Haploid accumulation and translational control of phosphoglycerate kinase-2 messenger RNA during mouse spermatogenesis

Characterization by enriched polyclonal antibodies of developmentally regulated and cell type specific mouse testis antigens

Polyclonal antisera directed against testicular proteins were characterized by immunocytochemistry and Western blot analysis. Antibodies binding to testis-specific, developmentally regulated protein bands were eluted from their antigens and used for further characterization of the developmental profile and cell type-specific expression of two antigens, PSM33 and NNA75. While PSM33 was found to be present in spermatocytes from the late pachytene stage on, NNA75 could be localized in neonatal interstitial cells. NNA75 expression ceases by to postnatal day ten, when first meiosis starts within the seminiferous tubules, thus suggesting an interactive role of Leydig cells during the onset of meiotic divisions.

Expression and processing of the rooster protamine mRNA

In situ hybridization in immature and mature testis sections shows that the rooster protamine mRNA is transcribed in the post-meiotic stages of spermatogenesis. Two distinct populations of rooster protamine mRNA are expressed as determined by Northern blot analysis. Since there are two copies of the chicken protamine gene per haploid genome, the question was raised of whether the two mRNA populations correspond to the two different genes or was a result of differential mRNA processing. The fact that the two genes differ only in one nucleotide (one extra A in the polyadenylation signal in the second locus) and that random sequencing of several cDNA clones has revealed only one poly-A tail addition site favors the hypothesis that the differences are due to mRNA processing. This is supported by 3' S1 mapping which shows a single poly-A tail addition site, which in turn suggests that the heterogeneity is due to differences in the length of the poly-A tail. The latter is confirmed by RNAse H digestion of mRNA-Oligo-dT hybrids which shows that the two mRNA populations (470 +/- 20 nucleotide (nt) and 430 +/- 20 nt respectively) are converted to a single population of 345 +/- 15 nt in good accordance with the poly-A tail site determined by S1 mapping (347 nt). Thus one species has a poly-A tail of 145 nt appearing in round spermatids and the second, a shorter tail of 105 nt present at the later stages of elongated spermatids.

Analysis of a murine male germ cell-specific transcript that encodes a putative zinc finger protein

A cDNA species, corresponding to a gene with testis-specific expression (TSGA), was isolated from a testis cDNA library. The temporal and spatial expression of TSGA was studied by in situ hybridization as well as RNA filter hybridization. In tissue sections, the TSGA sequence was confined to cells within the seminiferous tubules. For filter hybridization, RNA was isolated from testis of prepubertal rats of different ages as well as from enriched populations of various germ cell types. It was found that TSGA is expressed only in male germ cells and that the steady-state level of TSGA transcripts reaches a maximum during the meiotic and the postmeiotic stages of germ cell development, suggesting a meiotic or postmeiotic function for the encoded protein. TSGA encodes a putative protein having 1,214 amino acids and contains a zinc finger, a structure that previously has been shown to mediate binding to nucleic acids.

Cloning and sequence analysis of a human Y-chromosome-derived, testicular cDNA, TSPY

The human Y-specific gene TSPY (testis-specific protein Y-encoded) was originally defined by the genomic probe pJA36B2 (DYS14), which detects a poly(A)+ RNA transcript in human testis tissue. Using this probe we have now isolated the cDNA sequence pJA923 from a human testis cDNA library. Southern blot hybridization experiments with both probes yielded identical male-specific banding patterns, but sequence analysis revealed an overall homology of only 92.3%. It appears that pJA36B2 (DYS14) is a pseudogene to pJA923 (TSPY), as only pJA923-specific transcripts were discovered in testis mRNA. PCR analysis of genomic DNA from patients with specific primers confirmed the simultaneous presence of at least two independent loci on the proximal short arm of the Y chromosome.

Determining transcript number using the polymerase chain reaction: Pgk-2, mP2, and PGK-2 transgene mRNA levels during spermatogenesis

We describe a technique that uses reverse transcription and the polymerase chain reaction (pcr) to rapidly quantitate numbers of specific mRNA transcripts from nanogram quantities of total cellular RNA. Linearity of input molecules to output signal was maintained by limiting the cycle number and the amount of input RNA and by minimizing the number of manipulations. Absolute levels of specific transcripts were determined by the inclusion of a separate standard curve composed of serially diluted in vitro transcribed RNA run alongside the experimental samples. This allowed rapid quantitation of many samples simultaneously. We applied this technique to measuring the expression of phosphoglycerate kinase 2 (Pgk-2) transgenes in the mouse testis during development. A human PGK-2 transgene, a PGK-2/CAT transgene, and the endogenous mPgk-2 gene all displayed similar patterns and levels of expression, consistent with the conclusion that peak RNA accumulation occurs in pachytene spermatocytes. Mouse protamine 2 (mP2) is expressed at a level approximately tenfold higher than Pgk-2 and displays a different pattern of expression consistent with initiation of transcription occurring in haploid round spermatids.

Detection of secreted and temporarily inducible heat shock responsive proteins in mouse testicular tissue

Temperature-induced effects on the synthesis of murine testicular proteins were investigated by one- and two-dimensional SDS polyacrylamide gel electrophoresis. Newly synthesized proteins were monitored by incorporation of 35S-methionine and autoradiography. Three heat shock responsive proteins, which are differently affected by elevated temperatures, are described. These proteins represent special examples for how testicular cells respond to environmental stress. One of these proteins, HSl36, is synthesized and secreted at 38 degrees C, whereas at lower, scrotal temperatures it is not detectable. HSlD74 protein is synthesized at elevated temperatures, but only in prepuberal testis, not in adult. Synthesis of the third example, HSR28, is decreased within the seminiferous tubules, but only in those regions which bear cell associations of the elongation stage. These results indicate that the use of DNA probes of the 'heat shock'-gene family might not be sufficient to describe the molecular reasons for impaired spermatogenesis following hyperthermia.

Transcription of testicular angiotensin-converting enzyme (ACE) is initiated within the 12th intron of the somatic ACE gene

Angiotensin-converting enzyme (ACE) is a zinc-containing dipeptidyl carboxypeptidase that catalyzes the conversion of angiotensin I to the potent vasoconstrictor angiotensin II. By analyzing cDNA and genomic DNA, we have constructed a consensus sequence encoding the testis isozyme of mouse ACE. Testis ACE cDNA contains 2,435 base pairs and encodes a protein of 732 amino acids. The N-terminal 66 amino acids are unique to the testis isozyme, while the remaining 666 are identical to the carboxyl half of mouse somatic ACE. The overall conservation of amino acid sequence between the testis isozymes of the mouse, rabbit, and human is 78 to 84%. The conservation of amino acids for the N-terminal domain uniquely expressed within the testis is 63 to 67% between these species. Primer extension and RNase protection experiments show that RNA transcription of the testis ACE isozyme begins 16 or 17 bases upstream from the translation start site. A sequence element resembling a TATA box is found 25 bases 5' of the transcription start site. To create its unique isozyme of ACE, the testis begins mRNA transcription in the middle of the exonic-intronic structure of somatic ACE, within a sequence treated as an intron by somatic tissues. Testis ACE is not the result of alternative RNA splicing but seems due to the start of transcription at a unique site within the ACE gene.

Transcription of testicular angiotensin-converting enzyme (ACE) is initiated within the 12th intron of the somatic ACE gene

Angiotensin-converting enzyme (ACE) is a zinc-containing dipeptidyl carboxypeptidase that catalyzes the conversion of angiotensin I to the potent vasoconstrictor angiotensin II. By analyzing cDNA and genomic DNA, we have constructed a consensus sequence encoding the testis isozyme of mouse ACE. Testis ACE cDNA contains 2,435 base pairs and encodes a protein of 732 amino acids. The N-terminal 66 amino acids are unique to the testis isozyme, while the remaining 666 are identical to the carboxyl half of mouse somatic ACE. The overall conservation of amino acid sequence between the testis isozymes of the mouse, rabbit, and human is 78 to 84%. The conservation of amino acids for the N-terminal domain uniquely expressed within the testis is 63 to 67% between these species. Primer extension and RNase protection experiments show that RNA transcription of the testis ACE isozyme begins 16 or 17 bases upstream from the translation start site. A sequence element resembling a TATA box is found 25 bases 5' of the transcription start site. To create its unique isozyme of ACE, the testis begins mRNA transcription in the middle of the exonic-intronic structure of somatic ACE, within a sequence treated as an intron by somatic tissues. Testis ACE is not the result of alternative RNA splicing but seems due to the start of transcription at a unique site within the ACE gene.

Measurement by quantitative PCR of changes in HPRT, PGK-1, PGK-2, APRT, MTase, and Zfy gene transcripts during mouse spermatogenesis

A reverse transcriptase-polymerase chain reaction assay (RT-PCR) was used quantitatively to measure accumulated levels of RNA transcripts in total mouse RNAs derived from male germ cells at various spermatogenic stages. RNA levels for two X-linked enzymes, phosphoglycerate kinase (PGK-1) and hypoxanthine phosphoribosyl transferase (HPRT), both decrease during spermatogenesis, although the transcript levels decrease much more rapidly for PGK-1. RNA for the Y-linked ZFY (zinc finger protein) is elevated in all spermatogenic cell fractions tested, being particularly high in leptotene/zygotene spermatocytes and round spermatids. RNA for adenine phosphoribosyltransferase (APRT) increases 5-fold to a peak during late pachynema. RNA for PGK-2, undetectable in spermatogonial cells, increases at least 50-fold by the round spermatid stage. DNA (cytosine-5-)-methyltransferase (MTase) transcript levels are over an order of magnitude higher throughout spermatogenesis than in non-dividing liver cells.

Transcription of the testis-specific mouse protamine 2 gene in a homologous in vitro transcription system

Transcriptionally active nuclear extracts were prepared from mouse testes to study the transcription of the testis-specific mouse protamine 2 (Prm-2) gene in vitro. The testicular system is unique among mammalian in vitro transcription systems in regard to its temperature optimum. In extracts made from prepuberal testes, the temperature optimum for in vitro transcription of Prm-2 is 30 degrees C, similar to somatic in vitro systems. However, in adult testis extracts, the optimum temperature for Prm-2 transcription is 20 degrees C. The different temperature optima seen in vitro for prepuberal and adult testes extracts parallels in vivo physiological temperature sensitivities of the differentiating male germ cells. The testis system also differs from other in vitro transcription systems in its divalent metal cation and ionic strength requirements for optimal transcription. The mouse Prm-2 gene is maximally transcribed at a MgCl2 concentration of 3-5 mM and over a KCl concentration range of 40-100 mM. By using the testis in vitro transcription system to study the Prm-2 gene by deletion analysis, we have determined that positive promotion for the gene lies within the region -170 to -82 from the start of transcription. This region contains a putative Sp-1 binding site. Additional upstream sequences appear to repress Prm-2 transcription in a heterologous transcription system.

Sequence and developmental expression of the mRNA encoding the seleno-protein of the sperm mitochondrial capsule in the mouse

We have characterized cDNA clones encoding the selenium-containing polypeptide of the keratinous mitochondrial capsule in mouse sperm. The longest open reading frame encodes a polypeptide 143 amino acids long which contains 21% cysteine and 27% proline and closely resembles the size and amino acid composition of bull mitochondrial capsule seleno-protein (V. Pallini, B. Baccetti, and A. G. Burrini, 1979, in "The Spermatozoon," D. W. Fawcett and J. M. Bedford, Eds., pp. 141-151, Urban & Schwartzenberg, Baltimore/Munich). The reading frame encoding the mitochondrial capsule seleno-protein ends with an amber stop codon suggesting that selenium is not incorporated cotranslationally into the protein by an opal suppressor selenocysteyl-tRNA as has been found for several eukaryotic and bacterial proteins. Northern blots using RNA extracted from purified spermatogenic cells and staged prepuberal mice suggest that the mitochondrial capsule seleno-protein mRNA is first transcribed in late meiotic cells and that the levels of the mRNA increase after meiosis in early haploid cells. Southern blots demonstrate that there is one copy of the gene in the mouse genome. The identification of this cDNA clone, in combination with previous work (K. C. Kleene, 1989, Development 106, 367-373) demonstrates that the mRNA for the mitochondrial capsule seleno-protein is translationally repressed with long homogenous poly(A) tracts in round spermatids and translationally active with shortened heterogenous poly(A) tracts in elongating spermatids.

Transcription switch of two phosphoglycerate kinase genes during spermatogenesis as determined with mouse testis sections in situ

In order to elucidate the mechanistic interpretations underlying differential expression of the two phosphoglycerate kinase (PGK) genes during mammalian spermatogenesis, localization of its mRNAs in mouse testis sections was determined by in situ hybridization. MRNA for nonsperm-type PGK-1 was identified in nongerminal Leydig and Sertoli cells, spermatogonia, and spermatocytes, but was not detected in spermatids. In contrast, mRNA for sperm-type PGK-2 was notable in leptotene spermatocytes, becoming most abundant in pachytene spermatocytes. It was amply present in spermatids only up to step 10, completely disappearing after step 12. It is possible to assume that a transcription switch of the two PGK genes ensued following the onset of meiosis. These findings taken together with previous observations indicate that differential expression of the two PGK genes during mammalian spermatogenesis is regulated at the transcriptional and post-transcriptional levels.

Transcriptional regulatory regions of testis-specific PGK2 defined in transgenic mice

The gene encoding testis-specific phosphoglycerate kinase 2 (PGK; ATP:3-phospho-D-glycerate 1-phosphotransferase, EC 2.7.2.3) is expressed only in meiotic and haploid male germ cells. Transgenic mice containing an 8-kilobase human genomic PGK2 gene express the human gene in a tissue-specific and developmentally regulated manner. To determine the nature and location of sequences controlling this expression, transgenic mice with various lengths of the human PGK2 5' region fused to the chloramphenicol acetyltransferase (CAT) gene were analyzed for expression. A 323-base-pair region 5' to the coding region was found to contain information essential for both tissue-specific and developmentally regulated expression of the CAT reporter gene. Transgenic mice containing a PGK2/luciferase-coding construct were compared with mice containing an equivalent CAT construct. Luciferase gene expression was also testis-specific and was more sensitive than CAT gene expression, but otherwise regulation of the two reporter genes was similar in the germ cells of transgenic mice. Translation of both PGK2/CAT and PGK2/luciferase fusion genes was seen concurrently with the first detectable transcripts.

Expression of mouse protamine 1 genes in transgenic mice

Mouse protamine genes are expressed exclusively in spermatids. Mouse protamine 1 (mP1) transcriptional regulatory elements can target the expression of either marked mP1 transgenes or mP1 chimeric genes to spermatids in transgenic mice. Sequences between -40 and -465 bp relative to the transcription start site are required for expression in spermatids, whereas sequences 3' of the point of translation initiation are dispensable. mP1 transcriptional regulatory sequences were used to direct the expression of a toxic gene product to spermatids. The phenotypic consequences of toxin expression in spermatids are described.

Protamine 3'-untranslated sequences regulate temporal translational control and subcellular localization of growth hormone in spermatids of transgenic mice

Although the mouse protamine 1 gene (mP1) is first transcribed in round spermatids, its mRNA is not translated until about 1 week later in elongating spermatids. To determine what mP1 sequences are important for its transcriptional and translational regulation, we have constructed fusions between mP1 and the human growth hormone (hGH) structural gene and analyzed their expression in transgenic mice. We show that mP1 sequences 5' to the start of transcription are sufficient to confer spermatid-specific expression on the hGH gene. We also show that 156 nucleotides of mP1 3'-untranslated sequence is sufficient to confer mP1-like translational regulation on the hGH mRNA. Interestingly, the subcellular localization of hGH was dependent on the time during spermiogenesis that it was made. Synthesis of hGH in early round spermatids resulted in localization in the acrosome, whereas synthesis in late elongating spermatids resulted in intracellular, but not acrosomal, localization.

The protein encoded by a murine male germ cell-specific transcript is a putative ATP-dependent RNA helicase

The murine PL10 cDNA corresponds to a transcript expressed only in the male germ line. Its expression is developmentally regulated, with high levels of transcripts being present during the meiotic and haploid stages of spermatogenesis. The deduced protein is shown to be highly homologous to the murine translation initiation factor eIF-4A and to other proteins that are also homologous to eIF-4A, including the Drosophila protein vasa. By consensus sequence conservation and comparison of secondary structure predictions, putative mononucleotide binding and DNA/RNA binding domains are proposed to be shared by all these proteins. Taken together, these results suggest a helicase function for PL10 protein similar to that of eIF-4A and suggests its possible role in a key step of the spermatogenic process. The possible significance of the similarity between the PL10 protein and the protein product of the maternal effect gene vasa is also discussed.

Intracellular distribution of poly(ADP-ribose) synthetase in rat spermatogenic cells

The highest activity of poly(ADP-ribose) synthetase was found in the testis among several rat tissues tested. Subcellular fractionation of the testis demonstrated that the synthetase was localized primarily in the nucleus and partially in the microsomal-ribosomal fraction. This result was confirmed by immunocytochemical staining with the enzyme-specific antibody. The synthetase was localized in the nuclei of interstitial cells, Sertoli cells, spermatogonia, and spermatocytes. In addition, round spermatids showed a granular staining in the cytoplasm, which was comparable in intensity with that in the nucleus. The cytoplasmic synthetase had a molecular weight of 115,000 and synthesized oligomers of ADP-ribose on itself (automodification). The synthetase activity in the isolated cytoplasmic fraction was stimulated about threefold by the addition of DNA and depressed by treatment with DNase I, suggesting the presence of endogenous activator DNA. A candidate DNA for such an activator was isolated from the microsomal-ribosomal fraction, and identified tentatively as mitochondrial DNA on the basis of its size and restriction fragment patterns.

A candidate gene family for the mouse t complex responder (Tcr) locus responsible for haploid effects on sperm function

The mouse t complex responder (Tcr) locus plays a central haploid-specific role in the transmission ratio distortion phenotype expressed during germ cell differentiation in t-carrying males. The accumulated data map Tcr to a region of less than 500 kb. Over 400 kb of this region has been cloned and consists entirely of sequences associated with a clustered family of large cross-hybridizing elements of 30 kb to 70 kb in size. We have characterized a gene family within this region that is expressed uniquely in male germ cells with a complex pattern of RNA processing. Antibodies produced against a product of the putative open reading frame recognize a testes-specific polypeptide. Genetic data support the hypothesis that this polypeptide(s) functions to effect the Tcr phenotype.

Heart and bone tumors in transgenic mice

Tissue-specific tumorigenesis can be induced in transgenic mice by the directed expression of simian virus 40 (SV40) large tumor (T) antigen. In an attempt to determine the susceptibility of haploid, round spermatids to neoplastic transformation by this oncogene, transgenic mice were generated that harbored a chimeric gene composed of the SV40 T-antigen genes fused to the 5' and 3' flanking sequences of the mouse protamine 1 gene. The transgene was expressed in round spermatids and, surprisingly, in the heart and temporal bone as well. Expression in the heart resulted in rhabdomyosarcomas that always appeared in the right atrium. Bilateral osteosarcomas developed within the petrous portion of the temporal bone. No testicular pathology was observed. T-antigen immunostaining was readily detected in tumor tissue but not in the testis. In addition, SV40 transcripts were processed differently in testis and tumor tissue. Transgenic mouse lines were established that routinely develop these tumors, and they should provide a valuable resource for studies involving cardiac and bone physiology and neoplasia. The atrial tumor cells can be maintained in vitro and some continue to display a cardiac muscle phenotype.

Haploid expression of the rooster protamine mRNA in the postmeiotic stages of spermatogenesis

cDNA clones were prepared from poly(A)+ mRNA isolated from a population enriched in postmeiotic rooster testes spermatogenic cells. A series of clones was sequenced at random and two partial sequences corresponding to the C-terminal coding and 3' untranslated region of the chicken protamine mRNA were obtained. The deduced amino acid sequence of this C-terminal coding region corresponds to the sequence previously described at the protein level for the chicken protamine, galline [Nakano, M., Tobita, T., and Ando, T. (1976), Int. J. Peptide Prot. Res. 8, 565-578]. To study the expression of this protamine gene, RNA was prepared from chicken testes at different stages of development, electrophoresed in formaldehyde-agarose gels, transferred to a nylon membrane, and hybridized with a rooster protamine cDNA probe. Two populations of mRNA of sizes ranging between 420 and 465 bases are expressed in postmeiotic rooster testis cells. To determine if there was a differential expression of the two populations of mRNA in the final postmeiotic haploid stages of spermatogenesis, RNA was purified from adult rooster cells separated at unit gravity according to their differences in size by the Staput technique. The RNA was similarly analyzed by Northern blots. The results indicate that round spermatids are enriched in the 465-nucleotide mRNA species, whereas in the final stage of elongated spermatids the 420-nucleotide species is the only one present, suggesting either post-transcriptional processing, the presence of two different sets of genes that are differentially expressed, or a single set of genes with differential promoter usage.

Changes in polyadenylation of lactate dehydrogenase-X mRNA during spermatogenesis in mice

The expression of the mRNA for mouse testicular lactate dehydrogenase (LDH-X) was examined by RNA:cDNA hybridization in situ in the testis and by Northern analyses of meiotic and postmeiotic spermatogenic cell populations. Silver grains accumulated in cells inside the second layer from the periphery of the seminiferous tubule, confirming previous findings that LDH-X mRNA first appears in the spermatocyte and continues to accumulate until the late spermatid stage. Northern analyses showed that meiotic and postmeiotic cells contained 1.2 and 1.3 kb classes of hybridizing mRNA, respectively. RNase H digestion of oligo (dT)-hybridized RNA and poly(U)-Sepharose column chromatography with differential elution by formamide revealed that the difference in size of the two classes of mRNAs was due to the poly(A) tail length of the LDH-X mRNA. When the distribution of the LDH-X mRNA was examined across polysome gradients, both mRNAs were partially associated with polysomes. These results suggest that the changes in the polyadenylation of LDH-X mRNA were associated with the meiotic division during spermatogenesis in the mouse. They raise the possibility that the stable accumulation of the LDH-X mRNAs in the postmeiotic cells is enhanced by poly(A) tails of increased length.

The testis-specific phosphoglycerate kinase gene pgk-2 is a recruited retroposon

In both humans and mice, two genes encode phosphoglycerate kinase, a key enzyme in the glycolytic pathway. The pgk-1 gene is expressed in all somatic cells, is located on the X chromosome, and contains 10 introns. The pgk-2 gene is expressed only in sperm cells, is located on an autosome, and has no introns. The nucleotide sequence of the pgk-2 gene suggests that it arose from pgk-1 more than 100 million years ago by RNA-mediated gene duplication. The pgk-2 gene may, then, be a transcribed retroposon. Thus, gene duplication by retroposition may have been used as a mechanism for evolutionary diversification.

Differences in DNA methylation during oogenesis and spermatogenesis and their persistence during early embryogenesis in the mouse

We have examined the relative methylation levels of several dispersed repeated and low-copy-number gene sequences during gametogenesis and early embryogenesis. Southern blot analyses revealed that L1, intercisternal A particle (IAP), and major urinary protein (MUP) sequences were undermethylated extensively at MspI sites in DNA from diplotene oocytes. In contrast, the same sequences were highly methylated in DNA from pachytene spermatocytes, round spermatids, and epididymal sperm. These results indicate that there are genome-wide DNA methylation differences between oogenesis and spermatogenesis. Repeated sequences in DNA from cleavage-stage embryos and inner cell masses (ICM) were methylated at intermediate levels, consistent with transient maintenance of gametic methylation levels during early embryogenesis. Gametic differences in DNA methylation observed here indicate that methylation could provide a mechanism for imprinting maternal and paternal genomes resulting in differential regulation of parental genomes during early development.

The testis-specific phosphoglycerate kinase gene pgk-2 is a recruited retroposon

In both humans and mice, two genes encode phosphoglycerate kinase, a key enzyme in the glycolytic pathway. The pgk-1 gene is expressed in all somatic cells, is located on the X chromosome, and contains 10 introns. The pgk-2 gene is expressed only in sperm cells, is located on an autosome, and has no introns. The nucleotide sequence of the pgk-2 gene suggests that it arose from pgk-1 more than 100 million years ago by RNA-mediated gene duplication. The pgk-2 gene may, then, be a transcribed retroposon. Thus, gene duplication by retroposition may have been used as a mechanism for evolutionary diversification.

c-mos proto-oncogene RNA transcripts in mouse tissues: structural features, developmental regulation, and localization in specific cell types

c-mos RNA transcripts have been previously detected in mouse gonadal tissue and in late-term embryos. Here, we show that they are also present at low levels in placenta and in adult mouse brain, kidney, mammary gland, and epididymis. Marked differences are observed in the size of the mos RNA transcripts detected in different tissues. All transcripts appear to end at the same 3' position, and the tissue-specific size variations appear to be due to the use of different promoters. For example, the testicular and ovarian RNA transcripts initiate approximately 280 and approximately 70 base pairs, respectively, upstream from the first initiation codon, but both end at a common site downstream from the mos open reading frame. The expression of mos is developmentally regulated in gonadal tissue. Thus, the level of mos transcripts in testes is low for the first 3 weeks after birth, increases at least 10-fold around day 25, and reaches adult levels by day 30. In contrast, ovaries from preweaning mice contain a higher level of mos mRNA compared to ovaries from adult mice. In cell fractionation experiments we show that mos transcripts are present in haploid germ cells. We find that these transcripts are associated with monosomes and polysomes. The peculiar pattern of mos expression in mouse gonadal tissue suggests a role for the c-mos proto-oncogene in germ cell differentiation.

c-mos proto-oncogene RNA transcripts in mouse tissues: structural features, developmental regulation, and localization in specific cell types

c-mos RNA transcripts have been previously detected in mouse gonadal tissue and in late-term embryos. Here, we show that they are also present at low levels in placenta and in adult mouse brain, kidney, mammary gland, and epididymis. Marked differences are observed in the size of the mos RNA transcripts detected in different tissues. All transcripts appear to end at the same 3' position, and the tissue-specific size variations appear to be due to the use of different promoters. For example, the testicular and ovarian RNA transcripts initiate approximately 280 and approximately 70 base pairs, respectively, upstream from the first initiation codon, but both end at a common site downstream from the mos open reading frame. The expression of mos is developmentally regulated in gonadal tissue. Thus, the level of mos transcripts in testes is low for the first 3 weeks after birth, increases at least 10-fold around day 25, and reaches adult levels by day 30. In contrast, ovaries from preweaning mice contain a higher level of mos mRNA compared to ovaries from adult mice. In cell fractionation experiments we show that mos transcripts are present in haploid germ cells. We find that these transcripts are associated with monosomes and polysomes. The peculiar pattern of mos expression in mouse gonadal tissue suggests a role for the c-mos proto-oncogene in germ cell differentiation.

Human testis-specific PGK gene lacks introns and possesses characteristics of a processed gene

Phosphoglycerate kinase (PGK) (ATP:3-phospho-D-glycerate 1-phosphotransferase, EC 2.7.2.3) is a metabolic enzyme functioning in the Embden-Meyerhof pathway that converts glucose (or fructose) to pyruvate. Two functional loci for the production of PGK have been identified in the mammalian genome. PGK-1 is an X-linked gene expressed constitutively in all somatic cells and premeitotic germ cells. The human PGK-1 gene consists of 11 exons and 10 introns encompassing a region approximately 23 kilobases (kb) in length. PGK-2 is an autosomal gene expressed in a tissue-specific manner exclusively in the late stages of spermatogenesis. In the present study, a molecular analysis of a human genomic clone of PGK-2 originally isolated by Szabo et al. has revealed that this autosomal sequence completely lacks introns and contains characteristics of a processed gene, or 'retroposon', including the remnants of a poly(A)+ tail and bounding direct repeats. Typically such processed sequences form non-functional pseudogenes that have evolved multiple genetic lesions which preclude translation of any transcript into a functional polypeptide. For example, an X-linked processed pseudogene of PGK-1 (psi PGK-1) in humans has been identified and shown to contain premature termination codons in all reading frames. It was therefore unexpected to find that the intronless autosomal PGK sequence reported here is not a pseudogene, but is rather a functional gene that has retained a complete open reading frame, and is actively expressed in mammalian spermatogenesis. Both the unusual conservation of function in this processed PGK-2 gene and its tissue-specific expression in spermatogenesis are best explained as a compensatory response to the inactivation of the X-linked PGK-1 gene in spermatogenic cells before meiosis.

Nucleotide sequence of the promoter region of a tissue-specific human retroposon: comparison with its housekeeping progenitor

The intronless autosomal phosphoglycerate kinase gene (Pgk-2) is a functional retroposon expressed in a tissue-specific manner in the meiotic and postmeiotic stages of mammalian spermatogenesis. The nucleotide sequence of the promoter region of this gene and its transcription start point are compared with those of Pgk-1, an intron-containing, X-linked, housekeeping gene expressed constitutively in all somatic cells and premeiotic germ cells. The location of flanking direct repeats and apparent conservation of specific regulatory sequences suggest the Pgk-2 retroposon arose from reverse transcriptase-mediated processing of an aberrant Pgk-1 transcript that included the endogenous Pgk-1 promoter elements. Specific sequences that may be involved in mediating differences observed in both the level and cell-type specificity of expression of these genes in spermatogenesis are identified.

A postmeiotically expressed clone encodes lactate dehydrogenase isozyme X

We have analysed by the DNA sequencing one of the cDNA clones, pPM459, to mRNA abundant in spermatids of mice. This clone contained 535 base pair nucleotides with a coding region for 139 amino acids and a 3' untranslated region including a single polyadenylation signal. Screening of the protein database revealed that the deduced amino acid sequence highly matched the carboxyl terminal residues 192-330 of mouse lactate dehydrogenase isozyme X (LDH-X). Taken together with our previous report which showed transcription of the message hybridizing to pPM459 after meiosis, it was demonstrated that LDH-X mRNA synthesis continued during the postmeiotic phase in spermatogenesis.

Post-meiotic transcription of phosphoglycerate-kinase 2 in mouse testes

We have used a human phosphoglycerate kinase-1 (PGK-1) cDNA clone to study expression of PGK-2 during mouse spermatogenesis. Hybrid selection, in vitro translation with product identification by 2-D gel electrophoresis demonstrated that the PGK-1 cDNA clone hybridized to PGK-2 mRNA in mouse testes. Northern analyses of RNA purified from separated spermatogenic cells demonstrated a large increase in abundance of PGK-2 mRNA in post-meiotic cells. Thus, post-meiotic transcription of PGK-2 mRNA is demonstrable with cloned DNA probes.

Post-meiotic transcription in mouse testes detected with spermatid cDNA clones

cDNA clones to poly(A)+ mRNA from spermatids have been obtained to study gene transcription in post-meiotic germ cells. Four cDNA clones detect mRNAs that increase in abundance in post-meiotic germ cells. One clone, pPM459, was shown to correspond to an mRNA that is transcribed after meiosis. Pulse-labelling experiments demonstrate transcription o5 the message in spermatids. These data constitute further evidence for post-meiotic gene transcription in spermatids.

Translational regulation and deadenylation of a protamine mRNA during spermiogenesis in the mouse

The distribution of the mRNA for one of the two mouse protamines, the cysteine-rich, tyrosine-containing protamine (MP1), was examined in the polysomal and nonpolysomal compartments of total testis and purified populations of round and elongating spermatids using Northern blots. In postmitochondrial supernatants prepared from total testis, about 10-15% of MP1-mRNA sediments with the small polysomes. The nonpolysomal molecules of MP1-mRNA are homogeneous in size, about 580 bases, while the polysomal molecules are heterogeneous with a mode of about 450 bases. Digestion with RNase H and thermal chromatography on poly(U) Sepharose reveals that the difference in size of polysomal and nonpolysomal MP1-mRNA is due to a shortening of the poly(A) from about 160 to 30 bases. In round spermatids, essentially all of MP1-mRNA is 580 bases long and is in the nonpolysomal fraction. Elongating spermatids contain roughly equal proportions of the homogeneous, 580 base form in the nonpolysomal compartment, and the heterogeneous 450 base form solely in the polysomal compartment. These results indicate that mRNA for one of the mouse protamines is stored as an untranslated RNP in round spermatids, and that it is partially deadenylated when it is translated in elongating spermatids.

Analysis of male sterile mutations in the mouse using haploid stage expressed cDNA probes

A differential hybridization screening procedure has identified cDNAs which correspond to RNAs which are expressed in mouse testis and at lower levels in liver and spleen. The sensitivity of this procedure is such that approximately 0.5% of 1.4 X 10(4) cDNA clones are revealed as "testis specific". We have focused on ten cDNA clones which have been used to identify RNAs expressed in the haploid phase of spermatogenesis. Using Northern blots to analyse RNA isolated from the testes of mutant mice (Tfm/Y and Sxr/+) blocked at specific stages in spermatogenesis or RNA from sexually immature mice, 8 clones have been identified which correspond to RNAs expressed uniquely or at much higher levels in meiotic or post meiotic cells.

Transmission distortion and mosaicism in an unusual transgenic mouse pedigree

We have analyzed the structure, expression, and inheritance of a foreign DNA insert of an unusual transgenic mouse, designated MyK-103. The insert is composed of two copies of pMK (a metallothionein-thymidine kinase fusion gene) oriented as inverted repeats. No methylation of the foreign DNA could be detected. The original transgenic mouse was mosaic; 10% to 20% of both somatic and germ cells contained the plasmid insert. The pMK insert has been stably transmitted by females through five generations; however, expression of thymidine kinase is extremely variable in different members of the pedigree. Although males carrying the pMK insert are fertile, they never transmit the pMK insert. We propose that the foreign DNA has disrupted a gene that must be expressed during haploid stages of spermatogenesis.

cDNA clones encoding cytoplasmic poly(A)+ RNAs which first appear at detectable levels in haploid phases of spermatogenesis in the mouse

We have isolated several cDNA clones encoding cytoplasmic poly(A)+ RNAs which are enriched in postmeiotic (haploid) spermatogenic cells in the mouse. Seventeen of 750 clones from a testis cDNA library hybridized more strongly to 32P-labeled cDNA copied from cytoplasmic poly(A) RNA of round spermatids than pachytene spermatocytes. Northern gel blots demonstrated that these 17 plasmids hybridized to RNA(s) approximately 0.5 kb (1 clone), 0.7 kb (13 clones), 0.8 kb (1 clone), and 0.9 kb (2 clones). Four plasmids hybridizing to RNAs 0.7 and 0.9 kb were further characterized by Northern blots. The levels of hybridization were about 10-fold greater with RNA from round spermatids, elongating spermatids and residual bodies than from pachytene spermatocytes from adult testis. These plasmids did not hybridize with cytoplasmic poly(A)+ RNA from sexually immature testis, adult liver, or brain, larger precursors in adult testis nuclear RNA, total RNA from cultured Sertoli cells, poly(A)- RNA from adult testis or the mouse mitochondrial genome. These results demonstrate that certain poly(A)+ RNAs are abundant in haploid cells but barely or not detectable in meiotic cells suggesting the accumulation of these RNAs in round spermatids requires transcription in haploid cells.