whereas in Campanile anucleateand nucleate paraspermatozoa are present. On the basis of spermsynapomorphies of Plesiotrochus and Campanile, the Plesiotrochidaeare transferred from the Cerithioidea to the Campaniloidea. (Received 3 August 1992; accepted 18 September 1992)     

THE FINE STRUCTURE OF DIFFERENTIATING SPERMATOZOA AND SERTOLI CELLS IN THE GONAD OF THE POND SNAIL, LYMNAEA STAGNALIS

The fine structure has been examined, of spermatogonia, spermatocytes,early spermatids, late spermatids and early spermatozoa nestlingagainst Sertoli cells in the gonad of Lymnaea stagnalis. Changes in the Sertoli cells are linked with the phases of spermdifferentiation. Details on differentiation particularly ofthe head of the sperm, are presented. (Received 14 March 1981;     

Cyclic changes in the testis of the brook stickleback Eucalia inconstans (Kirtland)

The cyclic changes in the testis of the five-spined stickleback Eucalia inconstans (Kirtland) were studied histologically. Specimens were trapped between July 1965 and July 1967 in a shallow pond near London, Ontario. A three-dimensional microscopic study showed a main vas deferens and a system of primary, secondary and tertiary tubules. The testis cycle was divided into seven arbitrary stages. Spawning takes place from mid-April to mid-July. This is followed by the division of primary spermatogonia which are located along the walls of the tubules, producing cysts of spermatogonia enclosed in connective tissue which is surrounded by a thin epithelium. Both primary and secondary spermatocytes develop within these cysts. Breakdown of the cysts occurs with the development of spermatids and spermiogenesis occurs while spermatids are free in the tubules. Over-wintering of mature sperm takes place. Development of mature sperm from primary spermatogonia takes about 156 days. Germinal epithelium is absent but primary germ cells are believed to be those cells occupying the spaces between the tubules of the testis. No tissue which might be implicated in hormone production was observed. Phagocytic invasion of the testis has been studied. Massive infiltration by phagocytes is believed to be responsible for the sudden increase in testis weight observed during spawning. These cells ingest sperm nuclei and groups of them have been observed in the lumen of the tubules and the vas deferens, probably on their way out of the body.     

TMF/ARA160: A key regulator of sperm development

TMF/ARA160 is a Golgi-associated protein to which several cellular activities have been attributed. These include, trafficking of Golgi-derived vesicles and E3 ubiquitin ligase activity. Here we show that TMF/ARA160 is required for the onset of key processes which underlie the development of mature sperm in mammals.TMF/ARA160 is highly expressed in specific spermatogenic stages. While the protein is not detected in the spermatogenic progenitor cells — spermatogonia, it accumulates in the Golgi of spermatocytes and spermatids but then disappears and is absent from spermatozoa and epididymal sperm cells. Mice that are homozygous null for TMF develop normally are healthy and the females are fertile. However, the males are sterile and their spermatids suffer from several developmental defects. They lack homing of Golgi-derived proacrosomal vesicles to the perinuclear surface, resulting in spermatozoa and epididymal sperm cells which lack acrosome. In a later developmental stage, the cytoplasm is not properly removed, thus resulting in spermatids which bare the nucleus with tightly packed DNA, surrounded by a cytoplasm. Finally, the spermatozoa of TMF^−/− mice also suffer from misshaped heads, tails coiling around the sperm heads, and lack of motility. Taken together our findings portray TMF/ARA160 as a key regulator which is essential for the onset of key events in the differentiation and maturation of mammalian sperm and whose absence severely compromises their ability to fertilize ova.     

Fine structure of spermiogenesis with special reference to the spermatid morulae of the freshwater mussel Prisodon alatus (Bivalvia,Unionoidea)

Within the testicular cysts of the mussel Prisodon alatus are numerous somatic host cells described as Sertoli cells (SC), each containing a variable number of young spermatid morulae. Among them, several free spermatid morulae, spermatids, and spermatozoa were observed. Each free spermatid morula is surrounded by an external membrane. The early spermatids enclosed within the morulae have dense and homogeneous chromatin, and the cytoplasm occupies little space around the nucleus. Later, during spermiogenesis, the SC show lysis and disrupt to liberate the spermatid morulae. The membrane of the free morula is then disrupted, releasing the young spermatids. The SC disappear just after the appearance in the testis of a large number of free young spermatids. The nucleus of each free spermatid becomes gradually smaller and denser by the appearance of a granular pattern of condensed chromatin. During the maturation phase of the spermatids, the cytoplasm becomes more voluminous, and mitochondria and centrioles are more evident. Then, flagellogenesis occurs, and the nucleus gradually condenses into thicker strands. In the mature sperm, the apical zone has a disc-shaped acrosomal vesicle and the midpiece contains five mitochondria and two centrioles located at the same level. The flagellum has the common 9+2 microtubular pattern. The results are discussed with particular reference to Sertoli cells and clusters of spermatid morulae with those of species of closely related taxa in the bivalves. J. Morphol. 238:63–70, 1998. © 1998 Wiley-Liss, Inc.     

Association of egg zona pellucida glycoprotein mZP3 with sperm protein sp56 during fertilization in mice.

Purified mouse sperm receptor, a zona pellucida glycoprotein called mZP3, binds to plasma membrane overlying acrosome-intact sperm heads (P.M. Wassarman, 1999, Cell 96, 175-183). Some evidence suggests that mZP3 binds to sp56, a protein reported to be associated peripherally with the plasma membrane of acrosome-intact sperm heads (J.D. Bleil and P.M. Wassarman, 1990, Proc. Natl. Acad. Sci., USA 87, 7215-7219; A. Cheng et al., 1994, J. Cell Biol. 125, 867-878). Here, we report that membrane vesicles prepared from acrosome-intact sperm contain sp56. When these vesicles are incubated with eggs they inhibit binding of sperm to eggs in vitro (ID50 approximately 50-100 microg protein/ml). On the other hand, a monoclonal antibody directed against sp56 relieves the inhibition of binding of sperm to eggs by membrane vesicles. As expected, incubation of intact sperm with the antibody directed against sp56 inhibits binding of the sperm to eggs. Results of immunoprecipitation of sperm extracts incubated with mZP3, by either a polyclonal antibody directed against mZP3 or a monoclonal antibody directed against sp56, suggest that mZP3 is specifically associated with sp56. Results of laser scanning confocal microscopy of fixed sperm probed with antibodies directed against either sp56 or a approximately 155 kDa acrosomal protein, suggest that the two proteins are present in the acrosome, but with different distributions. Furthermore, confocal images of sperm, fixed after exposure to purified mZP3 and probed with antibodies against mZP3 and sp56, reveal overlap between mZP3 and sp56 at the surface of the sperm head. The possible implications of these results are discussed in the context of mammalian fertilization.     

The Spermatozoon of Brachionus plicatilis(Rotifera,Monogononta) With Some Notes on Sperm Ultrastructure in Rotifera

The spermatozoon of B. plicatilisis a thread–like cell with an anterior flagellar portion and a posterior cell body. The flagellum has a lateral ‘undulating membrane’, containing a folded longitudinal cisterna and an axoneme. The basal body of the axoneme is at the anterior tip. The axoneme lacks outer dynein arms and extends through the entire flagellar region and most of the cell body. The main portion of the flagellum and of the cell body contains a series of vesicles with tightly packed tubules that may serve as a cytoskeleton. The cell body contains a partly condensed nucleus, several mitochondria and some cytoplasm. Some elongated mitochondria are arranged in the postnuclear region. When the spermatozoon moves, the undulations propagate from the basal body at the flagellar tip. Late spermatids can be recognized by the nucleus and the flagellum being coiled and enclosed within a common cell membrane. As in other rotifers, there are cigar–like cell products (‘rods’) in the testes. The general organization of the cell, including the absence of an evident acrosome, resembles that of the other known monogonont sperm types.     

The Sperm‐surface glycoprotein,SGP, is necessary for fertilization in the frog,Xenopus laevis

To identify a molecule involved in sperm‐egg plasma membrane binding at fertilization, a monoclonal antibody against a sperm‐surface glycoprotein (SGP) was obtained by immunizing mice with a sperm membrane fraction of the frog, Xenopus laevis, followed by screening of the culture supernatants based on their inhibitory activity against fertilization. The fertilization of both jellied and denuded eggs was effectively inhibited by pretreatment of sperm with intact anti‐SGP antibody as well as its Fab fragment, indicating that the antibody recognizes a molecule on the sperm's surface that is necessary for fertilization. On Western blots, the anti‐SGP antibody recognized large molecules, with molecular masses of 65–150 kDa and minor smaller molecules with masses of 20–28 kDa in the sperm membrane vesicles. SGP was distributed over nearly the entire surface of the sperm, probably as an integral membrane protein in close association with microfilaments. More membrane vesicles containing SGP bound to the surface were found in the animal hemisphere compared with the vegetal hemisphere in unfertilized eggs, but the vesicle‐binding was not observed in fertilized eggs. These results indicate that SGP mediates sperm‐egg membrane binding and is responsible for the establishment of fertilization in Xenopus.     

Ultrastructure of sperm development in the free-living marine nematode Metachromadora itoi (Chromadoria, Desmodorida)

The spermatogenesis of the free‐living marine nematode Metachromadora itoi was studied with electron microscopy. Spermatocytes and early spermatids have no cytoplasmic components specific for nematodes, i.e. membranous organelles (MO) and fibrous bodies (FB). The late spermatids are subdivided into the residual body and the main cell body with a centrally located nucleus devoid of a nuclear envelope. A pair of 9 × 2 centrioles is associated with the nuclei of spermatids and spermatozoa. The nucleus of the mature spermatid is surrounded by a thick mass of radially arranged FB delimited externally by a discontinuous layer of mitochondria, which underlie a thin ectoplasm. Sperm development is accompanied by transfer of FB matter through the mitochondrion layer into the ectoplasm. The immature spermatozoa from the testis have the centrally located nucleus surrounded by a transparent halo with remnants of FB. The halo is delimited by a sphere of mitochondria that underlie the thick fibrous ectoplasm, a derivative of the FB. In the mature spermatozoa the ectoplasm is transformed into the prominent unpolarized pseudopod. The central nucleus is surrounded by a transparent halo and a sphere of mitochondria, which underlie the pseudopod. MO were not found throughout spermatogenesis. In general, spermatogenesis in M. itoi differs from that observed in many nematodes but resembles in some details the sperm development in some chromadorid and tylenchomorph nematodes. The phylogenetic importance of this sperm development is discussed.     

The location of the major protein in Caenorhabditis elegans sperm and spermatocytes

Using an affinity-purified antibody to the major sperm protein (MSP) in Caenorhabditis elegans sperm we have shown by immunofluorescence that the MSP is localized in the fibrous bodies of spermatocytes and early spermatids, in the cytoplasm of late spermatids, and in the pseudopods of spermatozoa. The MSP can also form crystalline inclusions in mutant and wild-type sperm. The function of this protein is still unknown, but its ability to form filaments and its localization in the pseudopod, together with the lack of actin in these sperm suggest that the MSP may be required for amoeboid motility.     

SPERM AND SPERMIOGENIC ULTRASTRUCTURE IN THE MATHILDIDAE WITH A REVIEW OF SPERM MORPHOLOGY AND ITS SYSTEMATIC IMPORTANCE IN THE ARCHITECTONICOIDEA (GASTROPODA)

The ultrastructure of spermiogenesis and spermatozoa is examinedfor the first time in the heterogastropod family Mathildidae(Mathilda brevicula Bavay and Mathilda sp.). Mathildid spermatozoaexhibit the following features: (1) an ovoid acrosomal vesicleshowing curved dense layers basally and underlain by a thincurved plate; (2) a solid, rod-shaped nucleus showing a shallowbasal invagination (nucleus helically keeled in Mathilda sp.);(3) a midpiece composed of a 9+2 axoneme, 9 thick and periodicallybanded coarse fibres (associated with the axonemal doublets)and a continuous mitochondrial derivative; (5) glyco-gen piececomposed of the axoneme surrounded by dense granules; (6) andend piece (paddle-shaped terminally). Results of the study demonstratethat mathildids share the same key sperm and spermi-ogenic featuresobserved in the Architectonicidae. The monophyly of the Architectonicoidea,established by previous authors on anatomical grounds, is thereforeconfirmed using sperm morphology. Spermatozoa of the two mathildidsinvestigated lack the periodically banded midpiece structuresseen in investigated species of Architectonica (A. pcrspectiva(Linnaeus), A. perdix (Hinds)), Heliacus (H. (Heliacus) variegatus(Gmelin)) and Pseudotorinia (P. laseronorum (Iredale)) therebyresembling most closely the spermatozoaof Philippia lutea (Lamarck)and Psilaxis oxytropis (A. Adams) which also lack suchbandedstructures. Given the widely accepted primitive status of theMathildidae within the Architectonicoidea, the genera Philippiaand Psilaxis may prove to be relatively basal rather than advancedgenera within the Architectonicidae. Thi: view needs to be testedby examination of sperm morphology in other genera of the Architectonicidaeand also the basal mathildid genus Tuba sensu lato (= Gegania+ Tubena). Such information will be vital in any future cladisticstudy of the Architectonicoidea. (Received 16 June 1994; accepted 6 February 1995)     

UTILIZATION AND DEGREE OF DEPLETION OF EXOGENOUS SPERM IN THREE HERMAPHRODITIC SEA HARES OF THE GENUS APLYSIA (GASTROPODA: OPISTHOBRANCHIA)

Two series of experiments were conducted to examine the utilizationof exogenous sperm and their degree of depletion in three hermaphroditicsea hares, Aplysia kurodai Baba, 1937, A. Juliana Quoy &Gaunard, 1832, and A. parvula Guilding in MOrch, 1863. The firstseries of experiments was designed to determine whether onemating is enough for female partners to receive sufficient spermto fertilize at least one egg mass. For this purpose, isolatedindividuals were mated as females once with conspecific individualsand the viability of their subsequent eggs was examined. Whensuccessfully inseminated, individuals of all the three speciesreceived enough sperm to fertilize at least one egg mass, andthey continued to lay 3.6–8.5 viable egg masses. However,10–36% of the matings by these sea hares did not resultin any viable egg production by the female partner, indicatingthat these matings did not involve sperm transfer Such matingswithout sperm transfer tended to be shorter than matings withsuccessful sperm transfer The second experimental series wasconducted to examine whether sperm depletion actually occursor not in field-caught adults. For this purpose, adult individualscaught in the field were allowed to lay eggs under isolatedconditions without mating All the individuals of A. kurodaiand A. juliana stored enough sperm to fertilize at least oneegg mass. However, in A. parvula, 23–33% of individualslaid egg masses containing non-viable eggs at their first spawningafter isolation, indicating that these individuals were depletedin exogenous sperm (Received 17 July 1995; accepted 18 August 1995)     

Participation of testicular spermatids in development upon intracytoplasmic injection into eggs of the sawfly, Athalia rosae (Insecta, hymenoptera)

Fertilization by intracytoplasmic injection of mature sperm into mature eggs has previously been achieved in the sawfly, Athalia rosae (Insecta, Hymenoptera). In the present study, we examined the potential of spermatids, premature male gametes, for participating in development. When round spermatids and elongating spermatids from pupal testes were injected into the anterior end of mature eggs, about 5% of the total injected eggs developed into chimeric embryos (independent participation in development of the egg and spermatid nuclei). Some of them developed further, hatched, and pupated, with 1-2% of the total injected eggs becoming haploid chimeric male adults in which both the egg-derived and injected spermatid-derived nuclei contributed to the germline. No fertilized embryos were obtained by these injections. Elongated spermatids (immature sperm) from newly eclosed adult male testes upon injection did produce fertilized embryos that developed into normal diploid females (about 7% of the total injected). These results indicate that insect spermatids (round and elongating) have the potential to participate in development, but only independently of the egg nucleus. J. Exp. Zool. 286:181-192, 2000.