Haploid-specific transcription of protamine-myc and protamine-T-antigen fusion genes in transgenic mice

Protamines and male infertility

Protamines are the major nuclear sperm proteins. The human sperm nucleus contains two types of protamine: protamine 1 (P1) encoded by a single-copy gene and the family of protamine 2 (P2) proteins (P2, P3 and P4), all also encoded by a single gene that is transcribed and translated into a precursor protein. The protamines were discovered more than a century ago, but their function is not yet fully understood. In fact, different hypotheses have been proposed: condensation of the sperm nucleus into a compact hydrodynamic shape, protection of the genetic message delivered by the spermatozoa, involvement in the processes maintaining the integrity and repair of DNA during or after the nucleohistone-nucleoprotamine transition and involvement in the epigenetic imprinting of the spermatozoa. Protamines are also one of the most variable proteins found in nature, with data supporting a positive Darwinian selection. Changes in the expression of P1 and P2 protamines have been found to be associated with infertility in man. Mutations in the protamine genes have also been found in some infertile patients. Transgenic mice defective in the expression of protamines also present several structural defects in the sperm nucleus and have variable degrees of infertility. There is also evidence that altered levels of protamines may result in an increased susceptibility to injury in the spermatozoan DNA causing infertility or poor outcomes in assisted reproduction. The present work reviews the articles published to date on the relationship between protamines and infertility.

Transcription in haploid male germ cells

Major modifications in chromatin organization occur in spermatid nuclei, resulting in a high degree of DNA packaging within the spermatozoon head. However, before arrest of transcription during midspermiogenesis, high levels of mRNA are found in round spermatids. Some transcripts are the product of genes expressed ubiquitously, whereas some are generated from male germ cell-specific gene homologs of somatic cell genes. Others are transcript variants derived from genes with expression regulated in a testis-specific fashion. The haploid genome of spermatids also initiates the transcription of testis-specific genes. Various general transcription factors, distinct promoter elements, and specific transcription factors are involved in transcriptional regulation. After meiosis, spermatids are genetically but not phenotypically different, because of transcript and protein sharing through cytoplasmic bridges connecting spermatids of the same generation. Interestingly, different types of mRNAs accumulate in the sperm cell nucleus, raising the question of their origin and of a possible role after fertilization.

Lessons from knockout and transgenic mice for infertility in men

This review concentrates on the clear cases where knocking out a gene in mice has caused male infertility and thus comes near to proving that the gene plays a role in the development of sperm. Knockout mice have been created with primary defects at every stage of spermatogenesis thus creating a framework for decoding the genetic hierarchy that causes male germ cell differentiation. As well as defining essential genes in vivo experiments have defined promoter and untranslated sequences responsible for the expression of proteins at all the spermatogenic stages. In conclusion knockout mice remain the ultimate test of spermatogenic hypotheses as well as providing detailed information about this complex process.

Round spermatid-specific transcription of the mouse SP-10 gene is mediated by a 294-base pair proximal promoter

Spermiogenesis is the terminal phase of male germ cell differentiation during which haploid spermatids engage in coordinate expression of a number of testis-specific genes, including those specifying acrosomal proteins. To begin to understand the transcriptional regulation during acrosomal biogenesis, we initiated promoter analysis of the gene encoding the acrosomal protein SP-10. SP-10 was previously shown to be transcribed within Golgi-phase round spermatids in the human. The present study characterizes SP-10 gene expression during spermiogenesis in the mouse and identifies regions of the mouse SP-10 (mSP-10) promoter that are capable of driving round spermatid-specific transcription in vivo. Expression of mSP-10 mRNA was initiated in early round spermatids coincident with acrosomal biogenesis and was terminated prior to nuclear elongation. The core promoter of mSP-10 lacked a TATA box but contained a canonical initiator (Inr) element surrounding the transcription start site. Using transgenic mice, we showed that the -408 to +28-base pair (bp) or the -266 to +28-bp mSP-10 5' flanking region is sufficient to direct round spermatid-specific expression of a green fluorescent protein reporter gene. On the other hand, the -91 to +28-bp mSP-10 gene fragment lacked promoter activity in vivo. This is the first functional characterization of a testis-specific gene promoter active in early round spermatids.

Testis-specific TTF-D binds to single-stranded DNA in the c-mos and Odf1 promoters and activates Odf1

We recently identified testis-specific nuclear factor binding sites in the testis-specific promoters of the c-mos gene and the Odf1 gene, which are 80% identical. Here we characterize a testis-specific nuclear factor, TTF-D, which is able to complex with both binding sites and stimulates Odf1 promoter activity. TTF-D is detectable in mouse testis as early as day 11 postpartum and contains three peptides of 22, 25, and 35 kDa in size. Surprisingly, TTF-D binds specifically to its cognate double-stranded DNA binding site as well as to its single-stranded DNA binding site. Both double-stranded and single-stranded binding site oligonucleotide DNA can specifically repress Odf1 promoter activity. Our results suggest that TTF-D is involved in positive transcription regulation of a pre-meiotic and a post-meiotic gene in the testis.

In vivo gene transfer to mouse spermatogenic cells by deoxyribonucleic acid injection into seminiferous tubules and subsequent electroporation

An in vivo gene transfer technique for living mouse testes was used to develop a novel transient expression assay system for transcriptional regulatory elements of spermatogenic specific genes. The combination of DNA injection into seminiferous tubules and subsequent in vivo electroporation resulted in an efficient and convenient assay system for gene expression during spermatogenesis. The transfer of the firefly luciferase reporting gene driven by the Protamine-1 (Prm-1) enhancer region revealed a significant increase in the activity of the reporter enzyme. Histochemical studies of the transfer of the lacZ gene driven by the Prm-1 enhancer showed specific lacZ expression only in haploid spermatid cells in adult testes, corresponding with the expression pattern of endogenous Prm-1. We were able to detect long-lasting transgene expression in the transfected spermatogenic cells. A group of spermatogenic differentiating cells maintained the transfected lacZ expression after more than 2 mo of transfection, suggesting that spermatogenic stem cells and/or spermatogonia could also incorporate foreign DNA and that the transgene could be transmitted to the progenitor cells derived from a transfected proliferating germ cell.

Mouse protamine genes are candidate targets for the novel orphan nuclear receptor, germ cell nuclear factor

Proper expression of the protamine genes is an important event in the terminal differentiation of the male gametes in mammals. Here we present evidence that the novel orphan member of the nuclear receptor gene superfamily, Germ Cell Nuclear Factor (GCNF), may play a role in the regulation of these genes. Previously, we have shown that high-level expression of GCNF mRNA is restricted to spermatids (stages 1-8) in the adult male mouse, which makes it temporally and spatially available to regulate the mouse protamine genes. Furthermore, we have previously identified a sequence to which GCNF can bind, which consists of a direct repeat of the core halfsite AGGTCA with zero base pairs spacing the repeats (DRO). We have identified several genes that contain DRO sequences in their 5' promoter regions, including the protamines. The mouse protamine 1 and 2 (Prm1 and Prm2) genes therefore are potential target genes for GCNF regulation. We show that GCNF binds to one of the two DRO sequences in the Prm1 promoter, and to the DRO sequence in the Prm2 promoter in a specific manner. Furthermore, by using antibodies directed against GCNF, we detect endogenous GCNF in testis nuclear extracts and elutriated round spermatid nuclear extracts in Western blots. Additionally, by using these antibodies in gel-shift assays, we show that this endogenous GCNF can bind to both the Prm1 and Prm2 promoters. This evidence supports the hypothesis that GCNF mediates a novel signaling pathway, two targets of which may be the Prm1 and Prm2 genes in spermatids.

Novel testis-specific protein-DNA interactions activate transcription of the mouse protamine 2 gene during spermatogenesis

The mouse protamines are expressed exclusively in postmeiotic male germ cells and are crucial for the compaction of chromatin during the late stages of spermatogenesis. The temporal expression of the two mouse protamines is transcriptionally regulated in the testis. Recent studies have demonstrated that ubiquitous and testis-specific proteins bind to the promoter of the mouse protamine 2 (mP2) gene. We have performed in vitro transcription and mobility shift assays to characterize the functional significance of the protein-DNA interactions within 180 base pairs upstream of the mP2 transcription start site. Deletion and mutational analyses reveal two positive regulatory sequences for mP2 transcription at positions -59/-47 and -83/-72 of the mP2 promoter. The proximal element at -59/-47 binds to a novel testis-specific protein we name protamine-activating factor 1 (PAF-1). PAF-1 reaches high levels in round spermatids at the time of mP2 transcription. Deletion of the -59/-47 sequence results in about a 3-fold reduction of mP2 transcription in vitro. Although the PAF-1 binding site (PAF-responsive element, PAF-RE), contains the sequence GTCA present in the cAMP-responsive element and is very similar to the estrogen-responsive element, mobility shift assays revealed that neither the cAMP-responsive element modulator nor the estrogen receptor is the protein(s) binding to PAF-RE. Competition mobility shift assays reveal that the second positive regulatory element at -83/-72 binds a Y-box-binding protein. Using in vitro transcription assays, a 5-fold decrease in mP2 transcription is seen when both the PAF-RE and this Y-box are deleted. These data suggest that the testis-specific PAF-1 and a Y-box-binding protein are needed to activate mP2 transcription in postmeiotic male germ cells.

Genomic analysis of the mouse protamine 1, protamine 2, and transition protein 2 gene cluster reveals hypermethylation in expressing cells

To understand the role of chromatin structure in the expression of the mouse protamine 1, protamine 2, and transition protein 2 genes during spermatogenesis, we have examined the genomic organization of this cluster of "haploid-specific" genes. As seen in the human genome, protamine 2, transition protein 2, and approximately 2.8 kb of a CpG island, hereafter called CpG island-dTP2, were clustered in a small region. Methylation analyses of this region have demonstrated that i) unlike most other tissue-specific genes, the protamine 1, protamine 2, and transition protein 2 genes were located in a large methylated domain in round spermatids, the cell type where they are transcribed, ii) the protamine 1 gene was only partially methylated in somatic cells and in testes from 7-day-old mice, and iii) the approximately 2 kb upstream and downstream of the CpG island-dTP2 were only partially methylated in somatic tissues. DNase I analysis revealed the presence of at least five strong DNase I hypersensitive sites over the CpG island-dTP2 in somatic tissues, but not in germ cells, and sequence analysis indicated that the CpG island-dTP2 is homologous to a CpG island located approximately 10.6 kb downstream of the human transition protein 2 gene. Although the nature of a CpG island-dTP2 and the function of a CpG island-dTP2-containing somatic tissue-specific DNase I hypersensitive sites in close proximity to the germ cell-specific gene cluster are unclear, the "open" chromatin structure of the CpG island-dTP2 may be responsible for the partial methylation pattern of the flanking sequences including the transition protein 2 gene in somatic tissues.

Human protamines and male infertility

PURPOSE

Our purpose was to determine the ratio of protamine 1 to protamine 2 in human spermatozoa and relate it to in vitro fertilization rates (IVF) and standard semen parameters.

METHODS

Couples who had been clinically diagnosed as having male-factor infertility and had undergone IVF treatment were grouped according to IVF rates and pregnancy outcome. Protamines were extracted and separated on acid urea polyacrylamide gels. The P1/P2 ratio correlation with semen parameters and IVF rates was investigated using nonparametric analysis.

RESULTS

The P1/P2 ratio ranged from 0.55 to 1.29 in the control group of patients, who had fertilization rates > or = 50% and had achieved a pregnancy in one IVF cycle. Of the test patients with IVF < 50%, three (14%) had P1/P2 ratios outside the range exhibited by the control group and their sperm possessed large heads.

CONCLUSIONS

P1/P2 ratios were statistically negatively correlated with IVF rates in the control group and with progressive motile sperm concentration in the test group. We do not think that altered P1/P2 ratios are the primary cause of reduced fertilization.

A cell- and developmental stage-specific promoter drives the expression of a truncated c-kit protein during mouse spermatid elongation

In the postnatal testis, the c-kit transmembrane tyrosine-kinase receptor is expressed in type A spermatogonia, and its transcription ceases at the meiotic phase of spermatogenesis. Alternative, shorter c-kit transcripts are expressed in post-meiotic germ cells. These transcripts should encode a truncated version of the c-kit protein, lacking the extracellular, the transmembrane and part of the intracellular tyrosine-kinase domains. The 5′ end of the alternative c-kit transcripts maps within an intron of the mouse c-kit gene. We now show that this intron contains a promoter active in nuclear extracts of round spermatids, and that two discrete sequences upstream of the transcriptional start site bind spermatid-specific nuclear factors. Deletion of both these sequences abolishes activity of the promoter in vitro. We have also established that this promoter is functional in vivo, in a tissue-and cell-specific fashion, since intronic sequences drive the expression of the E. coli lacZ reporter gene in transgenic mice specifically in the testis. Transgene expression is confined to haploid germ cells of seminiferous tubules, starting from spermatids at step 9, and disappearing at step 13, indicating that cryptic promoter within the 16th intron of the mouse c-kit gene is active in a short temporal window at the end of the transcriptional phase of spermiogenesis. In agreement with these data, western blot experiments using an antibody directed against the carboxy-terminal portion of the mouse c-kit protein showed that a polypeptide, of the size predicted by the open reading frame of the spermatid-specific c-kit cDNA, accumulates in the latest stages of spermatogenesis and in epididymal spermatozoa. An immunoreactive protein of the same size can be produced in both eukaryotic and prokaryotic artificial expression systems.

Expression of the rat testis-specific histone H1t gene in transgenic mice. One kilobase of 5'-flanking sequence mediates correct expression of a lacZ fusion gene

H1t is synthesized in mid to late pachytene spermatocytes of the male germ line and is the only tissue-specific member of the mammalian H1 histone family. As a step toward identifying DNA sequences that confer its tissue-specific expression, we have produced transgenic mice containing the intact rat H1t gene as well as a H1t-lacZ fusion gene. Transgenic mice carrying a 6.8-kilobase fragment of rat genomic DNA encompassing the H1t gene expressed rat H1t at high levels in the testis and in no other organ examined. H1t fragments truncated to within 141 base pairs (bp) of the gene in the 5' direction or within 837 bp in the 3' direction retained testis specificity. Expression of rat H1t protein was also evident in the testes of the transgenic mice, and in some lines the level of rat H1t exceeded that of the mouse protein. The stage of spermatogenesis of transgene expression was assessed by following appearance of transgenic mRNA in developing mice and by immunohistochemistry using an antiserum to rat H1t. In lines from three different constructs, expression was restricted to germinal cells, although in two strongly expressing lines the transgenes were expressed somewhat prematurely in preleptotene spermatocytes. An H1t(-948/+71)-lacZ fusion was also expressed specifically in the spermatocytes and round spermatids of a transgenic line, confirming that sequences sufficient for correct tissue and developmental expression lie within this 1,019-bp segment of the gene.

Boar proacrosin expressed in spermatids of transgenic mice does not reach the acrosome and disrupts spermatogenesis

Transgenic mice that express boar proacrosin were produced to examine mechanisms for targeting hydrolytic enzymes to the acrosome. A 2.3 kb transgene was constructed by ligating the cDNA for boar preproacrosin with the mouse protamine 2 promoter region. Six founder mice that incorporated the transgene were identified by polymerase chain reaction and Southern blot analysis. Northern blots indicated that the two male founders (Ac.2 and Ac.5) and male progeny from three female founders (Ac.3, Ac.4, Ac.6) expressed the transgene mRNA in testis, but not in somatic tissues. In these transgenic animals boar proacrosin was detected by immunohistochemistry in condensing spermatids, but was not localized in the acrosome. This acrosomal targeting defect of the transgene product may result from its delayed expression during the later steps of haploid differentiation. Furthermore, both male founders and all Ac.4 and Ac.6 males were infertile, as determined by multiple matings for at least 2 months. Ac.3 males were either infertile or rarely transmitted the transgene to their offspring. The infertile males mated, produced copulatory plugs, and had seminal vesicle weights and testosterone levels within the normal range. However, they produced significantly fewer spermatozoa and had lower testis weights than controls. Although the mitotic and meiotic phases of spermatogenesis appeared normal by histological criteria, condensing spermatids were missing from most tubules, and multinucleated cells were present in the lumen of seminiferous tubules and in the epididymis. We hypothesize that boar proacrosin which fails to reach the acrosome is activated in these transgenic mice, and that its proteolytic activity disrupts spermatogenesis during spermatid formation.

A 252 bp upstream region of the rat spermatocyte-specific hst70 gene is sufficient to promote expression of the hst70-CAT hybrid gene in testis and brain of transgenic mice

The rat hst70 gene belongs to a heat shock hsp70 multigene family and its expression has been detected so far solely in spermatocytes. To investigate the cis-elements responsible for testis-specific expression of the hst70 gene we produced several lines of transgenic mice carrying fragments of the 5'-flanking regions of the hst70 gene fused to the chloramphenicol acetyltransferase (CAT) reporter gene. Hybrid genes of series B were constructed such that, besides the 780 bp, 343 bp and 163 bp 5'-flanking region these plasmids contained no other sequences of the hst70 gene. In hybrid genes of series D the CAT gene was ligated to 343 bp and 252 bp 5'-flanking regions together with the 57 bp of the 5'-end nontranslated (leader) sequences of the hst70 gene. We found that in 780/B, 343/B, 343/D and 252/D adult mice the transgene was specifically and highly expressed in testes. In developing testes the high CAT activity appeared in transgenic mice aged 3 weeks and older. None of the three 163/B transgenic lines exhibited CAT activity in any tissue analyzed. In all CAT expressing lines a weak but significant CAT activity (up to 5% of that in testis) was detected also in the brain. RNase protection assay confirmed that the endogenous hst70 gene transcripts are present in testis as well as in brain of nontransgenic rats and mice. Our data show that the cis-regulatory sequences responsible for testis-specific and developmentally regulated expression of the hst70 gene are localized within the 252 bp region 5' to the gene and neither the 5'-end nor 3'-end nontranslated sequences of the gene are important for this specificity.

A haploid expressed gene cluster exists as a single chromatin domain in human sperm

Mammalian spermiogenesis is marked by the initial disruption of the nuclear-histone-DNA complex by the transition proteins for ultimate replacement with protamines. The genes for three of these low molecular weight basic nuclear proteins exist as a single linear array of PRM1, PRM2, and TNP2 on human chromosome 16p13.2. To begin to address the mechanism governing their transcriptional potentiation, a region of approximately 40 kilo-bases of the human genome encompassing these genes was introduced into the germ line of mice. Fluorescence in situ hybridization and Southern analysis showed that this segment of the human genome integrated into independent chromosomal sites while maintaining its fidelity. Transcript analysis demonstrated that the expression of the endogenous mouse protamine Prm1 and Prm2 genes as well as the mouse transition protein Tnp2 gene were expressed along with their human transgene counterparts. The pattern of expression of these transgenic human genes within this multigenic cluster faithfully represented that observed in vivo. In addition, all members of this transgenic gene cluster were expressed in proportions similar to those in human testis. Copy number-dependent and position-independent expression of the transgenic construct demonstrated that the corresponding biological locus was contained within this segment of the human genome. Furthermore, DNase I sensitivity established that in sperm the human PRM1-->PRM2-->TNP2 genic domain was contained as an approximately 28.5-kilobase contiguous segment bounded by an array of nuclear matrix associated topoisomerase II consensus sites. This is the first description of a multigenic male gamete-specific domain as a fundamental gene regulatory unit. A model of haploid-specific gene determination is presented.

Computer assisted promoter analysis of a human sperm specific nucleoprotein gene cluster

The promoter regions of the clustered human spermatid-specific nucleoprotein PRM1, PRM2 arid TNP2 genes were compared to define regulatory elements that may govern their expression. Sequence alignment revealed two wll conserved motifs, despite a lack of extensive homology. They are located at similar positions within the first 400 nt of their 5' UTRs. Conservation of these motifs may reflect selective evolutionary pressure to maintain their structure. This supports the view that these elements assume a central role in the coordinate regulation of this gene cluster during spermiogenesis. The distribution of binding sites of known transcription factors was also assessed within the regions flanking the 5' ends of these genes. This analysis should prove useful in directing studies that define the signals necessary for the coordinate regulation of this spermatid specific gene cluster.

The nuclear status of human sperm cells

In the last decade, and in particular since the development of in vitro fertilization techniques, the nuclear status of human sperm cells has shown to be a key parameter in the assessment of male fertility. The shape and condensed state of the mature sperm nucleus are determined by structural and functional events that occur during spermiogenesis. This paper reviews essential findings on re-organization of the nucleus during sperm differentiation and maturation, and reports recent data on the architecture, biochemical composition and stability of the nucleus in human ejaculated spermatozoa. Different methods used to evaluate nuclear maturity in relation to male fertility are critically appraised.

Growth factors and testicular development

During the last 5 years significant advances have been achieved in defining the endocrine, paracrine and cellular interactions required for normal testicular development. Numerous paracrine factors are likely to regulate spermatogenesis throughout the cycle of the seminiferous epithelium. These factors create the local hormonal milieu required for germ cell proliferation, meiosis and differentiation. The studies of the c-kit oncogene and the stem cell growth factor in the migration and survival of the primordial germ cells to the genital ridge during development have defined at least 1 important role of growth factors in spermatogenesis. 72, 142-146, 148, 149, 154, 159 It is likely that in the next 5 years the role of many of these other paracrine factors in the regulation of testicular development will be determined.

An upstream region of the rat spermatogenesis-specific heat-shock-like Hst70 gene confers testis-specific expression in transgenic mice

In order to study the temporal and spatial regulation of a rat testis-specific heat-shock-like hst70 gene, an 0.8-kb fragment of its upstream DNA was fused to the lacZ gene and microinjected into one-cell murine embryos. Independent tgHST1 and tgHST2 transgenic mice strains were established, containing about 5-7 and 40-60 transgene copies/haploid genome, respectively. Enzyme assays in various tissues showed that transgene-encoded beta-galactosidase accumulates exclusively in testes of transgenic animals and cannot be detected until 16-17 days after birth. In-situ assays revealed that the enzyme accumulates mainly in pachytene primary spermatocytes. Our data complement previous studies on the endogenous rat hst70 and suggest that its 0.8-kb upstream region contains sufficient information to function as an active spermatogenesis-specific promoter.

Human male infertility may be due to a decrease of the protamine P2 content in sperm chromatin

Basic chromosomal proteins were extracted from the sperm of fertile and infertile human males. The relative proportions of protamine 1, 2, and 3 were determined by scanning microdensitometry following electrophoresis of total protamine in polyacrylamide gels. The findings were as follows: (1) The proportion of protamine P(2 + 3) in sperm obtained from infertile males was lower than that in fertile males. (2) Protamine P(2 + 3) in infertile human males showed reduced affinity to DNA. The possibility that some cases of human male infertility may be due to mutation within the protamine P2 gene is discussed.

Functional and molecular characterization of the transcriptional regulatory region of Tcp-10bt, a testes-expressed gene from the t complex responder locus

Mouse t haplotypes contain several mutant alleles that disrupt spermatogenesis. Their phenotypes include sterility, reduced fertility and transmission ratio distortion (TRD). The substantial genetic analyses of these mutant alleles, coupled with intensive physical characterization of the t complex, provides a fertile ground for identifying and understanding genes essential to male gametogenesis. The t complex responder (Tcr) locus plays a central role in this process, interacting with other t haplotype-encoded genes to mediate TRD. A candidate responder gene, Tcp-10bt, has been cloned and subjected to molecular characterization. Here, we define the transcriptional regulatory regions of this gene in transgenic mice. A 1.6 kb (but not 0.6 kb) DNA fragment upstream of the transcription start site contains all the regulatory signals for appropriate temporal and germ cell-specific expression of this gene. Two smaller fragments within this region bound specifically to nuclear factor(s) from germ cell protein extracts in gel shift assays. This work is a step towards understanding the mechanism of Tcp-10bt regulated expression and may ultimately help reveal a common regulatory pathway shared by other similarly expressed spermatogenic genes.

Processing of the precursor of protamine P2 in mouse. Identification of intermediates by their insolubility in the presence of sodium dodecyl sulfate

Two basic proteins, protamines P1 and P2, are present in chromatin of mouse spermatozoa. Protamine P1, the less abundant protein in mouse, has a homolog in most mammals, and its synthesis follows a conventional route. In contrast, protamine P2 has been found only in certain other mammals, including humans, and it is synthesized as a precursor nearly twice as long as the mature protein. Processing of this precursor is not yet understood, although it necessarily takes place in elongating spermatids and is likely to play a role in the chromatin condensation occurring in these haploid cells. We have fractionated basic proteins from mouse testis chromatin and have identified six proteins on electrophoretic gels which, like protamines, are insoluble in SDS. All six were also soluble at the same trichloroacetic acid concentration as protamine P2 and were present in chromatin of elongating spermatids. Radioactive labelling patterns acquired by these SDS-insoluble proteins during translation in vitro of testis RNA indicate that the largest represents the precursor of protamine P2, and suggest that the others represent intermediates generated by proteolytic cleavage of the precursor. Results from pulse 3H labelling in vivo were also consistent with the conclusion that a precursor/product relationship exists between these proteins and protamine P2. Conclusions concerning the kinetics of processing have, in addition, been drawn from this data. Hypotheses concerning possible functional roles played by the precursor are presented.

A new rat gene RT7 is specifically expressed during spermatogenesis

We report the isolation of a new rat male germ cell-specific gene, RT7, by differential cDNA cloning procedures. The RT7 cDNA nucleotide sequence is not homologous to any sequences present in the GenBank library. RT7 RNA is expressed at very high levels in rat early spermatids, while its expression is not detectable in any other organ or tissue examined. Mapping of the RT7 transcription start site by two independent procedures demonstrated that RT7 has two major and a number of upstream minor start sites for transcription. RT7 encodes a putative 90-amino acid protein, of which the N-terminus is predicted to fold as an amphipathic alpha helix with features resembling the leucine zipper structure found in a family of transcription factors. However, unlike the leucine zipper proteins the RT7 alpha helix is not preceded by a basic region. Analysis of the RT7 promoter sequence indicates that it contains a putative testis-specific regulatory sequence found in protamine P1 and P2 promoters, as well as binding sites for several other transcription factors.

Selective activation of testis-specific genes in cultured rat spermatogenic cells

During mammalian spermatogenesis the isozyme pattern of a glycolytic enzyme, phosphoglycerate kinase (PGK; ATP: 3-phospho-D-glycerate 1-phosphotransferase, EC 2.7.2.3), changes from the somatic-type PGK-1 to the testis-specific PGK-2, and this change has been suggested to involve transcription switch. We have isolated genomic DNA fragments which code for the mouse PGK isozymes and determined the transcription start site of each gene. The results demonstrate that transcriptions of the two PGK genes are initiated at multiple sites under the control of TATA box-lacking promoters. The putative promoter regions of the two genes contain several distinct sequences known as the CCAAT box and the GC box which possibly bind CCAAT-binding proteins and Sp1, respectively. We next developed a culture system in which spermatogenic gene expression is partly reproduced. When spermatogenic cells of 20-day-old rats were cultured, transcripts from PGK-2 and another spermatogenic gene PRPS3 became detectable, while expression of other non-spermatogenic genes did not significantly change during culture. These results suggest that two spermatogenic genes PGK-2 and PRPS3 were activated in culture according to a developmental program of spermatogenesis. Thus, this culture system may be useful for studying the molecular mechanism underlying mammalian spermatogenic gene expression.

Metal-inducible pathology in the liver, pancreas, and kidney of transgenic mice expressing SV40 early region genes

Transgenic mice (SV-202) that carry the SV40 early region genes under the control of an inverted metallothionein promoter developed islet cell adenomas, hepatocellular carcinomas, and a generalized peripheral neuropathy. Both the islet cell adenomas and the hepatocellular carcinomas developed from the proliferation of T antigen-positive cells. However, T antigen expression was not seen in either the peripheral or central nervous systems. Stimulation of the metallothionein promoter with heavy metals altered the temporal onset of hepatic expression and broadened the distribution of oncogene expression to include exocrine pancreas and renal tubular epithelium. Although solid tumors were not seen in the exocrine pancreas or kidneys of SV-202 mice, all immunopositive tissues developed histologic changes. These results indicate that metallothionein-directed T antigen expression can induce abnormal cellular growth in a variety of tissues, and the distribution of these tissues can be manipulated with heavy metals.

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.

Mouse transition protein 1 is translationally regulated during the postmeiotic stages of spermatogenesis

Transition protein 1 (TP1) is a small basic nuclear protein that functions in chromatin condensation during spermatogenesis in mammals. Here, recently identified cDNA clones encoding mouse transition protein 1(mTP1) were used to characterize the expression of the mTP1 mRNA during spermatogenesis. Southern blot analysis demonstrates that there is a single copy of the gene for transition protein 1 in the mouse genome. Northern blot analysis demonstrates that mTP1 mRNA is a polyadenylated mRNA approximately 600 bases long, which is first detected at the round spermatid stage of spermatogenesis. mTP1 mRNA is not detectable in poly(A)+ RNAs isolated from mouse brain, kidney, liver, or thigh muscle. mTP1 mRNA is translationally regulated in that it is first detected in round spermatids, but no protein product is detectable until approximately 3 days later in elongating spermatids. In total cellular RNA isolated from stages in which mTP1 is synthesized, the mTP1 mRNA is present as a heterogeneous class of mRNAs that vary in size from about 480 to 600 bases. The shortened, heterogeneous mTP1 mRNAs are found in the polysome region of sucrose gradients, while the longer, more homogeneous mTP1 mRNAs are present in the postmonosomal fractions.