Microstructural analysis on the testicular cyst of the wolf spider by 3D volume rendering

Spermatogenesis has long been a major research area in understanding the development of living organisms. In vertebrates, sperm is produced along the wall of the seminiferous tubules, leaving spermatogonia in the outermost layer, which undergo cell division and differentiation. However, sperm in many invertebrates is developed in a testicular cyst, which contains germ cells at the same developmental stages. On the contrary, in spiders, it is very difficult to count the exact number of cells in a cyst, since each spermatid gets transformed to a round sperm ball within the cyst through the flagellar coiling process. Therefore, in this study, we applied a 3D rendering technique to analyze the exact number of germ cells per cyst in spiders. For image processing and reconstruction, serial section images were scanned and reconstructed into 3D images. Upon successful 3‐dimensional reconstruction of testicular cysts, the exact number of germ cells produced from a single cyst appeared to be 64, 2⁶ which indicates that a spider spermatogonium undergoes 6 cell divisions to produce spermatozoa.     

Structural analysis of theridiid spider's testicular cyst using 3D reconstruction rendering

A three dimensional reconstruction technique was used for the analysis of a theridiid spider's (Achaearanea tepidariorum) testicular cyst. Although microscopic techniques have greatly improved, most of the information gathered is still based on two‐dimensional images. Particularly in spiders, it is very difficult to count the exact number of sperm in a single cyst, since their spermatogenetic processes takes place within the spherical cysts through the flagellar coiling process. Since morphological features of spider sperm provide detailed information on the whole spermatogenetic processes, we analyzed the exact number of germ cells per cyst in A. tepidariorum through a three‐dimensional image reconstruction technique. For image processing, serially sectioned histological images were scanned using a light microscope and 3D rendering images were reconstructed from these sections. Based on the three dimensional image analysis of the testicular cyst, the number of secondary spermatocytes per cyst was calculated to be 32 (2⁵). Therefore the total number of sperm produced from a single cyst can be calculated as 64 (2⁶), which indicates that a single spermatogonium undergoes four mitotic divisions and an additional two meiotic divisions to produce mature spermatozoa.     

Microstructural Reconstruction for the Testicular Cysts of Wolf Spider Using 3D Volume Rendering Technique

In insects, the alignment of neighboring spermatid in the late stages is nearly perfect, so that a transverse section of a cyst containing late spermatids transects all the spermatids at approximately the same level. However, the testicular cysts of spiders are spherical, most cysts are arranged in order of increasing maturity from the periphery to the center of the testis. For this reason, it is difficult to observe the whole spermatids within a single microscopic slide and count them. Therefore, we demonstrate microstructural reconstruction technique enabling to count exact number of sperm cells per cyst with aid of 3D volume rendering. For image processing and reconstruction, serially sectioned histologic specimens were scanned with microscopy and 3D images were reconstructed using Amira 5.3.2 software from the image stacks of the germ cells and surrounding testicular cysts subsequentially. With the information gathered by 3D reconstruction, it has finally been counted that exactly 32 (2⁵) cells of the secondary spermatocytes per cyst. This means that most cysts in P. laura contain exactly 64 (2⁶) spermatids or spermatozoa, which presumably arose from four synchronous mitotic and two meiotic divisions. In addition, the number of divisions occurring in a cyst appears to be constant for this spider because it has been known that the number of spermatids per cyst is characteristic for each species.     

Evidence for asynchronous mitotic cell divisions in secondary spermatogonia of Drosophila

Examination of germ cell numbers within premeiotic as well as postmeiotic cysts of various Drosophila species gave evidence against any strict synchrony of mitotic cell division in secondary spermatogonia. The evidence was based on numbers of germ cells in primary spermatocyte cysts and spermatid bundles. Each species examined had its own distribution of primary spermatocyte cyst types in pupal testes, and the most common cyst type did not necessarily contain 2, 4, 8, 16 or (2) ⁿ germ cells which implies asynchrony of the previous spermatogonial divisions. Similar but not exactly the same distributions of germ cells were found in adult spermatid bundles, if allowances were made for a 4-fold increase in germ cell number during meiosis. This observation gives support to the operation of an age-dependent factor which controls germ cell numbers within cysts [1], The data thus suggest that the commonly accepted concept of a (2) ⁿ increase of spermatogonia via synchronous mitotic divisions is not true for the species of Drosophila studied.     

Sperm cell number per bundle in Gnorimus nobilis L. (Coleoptera,Scarabaeidae)

An attempt was made to determine the number of spermatozoa per bundle in a scarabaeoid species Gnorimus nobilis both through the analysis of the premeiotic cytology of germ line cells and by counting the spermatids within a spermiocyst at the beginning of the process of spermiogenesis. The obtained results, taken together, indicate that definitive spermatogonia go through a series of 6 synchronous mitotic divisions before entering meiosis as primary spermatocytes, which in turn produce 256 (2⁸) spermatozoa per bundle after completion of meiosis and spermiogenesis. The obtained data are compared with similar ones for other beetle species belonging to the family Scarabaeidae and the suborder Coleoptera-Polyphaga, respectively. Also, some phylogenetic implications of these data are briefly discussed.     

Factors affecting spermatogenesis in the stallion

Spermatogenesis is a process of division and differentiation by which spermatozoa are produced in seminiferous tubules. Seminiferous tubules are composed of somatic cells (myoid cells and Sertoli cells) and germ cells (spermatogonia, spermatocytes, and spermatids). Activities of these three germ cells divide spermatogenesis into spermatocytogenesis, meiosis, and spermiogenesis, respectively. Spermatocytogenesis involves mitotic cell division to increase the yield of spermatogenesis and to produce stem cells and primary spermatocytes. Meiosis involves duplication and exchange of genetic material and two cell divisions that reduce the chromosome number to haploid and yield four spermatids. Spermiogenesis is the differentiation without division of spherical spermatids into mature spermatids which are released from the luminal free surface as spermatozoa. The spermatogenic cycle (12.2 days in the horse) is superimposed on the three major divisions of spermatogenesis which takes 57 days. Spermatogenesis and germ cell degeneration can be quantified from numbers of germ cells in various steps of development throughout spermatogenesis, and quantitative measures are related to number of spermatozoa in the ejaculate. Germ cell degeneration occurs throughout spermatogenesis; however, the greatest seasonal impact on horses occurs during spermatocytogenesis. Daily spermatozoan production is related to the amount of germ cell degeneration, pubertal development, season of the year, and aging. Number of Sertoli cells and amount of smooth endoplasmic reticulum of Leydig cells and Leydig cell number are related to spermatozoan production. Seminiferous epithelium is sensitive to elevated temperature, dietary deficiencies, androgenic drugs (anabolic steroids), metals (cadmium and lead), x-ray exposure, dioxin, alcohol, and infectious diseases. However, these different factors may elicit the same temporary or permanent response in that degenerating germ cells become more common, multinucleate giant germ cells form by coalescence of spermatocytes or spermatids, the ratio of germ cells to Sertoli cells is reduced, and spermatozoan production is adversely affected. In short, spermatogenesis involves both mitotic and meiotic cell divisions and an unsurpassed example of cell differentiation in the production of the spermatozoon. Several extrinsic factors can influence spermatogenesis to cause a similar degenerative response of the seminiferous epithelium and reduce fertility of stallions.     

Magnetic resonance methods for studying intact spermatozoa

Motility is used as a routine parameter for assessing spermatozoa activity. The quality rating techniques adopted are based on electron or optical microscopy. However, these methods depend on gross structural and dynamical features of sperm cells and do not provide information on metabolic activity of intact cells. Lately, biochemical assays have become popular. Such methods are cumbersome and destroy the samples. Magnetic resonance methods offer a non-invasive method for studies on intact sperms. We have investigated respiration, maturation andin vitro capacitation of sperms from human ejaculates and sperms extracted from goat reproductive organ using electron spin resonance spin labelling and [³¹P] nuclear magnetic resonance methods. These studies clearly establish the advantages of magnetic resonance in studies related to metabolic activity of sperms.     

Number of primary spermatocytes in the Drosophila immigrans (Sturtevant) group (Diptera : Drosophilidae)

Nine species of the Drosophila immigrans (Sturtevant) group (Diptera Drosophilidae) were examined for the number of primary spermatocytes per cyst. Seven species (D. formosana, D. immigrans, D. kohkoa, D. nasuta, D. neohypocausta, D. quadrilineata and D. sulfurigaster albostrigata) showed nearly 16 primary spermatocytes per cyst, but 2 species (D. annulipes and D. curviceps) had mean numbers of 20.41 and 24.02 primary spermatocytes per cyst, respectively. The frequency distribution patterns of the numbers of primary spermatocytes suggest that the multiplication divisions do not occur synchronously in these species. The systematic positions of D. annulipes and D. curviceps are also discussed.     

Spermatogenesis and sperm transit through the epididymis in mammals with emphasis on pigs

Starting from the period of testis differentiation, the Sertoli cell plays a pivotal role in the development of a functional testis. FSH is the major mitotic factor for Sertoli cells. Because the supporting capacity of Sertoli cells is relatively fixed for each species, their total number per testis, established just before puberty (approximately 4 months in pigs), dictates the potential for sperm production. In contrast to Sertoli cells that are still undifferentiated, mature Leydig cells are already present at birth in pigs. Spermatogenesis lasts from 30 to 75 days in mammals, and this time period is under the control of the germ cell genotype. In boars, each spermatogenic cycle and the entire spermatogenic process lasts 8.6-9.0 and approximately 40 days, respectively. The sperm transit through the epididymis takes approximately 10 days in pigs and this is within the range cited for most mammals. Germ cell loss occurs normally during spermatogenesis, mainly during the spermatogonial and meiotic phases. In pigs, significant germ cell loss also takes place during spermiogenesis. In mammals in general, including pigs, only 2-3 out of a possible 10 spermatozoa are produced from each differentiated type A1 spermatogonium. The high supporting capacity of Sertoli cells and the short duration of the spermatogenic cycle are the main factors responsible for the comparatively high spermatogenic efficiency of pigs.     

Spermiogenesis of inversion heterozygotes in backcross hybrids between Drosophila buzzatii and D. serido

Interspecific F1 hybrid females of D. serido and D. buzzatii are fertile, but hybrid males are sterile. By successive backcrossing of hybrid females to D. buzzatii males it is possible to diminish the genomic contribution of D. serido to the hybrid karyotype. Finally, only selected chromosome sections of D. serido known as inversions restricted to this species were individually left in the otherwise D. buzzatii karyotype, namely: 2 C2b-F4a (j⁹m⁹n⁹), 2 B2c-F4a (j⁹k⁹), 3 C5a-G1b (k²), 4 E2a-G2f (m) and 5 C5d-F2h (w). The present paper deals with the influence of these chromosome sections on sperm differentiation. Any of them produces hybrid male sterility in heterozygous condition. We analyzed spermiogenesis using the DNA specific fluorescence dye BAO in hybrid males which were heterozygous either for only one inversion, as in chromosomes 3, 4 and 5, or for a series of inversions on the same chromosome, as in chromosome 2. The abnormalities recorded included abnormal formation of the cysts, lower than normal number of cysts, abnormal number of nuclei per cyst, incomplete elongation of the cyst, incomplete elongation of the nuclei, displacement of the nuclei from the head region of the cyst and lack of individualization. In no case was there any contents in the seminal vesicle. The section from chromosome 2 of D. serido had the most drastic effect; the disruption produced by the chromosome section corresponding to inversion 3 k² was only a little more severe than that due to 5 w, and both may be distinguished only quantitatively; inversion 4 m produced the slightest deviation from normal spermiogenesis. The larger the serido section introduced in the hybrid, the more severe were the abnormalities it produced. An interpretation in terms of a balance genic theory on the functioning of the genetic system is given.This is paper No. VII in the series The evolutionary history of Drosophila buzzatii.     

Evolution and development of polarized germ cell cysts: new insights from a polychaete worm, Ophryotrocha labronica

Polarized oogenic cysts are clonal syncytia of germ cells in which some of the sister cells (cystocytes) differentiate not as oocytes, but instead as nurse cells: polyploid cells that support oocyte development. The intricate machinery required to establish and maintain divergent cell fates within a syncytium, and the importance of associated oocyte patterning for subsequent embryonic development, have made polarized cysts valuable subjects of study in developmental and cell biology. Nurse cell/oocyte specification is best understood in insects, particularly Drosophila melanogaster. However, polarized cysts have evolved independently in several other animal phyla. We describe the differentiation of female cystocytes in an annelid worm, the polychaete Ophryotrocha labronica. These worms are remarkable for their elegantly simple cysts, which comprise a single oocyte and nurse cell, making them an appealing complement to insects as subjects of study. To elucidate the process of cystocyte differentiation in O. labronica, we have constructed digital 3D models from electron micrographs of serially sectioned ovarian tissue. These models show that 2-cell cysts arise by fragmentation of larger “parental” cysts, rather than as independent units. The parental cysts vary in size and organization, are produced by asynchronous, indeterminate mitotic divisions of progenitor cystoblasts, and lack fusome-like organizing organelles. All of these characteristics represent key cytological differences from “typical” cyst development in insects like D. melanogaster. In light of such differences and the plasticity of female cyst structure among other animals, we suggest that it is time to reassess common views on the conservation of oogenic cysts and the importance of cysts in animal oogenesis generally.     

Mechanism of chromosome elimination in the hybridogenetic spermatogenesis of allotriploid males between Japanese and European water frogs

Of 21 allotriploid males that possessed two genomes of Rana nigromaculata and one genome of Rana lessonae 10 produced a large number of spermatozoa in their testes. When 4 of these males were backcrossed with a female of R. nigromaculata, all of the resulting froglets were diploid in chromosome number and were completely R. nigromaculata type in appearance. These allotriploid males proved to have produced spermatozoa with one R. nigromaculata genome hybridogentically. Therefore, their germ line cells were investigated for the mechanism of elimination of their R. lessonae chromosomes. In histologicla sections of testes, the great majority of spermatogonia (approximately 10⁴ cells) between mitotic prometaphase and anaphase appeared normal in chromosome behavior, whereas 17 spermatogonia showed several chromosomes whose behavior deviated from the normal course during the same period. These deviant chromosomes concentrated together near the equatorial plate and remained stationary at anaphase. In metaphase chromosome preparations made from spermatogonia, 67 and 185 of the 477 chromosome spreads were diploid and triploid, respectively. The rest were aneuploid. Notably, 8 triploid spreads consisted of 26 or more normal chromosomes and 13 or fewer degenerate chromosomes. From these results it is concluded that a set of R. lessonae chromosomes is eliminated from some, but not all spermatogonia by becoming degenerate during the mitotic period.by H.C. Macgregor     

Initiation and kinetic profiles of spermatogenesis in the frog, Runa esculenta (Amphibia)

Spermatogenesis in Rana esculenta is initiated during metamorphic climax and mature spermatozoa are present in froglets 45 days old. Cytological analysis of cell populations shows that some of the primary spermatogonia may lie dormant for brief intervals of time. Timing analysis of the process of spermatogenesis, in adults and in developing Frog larvae maintained at approximately 18°C, was investigated by different methods. The results are remarkably similar. Although perfect synchrony of the developing cells within a single germinal cyst is not the rule, a uniform rate of advancement of germinal cysts of the same stage of development, in most of the seminiferous tubules of a testis is evident. The duration of the secondary spermatogonial divisions is five to six days, involving five or six mitotic cycles, each cycle lasting approximately 24 h. The premeiotic S-phase, and phases of leptotene, zygotene, pachytene, diplotene+secondary spermatocytes, and spermiogenesis each have a duration, respectively, of six, two, six, twelve, two and seven days. The duration of spermatogenesis, from a "committed" primary spermatogonium to the formation of spermatozoa is 41 days.     

Cytofluorescent assay to quantify adhesion of equine spermatozoa to oviduct epithelial cells in vitro

To facilitate the study of interactions between equine spermatozoa and homologous oviduct epithelial cells, we developed an assay to count labelled spermatozoa bound to oviduct epithelial cell (OEC) monolayers and used the assay to compare the binding ability of spermatozoa from different stallions. Washed spermatozoa from three stallions were incubated with the fluorochrome Hoechst 33342 (5 μg/ml) for 1 min. Spermatozoa were then layered over confluent monolayers of oviduct epithelial cells in 2 cm² culture wells. Coculture treatments comprised five concentrations of spermatozoa (10⁵, 5 × 10⁵, 10⁶, 2.5 × 10⁶, and 5 × 10⁶ per well). Cocultures were incubated for 30 min before unattached spermatozoa were aspirated in coculture supernatant. Fluorescent videoimages of attached spermatozoa were digitized, and attached spermatozoa were counted by image processing and analysis. Four wells (replicates) of each concentration were allocated within each ejaculate, and ejaculates were blocked by stallion for ANOVA. The total number of spermatozoa bound was not different between replicate wells (P > 0.1). Stallion, ejaculate, concentration, and all higher level interactions influenced total spermatozoa bound (P < 0.00001). Coefficients of variation between replicates were lowest for inseminate concentrations between 10⁶ and 5 × 10⁶ spermatozoa per well. Within the ejaculate, a log linear relationship exists between the number of bound spermatozoa and a spermatozoal concentration of the inseminate between 5 × 10⁵ and 5 × 10⁶ spermatozoa per well. This assay provides a reliable method of determining numbers of spermatozoa bound to somatic cells in vitro. Furthermore, differences exist in the ability of spermatozoa from different stallions to bind OEC monolayers. © 1996 Wiley-Liss, Inc.     

Ultrastructural comparison of the spermatozoa of the Pacific oyster Crassostreagigas inhabiting polluted and relatively clean areas in Taiwan

The ultrastructure of spermatozoa of the Pacific oysters Crassostrea gigas from an industrially polluted area on the Hsinchu City coast and a relatively clean aquaculture area on Penghu Island, Taiwan, was studied. Oyster gonads were sectioned and examined with light and transmission electron microscopes. The number of spermatozoa in the acinus lumen was significantly lower in oysters from the polluted area than that from the relatively clean area (160 ± 33 cells per 0.01 mm² against 280 ± 42 cells per 0.01 mm², respectively, P < 0.01). Oysters from the polluted area on the Hsinchu City coast had 26.6% spermatozoa with damaged acrosome, coarsely granular chromatin and electron-lucent areas in the nucleus; cell membrane, mitochondria and flagellum were frequently absent in these spermatozoa. By contrast, oysters from the clean area on Penghu Island had 0.4% spermatozoa with the same impairments. Sea water temperature and salinity were similar in the two areas, whereas concentrations of nitrogenous nutrients and heavy metals (e.g., cadmium, copper, and zinc) were higher in the industrially polluted area. It is suggested that high percentage of impairments in the spermatozoa of oysters from the industrial area is attributable to environmental pollution.     

Lymphocyte and sperm chromosome studies in cancer-treated men

Summary To evaluate the reliability of the quantitative extrapolation of the long-term effect of cancer therapies from somatic cells to germ cells, we compared the frenuency of chromosome abnormalities in 303 lymphocytes from four individuals treated with radio- and/or chemotherapy 5–18 years earlier with the frequency in 422 spermatozoa from the same individuals. The mean frequency of structurally abnormal complements was much higher in germ cells than in somatic cells (P = 2.08 × 10^–6). The fact that spermatogenic cells share cytoplasm is suggested as a possible factor in the increased viability of germ cells with chromosome aberrations. In addition, in spermatozoa the incidence of structural chromosome abnormalities was much higher in treated individuals than in controls (P < 0.00060), while in lymphocytes no statistically significant differences could be observed. This observation and the apparent lack of relationship between individual frequencies in the two kinds of cells suggest that the long-term effect of antitumor treatments on germ cells cannot be extrapolated from the analysis of somatic cells.     

Cytoplasmic bridges,intercellular junctions,and individualization of germ cells during spermatogenesis in Dermatobia hominis (Diptera: Cuterebridae)

During mitotic and meiotic divisions in Dermatobia hominis spermatogenesis, the germ cells stay interlinked by cytoplasmic bridges as a result of incomplete cytokinesis. By the end of each division, cytoplasmic bridges flow to the center of the cyst, forming a complex, called the fusoma. During meiotic prophase I, spermatocytes I present desmosome-like junctions and meiotic cytoplasmic bridges. At the beginning of spermiogenesis, the fusoma moves to the future caudal end of the cyst, and at this time the early spermatids are linked by desmosome-like junctions. Throughout spermiogenesis, new and sometimes broad cytoplasmic bridges are formed among spermatids at times making them share cytoplasm. In this case the individualization of cells is assured by the presence of smooth cisternae that outline their structures. The more differentiated spermatids have in addition to narrow cytoplasmic bridges, plasmic membranes junctions. By the end of spermiogenesis, the excess cytoplasmic mass is eliminated leading to spermatid individualization. Desmosome-like junctions of spermatocytes I and early spermatids appear during the fusoma readjustment and segregations; on the other hand, plasmic membrane junctions appear in differentiating spermatids and are eliminated along with the cytoplasmic excess. These circumstances suggest that belt desmosome-like and plasmic membrane junctions are involved in the maintenance of the relative positions of male germ cells in D. hominis while they are inside the cysts. © 1996 Wiley-Liss, Inc.     

Histomorphological studies of the testis and male genital ducts of Supachai's caecilian,Ichthyophis supachaii Taylor, 1960 (Amphibia: Gymnophiona)

We investigated the structure of the male reproductive system in Ichthyophis supachaii. The testis comprises a series of mulberry‐like lobes, each of which contains testis lobules occupied by germ cysts. A single cyst consists of synchronously developing germ cells. Six spermatogenic cell types, viz. primary spermatogonia, secondary spermatogonia, primary spermatocytes, secondary spermatocytes, spermatids and spermatozoa, have been identified and described. Notably, the testis of I. supachaii encompasses specific organization patterns of spermatids and spermatozoa during spermiogenesis. Spermiating cysts rupture and release spermatozoa to the collecting ducts, which are subsequently transported to the sperm duct, Wolffian duct and cloaca. We report for the first time ciliated cells in the epithelium of the caecilian Wolffian duct. The cloaca is divided into the urodeum and phallodeum. The urodeum has ciliated and glandular epithelia at its dorsolateral and ventral regions, respectively, as the lining of its internal surface. The muscular phallodeum is lined by ciliated epithelium. Paired Mullerian ducts lie parallel to the intestine and join the cloaca. The posterior portion of the duct is modified as the Mullerian gland. The most posterior region is non‐glandular and lined by ciliated epithelium. Our findings contribute further to information on the reproductive biology of caecilians in Thailand.     

Ultrastructural investigation of spermatogenesis in Spongilla lacustris and Ephydatia fluviatilis (Porifera,Spongillidae)

Summary Spermatogenesis of the spongillids investigated here is similar in Spongilla lacustris and Ephydatia fluviatilis and proceeds, on the whole, as in other Eumetazoa. Sponges however lack true sex organs, the germ cells developing from somatic cells. The male germ cells originate in spongillids from choanocytes and the female ones from archaeocytes. In Spongilla lacustris single choanocytes leave the flagellated chambers and transform into spermatogonia; in Ephydatia fluviatilis they result from differential cell division. The spermatogonia gather in distinct mesenchyme regions and are surrounded by cyst-building cells. Thus spermatocysts are built in which spermatogenesis proceeds. The spermatogonia in the spermatocysts differentiate into flagellated spermatocytes of I. order. In this process, the early appearance of the flagellum and its mode of formation are uncommon. The following meiotic divisions generate spermatocytes of II. order in the first step and spermatids in the second. In both developmental stages the cells remain connected by cytoplasmic bridges. In the subsequent spermiocytogenesis the cytoplasm of the spermatids is reduced. The reduced parts of the cytoplasm appear as cell fragments in the lumen of the spermatocysts and are eventually ingested by the cystwall cells. The mature spermatozoa arrange in the spermatocysts in a characteristic pattern. Later the spermatocysts open into the excurrent canal system and the spermatozoa leave the sponge with the egestive water stream.     

Induction of Mutations by gamma-Rays in Pregonial Germ Cells of Zebrafish Embryos

Specific locus (gol-1) germ line mutations are induced by γ-rays with high frequencies (about 10^-5 r ^-1) during cleavage divisions in zebrafish. Mutant clone sizes range from 3 to 50% of the total number of germ cells, with a mean of about 10%, when embryos are exposed between the 16 and 10³ cell stages. About five pregonial cells are calculated to be present during the cleavage period.