Histology of salmonid testes during maturation

The commonly applied classification systems of fish gonad maturity divide the maturation process into certain stages. However, the scales do not entirely reflect the continuity of the maturation process. Based on light microscope observations, the paper describes a comprehensive pattern of testicular transformations during maturation. The study was carried out on precocious underyearling and 1-year-old males of sea trout (Salmo trutta m. trutta L.), 1-year-old males of salmon (Salmo salar L.), and males of brown trout (Salmo trutta m. fario L.) aged from 7 months to 4 years. A total of 821 gonads collected during all seasons of the year were examined. The fish were fixed in Bouin's fluid. Histological slides of the mid-part of the gonad were made using the standard paraffin technique. The 3-6 microm sections were stained with Heidenhain haematoxylin. Histological changes of testes during maturation were similar in the three species studied. Immature and resting gonads contained type A spermatogonia in lobules only. The appearance of cystic structures containing type B spermatogonia in the lobules signalled the beginning of the sexual cycle in male gonads. Type B spermatogonia underwent synchronous mitotic divisions resulting in an increase in the total number of spermatogonia. As the spermatogenesis continued, the gonads showed a gradual increase in the number of cysts containing cells at all the spermatogenetic stages: type B spermatogonia, primary and secondary spermatocytes, spermatids, and spermatozoa. The well-formed spermatozoa were released to the lobule lumen once the Sertoli cells and spermatozoa connections broke up and the cyst disappeared. This was a continuous process observed throughout the spawning season. The spermatozoa were moved to the efferent duct. While some of the germ cells were completing spermatogenesis, the lobules contained less and less cysts with type B spermatogonia, primary and secondary spermatocytes, and spermatids; eventually all the cells completed spermatogenesis. At the end of maturation, vacuoles, up to 18.9 microm in final diameter (brown trout), appeared in the Sertoli cells. The vacuoles were visible in the lobule wall epithelium for a prolonged period of time. In most salmonid individuals examined, the reproductive cycles were observed to overlap. In some fish, the preparation for another cycle began very early, i.e., at the and of preceding spermatogenesis, which had not been observed before. Gonad maturation in some males was incomplete.     

Spermatogenesis and related plasma androgen levels in Atlantic halibut (Hippoglossus hippoglossus L.)

Spermatogenesis in male Atlantic halibut (Hippoglossus hippoglossus L.) was investigated by sampling blood plasma and testicular tissue from 15-39-month-old fish. The experiment covered a period in which all fish reached puberty and completed sexual maturation at least once. The germinal compartment in Atlantic halibut testis appears to be organized in branching lobules of the unrestricted spermatogonial type, because spermatocysts with spermatogonia were found throughout the testis. Spermatogenesis was characterized histologically, and staged according to the most advanced type of germ cell present: spermatogonia (Stage I), spermatogonia and spermatocytes (Stage II), spermatogonia, spermatocytes and spermatids (Stage III), spermatogonia, spermatocytes, spermatids and spermatozoa (Stage IV), and regressing testis (Stage V). Three phases could be distinguished: first, an initial phase with low levels of circulating testosterone (T; quantified by RIA) and 11-ketotestosterone (11-KT; quantified by ELISA), spermatogonial proliferation, and subsequently the initiation of meiosis marked by the formation of spermatocytes (Stage I and II). Secondly, a phase with increasing T and 11-KT levels and with haploid germ cells including spermatozoa present in the testis (Stage III and IV). Thirdly, a phase with low T and 11-KT levels and a regressing testis with Sertoli cells displaying signs of phagocytotic activity (Stage V). Circulating levels of 11-KT were at least four-fold higher than those of T during all stages of spermatogenesis. Increasing plasma levels of T and 11-KT were associated with increasing testicular mass throughout the reproductive cycle. The absolute level of, or the relation between, testis growth and circulating androgens were not significantly different in first time spawners compared to fish that underwent their second spawning season. These results provide reference levels for Atlantic halibut spermatogenesis.     

Telomere length in male germ cells is inversely correlated with telomerase activity

Telomeres, the noncoding sequences at the ends of chromosomes, progressively shorten with each cellular division. Spermatozoa have very long telomeres but they lack telomerase enzymatic activity that is necessary for de novo synthesis and addition of telomeres. We performed a telomere restriction fragment analysis to compare the telomere lengths in immature rat testis (containing type A spermatogonia) with adult rat testis (containing more differentiated germ cells). Mean telomere length in the immature testis was significantly shorter in comparison to adult testis, suggesting that type A spermatogonia probably have shorter telomeres than more differentiated germ cells. Then, we isolated type A spermatogonia from immature testis, and pachytene spermatocytes and round spermatids from adult testis. Pachytene spermatocytes exhibited longer telomeres compared to type A spermatogonia. Surprisingly, although statistically not significant, round spermatids showed a decrease in telomere length. Epididymal spermatozoa exhibited the longest mean telomere length. In marked contrast, telomerase activity, measured by the telomeric repeat amplification protocol was very high in type A spermatogonia, decreased in pachytene spermatocytes and round spermatids, and was totally absent in epididymal spermatozoa. In summary, these results indicate that telomere length increases during the development of male germ cells from spermatogonia to spermatozoa and is inversely correlated with the expression of telomerase activity.     

Annual cyclical changes in the testicular activity of an Indian freshwater major carp, Labeo rohita (Hamilton)

Different male germ cells identified on the basis of histological and cytological characteristics in the testicular lobules of Labeo rohita have been grouped into spermatogonia, primary spermatocytes, secondary spermatocytes, spermatids and spermatozoa. The seasonal changes of the testis in L. rohita have been described according to its morphological peculiarities as well as to its variations in gonadal volumes, GSI values and frequency percentages of the different male germ cells occurring in the testicular lobules. Consequently, the entire testicular cycle in L. rohita may be categorised into 4 distinct phases viz., growth, maturation of pre-spawning, spawning, and resting or post-spawning phases.     

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.     

Annual changes in germinal epithelium determine male reproductive classes of the cobia

Five reproductive classes of cobia Rachycentron canadum , caught along the Gulf of Mexico and the south-east Atlantic coast of the U.S.A., are described during the annual reproductive cycle. These are based upon changes in the testicular germinal epithelium and the stages of germ cells that are present: early maturation, mid maturation, late maturation, regression and regressed. During early maturation, the germinal epithelium is continuous from the testicular ducts to the periphery of the testis and active spermatogenesis occurs throughout the testis. In mid maturation, the germinal epithelium near the ducts becomes discontinuous, but it remains continuous distally. In late maturation, a discontinuous germinal epithelium extends all along the lobules to the testicular periphery; lobules are swollen with sperm and there is minimal spermatogenesis. The regression class is characterized by a discontinuous epithelium throughout the testis, sperm storage and widely scattered spermatocysts. Spermatogonial proliferation also occurs along the lobule walls and at the periphery of the testis. In regressed testes, spermatogonia exist only in a continuous or discontinuous germinal epithelium, although residual sperm are nearly always present in the lobules and ducts. The presence or absence of sperm is not an accurate indicator of reproductive classes. At the periphery of the testis in the regression and regressed classes, the distal portions of lobules elongate as cords of cells containing spermatogonia and Sertoli cells. All reproductive classes can be identified in paraffin sections, although plastic sections provide better resolution. Using maturation classes defined by changes in the germinal epithelium to describe testicular development and spermatogenesis gives a more accurate picture than does using the traditional terminology.     

Morphology of the male reproductive system of freshwater prawn Macrobrachium carcinus (Decapoda,Caridea): Functional and comparative aspects

Testes and vasa deferentia are parts of the male reproductive system of decapod crustaceans. Both organs show morphological differences among decapod species in terms of anatomical and histological patterns reflecting the diversity of this group. Describing these features may assist in systematics, phylogenetics, and studies of reproductive behavior, especially for species of commercial interest, such as Macrobrachium carcinus, a native American species that, unusually for this genus, has no precopulation courting behavior. This study aims to describe the reproductive morphology and spermatogenesis of the male freshwater prawn M. carcinus. The male reproductive system of this species consisted of lobed testes connected to the vasa deferentia. The testis of M. carcinus was divided into several lobules. Each lobule was formed by a cluster of germ cells surrounded by connective tissue and nurse cells. This microscopic anatomy and histology of the testicular histoarchitecture has been described for many species of Decapoda and may represent a derived design of the testes. Unlike that in other decapod species, spermatogenesis proceeds in short transitory phases that produce spermatozoa at high concentrations and frequencies, corroborating the uncommon male reproductive behavior of this species. In the spermatic pathway, the lobules develop and fuse before releasing spermatozoa from the testes; however, this process has not been observed in decapods, yet. The neutral compounds secreted by the vas deferens are important for sperm nutrition as females secrete a substance for spermatophore adhesion during reproduction. This study presents different features and dynamics of the spermatogenic process in the male reproductive system of M. carcinus that have not yet been presented in the literature for decapods.     

Hormonal induction of all stages of spermatogenesis in germ-somatic cell coculture from immature Japanese eel testis

In cultivated male eel, spermatogonia are the only germ cells present in testis. Our previous studies using an organ culture system have shown that gonadotropin and 11-ketotestosterone (11-KT, a potent androgen in teleost fishes) can induce all stages of spermatogenesis in vitro. for detailed investigation of the control mechanisms of spermatogenesis, especially of the interaction between germ cells and testicular somatic cells during 11-KT-induced spermatogenesis in vitro, we have established a new culture system in which germ cells and somatic cells are cocultured after they are aggregated into pellets by centrifugation. Germ cells (spermatogonia) and somatic cells (mainly Sertoli cells) were isolated from immature eel testis. Coculture of the isolated germ cells and somatic cells without forming aggregation did not induce spermatogenesis, even in the presence of 11-KT. In contrast, when isolated germ cells and somatic cells were formed into pellets by centrifugation and were then cultured with 11-KT for 30 days, the entire process of spermatogenesis from premitotic spermatogonia to spermatozoa was induced. However, in the absence of 11-KT in the culture medium spermatogenesis was not induced, even when germ cell and somatic cells were aggregated. These results demonstrate that physical contact of germ cells to Sertoli cells is required for inducing spermatogenesis in response to 11-KT.     

Developmental expression of the translocator protein 18 kDa (TSPO) in testicular germ cells

Translocator protein (TSPO) is a high affinity 18 kDa drug- and cholesterol-binding protein strongly expressed in steroidogenic tissues where it mediates cholesterol transport into mitochondria and steroid formation. Testosterone formation by Leydig cells in the testis is critical for the regulation of spermatogenesis and male fertility. Male germ cell development comprises two main phases, the pre-spermatogenesis phase occurring from fetal life to infancy and leading to spermatogonial stem cell (SSC) formation, and spermatogenesis, which consists of repetitive cycles of germ cell mitosis, meiosis and differentiation, starting with SSC differentiation and ending with spermiogenesis and spermatozoa formation. Little is known about the molecular mechanisms controlling the progression from one germ cell phenotype to the next. Here, we report that testicular germ cells express TSPO from neonatal to adult phases, although at lower levels than Leydig cells. TSPO mRNA and protein were found at specific steps of germ cell development. In fetal and neonatal gonocytes, the precursors of SSCs, TSPO appears to be mainly nuclear. In the prepubertal testis, TSPO is present in pachytene spermatocytes and dividing spermatogonia. In adult testes, it is found in a stage-dependent manner in pachytene spermatocyte and round spermatid nuclei, and in mitotic spermatogonia. In search of TSPO function, the TSPO drug ligand PK 11195 was added to isolated gonocytes with or without the proliferative factors PDGF and 17β-estradiol, and was found to have no effect on gonocyte proliferation. However, TSPO strong expression in dividing spermatogonia suggests that it might play a role in spermatogonial mitosis. Taken together, these results suggest that TSPO plays a role in specific phases of germ cell development.     

Flow-cytometric isolation and enrichment of teleost type A spermatogonia based on light-scattering properties

The transplantation of germ cells is a powerful tool both for studying their development and for reproductive biotechnology. An intraperitoneal germ cell transplantation system was recently developed for use in several teleost species. Donor germ cells transplanted into the peritoneal cavity of hatchlings migrated toward and were incorporated into the recipient's genital ridges, where they underwent gametogenesis. Among male germ cells, only type A spermatogonia were capable of colonizing the recipient gonads, unlike those at more advanced stages. The enrichment of type A spermatogonia is therefore important to achieve efficient donor-cell incorporation and subsequent donor-derived gametogenesis. Here we established a simple and rapid system of isolation and enrichment for fish type A spermatogonia, using flow cytometry. Type A spermatogonia were found to have distinctive forward and side light scatter properties compared to that with other types of testicular cell. Based on these characteristics, we were able to isolate and enrich type A spermatogonia by using flow cytometry. After intraperitoneal transplantation, the enriched type A spermatogonia could be successfully incorporated into the recipient genital ridges. This flow cytometry approach using forward and side light scatter was also found to be applicable to other salmonid and sciaenid species, suggesting that it could be a powerful tool for isolating and enriching transplantable type A spermatogonia in a wide range of teleosts. We expect this method to contribute significantly to germ cell biology and biotechnology.     

Ultrastructure of the testis in Synbranchus marmoratus (Teleostei,Synbranchidae): the germinal compartment

Synbranchus marmoratus, is a protogynic diandric species in which two types of males, primary and secondary, are found. In both types, the germinal compartment in the testes is of the unrestricted lobular type, but in secondary (sex reversed females) males the lobules develop within the former ovarian lamellae. In the present study, the germinal compartment was examined in both types of males using light microscopy as well as scanning and transmission electron microscopy. Germinal compartment is limited by a basement membrane and contains Sertoli and germ cells. During maturation, processes of Sertoli cells form the borders of spermatocysts containing isogenic germ cells. Characteristically, type A and type B spermatogonia have a single nucleolus and grouped mitochondria associated with dense bodies or nuage. Type B spermatogonia, spermatocytes and spermatids are joined by cytoplasmatic bridges and are confined within spermatocysts. Secondary spermatocytes are difficult to find, indicating that this stage is of short duration. Biflagellated spermatozoa have a rounded head, no acrosome, and possess a midpiece consisting of two basal bodies, each of which produces a flagellum with a typical 9+2 microtubular composition. No associations occur between sperm and Sertoli cells. There were no differences between spermatogenesis in primary and secondary males in this protogynic, diandric fish.     

Novel identification of peripheral dopaminergic D2 receptor in male germ cells

Dopamine is a recognized modulator in the central nervous system (CNS) and peripheral organ functions. The presence of peripheral dopamine receptors outside the CNS has suggested an intriguing interaction between the nervous system and other functional systems, such as the reproductive system. In the present study we analyzed the expression of D2R receptors in rat testis, rat spermatogenic cells and spermatozoa, in different mammals. The RT-PCR analysis of rat testis mRNA showed specific bands corresponding to the two dopamine receptor D2R (L and S) isoforms previously described in the brain. Using Western blot analysis, we confirmed that the protein is present in rat testis, isolated spermatogenic cells and also in spermatozoa of a range of different mammals, such as rat, mouse, bull, and human. The immunohistochemistry analysis of rat adult testis showed that the receptor was expressed in all germ cells (pre- and post-meiotic phase) of the tubule with staining predominant in spermatogonia. Confocal analysis by indirect immunofluorescence revealed that in non-capacitated spermatozoa of rat, mouse, bull, and human, D2R is mainly localized in the flagellum, and is also observed in the acrosomal region of the sperm head (except in human spermatozoa). Our findings demonstrate that the two D2 receptor isoforms are expressed in rat testis and that the receptor protein is present in different mammalian spermatozoa. The presence of D2R receptors in male germ cells implies new and unsuspected roles for dopamine signaling in testicular and sperm physiology.     

An overview of cell renewal in the testis throughout the reproductive cycle of a seasonal breeding teleost, the gilthead seabream (Sparus aurata L)

The gilthead seabream is a protandrous hermaphrodite seasonal breeding teleost with a bisexual gonad that offers an interesting model for studying the testicular regression process that occurs in both seasonal testicular involution and sex change. Insofar as fish reproduction is concerned, little is known about cell renewal and elimination during the reproductive cycle of seasonal breeding teleosts with asynchronous spermatogenesis. We have previously described how acidophilic granulocytes infiltrate the testis during postspawning where, surprisingly, they produce interleukin-1beta, a known growth factor for mammalian spermatogonia, rather than being directly involved in the elimination of degenerative germ cells. In this study, we are able to discriminate between spermatogonia stem cells and primary spermatogonia according to their nuclear and cytoplasmic diameters and location in the germinal epithelium, finding that these two cell types, together with Sertoli cells, proliferate throughout the reproductive cycle with a rate that depends on the reproductive stage. Thus, during spermatogenesis the spermatogonia stem cells, the Sertoli cells, and the developing germ cells (primary spermatogonia, A and B spermatogonia, and spermatocytes) in the germinal compartment, and cells with fibroblast-shaped nuclei in the interstitial tissue proliferate. However, during spawning, the testis shows few proliferating cells. During postspawning, the resumption of proliferation, the occurrence of apoptotic spermatogonia, and the phagocytosis of nonshed spermatozoa by Sertoli cells lead to a reorganization of both the germinal compartment and the interstitial tissue. Finally, the proliferation of spermatogonia increases during resting when, unexpectedly, both oogonia and oocytes also proliferate. This proliferative pattern was correlated with the gonadosomatic index, testicular morphology, and testicular and gonad areas, suggesting that complex mechanisms operate in the regulation of gonocyte proliferation in hermaphrodite fish.     

Proteome analysis of spermatogonia: identification of a first set of 53 proteins

During spermatogenesis, the various classes of germ cells synthesize proteins necessary for their own functioning and for regulation of the Sertoli cells. However, the nature of these proteins has been little studied, especially in spermatogonia, the germ stem cells. In this study, the electrophoretic patterns of high-resolution, silver-stained, two-dimensional polyacrylamide gels of intracellular spermatogonial protein extracts were studied by computerized gel image analysis. We detected 675 individual spots, some of which we identified by mass spectrometry and database searching. We present here a first set of 53 proteins identified. They include housekeeping proteins never before detected in spermatogonia, ten proteins previously detected in the reproductive tract but not in spermatogonia, including stathmin, a protein previously shown to be involved in cell proliferation and differentiation, and one new testicular protein named translationally controlled tumor protein (TCTP), also known as a growth-related protein. Immunohistochemistry demonstrated that the two latter proteins were indeed highly expressed in spermatogonia in situ, and their possible involvement in spermatogonial division and proliferation is currently under investigation in our laboratory. We conclude that this type of experimental strategy, known as proteomics, is a very powerful way to analyze germ cell proteins comprehensively and should rapidly greatly improve our understanding of spermatogenesis.     

Peculiarities in the organization of testis of Ophidian sp. (Pisces Teleostei). Evidence for two types of spermatogenesis in teleost fish

The walls of lobules in the testis of Ophidion sp. are composed of Scrtoli cells and young germinal cells (spermatogonia and spermatocytes). Spermatocytes are linked by cytoplasmic bridges. The associations of Sertoli cells and spermatocytes constitute true cysts. Meiosis takes place in the cysts. When meiosis is complete, cysts open. Spermatids are released into the lumen of the lobules and the cyloplasmic bridges break down. Spermiogenesis occurs in the lumen. Spermatids at various levels of spermiogenesis are then mixed with ripe spermatozoa. In teleosts we thus recognize two types of spermatogenesis: a cystic type where spermatogenesis is completed within cysts, and leads to synchronous development of germ-cells; and a semi-cystic type, where spermatogenesis occurs partly outside cysts. This may produce asynchronous spermatogenesis.     

Testicular structure and spawning cycle in the silvery croaker, <Emphasis Type="Italic">Otolithes ruber</Emphasis> (Perciformes: Sciaenidae) in the Kuwaiti waters of the Arabian Gulf

The structure of the testes and maturity stages in the male silvery croaker, Otolithes ruber were investigated from March 1999 to March 2000. Based on the location of spermatogonia within the germinal epithelium, the testis structure is classified as the unrestricted spermatogonial testicular type. Germ cells proliferate through mitotic divisions of spermatogonia, giving rise to primary and secondary spermatocytes, which through meiotic divisions transform into spermatids. As spermatogenesis progresses, an elongation of the testicular lobules takes place. During final spermiogenesis, spermatids are arranged in clusters, with heads in one direction and tails in the opposite. Spermatozoa are then liberated from these structures into the lobula lumina. The testicular lobules further elongate, and many of them form a continuum within the germinal epithelium, extending toward the periphery. The walls of the other lobules fuse, producing anastomosing sperm-filled lobular compartments. A main sperm duct is formed into which spermatozoa from the lobules are voided. A time lapse between sexual maturity and onset of spawning was observed, thus supporting the existing view that the anastomosing compartments are used for sperm storage during the latter part of the maturation process. Six maturity stages of the testis are delineated during the annual reproductive cycle based on macroscopic and histological characteristics. Results show that male O. ruber spawns from March through April in Kuwaiti waters.     

Distribution of sulfhydryloxidase (SOx) immunoreactivity in the testis of the axolotl (Ambystoma mexicanum) (amphibia, urodela)

Immunohistochemical localization of sulfhydryloxidase (SOx) has been examined in the testis of the Axolotl (Ambystoma mexicanum). The urodelan testis contains germ cells in various phases of differentiation from primordial germ cells to mature spermatozoa. SOx immunoreactivity is present in mitochondria of primordial germ cells and primary spermatogonia and declines within the population of secondary spermatogonia, suggesting, that the antibody used to localize SOx may serve to estimate the developmental stage of spermatogonia towards meiosis, since more undifferentiated cells react positively. Intensity of immunostaining increases again in spermatocytes and becomes most intense in early round spermatids correlating on ultrastructural level with an accumulation of numerous mitochondria in that part of the cytoplasm, where the acrosome vesicle is formed. Mature sperm are immunonegative. Additionally, Leydig cells within the glandular tissue are stained by the antibody. Thus the distribution pattern of SOx immunoreactivity principally resembles that in the mammalian testis found during ontogenesis or in the adult seminiferous epithelium. The possible functional significance of mitochondrial SOx in germ cells and Leydig cells is discussed. These results suggest, that the amphibian testis is a model for experimental problems dealing with the investigation of germ cells in various developmental phases including very undifferentiated premeiotic germ cells. The cystic testis may be of value in studying influences of various experimental conditions on varied homogeneous populations of germ cells.     

Developmental changes of DNA ligase during ram spermatogenesis

The molecular forms and activities of ram DNA ligase have been investigated during spermatogenesis from the stage of early round spermatids to ejaculated spermatozoa. Through germ cell maturation, two consecutive forms of the enzyme (6S and 7S) have been found. The 6S form (DNA ligase II) is observed in primary and secondary spermatocyte, as well as in round spermatids. The 7S form (DNA ligase I) is present in elongated spermatids and in the sole round cell population with spermatogonia and young primary spermatocytes. In ram germ cells, DNA ligase I and DNA ligase II appear to be respectively associated with DNA replication repair. The absence of DNA ligase II associated with the absence of DNA repair in testicular and ejaculated spermatozoa might be related to male infertility.     

Fundamental cryobiology of reproductive cells and tissues

During the last half of the 20th century there have been considerable advancements in mammalian reproductive technologies, including in vitro production of pre-implantation embryos and embryo sexing, and even cloning in some species. However, in most cases, management of non-cryopreserved reproductive cells (i.e., spermatozoa or oocytes) and tissues (i.e., testicular tissue or ovarian tissue) is problematic due to difficulties in donor-recipient synchronization and the potential for transmission of infectious pathogens, which cumulatively limits widespread application of these techniques. Therefore, there is an urgent need for the development of optimum cryopreservation methods for reproductive cells and tissues from many species. Today frozen-thawed spermatozoa and embryos have become an integral component of animal agriculture, laboratory animal genome banking, and human sperm banking and infertility programs. However, although widely implemented, the protocols currently used to cryopreserve bull sperm, for example, are still suboptimal, and cannot readily be extrapolated to other species' sperm. Similarly, embryo-freezing protocols successfully used for mouse and cattle have yielded little success when applied to some other species' embryos, or to a related cell type, oocytes. To date, with the exception of mouse oocytes, almost all mammalian species' oocytes studied have proven very difficult to successfully cryopreserve. Currently, there is a growing interest to understand the underlying cryobiological fundamentals responsible for these low survival rates in an effort to develop better cryopreservation methods for oocytes. Additionally, there is growing interest in developing technologies for the optimal isolation and cryopreservation of the earliest stage of male (spermatogonia, spermatids) and female (primordial follicle) germ cells, with subsequent maturation to the desired stage in vitro. Female gamete maturation, fertilization, and embryo development entirely under in vitro conditions from primordial follicles has been achieved in mice, however techniques for this and other species are still very early in their development. Furthermore, with the recent advances made in intracytoplasmic sperm injection (ICSI), and gamete isolation and maturation, close attention has been given to cryopreservation of gametes in the form of gonadal tissue (i.e., testicular tissue and ovarian tissue) containing various developmental stages of male (spermatogonia, spermatids, and spermatozoa) and female (primordial, secondary) germ lines.