Poly(A)+ ribonucleic acids are enriched in spermatocyte nuclei but not in chromatoid bodies in the rat testis

To determine whether male germ cells contain specific storage sites for poly(A)+ RNAs, in situ hybridizations were performed with sections of rat testis and a [3H]polyuridylic acid probe. The highest levels of poly(A)+ RNA were found in spermatocytes and round spermatids, while lower levels of poly(A)+ RNA were detected in spermatogonia, elongated spermatids, Sertoli cells, myoid cells, fibroblasts, macrophages, and Leydig cells. No poly(A)+ RNA was detected in residual bodies of elongated spermatids. At stages IX-XI of the seminiferous cycle, the nuclei and cytoplasm of pachytene spermatocytes contained approximately equal amounts of poly(A)+ RNA, suggesting nuclear RNA storage and/or a reduced processing rate of mRNA precursors at this stage of germ cell differentiation. To examine the distribution of poly(A)+ RNAs in subcellular components of testicular cells, electron microscope radioautography was used. In germ cells and Sertoli cells, poly(A)+ RNA was often seen free in the cytoplasm or associated with the endoplasmic reticulum and was only occasionally found associated with mitochondria, lysosomes, lipid inclusions, and axonemes. As previously reported for the mRNAs of transition protein 1 and protamine 1 [Morales et al., J Cell Sci 1991; 100:119-131], no compartmentalization of poly(A)+ RNAs was detected in the cytoplasm of round and elongated spermatids. No poly(A)+ RNA was detected in association with the radial body and in most sections, the chromatoid body did not contain any significant amounts of poly(A)+ RNA.

Binding of a phosphoprotein to the 3' untranslated region of the mouse protamine 2 mRNA temporally represses its translation

The synthesis of the protamines, the predominant nuclear proteins of mammalian spermatozoa, is regulated during germ cell development by mRNA storage for about 7 days in the cytoplasm of differentiating spermatids. Two highly conserved sequences, the Y and H elements present in the 3' untranslated regions (UTRs) of all known mammalian protamine mRNAs, form RNA-protein complexes and specifically bind a protein of 18 kDa. Here, we show that translation of fusion mRNAs was markedly repressed in reticulocyte lysates supplemented with a mouse testis extract enriched for the 18-kDa protein when the mRNAs contained the 3' UTR of mouse protamine 2 (mP2) or the Y and H elements of mP2. No significant decrease was seen when the fusion mRNAs contained the 3' UTR of human growth hormone. The 18-kDa protein is developmentally regulated in male germ cells, requires phosphorylation for RNA binding, and is found in the ribonucleoprotein particle fractions of a testicular postmitochondrial supernatant. We propose that a phosphorylated 18-kDa protein plays a primary role in repressing translation of mP2 mRNA by interaction with the highly conserved Y and H elements. At a later stage of male gamete differentiation, the 18-kDa protein no longer binds to the mRNA, likely as a result of dephosphorylation, enabling the protamine mRNA to be translated.

Tracing the incorporation of the sperm tail in the mouse zygote and early embryo using an anti-testicular alpha-tubulin antibody

The mechanism of sperm tail incorporation and the fate of the tail during mouse fertilization and early embryogenesis were examined. Time-lapse video microscopy and anti-tubulin immunofluorescence show that the incorporation of the sperm tail, but not the sperm head, is sensitive to cytochalasin B (a microfilament inhibitor). Colcemid, a microtubule inhibitor, does not affect tail incorporation. High-resolution, low-voltage scanning electron microscopy demonstrates that the plasma membrane covering the sperm tail does not appear to fuse with the oocyte membrane during in vitro fertilization in the presence of cytochalasin. In control and colcemid-treated oocytes, the plasma membrane along the sperm tail, which is oriented tangential to the egg surfaces, appears to fuse with the oocyte membrane at multiple sites. An antibody to testicular alpha-tubulin detects sperm-derived, but not egg, microtubules and this has permitted us to trace the behavior and disappearance of the sperm tail during embryogenesis. Conventional and confocal microscopy show that following sperm incorporation, the tail often splays into multiple fibers. At the two-cell stage, the axoneme may be localized in either blastomere or it may be found to run through the midbody between both blastomeres. The tail appears to shorten by the 8-cell stage and is undetectable after the 16-32 cell stage. In morulae, tail fragments have been found in outer cells but not in inner ones, and fragments have not be found in blastocysts. These data suggest that microtubules of sperm and oocytes contain different isotypes of alpha-tubulin, nongenomic sperm-derived components survive at least to the morula stage of mouse development, and egg microfilaments are involved in the incorporation of the sperm tail but not the sperm head, which demonstrates that motility during sperm incorporation is different in mammals when compared to lower vertebrates and invertebrates.

Proteins homologous to the Xenopus germ cell-specific RNA-binding proteins p54/p56 are temporally expressed in mouse male germ cells

Antibodies specific for the Xenopus oocyte cytoplasmic 6S mRNA-binding particle p54/p56 and antibodies against Xenopus germ cell DNA-binding protein FRG Y2 recognize two RNA-binding proteins of the mouse testis. The mouse testis proteins, estimated by SDS-PAGE to be about 48 and 52 kDa, form RNA-protein complexes with either translationally regulated or control RNAs, suggesting that they are sequence-independent RNA-binding proteins. The binding of the 48/52-kDa proteins to RNA is reduced by heparin. The expression of the 48/52-kDa mouse proteins is germ cell-specific and developmentally regulated in the testis with a maximal amount of the two proteins being detected in early postmeiotic cells (round spermatids), a cell type where many mRNAs are stored. The 48/52-kDa proteins are detected solely in the nonpolysomal fractions of postmitochondrial adult testis extracts and are not detected in extracts of brain, liver, or prepuberal testes from 12-day-old mice. We conclude that two RNA-binding proteins that appear to be immunological and functional homologues of the Xenopus germ cell-specific RNA/DNA-binding proteins p54/p56/FRG Y2 are present in male germ cells and form complexes with stored mRNAs.

Utilization of an alternative transcription initiation site of somatic cytochrome c in the mouse produces a testis-specific cytochrome c mRNA

The differential regulation of somatic and testis-specific cytochromes c during spermatogenesis in the mouse is accompanied by changes in mRNA length (Hake, L. E., Alcivar, A. A., and Hecht, N. B. (1990) Development 110, 249-257). In spermatogenic stem cells through early meiotic cells, we detect four somatic cytochrome c (cyt cs) mRNAs of 1.3, 1.1, and 0.7-0.5 kilobases (kb), whereas in postmeiotic cells we detect a larger cyt cs mRNA of 1.7 kb. Oligonucleotide-directed RNase H cleavage of cyt cs mRNA revealed that the 1.7-kb mRNA contains over 1 kb of 5'-untranslated region which is not present in the four shorter cyt cs mRNAs. RNase protection assays indicate that this additional sequence arises from the utilization of an alternative transcription initiation site of the functional cyt cs gene which is 1085 base pairs upstream of the initiation site for the four shorter cyt cs mRNAs. To analyze the promoter for the 1.7-kb mRNA, a genomic clone containing the cyt cs gene and 5 kb of 5'-flanking DNA was isolated. Sequence comparison of the putative promoter region with promoters of other postmeiotically expressed genes reveals several conserved regions. Utilization of this alternative initiation site may be involved in the down-regulation of cytochrome cs during spermatogenesis.

Cellular localization of the mRNAs of the somatic and testis-specific cytochromes c during spermatogenesis in the rat

During mammalian spermatogenesis, two forms of cytochrome c, cytochromes cs and ct, are present in male germ cells. During meiosis, cytochrome ct begins to replace cytochrome cs. At least four size classes of cytochrome cs mRNA are expressed in all somatic cells and in early stages of male germ cells. In addition, a cytochrome cs transcript of 1.7 kB has been detected in rodent testes and is abundant in post meiotic male germ cells. Here we utilize "in situ" hybridization to define the cellular sites where the four ubiquitous cytochrome cs transcripts, the 1.7 kB cytochrome cs transcripts, and the testis-specific cytochrome ct transcripts are expressed in the rat. Low levels of cytochrome cs mRNAs are detected in Leydig cells, myoepithelial cells, Sertoli cells, all types of spermatogonia, and during meiotic prophase. The 1.7 kB cytochrome cs mRNA is first detected in late stages of meiotic prophase and reaches its highest levels in steps 1 to 9 spermatids. No cytochrome cs mRNAs are detected in spermatids between steps 10 to 19. Low levels of cytochrome ct mRNAs, initially detected in zygotene spermatocytes, reach maximal levels in round spermatids. For all three probes the majority of the silver grains are localized randomly throughout the cytoplasm, suggesting that neither the translating nor non-translating (the 1.7 kB mRNA) forms of cytochrome cs mRNA nor the cytochrome ct mRNAs are sequestered during spermatogenesis. The absence of cytochrome cs or ct mRNAs in steps 10-19 spermatids suggest that the cytochrome ct protein does not turn over rapidly in late stage male germ cells.

Temporal gene expression is restored concomitantly with germ cells in the experimentally regressed rat testis

The present study was designed to examine the effect of hypophysectomy and subsequent testosterone administration on germ cell numbers and germ cell- and Sertoli cell-specific mRNA levels in adult rats. Rats were hypophysectomized and 4 weeks later received 24-cm testosterone-containing polydimethylsiloxane (PDS) implants. Sham-hypophysectomized rats received an empty PDS implant. At 0 and 3 days, and at 1, 2, 4, and 8 weeks, rats were killed. One testis from each rat (n = 4/group) was used to prepare total RNA; the other testis was used to enumerate stage VII-VIII germ cells. cDNA probes for germ cell and Sertoli cell products were used to monitor germ cell- and Sertoli cell-specific mRNAs on Northern blots. Four weeks after hypophysectomy (0 days), preleptotene and pachytene spermatocytes and round and elongating spermatids were reduced in number to 54%, 12%, 1%, and 0%, respectively, of the control values. Testosterone administration caused a time-dependent increase in germ cell numbers; after 8 weeks of testosterone treatment, preleptotene and pachytene spermatocytes and round and elongating spermatids were 75%, 79%, 74%, and 22%, respectively, of control values. Lactate dehydrogenase-C, phosphoglycerate kinase-2, protamine-1, and sulfated glycoprotein-2 mRNA levels (on a per micrograms RNA basis) were 34%, 34%, less than 1%, and 580% of control values, respectively, 4 weeks after hypophysectomy and 79%, 87%, 61%, and 192% of control values, respectively, after 8 weeks of testosterone treatment. Pachytene spermatocyte and round spermatid numbers increased, while Sertoli cell sulfated glycoprotein-2 mRNA levels decreased, with respect to 4 week hypophysectomy values, as early as 3 days after implantation of testosterone capsules. In contrast, germ cell (lactate dehydrogenase-C, phosphoglycerate kinase-2, and protamine-1) mRNA levels increased to the greatest extent between 1-4 weeks after the start of testosterone treatment and, after a short lag period, reflected increases in germ cell type and number. The results indicate that cell-specific mRNAs appear concomitantly with germ cell reappearance in a time-dependent manner in the testes of testosterone-treated hypophysectomized adult rats.

DNA methyltransferase is developmentally expressed in replicating and non-replicating male germ cells

Genomic methylation patterns are established during maturation of primordial germ cells and during gametogenesis. While methylation is linked to DNA replication in somatic cells, active de novo methylation and demethylation occur in post-replicative spermatocytes during meiotic prophase (1). We have examined differentiating male germ cells for alternative forms of DNA (cytosine-5)-methyltransferase (DNA MTase) and have found a 6.2 kb DNA MTase mRNA that is present in appreciable quantities only in testis; in post-replicative pachytene spermatocytes it is the predominant form of DNA MTase mRNA. The 5.2 kb DNA MTase mRNA, characteristic of all somatic cells, was detected in isolated type A and B spermatogonia and haploid round spermatids. Immunobolt analysis detected a protein in spermatogenic cells with a relative mass of 180,000-200,000, which is close to the known size of the somatic form of mammalian DNA MTase. The demonstration of the differential developmental expression of DNA MTase in male germ cells argues for a role for testicular DNA methylation events, not only during replication in premeiotic cells, but also during meiotic prophase and postmeiotic development.

DNA polymerase-beta and poly(ADP)ribose polymerase mRNAs are differentially expressed during the development of male germinal cells

We have examined the steady-state mRNA levels in spermatogenic cells of two nuclear enzymes that appear to be involved in DNA repair, DNA polymerase-beta (pol-beta) and poly(ADP)ribose polymerase (PADPRP). Two pol-beta mRNAs of 1.3 kb and 1.4 kb were detected in extracts from mouse testes. In leptotene/zygotene spermatocytes a low level of the 1.4-kb mRNA was observed. Both pol-beta mRNAs were found in meiotic pachytene spermatocytes, with the 1.3-kb form being more abundant. In contrast, the 1.4-kb form was more abundant in haploid round spermatids. Polysome gradient analyses indicated that the two pol-beta mRNAs were predominantly present in the nonpolysomal fractions of spermatocytes. In round spermatids, a larger fraction of the 1.4-kb pol-beta mRNA was associated with polysomes, correlating well with the higher levels of pol-beta enzyme detected during spermiogenesis. The pattern of PADPRP mRNA expression differed from the expression of pol-beta mRNA. The two PADPRP mRNAs of 3.7 and 3.8 kb were present in type A and type B spermatogonia, reached their highest levels in pachytene spermatocytes, and were greatly reduced in haploid round and elongating spermatids. Most of the pachytene spermatocyte PADPRP and mRNAs were present in polysomes, whereas a greater percentage of PADPRP mRNAs in round spermatids were detected in the nonpolysomal fractions. This finding correlates with the immunocytochemical nuclear localization of this enzyme in pachytene spermatocytes. These data demonstrate that different developmental patterns of mRNA expression and translational regulation exist for the pol-beta and PADPRP mRNAs during differentiation of male germinal cells.

junD mRNA expression differs from c-jun and junB mRNA expression during male germinal cell differentiation

The members of the jun family of protooncogenes (junB, c-jun, and junD) share a high degree of sequence homology and function as transcriptional regulators. Here we compare the pattern of junD mRNA expression during spermatogenesis to that of junB and c-jun (Alcivar et al.: J Biol Chem 265:20160-20165, 1990). junD transcripts are present at high levels in total RNA obtained from both prepuberal and adult intact testes, with the highest levels at stages containing predominantly premeiotic and postmeiotic germ cells. Analyses of cells isolated from testes of 8-day-old mice indicate that the level of the 1.8 kb junD mRNA is higher in type B spermatogonia than in type A spermatogonia. In testes of 17-day-old mice, the highest junD mRNA levels are detected in preleptotene spermatocytes compared to leptotene/zygotene and prepuberal pachytene spermatocytes. In cells from adult testes, the junD mRNA levels are higher in postmeiotic round spermatids and residual bodies/cytoplasts than in meiotic pachytene spermatocytes. An additional junD transcript of about 1.6 kb is detected in postmeiotic cells. Analyses of polysomal and nonpolysomal RNAs prepared from isolated testicular cells indicate that in early meiotic cell types the junD transcript is more efficiently loaded onto polysomes than in later cell types. In summary, the pattern of expression of junD differs from that of junB and c-jun during spermatogenesis most notably in that 1) junD mRNA levels do not increase following dissociation of testicular cells and 2) in contrast to the nearly undetectable levels of junB and c-jun mRNAs in adult postmeiotic testicular cells, high levels of junD mRNAs are seen.(ABSTRACT TRUNCATED AT 250 WORDS)

The mouse transition protein 1 gene contains a B1 repetitive element and is located on chromosome 1

The gene for mouse transition protein 1 (mTP1) was isolated, sequenced, and chromosomally mapped. The nucleotide sequence of 1895 bp of a 6.4-kb mTP1 genomic subclone was determined to include 788 bp of 5' flanking region, 564 bp of coding region including a 396-bp intron and a TAA stop codon, and 543 bp of 3' flanking region. The mTP1 gene contains a B1 repeat sequence within the only intron of the gene. The transcriptional start site of the mTP1 mRNA was determined to be located 31 bases upstream of the ATG translational start codon. Southern blot analysis demonstrated the presence of sequences homologous to the mTP1 cDNA in the genomes of the rat, hamster, bull, boar, dog, horse, ram, human, and two marsupials (the American opossum and Monodelphis), suggesting that the mTP1 gene sequence is widely conserved. The TP1 gene has been mapped by analysis of restriction fragment length variants (RFLV) in an interspecific backcross to a position 0.7 +/- 0.4 cM telomeric of Mylf and 1.2 +/- 0.5 cM centromeric of Vil on mouse chromosome 1.

Cytoplasmic localization during storage and translation of the mRNAs of transition protein 1 and protamine 1, two translationally regulated transcripts of the mammalian testis

During spermatogenesis in mammals, the transcripts of transition protein 1 (TP 1) and protamine 1 (Prm 1) are under translational regulation. Following their transcription in round spermatids, the mRNAs for TP 1 and Prm 1 are stored in the cytoplasm from 3–7 days before being translated towards the end of spermatogenesis. To test the hypothesis that the inactivation or activation of transcripts during spermiogenesis could be mediated by mRNA compartmentalization in the cytoplasm of spermatids, light and electron microscopy were used to localize, by in situ hybridization, the cellular and subcellular sites of stored and translated mRNAs for these two testis-specific transcripts. During early spermiogenesis (before step 7) nuclear transcripts of both TP 1 and Prm 1 were seen. After step 7 the TP 1 and Prm 1 mRNAs were only detected in the cytoplasm. Throughout spermiogenesis the cytoplasmic mRNAs were not localized to any membrane-bound organelles such as the endoplasmic reticulum or mitochondria or to non-membrane-bound structures such as the chromatoid body. These studies demonstrate that the translational arrest of the TP 1 and Prm 1 mRNAs is not primarily controlled by compartmentalized storage in the cytoplasm of spermatids. Moreover, when translation of these mRNAs occurs in elongated spermatids, the mRNAs are present throughout the cytoplasm.

Distribution of actin isoforms within cells of the seminiferous epithelium of the rat testis: evidence for a muscle form of actin in spermatids

Recently, a cDNA that coded for an enteric smooth muscle gamma-actin (SMGA) that was expressed in post-meiotic mouse testicular cells was identified. To determine the cellular location(s) of the protein encoded by this cDNA, this SMGA was probed for by immunocytochemistry in the cells of the seminiferous epithelium with two different monoclonal antibodies (Mabs), B4 and HUC 1-1, known to be muscle actin selective. As a control, we also examined the immunoreactivity of a third Mab, C4, that reacts with all non-muscle and muscle vertebrate isoactins. Using light and electron microscopy, a progressive increase in immunolabeling was observed with the muscle selective HUC 1-1 Mab over a loose actin filamentous network distributed throughout the cytoplasm of steps 4-16 spermatids. Thereafter, the labeling decreased such that at step 17 spermatids, only cytoplasmic labeling in the tail of the spermatids was observed. No labeling of this network was noted with the C4 or B4 Mabs. However, myoid cells enveloping seminiferous tubules and smooth muscle cells of interstitial blood vessels demonstrated comparable intense labeling with each of the three Mabs. The C4 Mab intensely labeled actin filaments of the Sertoli-Sertoli and Sertoli-spermatid ectoplasmic specializations. Also well labeled were numerous actin filaments found in the apical Sertoli cell processes encapsulating the heads of late step 19 spermatids at stage VII of the cycle of the seminiferous epithelium. In addition, actin filamentous bundles enveloping tubulobulbar complexes of the late spermatids within the Sertoli cell apical processes were intensely labeled. The actin filaments in the Sertoli apical processes and surrounding the tubulobulbar complexes were also strongly immunolabeled with the HUC 1-1 Mab. The C4 Mab but not the B4 or HUC 1-1 Mabs, recognized actin in the subacrosomal space of steps 4-18 spermatids. This study suggests that there are muscle isoforms of actin within the cytoplasm of developing spermatids and within apical processes of Sertoli cells.

A complex pattern of H2A phosphorylation in the mouse testis

Phosphorylation of H2A histones in mouse testis was examined using testis tubule cultures labeled with 32PO4. Histones were analyzed by two systems of two-dimensional polyacrylamide gel electrophoresis, followed by autoradiography of the gels. Of the 32PO4 detected in histones, 95% was incorporated by certain modified forms of the H2A variants H2A.1 and H2A.X. Phosphorylation sites were mapped to N- and C-terminal regions of the modified variants by SDS gel electrophoresis and autoradiography of peptides generated by cleavage of in vitro-labeled proteins with N-bromosuccinimide. Incorporation rates differed for N- and C-terminal regions from different modified forms, demonstrating a complex pattern of H2A phosphorylation in the mouse testis.

Cytoplasmic protein binding to highly conserved sequences in the 3' untranslated region of mouse protamine 2 mRNA, a translationally regulated transcript of male germ cells

The expression of the protamines, the predominant nuclear proteins of mammalian spermatozoa, is regulated translationally during male germ-cell development. The 3' untranslated region (UTR) of protamine 1 mRNA has been reported to control its time of translation. To understand the mechanisms controlling translation of the protamine mRNAs, we have sought to identify cis elements of the 3' UTR of protamine 2 mRNA that are recognized by cytoplasmic factors. From gel retardation assays, two sequence elements are shown to form specific RNA-protein complexes. Protein binding sites of the two complexes were determined by RNase T1 mapping, by blocking the putative binding sites with antisense oligonucleotides, and by competition assays. The sequences of these elements, located between nucleotides + 537 and + 572 in protamine 2 mRNA, are highly conserved among postmeiotic translationally regulated nuclear proteins of the mammalian testis. Two closely linked protein binding sites were detected. UV-crosslinking studies revealed that a protein of about 18 kDa binds to one of the conserved sequences. These data demonstrate specific protein binding to a highly conserved 3' UTR of translationally regulated testicular mRNA.

DNA methylation and expression of the genes coding for lactate dehydrogenases A and C during rodent spermatogenesis

The testis chromatin undergoes profound structural alterations and functional changes during spermatogenesis. Changes in DNA methylation have been correlated with gene expression in a number of systems, but the relationship between methylation and gene expression for testicular genes is unclear. To address this question, DNA methylation patterns and mRNA expression for a somatic form of lactate dehydrogenase (LDH), LDH-A, were compared with those of the testis-specific form, LDH-C, in preparations from testes of prepubertal and sexually mature mice, from isolated testicular cells, and from somatic tissues. At specific sites, LDH-A was less methylated in adult testis than in spleen DNA; the decreased methylation in the testicular DNA occurred as early as type A spermatogonia. In contrast, DNA methylation patterns for LDH-C did not differ between spleen and testis DNAs. In Northern blots, the levels of LDH-A transcripts were low in total testis RNA obtained from 6-12-day-old mice, and in type A and B spermatogonia from 8-day-old mice. LDH-A mRNA levels increased gradually in testes from 16-45-day-old mice. LDH-C transcripts were first detectable in the testes of 12-day-old mice and increased as spermatogenesis proceeded. Both LDH-A and LDH-C mRNA levels were low in preleptotene spermatocytes and leptotene/zygotene spermatocytes and increased substantially in pachytene spermatocytes and round spermatids. Reduced levels of LDH-A and LDH-C mRNAs were found in the residual bodies/cytoplasts fraction.(ABSTRACT TRUNCATED AT 250 WORDS)

Protein binding regions in the mouse and rat protamine-2 genes

To help define the regulatory mechanisms for tissue-specific and temporal transcription of the mouse protamine genes, the mouse protamine-2 gene was examined in vitro using protein-DNA binding assays to determine which 5' flanking regions of the gene bind proteins. DNA binding was examined in nuclear extracts prepared from expressing and nonexpressing tissues. One fragment of the gene, from -419 to -141, bound a factor present in nuclear extracts prepared from tissues in which the gene is not expressed (testis from 16-day-old animals, liver and brain), but formed very little complex in extracts from adult testis where the gene is normally expressed. This suggests that this region may be recognized by a negative regulatory factor that prevents the gene from being expressed in inappropriate tissues. Another region of the gene, from -140 to -23, formed a complex in all extracts tested, and an additional complex specific to adult testis extracts. These complexes were not formed with the rat protamine-2 gene, whose mRNA is present in vivo at approximately 5% of the level of mouse protamine-2 mRNA and is poorly transcribed in an in vitro testicular transcription system. This suggests that the factor or factors binding to this region serve as positive regulatory factors that are necessary to maintain a high level of protamine gene transcription. These studies present the first analysis of protein binding sites within the promoter of a testis-specific gene.

Differential post-translational modifications of microtubules in cells of the seminiferous epithelium of the rat: a light and electron microscope immunocytochemical study

The cells of the seminiferous epithelium of the rat testis are a rich source of microtubules and contain distinct microtubular structures such as the meiotic spindle and manchette. Microtubule diversity can be maintained by differential genetic expression of the multiple alpha- and beta-tubulin polypeptides or by tubulin monomer acetylation and detyrosination, post-translational modifications of alpha-tubulin. In the present analysis, antibodies that specifically recognize acetylated (antiacetylated), tyrosinated (anti-Tyr) and detyrosinated (anti-Glu) alpha-tubulins were employed to examine the distribution of post-translationally modified microtubules in the cells of the seminiferous epithelium. In the light microscope, a distinct pattern of staining for each antibody was detected using immunoperoxidase techniques on paraffin-embedded testicular sections. In the case of the anti-Glu antibody, a dense immunoperoxidase staining was detected in the cytoplasm of steps 4-7 spermatids. Thereafter, staining was noted over the area corresponding to the manchette of steps 8-15 spermatids, but not over their cytoplasm. The tails of spermatids were also reactive with this antibody. The anti-Tyr antibody was observed to be localized over the cytoplasm of Sertoli cells in their basal, supranuclear, and apical regions. A dense immunoperoxidase staining was also noted in the cytoplasm of pachytene spermatocytes, but it was negligible in the cytoplasm of spermatocytes undergoing their meiotic division; in these cells the centrioles and meiotic spindle were reactive. The spermatid's tails were also reactive. The antiacetylated antibody showed reactivity only over the tails of spermatids. With the electron microscope, a similar pattern of labeling was noted using immunogold labeling on Lowicryl K4M embedded testicular sections. The anti-Glu antibody heavily labeled microtubules of the manchette and the axoneme of tails of spermatids as well as microtubules of the proximal and distal centrioles and centriolar adjunct. The anti-Tyr antibody strongly labeled microtubules of Sertoli cells and the meiotic spindle and midbody of dividing spermatocytes. The anti-Tyr antibody also labeled the microtubules of the axoneme, centrioles, and centriolar adjunct of spermatids, but to a lesser degree than the anti-Glu antibodies; the manchette was faintly labeled. Of the three antibodies, the antiacetylated antibody showed the weakest labeling of microtubules of the centrioles, centriolar adjunct, and midbody, whereas those of the manchette and Sertoli cells were unreactive; the axoneme was moderately labeled.(ABSTRACT TRUNCATED AT 400 WORDS)

Increased levels of junB and c-jun mRNAs in male germ cells following testicular cell dissociation. Maximal stimulation in prepuberal animals

We have examined the relative transcript levels of the junB and c-jun proto-oncogenes during development of the mouse testis. junB and c-jun mRNA levels are low in total RNA from intact immature or mature testes. Dissociation of testicular cells, however, increases the levels of junB and c-jun mRNAs, with higher increases in the dissociated cells from testes of 8-day-old mice than from 17-day-old or sexually mature mice. These differences in junB and c-jun mRNA levels localize to specific cell types. In testes from 8-day-old mice, the mRNA levels for both proto-oncogenes are higher in type B spermatogonia and in the interstitial cell fraction than in type A spermatogonia. In testes of 17-day-old mice, the highest mRNA levels for both proto-oncogenes are seen in preleptotene spermatocytes and interstitial cells, with decreasing levels in leptotene/zygotene spermatocytes and prepuberal pachytene spermatocytes. junB and c-jun mRNAs are nearly undetectable in pachytene spermatocytes, round spermatids, and residual bodies/cytoplasts. The increased junB mRNA levels originate not only from the expected 2.1-kilobase transcript but from a more slowly migrating transcript of about 2.3 kilobases. RNase H analysis demonstrates that this migration change was due to an increase in mRNA polyadenylation. The low levels of junB and c-jun mRNAs in intact testes and the much higher levels in isolated cells from identical testes suggest that the disruption of cell-to-cell contact increases the amount of junB and c-jun transcripts in specific cells of the testis. Coupled with this increase, structural changes are seen with the junB mRNA.

Stage- and cell-specific expression of the ornithine decarboxylase gene during rat and mouse spermatogenesis

Ornithine decarboxylase (ODC) is an enzyme that has been shown to be induced in the growth, differentiation and proliferation of cells. We have used a cDNA probe to determine ODC mRNA levels in different stages of the cycle of rat and mouse seminiferous epithelium. For Northern and slot-blot hybridizations, RNA was isolated from microdissected staged seminiferous tubules. Cell-specific localization of ODC mRNA was studied by in situ hybridization. In the rat, in situ hybridization showed increasing mRNA levels during prophase of meiosis with the highest mRNA levels seen in late pachytene spermatocytes and step 3-5 spermatids. In the mouse, the mRNA levels increased in a similar fashion and the highest mRNA levels were found in step 1-8 spermatids. In the rat, Northern blot hybridizations revealed three molecular sizes of ODC mRNA: 2.2, 2.7 and 1.6 kb. The levels of all molecular sizes were highest in stages VII-VIII, and the lowest mRNA levels were seen in stage I of the seminiferous epithelial cycle. The level of the 2.2 kb transcript was low during stages XIII-I. In the mouse, the Northern blot hybridizations also showed three molecular sizes of ODC mRNA: 2.2 and 2.7 kb and very low levels of 1.6 kb transcript. The levels of the transcripts were steady throughout the cycle. In the mouse, the 2.2 kb transcript was more abundant than the 2.7 kb transcript indicating a species difference between rat and mouse in the usage of the two polyadenylation signals within the ODC gene.(ABSTRACT TRUNCATED AT 250 WORDS)

Changes in mRNA length accompany translational regulation of the somatic and testis-specific cytochrome c genes during spermatogenesis in the mouse

The mouse testis contains two isotypes of cytochrome c, which differ in 14 of 104 amino acids: cytochrome cs is present in all somatic tissues and cytochrome cT is testis specific. The regulation of cytochrome cS and cytochrome cT gene expression during spermatogenesis was examined by Northern blot analysis using specific cDNA probes. Total RNA was isolated from adult tissues, enriched germinal cell populations and polysomal gradients of total testis and isolated germinal cells. Three cytochrome cS mRNAs were detected averaging 1.3 kb, 1.1 kb and 0.7 kb in all tissues examined; an additional 1.7 kb mRNA was observed in testis. Isolated germinal cells through prepuberal pachytene spermatocytes contained only the three smaller mRNAs; the 1.7 kb mRNA was enriched in round spermatids. All three smaller cytochrome cS mRNAs were present on polysomes; the 1.7 kb mRNA was non-polysomal. Cytochrome cT mRNA of 0.6-0.9 kb was detected in testis; mRNA levels were low in early spermatogonia and peaked in prepuberal pachytene spermatocytes. In adult pachytene spermatocytes, a subset of the cytochrome cT mRNAs, 0.7-0.9 kb, was present on polysomes; a shortened size class, 0.6-0.75 kb, was non-polysomal. A distinct, primarily non-polysomal, cytochrome cT 0.7 kb mRNA was present in round spermatids. These results indicate that (1) both cytochrome cS and cytochrome cT mRNAs are present in early meiotic cells, (2) a 1.7 kb cytochrome cS mRNA is post-meiotically expressed and non-polysomal and (3) cytochrome cS and cytochrome cT mRNAs are each developmentally and translationally regulated during spermatogenesis.

Expression of the rat protamine 2 gene is suppressed at the level of transcription and translation

We have compared the rat protamine 2 gene sequence (rP2) to that of the mouse protamine 2 (mP2) gene. The sequence encompasses 435 nucleotides of the coding region which includes an intron of 120 nucleotides, 461 nucleotides 5' to the coding sequence and 181 bases 3' to it. In the mouse the protamine 2 gene is abundantly transcribed and translated. The mP2 protein is initially synthesized as a precursor and then proteolytically processed to yield the mature protein. In contrast, in the rat, protamine 2 transcripts are present at 2-5% that found in the mouse and the mature protein has never been detected in spermatozoa. Although there is 92% nucleotide similarity between rat and mouse genes and 91% similarity of the predicted amino acid sequences, in vitro runoff transcription assays performed in either rat or mouse testis-derived transcription systems reveal that the rP2 promoter is only 30% as efficient a promoter as the mP2 promoter. Analyses of total sperm basic nuclear proteins extracted from epididymal sperm using a monoclonal antibody specific for protamine 2 suggest that the rat P2 mRNA is translated in vivo but is not properly processed. These results suggest that the lowered transcription rate and altered processing sites of the rat protamine 2 gene are likely to contribute to the lack of protamine 2 in rat spermatozoa.

The mouse smooth muscle gamma actin gene is on chromosome 6

Smooth muscle gamma actin (Actg) is expressed in smooth muscle and in haploid male germ cells. In order to further characterize the Actg gene, a 60-nucleotide-long isotype-specific probe was synthesized. Single bands of DNA were detected when this oligonucleotide was used to probe blots of mouse genomic DNA digested with PstI, EcoRI, KpnI, or XbaI. These results suggest Actg is a single-copy gene with no detectable pseudogenes. The Actg gene was mapped to mouse chromosome 6 by Southern blot analysis of DNA isolated from 15 mouse-hamster hybrid cell lines.