Changes in sperm plasma membrane lipid diffusibility after hyperactivation during in vitro capacitation in the mouse

We have used the technique of fluorescence recovery after photobleaching to measure the diffusibility of the fluorescent lipid analogue, 1,1'-dihexadecyl 3,3,3',3'-tetramethylindocarbocyanine perchlorate on the morphologically distinct regions of the plasma membranes of mouse spermatozoa, and the changes in lipid diffusibility that result from in vitro hyperactivation and capacitation with bovine serum albumin. We found that, as previously observed on ram spermatozoa, lipid analogue diffusibility is regionalized on mouse spermatozoa, being fastest on the flagellum. The bovine serum albumin induced changes in diffusibility that occur with hyperactivation are also regionalized. Specifically, if we compare serum incubated in control medium, which maintains normal motility, with those hyperactivated in capacitating medium, we observe with hyperactivation an increase in lipid analogue diffusion rate in the anterior region of the head, the midpiece, and tail, and a decrease in diffusing fraction in the anterior region of the head.     

Selective partitioning of plasma membrane antigens during mouse spermatogenesis

The selective partitioning of cell membrane components during mouse spermatogenesis has been examined using a heterologous antibody raised against isolated type B spermatogonia. The anti-type B spermatogonia rabbit IgG (ATBS) binds to isolated populations of mouse primitive type A spermatogonia, type A spermatogonia, type B spermatogonia, preleptotene spermatocytes, leptotene/zygotene spermatocytes, pachytene spermatocytes, round spermatids, residual bodies, and mature spermatozoa. Although immunofluorescent labeling is uniformly distributed on the cell surface of early spermatogenic cells, a discrete topographical localization of IgG is observed on testicular, epididymal, and vas deferens spermatozoa. The convex surface of the acrosome, postacrosomal region, and tail are labeled. Antibody does not bind to a broad area corresponding to the concave region of the acrosome. The antibody also binds to mouse somatic cells including Sertoli cells, Leydig cells, thymocytes, and splenocytes, but not to mature spermatozoa of the vole, rat, hamster, guinea pig, rabbit, or human. ATBS, after absorption with mouse splenocytes or thymocytes, does not react with any somatic cells examined by fluorescence except with Sertoli cells. In addition, all reactivity with testicular, epididymal, and was deferens spermatozoa is abolished. However, spermatogenic cells at earlier stages of differentiation, including residual bodies, still react strongly with the absorbed antibody. The number of surface receptor sites per cell for absorbed ATBS ranges from approximately 3 million on primitive type A spermatogonia to 1 million on round spermatids and on residual bodies. Spermatozoa, however, have only 0.003 million binding sites for absorbed ATBS, in contrast to 10 million sites for the unabsorbed antibody. It appears that receptor sites for absorbed ATBS are not masked by components of epididymal secretions. These data imply, therefore, that specific mechanisms operate at the level of the cell membrane during spermiogenesis to insure that some surface components, not required in the mature spermatozoon, are removed selectively by partitioning to that portion of the spermatid membrane destined for the residual body.     

Changes in lipid diffusibility in the hamster sperm head plasma membrane during capacitation in vivo and in vitro

The technique of fluorescence recovery after photobleaching (FRAP) was employed on spermatozoa labeled with the fluorescent lipid analogue C₁₄diI to provide two measures of lateral diffusion in the plane of the sperm plasma membrane during capacitation in vivo and in vitro: the diffusion coefficient (D) for C₁₄diI and the fraction of C₁₄diI that is free to diffuse (%R) within the domain. To evaluate changes in lipid diffusibility during capacitation in vivo, spermatozoa were recovered from the uterus within 30 min after ejaculation or from the oviduct at 2, 4, 6 and 8 hr after mating. To compare the changes which occur in vivo with those which occur during capacitation in vitro, caudal epididymal spermatozoa were incubated under capacitating or non-capacitating (control) conditions for 4 hr. Although transient changes in D occurred during the course of capacitation, there was no net change in D for either anterior (AH) or posterior head (PH) domains following capacitation in vitro or in vivo. Significant differences in the lipid diffusion coefficient between the two head domains were observed during the course of capacitation. A transient decrease in %R was observed for the AH domain during capacitation in vitro and incubation under control conditions, but no significant change in %R was observed in the AH domain during capacitation in vivo. A significant decline in %R of the PH domain was observed for spermatozoa during capacitation in vivo, in vitro and following incubation under non-capacitating conditions. These data indicate that the changes in the lipid diffusibility of the AH and PH domains which occur during capacitation in vivo exhibit both similarities and differences to those which occur during capacitation in vitro. Mol. Reprod. Dev. 50:86–92, 1998. © 1998 Wiley-Liss, Inc.     

Clinical aspects of male germ cell apoptosis during testis development and spermatogenesis

Apoptosis appears to have an essential role in the control of germ cell number in testes. During spermatogenesis germ cell deletion has been estimated to result in the loss of up to 75% of the potential number of mature sperm cells. At least three factors seem to determine the onset of apoptosis in male germ cells: (1) lack of hormones, especially gonadotropins and androgens; (2) the specific stage in the spermatogenic cycle; (3) and the developmental stage of the animal. Although male germ cell apoptosis has been well characterized in various animal models, few studies are presently available regarding germ cell apoptosis in the human testis. The first part of this review is focused on germ cell apoptosis in testes of prepubertal boys, with special emphasis on apoptosis in normal and cryptorchid testes. A higher percentage of apoptotic spermatogonia was seen in the cryptorchid testes than in the scrotal testes. The hCG-treatment increased the number of apoptotic spermatogonia. The hCG-treatment-induced apoptosis in spermatogonia had severe long-term consequences in reproductive functions in adulthood. Increased apoptosis after hCG-treatment was associated with subnormal testis volumes, subnormal sperm density and pathologically elevated serum FSH. This finding indicates that increased apoptosis in spermatogonia in prepuberty leads to disruption of testis development. To evaluate the role of apoptosis in human adult testes, apoptosis was induced in seminiferous tubules that were incubated under serum-free conditions in the absence or presence of testosterone. Most frequently apoptosis was identified in spermatocytes. Occasionally some spermatids also showed signs of apoptosis. In short term incubations apoptosis was suppressed by testosterone. Our findings lead to the conclusion that apoptosis is a normal, hormonally controlled phenomenon in the human testis. The role of apoptosis in disorders of spermatogenesis remains to be established.     

Changes in the organization of the lipid bilayer of the plasma membrane during spermatogenesis and epididymal maturation

Ram, bull, and mouse sperm cells were stained with several fluorescent membrane probes. In contrast to nonspecific probes, merocyanine 540 (MC540), which displays preferential binding to loosely packed phospholipids in model membranes, was specifically localized to the anterior portion of the head and the midpiece of mature sperm. To establish when during development this distinctive staining pattern was acquired, germ cells from prepubescent and adult mouse testes as well as sperm from the caput, corpus, and cauda epididymides were isolated and examined. Localized staining with MC540 was not observed until sperm reached the corpus epididymidis, where those cells with a completely translocated (i.e., distally located) cytoplasmic droplet fluoresced. Likewise, when sperm were stained with fluoresceinated concanavalin A (fl-ConA), a localized pattern of fluorescence with lectin restricted to the anterior portion of the head was not observed until the corpus epididymidis was reached. However, in contrast to MC540 staining, only a fraction of sperm with completely translocated droplets exhibited this localized staining with fl-ConA, the remainder exhibiting diffuse fluorescence over the entire cell as seen on caput epididymal sperm. These developmental changes in staining patterns are specific to murine cells, since no change in the pattern of staining by either MC540 or fl-ConA was seen on epididymal sperm of the ram. These results are discussed with respect to: 1) species-to-species differences in sperm membrane features; and 2) the hypothesis that domains of loosely packed lipids may be involved in the regionalization of membrane proteins that occurs during sperm development.     

Uncovering gene regulatory networks during mouse fetal germ cell development

The commitment of germ cells to either oogenesis or spermatogenesis occurs during fetal gonad development: germ cells enter meiosis or mitotic arrest, depending on whether they reside within an ovary or a testis, respectively. Despite the critical importance of this step for sexual reproduction, gene networks underlying germ cell development have remained only partially understood. Taking advantage of the W(v) mouse model, in which gonads lack germ cells, we conducted a microarray study to identify genes expressed in fetal germ cells. In addition to distinguishing genes expressed by germ cells from those expressed by somatic cells within the developing gonads, we were able to highlight specific groups of genes expressed only in female or male germ cells. Our results provide an important resource for deciphering the molecular pathways driving proper germ cell development and sex determination and will improve our understanding of the etiology of human germ cell tumors that arise from dysregulation of germ cell differentiation.     

Regulation of primordial germ cell development in the mouse

Primordial germ cells (PGCs) are the founders of the gametes. They arise at the earliest stages of embryonic development and migrate to the gonadal ridges, where they differentiate into oogonia/oocytes in the ovary, and prospermatogonia in the testis. The present article is a review of the main studies undertaken by the author with the aim of clarifying the mechanisms underlying the development of primordial germ cells. Methods for the isolation and purification of migratory and post-migratory mouse PGCs devised in the author's laboratory are first briefly reviewed. Such methods, together with the primary culture of PGCs onto suitable cell feeder layers, have allowed the analysis of important aspects of the control of their development, concerning in particular survival, proliferation and migration of mouse PGCs. Compounds and growth factors affecting PGC numbers in culture have been identified. These include survival anti-apoptotic factors (SCF, LIF) and positive regulators of proliferation (cAMP, PACAPs, RA). Evidence has been provided that the motility of migrating PGCs relies on integrated signals from extracellular matrix molecules and the surrounding somatic cells. Moreover, homotypic PGC-PGC interaction has been evidenced that might play a role in PGC migration and in regulating their development. Several molecules (i.e. integrins, specific types of oligosaccharides, E-cadherin, the tyrosine kinase receptor c-kit) have been found to be expressed on the surface of PGCs and to mediate adhesive interactions of PGCs with the extracellular matrix, somatic cells and neighbouring PGCs.     

Temporal expression of membrane antigens during mouse spermatogenesis.

The temporal expression of cell surface antigens during mammalian spermatogenesis has been investigated using isolated populations of mouse germ cells. Spermatogenic cells at advanced stages of differentiation, including pachytene primary spermatocytes, round spermatids, and residual bodies of Regaud and mature spermatozoa, contain common antigenic membrane components which are not detected before the pachytene stage of the first meiotic prophase. These surface constituents are not detected on isolated populations of primitive type A spermatogonia, type A spermatogonia, type B spermatogonia, preleptotene primary spermatocytes, or leptotene and zygotene primary spermatocytes. These results have been demonstrated by immunofluorescence microscopy, by complement-mediated cytotoxicity, and by quantitative measurements of immunoglobulin (Ig) receptors on the plasma membrane of all cell populations examined. The cell surface antigens detected on germ cells are not found on mouse thymocytes, erythrocytes, or peripheral blood lymphocytes as determined by immunofluorescence and by cytotoxicity assays. Furthermore, absorption of antisera with kidney and liver tissue does not reduce the reactivity of the antibody preparations with spermatogenic cells, indicating that these antigenic determinants are specific to germ cells. This represents the first direct evidence for the ordered temporal appearance of plasma membrane antigens specific to particular classes of mouse spermatogenic cells. It appears that at late meiotic prophase, coincident with the production of pachytene primary spermatocytes, a variety of new components are inserted into the surface membranes of developing germ cells. The further identification and biochemical characterization of these constituents should facilitate an understanding of mammalian spermatogenesis at the molecular level.     

The amphibian testis as model to study germ cell progression during spermatogenesis

Testicular morphology of vertebrate testis indicates requirement of local control. In urodeles, the testis is organized in lobes of increasing maturity throughout the cephalocaudal axis. The anuran testis is organized in tubules. Spermatogenesis occurs in cysts composed by Sertoli cells enveloping germ cells at synchronous stages. Moreover, in numerous species germ cell progression lasts a year which defines the sexual cycle. Due to the above quoted features, research on factors regulating germ cell progression in amphibians may reach greater insight as compared with mammalian animal models. In particular, studies on endocrine and paracrine/autocrine factors involved in the regulation of germ cell functions reveal that fos activation and a J protein, previously specifically found in mouse testis, exert an important role in spermatogonial proliferation and maturation of post-meiotic stages, respectively.     

Expression and intracellular localization of mouse Vasa-homologue protein during germ cell development

To demonstrate the cellular and subcellular localization of mouse vasa homologue protein during germ cell development, specific antibody was raised against the full-length MVH protein. The immunohistochemical analyses demonstrated that MVH protein was exclusively expressed in primordial germ cells just after their colonization of embryonic gonads and in germ cells undergoing gametogenic processes until the post-meiotic stage in both males and females. The co-culture of EG cells with gonadal somatic cells indicated inductive MVH expression caused by an intercellular interaction with gonadal somatic cells. In adult testis, MVH protein was localized in the cytoplasm of spermatogenic cells, including chromatoid bodies in spermatids, known to be a perinuclear nuage structure which includes polar granules that contain VASA protein in Drosophila.     

Establishment and maintenance of a regionalized glycoprotein distribution during early mouse development

The regionalization of the cell membranes of the mouse embryo into apical and basolateral zones has been studied using antibodies to a pair of glycoproteins expressed during the two-cell to early blastocyst stage. These antigens are found on the outer, free surface and in the underlying cortical cytoplasm, but are not detectable at areas of cell contact. In the early blastocyst stage, antigen also appears at the free surfaces of cells bordering the blastocoel. Antigen regionalization is also reestablished after experimental manipulation and appears to be a direct consequence of cell contact. Thus, blastomeres examined 4 hr after dissociation from four- and eight-cell stage embryos express antigen in cortical areas underlying newly exposed surfaces and new sites of contact between embryos in multiple-embryo aggregates lose detectable antigen within 2 to 4 hr of the formation of the contacts. Microfilaments are involved in controlling the regional expression of these glycoproteins. Incubation of embryos from the two-cell stage in medium containing cytochalasin B interferes with antigen targeting, resulting in abnormal expression of the antigens both on the surface and in the cytoplasm of the embryos. Cytochalasin B treatment of later stage embryos results in an uneven distribution of the antigen in cortical cytoplasm and prevents the complete removal of antigen from new sites of cell contact in multiple-embryo aggregates. The presence of nocodozole, which inhibits the polymerization of microtubules, had no detectable effect on the expression of the antigens. Interference with the glycosylation of these proteins, by incubation of embryos in the presence of tunicamycin, did not alter the regionalized pattern of expression.     

Mouse germ cell development during embryogenesis

The discrimination and differentiation of germ cells from somatic cells is a fundamental issue during development. The early specification of mouse primordial germ cells (PGCs) is achieved by the induction of Blimp1, a key regulator of germ cells. Nanos3 is one of the genes activated in early PGCs and prevents apoptosis during their migration stage. Once PGCs enter the embryonic gonads, they differentiate according to the somatic sex of the organism. During this process, Nanos2 plays an important role as it promotes male germ cell pathway by suppressing the female fate. In this review, the process of germ cell development in the mouse is discussed with a particular focus on the functions of the key proteins, Blimp1, Nanos, and Dead end1.     

Relationship of plasma steroids to germ cell development and the presence of protamine mRNA in rainbow trout during the induction of spermatogenesis with partially purified salmon gonadotropin

The gonadosomatic index (GSI) of pre–pubertal male rainbow trout, which had been injected biweekly with partially purified salmon gonadotropin (sG–G100, 50 μ mUg kg⁻¹ body weight), increased from 0.05 to 1.85 over 21 weeks from injection, while control GSI remained below 0.05. Plasma testosterone (T) increased from 2 to 11.34 ng ml⁻¹ by week 21 in injected fish, while control level remained below 1.5 ng ml⁻¹. In injected fish plasma 11–ketotestosterone (KT) and 17,20–dihydroxyprogesterone (17α20βP) levels increased from 20.2 to 41.9 and 8.9 to 219.7 ng ml⁻¹ respectively. Plasma T, 11–KT, and 17α20βP were all correlated with the GSI ( P <0–001) in injected fish. The most advanced stage of germ cells present in the control fish were spermatogonia. However, in injected fish spermatozoa were present by week 21. Eggs fertilized at this time with spermatozoa from injected fish achieved a 78% fertilization rate, whereas the testicular homogenate was incapable of fertilizing eggs.     

Sexually dimorphic development of mouse primordial germ cells: switching from oogenesis to spermatogenesis

During embryogenesis, primordial germ cells (PGCs) have the potential to enter either spermatogenesis or oogenesis. In a female genital ridge, or in a non-gonadal environment, PGCs develop as meiotic oocytes. However, male gonadal somatic cells inhibit PGCs from entering meiosis and direct them to a spermatogenic fate. We have examined the ability of PGCs from male and female embryos to respond to the masculinising environment of the male genital ridge, defining a temporal window during which PGCs retain a bipotential fate. To help understand how PGCs respond to the male gonadal environment, we have identified molecular differences between male PGCs that are committed to spermatogenesis and bipotential female PGCs. Our results suggest that one way in which PGCs respond to this masculinising environment is to synthesise prostaglandin D(2). We show that this signalling molecule can partially masculinise female embryonic gonads in culture, probably by inducing female supporting cells to differentiate into Sertoli cells. In the developing testis, prostaglandin D(2) may act as a paracrine factor to induce Sertoli cell differentiation. Thus part of the response of PGCs to the male gonadal environment is to generate a masculinising feedback loop to ensure male differentiation of the surrounding gonadal somatic cells.     

Stereological studies on germ cell mitochondria of rat during spermatogenesis and spermiogenesis

The following stereological parameters of mitochondria were calculated in rat germ cells during the spermatogenesis: volume density of matrix, outer compartment, outer membrane and inner membrane, surface density of outer membrane and inner membrane. They were the basis to calculate the partition coefficient of matrix and partition coefficient of outer compartment. The matrix volume demonstrated a decreasing in mitochondria of germ cells during spermatogenesis. The relative volume of outer compartment was calculated with the intracristal spaces and revealed increasing from spermatogonia to spermatids. The partition coefficient for the matrix significantly decreased. Our observations suggest that transformation of mitochondrial configuration during spermatogenesis and spermiogenesis is the expression of intensive metabolic processes and activity of membrane transport in germ cells.     

A seamless trespass: germ cell migration across the seminiferous epithelium during spermatogenesis

During spermatogenesis, preleptotene spermatocytes traverse the blood-testis barrier (BTB) in the seminiferous epithelium, which is reminiscent of viral pathogens breaking through the tight junctions of host epithelial cells. The process also closely resembles the migration of leukocytes across endothelial tight junctions to reach inflammation sites. Cell adhesion molecules of the immunoglobulin superfamily (e.g., JAM/CAR/nectin) participate in germ cell migration by conferring transient adhesion between Sertoli and germ cells through homophilic and heterophilic interactions. The same molecules also comprise the junctional complexes at the BTB. Interestingly, JAM/CAR/nectin molecules mediate virus uptake and leukocyte transmigration in strikingly similar manners. It is likely that the strategy used by viruses and leukocytes to break through junctional barriers is used by germ cells to open up the inter-Sertoli cell junctions. In associating these diverse cellular events, we highlight the "guiding" role of JAM/CAR/nectin molecules for germ cell passage. Knowledge on viral invasion and leukocyte transmigration has also shed insights into germ cell movement during spermatogenesis.