An SNP in protamine 1: a possible genetic cause of male infertility?

Gene targeting of the sperm nuclear proteins, the protamines, in mice leads to haploinsufficiency, abnormal chromatin compaction, sperm DNA damage, and male infertility. In order to investigate whether changes in amount or structure of the protamines could be a cause of human infertility, we sequenced the protamine genes of infertile men whose sperm appeared phenotypically similar to those of protamine deficient mice. We identified a heterozygous single nucleotide polymorphism (SNP) in the protamine (PRM1) gene in three infertile men (10% of the total infertile men analysed). This SNP disrupts one of the highly conserved arginine clusters needed for normal DNA binding. To rapidly screen for this SNP in infertile patients, we developed a simple PCR restriction fragment length polymorphism assay. This is the first report of a SNP in the PRM1 gene that appears associated with human male infertility.

Disruption of germ cell-Sertoli cell interactions leads to spermatogenic defects

In the aging human testis, partially regressed tubules contain Sertoli cells with an altered appearance and reduced numbers of germ cells. Investigating the effects of aging on Sertoli cell-germ cell interactions from Brown Norway rats, we have found that a selective breakdown in germ cell-Sertoli interactions could lead to severe reductions in male fertility. Previous studies have identified two specific inducible germ cell markers (a von Ebner's-like protein and the Huntington disease protein) and two specific inducible Sertoli cell markers (a sertonin receptor and a novel gene) that are expressed in Sertoli cell-germ cell cocultures and in vivo [Endocrinology 140 (1999a) 5754; J. Biol. Chem. 27 (1999b) 10737]. We find that germ cells from aged regressed testes are unable to respond to selective signals from Sertoli cells, although germ cells from aged normal sized testes respond well. Similarly, Sertoli cells from aged regressed testes fail to respond to certain signals from young germ cells. We propose that selective disruptions in communication between Sertoli cells and germ cells contribute to germ cell loss during aging.

Altering the GTP binding site of the DNA/RNA-binding protein, Translin/TB-RBP, decreases RNA binding and may create a dominant negative phenotype

The DNA/RNA-binding protein, Translin/Testis Brain RNA-binding protein (Translin/TB-RBP), contains a putative GTP binding site in its C-terminus which is highly conserved. To determine if guanine nucleotide binding to this site functionally alters nucleic acid binding, electrophoretic mobility shift assays were performed with RNA and DNA binding probes. GTP, but not GDP, reduces RNA binding by approximately 50% and the poorly hydrolyzed GTP analog, GTPgammaS, reduces binding by >90% in gel shift and immunoprecipitation assays. No similar reduction of DNA binding is seen. When the putative GTP binding site of TB-RBP, amino acid sequence VTAGD, is altered to VTNSD by site directed mutagenesis, GTP will no longer bind to TB-RBP(GTP) and TB-RBP(GTP) no longer binds to RNA, although DNA binding is not affected. Yeast two-hybrid assays reveal that like wild-type TB-RBP, TB-RBP(GTP) will interact with itself, with wild-type TB-RBP and with Translin associated factor X (Trax). Transfection of TB-RBP(GTP) into NIH 3T3 cells leads to a marked increase in cell death suggesting a dominant negative function for TB-RBP(GTP) in cells. These data suggest TB-RBP is an RNA-binding protein whose activity is allosterically controlled by nucleotide binding.

Mouse testis-brain RNA-binding protein (TB-RBP): expression, purification and crystal X-ray diffraction

TB-RBP (testis-brain RNA-binding protein) is a mouse RNA-binding protein that controls the temporal and spatial expression of mRNA. Found most abundantly in brain and male germ cells in the testis, TB-RBP is known to suppress the translation of specific testicular and brain mRNAs as part of cell development. TB-RBP-mRNA complexes can bind microtubules and thereby facilitate RNA translocation. Translin is the human orthologue of TB-RBP which binds to single-stranded ends of DNA sequences in breakpoint regions of chromosomal translocations. TB-RBP/translin has been crystallized in space group P2(1)2(1)2. The expression, purification, and crystallization of TB-RBP are described as well as preliminary X-ray diffraction data. The multimeric state of TB-RBP is addressed using dynamic light-scattering results.

Expression of MSY2 in mouse oocytes and preimplantation embryos

Translational control plays a central role during oocyte maturation and early embryogenesis, as these processes occur in the absence of transcription. MSY2, a member of a multifunctional Y-box protein family, is implicated in repressing the translation of paternal mRNAs. Here, we characterize MSY2 expression in mouse oocytes and preimplantation embryos. Northern blot analysis indicates that MSY2 expression is highly restricted and essentially confined to the oocyte in the female mouse. MSY2 transcript and protein, as assessed by reverse transcription-polymerase chain reaction and immunoblotting, respectively, are expressed in growing oocytes, metaphase II-arrested eggs, and 1-cell embryos, but then are degraded by the late 2-cell stage; no expression is detectable in the blastocysts. During oocyte maturation, MSY2 is phosphorylated and following fertilization it is dephosphorylated. Quantification of the mass amount of MSY2 reveals that it represents 2% of the total protein in the fully grown oocyte, i.e., it is a very abundant protein. Both endogenous MSY2 and MSY2-enhanced green fluorescent protein (EGFP), which is synthesized following microinjection of an mRNA encoding MSY2-EGFP, are primarily localized in the cytoplasm, and about 75% of the MSY2 remains associated with oocyte cytoskeletal preparations. Results of these studies are consistent with the proposal that MSY2 functions by stabilizing and/or repressing the translation of maternal mRNAs.

Haploinsufficiency of protamine-1 or -2 causes infertility in mice

Protamines are the major DNA-binding proteins in the nucleus of sperm in most vertebrates and package the DNA in a volume less than 5% of a somatic cell nucleus. Many mammals have one protamine, but a few species, including humans and mice, have two. Here we use gene targeting to determine if the second protamine provides redundancy to an essential process, or if both protamines are necessary. We disrupted the coding sequence of one allele of either Prm1 or Prm2 in embryonic stem (ES) cells derived from 129-strain mice, and injected them into blastocysts from C57BL/6-strain mice. Male chimeras produced 129-genotype sperm with disrupted Prm1 or Prm2 alleles, but failed to sire offspring carrying the 129 genome. We also found that a decrease in the amount of either protamine disrupts nuclear formation, processing of protamine-2 and normal sperm function. Our studies show that both protamines are essential and that haploinsufficiency caused by a mutation in one allele of Prm1 or Prm2 prevents genetic transmission of both mutant and wild-type alleles.

Trax (translin-associated factor X), a primarily cytoplasmic protein, inhibits the binding of TB-RBP (translin) to RNA

Trax (Translin-associated factor X) has been shown to interact with TB-RBP/Translin by its coimmunoprecipitation and in yeast two-hybrid assays. Here we demonstrate that Trax is widely expressed, does not bind to DNA or RNA, but forms heterodimers with TB-RBP under reducing conditions. The heterodimer of TB-RBP and Trax inhibits TB-RBP binding to RNA, but enhances TB-RBP binding to specific single stranded DNA sequences. The in vitro interactions between TB-RBP and Trax are confirmed by similar interactions in the yeast two-hybrid system. Cell fractionation and confocal microscope studies reveal that Trax is predominantly cytoplasmic. In contrast, TB-RBP is present in both the nuclei and cytoplasm of transfected cells and uses a highly conserved nuclear export signal to exit nuclei. In addition to a leucine zipper, two basic domains in TB-RBP are essential for RNA binding, but only one of these domains is needed for DNA binding. Trax restores DNA binding to TB-RBP containing an altered form of this domain. These data suggest that Trax-TB.RBP interactions modulate the DNA- and RNA-binding activity of TB-RBP.

Elevated levels of the polyadenylation factor CstF 64 enhance formation of the 1kB Testis brain RNA-binding protein (TB-RBP) mRNA in male germ cells

The single copy mouse Testis Brain RNA-Binding Protein (TB-RBP) gene encodes three mRNAs of 3.0, 1.7, and 1.0 kb which only differ in their 3' UTRs. The 1 kb TB-RBP mRNA predominates in testis, while somatic cells preferentially express the 3.0 kb TB-RBP mRNA. Here we show that the 1 kb mRNA is translated several-fold more efficiently than the 3 kb TB-RBP in rabbit reticulocyte lysates and cells with elevated levels of the 1 kB TB-RBP mRNA express high levels of TB-RBP. To determine if the cleavage stimulatory factor CstF 64 can modulate the alternative splicing of the TB-RBP pre-mRNA and therefore TB-RBP expression, CstF 64 levels and binding to alternative polyadenylation sites were examined. CstF 64 is abundant in the testis and preferentially binds to a distal site in the TB-RBP pre-mRNA that produces the 3 kb TB-RBP. Moreover, upregulation or overexpression of CstF 64 increases the poly(A) site selection for the 1 kb TB-RBP mRNA. We propose that the level of the polyadenylation factor CstF 64 modulates the level of TB-RBP synthesis in male germ cells by an alternative processing of the TB-RBP pre-mRNA.

Selective loss of Sertoli cell and germ cell function leads to a disruption in sertoli cell-germ cell communication during aging in the Brown Norway rat

We investigated the effects of aging on Sertoli cell-germ cell interactions from Brown Norway rats using the induction of four specific mRNAs as markers. The testes from aging (24 mo old) Brown Norway rats can be normal size or regressed. One marker, a von Ebner's-like protein, is expressed in coculture and "in vivo" in germ cells from normal testes of 6- and 24-mo-old rats but not in germ cells from regressed testes of 24-mo-old rats. A second germ cell marker, the Huntington disease protein, is expressed in all germ cells. Two Sertoli cell markers, a serotonin receptor and a novel gene, are induced in Sertoli cells by meiotic germ cells. The serotonin receptor mRNA is expressed in Sertoli cells from 20-day, 6-mo, and 24-mo normal testes but not in those from 24-mo regressed testes. The novel gene is induced in Sertoli cells from all testes. We conclude that Sertoli cells from aged regressed testes are unable to respond to selective signals from germ cells from young rats, and germ cells from regressed testes show a similar selective loss. Such disruptions in communication between Sertoli cells and germ cells likely contribute to germ cell loss during aging.

Identification of meiotic and postmeiotic gene expression in testicular tissue of patients histologically classified as Sertoli cell only

OBJECTIVE

To determine whether meiotic and postmeiotic germ cell gene products could be detected in biopsy specimen from patients with Sertoli cell only (SCO) and maturation arrest.

DESIGN

Prospective clinical study.

SETTING

University-based departments and laboratories.

PATIENT(S)

Nine patients, seven with nonobstructive azoospermia (12 biopsies) and two with obstructive azoospermia (controls) (2 biopsies).

INTERVENTION(S)

Specimens were divided into three parts: IVF laboratory, histology, and molecular analysis. Germ cell-specific messenger RNAs (mRNAs) were detected by extracting total RNA for Northern blotting or reverse transcription-polymerase chain reaction.

MAIN OUTCOME MEASURE(S)

Detection of meiotic (lactate dehydrogenase C4) and postmeiotic (transition protein 1 and protamine 1 and 2) gene expression and correlation with histologic and IVF laboratory findings.

RESULT(S)

The IVF laboratory identified spermatozoa in 3 of 14 biopsies (controls and severe hypospermatogenesis). Histologically, 6 of 14 biopsies (43%) were diagnosed as SCO, 4 (29%) maturation arrest, 2 (14%) severe hypospermatogenesis, and 2 normal. Molecular analysis showed mRNA for meiotic and postmeiotic genes in 12 of 14 biopsies (86%) (P =. 006), of which 4 (67%) in SCO and 3 (75%) in maturation arrest.

CONCLUSION(S)

Differentiated germ cells are present in biopsies of men histologically diagnosed as SCO. Absence of these molecular markers strengthens the histologic diagnosis and helps the physician in counseling the infertile couple.

Intracellular and intercellular transport of many germ cell mRNAs is mediated by the DNA- and RNA-binding protein, testis-brain-RNA-binding protein (TB-RBP)

Functions ranging from RNA transport and translational regulation to DNA rearrangement and repair have been proposed for the DNA- and RNA-binding protein, testis-brain-RNA-binding protein (TB-RBP). TB-RBP is primarily in the nuclei of male germ cells during meiosis and in the cytoplasm of male cells after metaphase I of meiosis. Based on its shift in subcellular locations as germ cells differentiate and its binding to microtubules and microfilaments, a model is presented proposing an involvement of TB-RBP in mRNA transport from nucleus to cytoplasm and in the sharing of mRNAs transcribed from the sex chromosomes by movement through intercellular bridges of germ cells.

Mouse testis brain ribonucleic acid-binding protein/translin colocalizes with microtubules and is immunoprecipitated with messenger ribonucleic acids encoding myelin basic protein, alpha calmodulin kinase II, and protamines 1 and 2

Testis brain RNA-binding protein (TB-RBP) is a sequence-dependent RNA-binding protein that binds to conserved Y and H sequence elements present in many brain and testis mRNAs. Using recombinant TB-RBP and a highly enriched tubulin fraction, we demonstrate here that recombinant TB-RBP binds to microtubules assembled in vitro. The interaction between recombinant TB-RBP and microtubules was inhibited by high salt and by the microtubule disassembling agents colcemid and calcium, but not by the microfilament-disassembling agent cytochalasin D. Confocal microscopy confirmed colocalization of TB-RBP and tubulin in the cytoplasm of male germ cells. An affinity-purified antibody prepared against recombinant TB-RBP specifically precipitated mRNAs encoding myelin basic protein and alpha calmodulin-dependent kinase II-two transported mRNAs, and protamines 1 and 2-two translationally regulated testicular mRNAs. These data indicate an intracellular association between TB-RBP and specific target mRNAs and suggest an involvement of TB-RBP in microtubule-dependent mRNA transport in the cytoplasm of cells.

Sperm antigen 6 is the murine homologue of the Chlamydomonas reinhardtii central apparatus protein encoded by the PF16 locus

A cDNA encoding sperm antigen 6 (Spag6), the murine homologue of the Chlamydomonas reinhardtii PF16 protein-a component of the flagella central apparatus-was isolated from a mouse testis cDNA library. The cDNA sequence predicted a 55.3-kDa polypeptide containing 8 contiguous armadillo repeats with 65% amino acid sequence identity and 81% similarity to the Chlamydomonas PF1 protein. An antipeptide antibody generated against a C-terminal sequence recognized a 55-kDa protein in sperm extracts and localized Spag6 to the principal piece of permeabilized mouse sperm tails. When expressed in COS-1 cells, Spag6 colocalized with microtubules. The Spag6 gene was found to be highly expressed in testis and was mapped using the T31 radiation hybrid panel to mouse chromosome 16. Mutations in the Chlamydomonas PF16 gene cause flagellar paralysis. The presence of a highly conserved mammalian PF16 homologue (Spag6) raises the possibility that Spag6 plays an important role in sperm flagellar function.

Messenger ribonucleic acids encoding a serotonin receptor and a novel gene are induced in Sertoli cells by a secreted factor(s) from male rat meiotic germ cells

Using Sertoli cell-germ cell cocultures and messenger RNA (mRNA) differential display, we have identified a complementary DNA of 355 nucleotides that is up-regulated in Sertoli cells by pachytene spermatocytes. The mRNA differential display pattern was confirmed by Northern blotting. Sequence analysis revealed a homology of 91% (nt) and 86% (aa) to a serotonin receptor. The mRNA encoding the serotonin receptor was detected in Sertoli cells after 18 h of coculture. Its induction did not require cell contact, as germ cell-conditioned medium also induced the mRNA. The germ cell factor(s) inducing the serotonin receptor mRNA is more than 10 kDa, survives freezing and thawing, and is heat sensitive. A high dose of serotonin (10 microM) or the serotonin receptor agonists (+/-)-1-(2,5-dimethoxy-4-iodophenyl)-2-aminopropane HCl and quipazine induce the serotonin receptor mRNA in Sertoli cells after 24 h. The antagonists, ketanserin and spiperone, inhibit the serotonin-mediated mRNA induction but fail to inhibit the germ cell-mediated induction, suggesting that the germ cell factor(s) up-regulates the serotonin receptor by a distinct pathway. A second clone of 380 nucleotides, induced in Sertoli cells by pachytene spermatocytes or germ cell-conditioned medium, did not show homology to database sequences. The germ cell factor(s) inducing the second clone is larger than 10 kDa, but is inactivated by freezing/thawing and boiling. The induction of a serotonin receptor mRNA and a second novel mRNA in Sertoli cells by pachytene spermatocytes demonstrates that meiotic germ cells induce mRNA encoding an important receptor in Sertoli cells.

The suppression of testis-brain RNA binding protein and kinesin heavy chain disrupts mRNA sorting in dendrites

Ribonucleoprotein particles (RNPs) are thought to be key players in somato-dendritic sorting of mRNAs in CNS neurons and are implicated in activity-directed neuronal remodeling. Here, we use reporter constructs and gel mobility shift assays to show that the testis brain RNA-binding protein (TB-RBP) associates with mRNPs in a sequence (Y element) dependent manner. Using antisense oligonucleotides (anti-ODN), we demonstrate that blocking the TB-RBP Y element binding site disrupts and mis-localizes mRNPs containing (alpha)-calmodulin dependent kinase II (alpha)-CAMKII) and ligatin mRNAs. In addition, we show that suppression of kinesin heavy chain motor protein alters only the localization of (alpha)-CAMKII mRNA. Thus, differential sorting of mRNAs involves multiple mRNPs and selective motor proteins permitting localized mRNAs to utilize common mechanisms for shared steps.

Protein-protein interactions between the testis brain RNA-binding protein and the transitional endoplasmic reticulum ATPase, a cytoskeletal gamma actin and Trax in male germ cells and the brain

Numerous functions have been proposed for the testis brain RNA-binding protein (TB-RBP) and its human homologue, Translin, ranging from mRNA transport and translational regulation to DNA rearrangement and repair. To gain insight into the likely functions of this 26 kDa protein, immunoprecipitation was used to identify proteins that interact with TB-RBP in mouse cytosolic extracts. Three proteins, the transitional endoplasmic reticulum ATPase, a cytoskeletal gamma actin, and Trax, were specifically immunoprecipitated with an affinity-purified antibody to recombinant mouse TB-RBP. In vitro binding assays with recombinant proteins and EM immunocytochemistry confirm that TB-RBP interacts with the TER ATPase in vitro and in vivo. Confocal microscopy has demonstrated that TB-RBP colocalizes with actin in the cytoplasm of male germ cells. The immunoprecipitation of Trax with TB-RBP confirms a published report demonstrating protein interactions between the two proteins in a yeast two-hybrid assay. These data support the hypothesis that TB-RBP serves as a link in attaching specific mRNAs to cytoskeletal structures and suggests an involvement for the ubiquitously expressed TER ATPase in intracellular and/or intercellular mRNA transport.

mRNAs encoding a von Ebner's-like protein and the Huntington disease protein are induced in rat male germ cells by Sertoli cells

The success of spermatogenesis is dependent upon closely coordinated interactions between Sertoli cells and germ cells. To identify specific molecules that mediate interactions between somatic cells and germ cells in the rat testis, Sertoli cell-germ cell co-cultures and mRNA differential display were used. Two cDNAs, clone 1 (660 nucleotides) and clone 2 (390 nucleotides) were up-regulated when Sertoli cells were co-cultured with pachytene spermatocytes or round spermatids. Northern blot analyses confirmed the differential display expression patterns. Sequence analyses indicated that clone 1 was similar to a von Ebner's gland protein (87% at the nucleotide level and 80% at the amino acid level) and clone 2 was identical to a region of the Huntington disease protein. The von Ebner's-like protein mRNA was induced after 4 h of co-culture, while the Huntington disease protein required 18 h of co-culture for expression. The von Ebner's-like protein was induced in germ cells by a secreted Sertoli cell factor(s) smaller than 10 kDa that is sensitive to freezing and thawing or boiling. The Huntington disease protein was induced in germ cells by a Sertoli cell secreted factor(s) larger than 10 kDa which survives freezing and thawing, but is inactivated by boiling.

The mouse Y-box protein, MSY2, is associated with a kinase on non-polysomal mouse testicular mRNAs

In male germ cells many mRNAs are sequestered by proteins into translationally silent messenger ribo-nucleoprotein (mRNP) particles. These masked paternal mRNAs are stored and translated at specific times of germ cell development. Little is known about the mammalian testicular mRNA masking proteins bound to non-polysomal mRNAs. In this report, the major proteins binding to non-polysomal testicular mRNAs were isolated and analyzed. The two predominant proteins identified were: a Y-box protein (MSY2), the mammalian homolog to the Xenopus oocyte masking protein FRGY2/mRNP3+4, and a poly(A) binding protein. A kinase activity was also found associated with these non-polysomal RNAs. The kinase co-immunoprecipitates with MSY2 and phosphorylates MSY2 in vitro. The MSY2 associated kinase is not casein kinase 2, the kinase believed to phosphorylate mRNP3+4 in oocytes, but a yet unidentified kinase. MSY2 was found to be phosphorylated in vivo and MSY2 dephosphorylation led to a decrease in its affinity to bind RNA as judged by northwestern blotting. Therefore, testicular masked mRNAs may be regulated by the phosphorylation state of MSY2. Reconstitution experiments in which non-polysomal mRNA-binding proteins are dissociated from their RNAs and allowed to bind to exogenous mRNAs suggest that MSY2 binds RNA in a sequence-independent fashion. Furthermore, association of the non-polysomal derived proteins to exogenous non-specific mRNAs led to their translational repression in vitro.

Testis-brain RNA-binding protein (Translin) is primarily expressed in neurons of the mouse brain

The subcellular location(s) of the DNA- and RNA-binding protein, Testis-Brain RNA-Binding Protein (TB-RBP)/Translin in mouse brain has been determined in paraffin sections by immunocytochemistry with an affinity purified antibody to mouse recombinant TB-RBP. Nuclear staining was frequently seen in neurons throughout the brain, but no TB-RBP/Translin was detected in many of the neurons in superficial layers of the cerebral cortex and in some cells of the cerebellum. Cytoplasmic staining extending into the dendrites was seen in large neurons such as pyramidal neurons in Layer 5 of the cortex and magnocellular neurons of the hypothalamus or the brainstem raphe.

Contrin, the human homologue of a germ-cell Y-box-binding protein: cloning, expression, and chromosomal localization

Inactivation of germ-cell-specific molecules essential for the production of functional spermatozoa could lead to attractive new means for male contraception. The mouse protein MSY2 is the mammalian homologue of a class of Xenopus DNA/RNA-binding proteins needed for the transcription of testis-specific genes and for translational repression (masking) of paternal mRNAs. In this report, we describe the human homologue for MSY2, Contrin. Sequence analysis of Contrin cDNAs predicts a protein highly similar to its mouse and Xenopus germ-cell Y-box protein homologues with a cold shock domain and four basic/aromatic islands. Contrin is highly basic and is rich in the amino acids arginine and proline. It contains seven putative casein kinase 2 phosphorylation sites and three putative protein kinase C phosphorylation sites, suggesting that Contrin could be highly phosphorylated in vivo. The predicted protein sequence contains two nuclear localization signals, consistent with its predicted role of shuttling between nucleus and cytoplasm. Contrin maps to human chromosome 17p11.2-13.1. By the criteria of northern and western blotting, Contrin appears to be testis specific and distinct from other mammalian Y-box-binding proteins. We predict that inactivation of Contrin function in mammalian germ cells would prevent the formation of functional male gametes.

Mammalian male and female germ cells express a germ cell-specific Y-Box protein, MSY2

Here we report the isolation and characterization of mouse testicular cDNAs encoding the mammalian homologue of the Xenopus germ cell-specific nucleic acid-binding protein FRGY2 (mRNP3+4), hereafter designated MSY2. MSY2 is a member of the Y box multigene family of proteins; it contains the cold shock domain that is highly conserved among all Y box proteins and four basic/aromatic islands that are closely related to the other known germline Y box proteins from Xenopus, FRGY2, and goldfish, GFYP2. Msy2 undergoes alternative splicing to yield alternate N-terminal regions upstream of the cold shock domain. Although MSY2 is a member of a large family of nucleic acid-binding proteins, Southern blotting detects only a limited number of genomic DNA fragments, suggesting that Msy2 is a single copy gene. By Northern blotting and immunoblotting, MSY2 appears to be a germ cell-specific protein in the testis. Analysis of Msy2 mRNA expression in prepubertal and adult mouse testes, and in isolated populations of germ cells, reveals maximal expression in postmeiotic round spermatids, a cell type with abundant amounts of stored messenger ribonucleoproteins. In the ovary, MSY2 is present exclusively in diplotene-stage and mature oocytes. MSY2 is maternally inherited in the one-cell-stage embryo but is not detected in the late two-cell-stage embryo. This loss of MSY2 is coincident with the bulk degradation of maternal mRNAs in the two-cell embryo.

The DNA/RNA-binding protein, TB-RBP, moves from the nucleus to the cytoplasm and through intercellular bridges in male germ cells

The genetically haploid spermatids are functionally diploid as a result of the sharing of gene products through their intercellular bridges. This movement of molecules among haploid cells is crucial for the production of spermatozoa since numerous essential proteins are encoded on sex chromosomes. Testis-brain RNA-binding protein (TB-RBP) is a single-stranded DNA- and RNA-binding protein prominent in the nuclei and cytoplasm of specific stages of differentiating male germ cells. Here we present evidence that TB-RBP moves from the nucleus to the cytoplasm and through intercellular bridges of male germ cells. Based on its RNA-binding capabilities, we propose a role for TB-RBP in the distribution of equal amounts of mRNAs in haploid male germ cells.

Rat pachytene spermatocytes down-regulate a polo-like kinase and up-regulate a thiol-specific antioxidant protein, whereas sertoli cells down-regulate a phosphodiesterase and up-regulate an oxidative stress protein after exposure to methoxyethanol and methoxyacetic acid

2-Methoxyethanol (ME) and its metabolite, methoxyacetic acid (MAA), produce testicular lesions characterized by pachytene spermatocyte degeneration. To understand the molecular basis of this action on meiotic prophase cells, mRNA differential display was used to identify gene expression changes in control and treated cells. When pachytene spermatocytes were cultured with 5 mM ME or 5 mM MAA for 24 h, two complementary DNAs (cDNAs), of 557 nucleotides (clone 5) and 388 nucleotides (clone 6), were up-regulated; and a cDNA of 648 nucleotides (clone 1) was down-regulated. The altered expression pattern shown by differential display was confirmed by Northern blotting. Sequence analyses indicate that clones 1 and 6 have 83% and 79% homology at the nucleotide level to a polo-like kinase and a thiol-specific antioxidant, respectively. Clone 5 shows no homology to any known gene in the database. Messenger RNAs (mRNAs) encoding the thiol-specific antioxidant and clone 5 are up-regulated within 30 min of the addition of MAA, whereas the polo-like kinase mRNA decreased to undetectable levels after 6 h. Changes in Sertoli cell gene expression were also detected when Sertoli cells were cultured with 5 mM ME or MAA for 24 h. Two cDNAs, of 367 nucleotides (clone 2) and 676 nucleotides (clone 3), were up-regulated; and a cDNA of 538 nucleotides (clone 4) was down-regulated. Homology searches revealed that clones 3 and 4 have 90 and 91% homology at the nucleotide level to an oxidative stress protein and a phosphodiesterase (PDE), respectively. Northern blotting confirmed the differential display expression pattern for the PDE and oxidative stress protein. mRNAs for the latter were induced within 30 min, and PDE mRNAs were down-regulated within one h, after the addition of MAA. To determine whether the changes in gene expression seen with cells in culture also occur in vivo, rats were given a single oral dose of 250 mg/kg ME or MAA. After 24 h, total testis RNAs from control and treated rats were purified and hybridized. The expression patterns seen in vivo for the differentially expressed cDNAs were identical to those seen in vitro. We conclude that, although pachytene spermatocytes seem to be selectively affected by ME and MAA, changes in gene expression are also detected in Sertoli cells, suggesting that the action(s) of ME or MAA on pachytene spermatocytes could be mediated through Sertoli cells.

Molecular mechanisms of male germ cell differentiation

During spermatogenesis, diploid stem cells differentiate, undergo meiosis, and transform into haploid spermatozoa. As this precisely timed series of events proceeds, chromosomal ploidy is reduced and the nucleosomes of the chromatin are replaced by a transcriptionally quiescent protamine-containing nucleus. The premature termination of transcription during the haploid phase of spermatogenesis necessitates an especially prominent role for posttranscriptional regulation in the temporal and spatial expression of many testis-specific proteins and isozymes. In this review article, discussion will focus on novel mechanisms regulating gene expression in mammalian male germ cells from genome to protein.

Molecular mechanisms of male germ cell differentiation

During spermatogenesis, diploid stem cells differentiate, undergo meiosis, and transform into haploid spermatozoa. As this precisely timed series of events proceeds, chromosomal ploidy is reduced and the nucleosomes of the chromatin are replaced by a transcriptionally quiescent protamine-containing nucleus. The premature termination of transcription during the haploid phase of spermatogenesis necessitates an especially prominent role for posttranscriptional regulation in the temporal and spatial expression of many testis-specific proteins and isozymes. In this review article, discussion will focus on novel mechanisms regulating gene expression in mammalian male germ cells from genome to protein.

Dimerization of the testis brain RNA-binding protein (translin) is mediated through its C-terminus and is required for DNA- and RNA-binding

Testis brain-RNA-binding protein (TB-RBP) is a single-stranded DNA- and RNA-binding protein that is involved in chromosomal translocations, mRNA transport and translational regulation. Here we show from in vitro and in vivo protein binding studies that TB-RBP dimers are the minimum structural unit needed for DNA- and RNA-binding. Truncation studies demonstrate that the C-terminus of 55 amino acids of TB-RBP is essential, but not sufficient for DNA- or RNA-binding, and deletion of the leucine zipper motif in the C-terminus abolishes DNA- and RNA-binding. Changing cysteine 225 in the C-terminus to alanine does not significantly reduce DNA- or RNA-binding, but reduces the stability of the dimer. We conclude that the leucine zipper motif is required to maintain two molecules of TB-RBP as a dimer which is stabilized by a disulfide bond involving cysteine 225.

The RNA- and DNA-binding protein TB-RBP is spatially and developmentally regulated during spermatogenesis

Testis brain RNA-binding protein (TB-RBP) suppresses translation in vitro and attaches mRNAs to microtubules by binding to conserved elements in the 3' untranslated regions (UTRs) of specific testis and brain mRNAs. Purification of TB-RBP from testicular and brain cytoplasmic extracts has revealed that mouse TB-RBP is 99% identical to the human protein translin, a recombination "hot spot" binding protein associated with chromosomal translocations. Using a cDNA encoding TB-RBP, the gene copy number and the developmental expression of TB-RBP have been analyzed by Southern blotting, Northern blotting, and in situ hybridization. In the mouse, TB-RBP is encoded by a single copy gene. In mouse testes, three TB-RBP mRNAs of about 1.2, 1.7, and 3.0 kb are developmentally regulated with high levels of expression in meiotic and postmeiotic germ cells. A fourth TB-RBP transcript of about 3.2 kb is seen in the brain. In situ hybridization confirms high levels of testicular TB-RBP mRNAs in meiotic and postmeiotic cells, with the highest levels of TB-RBP mRNAs in pachytene spermatocytes and round spermatids of the mouse and in round spermatids of the rat. RNase H digestion assays reveal that the three TB-RBP mRNAs of mouse testes result from processing differences in their 3' untranslated regions. These data demonstrate that multiple TB-RBP mRNAs are primarily expressed in meiotic and postmeiotic germ cells in the mammalian testis, and although the specific RNA-binding ability of TB-RBP appears limited to brain and testis, TB-RBP mRNAs are widely expressed.

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.

Up-regulation and down-regulation of genes expressed in cocultures of rat Sertoli cells and germ cells

To better understand the molecular interactions between somatic and germ cells in the mammalian testis, we have begun to analyze with mRNA differential display changes in gene expression induced by coculturing rat Sertoli cells and germ cells. We have identified 10 cDNAs that are either down-regulated or up-regulated in cocultures of germ cells and Sertoli cells. Three genes expressed in Sertoli cells and three genes expressed in germ cells were down-regulated in Sertoli cell-germ cell cocultures, whereas four genes were up-regulated in the cocultures. Northern blot analysis was used to establish the expression pattern of the mRNAs encoded by the cDNAs and to define the sizes of the differentially expressed mRNAs. Sequence analysis of the cDNAs and computer searches against the GenBank and EMBL DNA databases were used to relate the ten cDNAs to known genes. Of the three Sertoli cell cDNAs, one appeared identical to transferin, while the other two shared regions of similarity to an endoplasmic reticulum stress protein and to a pro-alpha 2 XI collagen, respectively. The three germ cell cDNAs shared sequences with fibronectin, with a basic fibroblast growth factor receptor and with an IgG gamma 2b, respectively. The four cDNAs that were up-regulated in the Sertoli-germ cell cocultures showed similarity to an isoform of casein kinase 1 delta, to an epidermal growth factor, to a statin-related protein, and to an integral membrane glycoprotein. These data demonstrate that a number of specific genes are up- and down-regulated when germ cells and Sertoli cells are cocultured, and suggest these genes are important in cell to cell communication during spermatogenesis.

Deoxyribonucleic acid-protein interactions associated with transcriptional initiation of the mouse testis-specific cytochrome c gene

Transcriptional regulation of the mouse testis-specific cytochrome c (cyt. cT) gene was studied by examining DNA-protein interactions in its proximal promoter. Testicular and liver nuclear proteins bound to the cyt. cT gene at sites -105 to -81, +87 to +113, and +146 to +169, suggesting interactions with ubiquitous nuclear proteins. Protein present in liver nuclear extracts bound to a fourth site at -176 to -125, whereas protein present in testicular nuclear extracts bound to a subregion of this site at -176 to -140. The sequence from -136 to -127, bound by liver but not testicular nuclear proteins, is similar to that of the binding site of a somatic c-mos repressor protein. Lastly, different nuclear proteins from mouse liver and testis bound to a region from -18 to +31 that contains a putative Y box at -13 to -2. Mobility shift assays, Southwestern blots, and immunoprecipitation studies have established that this putative Y box binds a 52-kDa mouse testicular homologue of the Xenopus germ cell-specific Y-box protein and a competing 50-kDa protein present in both liver and testis nuclear extracts. These data suggest that the testis-specific expression of the mouse cyt. cT gene during spermatogenesis may be regulated by the differential binding of tissue-specific nuclear proteins to its proximal promoter region.

The RNA-binding protein, TB-RBP, is the mouse homologue of translin, a recombination protein associated with chromosomal translocations

The mouse RNA-binding protein, TB-RBP, suppresses translation in vitro and attaches mRNAs to microtubules by binding to conserved elements in the 3' untranslated regions of specific mRNAs. We have now purified TB-RBP from testicular and brain cytoplasmic extracts and cloned its cDNA. We find that the mouse TB-RBP cDNAs contain an open reading frame of 228 amino acids with a leucine zipper domain within its C terminus, a transmembrane helix, and a group of putative phosphorylation sites. TB-RBP shows 99% identity to the human protein, translin, a recombination hotspot-binding protein associated with chromosomal translocations [Aoki, K., Suzuki, K., Sugano, T., Tasaka, T., Nakahara, K., Kuge, O., Omori, A. & Kasai, M. (1995) Nat. Genet. 10, 167-174]. As shown for translin, TB-RBP also binds to single-stranded DNAs containing a broad range of consensus sequences, many of which are similar to the Y and H RNA-binding sequences. Recombinant TB-RBP was synthesized and an antiserum was prepared against the recombinant protein. The identity between translin and TB-RBP was confirmed by demonstrating that immunoprecipitation of TB-RBP from testicular extracts abolished formation of the RNA-TB-RBP complex. Based upon its DNA binding to target sequences in clustered breakpoint regions, we propose that TB-RBP may be involved in DNA recombination or DNA repair in 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.

The enzymatic activity of Cu/Zn superoxide dismutase does not fluctuate in mouse spermatogenic cells despite mRNA changes

In the mammalian testis, multiple mRNAs encoding the copper zinc superoxide dismutase (SOD-1) are expressed in postmeiotic male germ cells. Here we relate SOD-1 mRNA levels to SOD-1 protein and enzyme activity levels in mouse spermatogenic cells. Although the sizes and relative amounts of the multiple SOD-1 mRNAs vary as male germ cells enter meiosis and proceed into the postmeiotic stages of spermatogenesis, the amount of SOD-1 protein and enzyme activity does not fluctuate significantly, suggesting a precise control of SOD-1 activity in male germ cells.

Sertoli cells in culture and mRNA differential display provide a sensitive early warning assay system to detect changes induced by xenobiotics

We have used cultured rat Sertoli cells as an "early warning system" to monitor for morphological and biochemical changes induced by two different xenobiotics-cadmium acetate and polychlorinated biphenyls (PCBs). Sertoli cells begin to round, become vacuolized, and detach from their substrate within 24 hours of culture in the presence of cadmium at concentrations of 0.5-1.0 microM. Similar results were obtained with a lower dose of cadmium (0.01 microM) after 72 hours. When Sertoli cells are cultured for 24 hours in the presence of a mixture of PCBs (3,3',4,4'-tetrachlorobiphenyl, 2,2',4,6,6'-pentachlorophenyl, and 2,2',3,3',4,5,5', 6,6'-nonachlorobiphenyl) at concentrations of 1.0-2.0 microM, they enlarge. After 72 hours, a lower dose of PCBs (0.01 microM) produces similar cellular enlargement. Despite their changes in morphology, no reduction in Sertoli cell viability was seen at any of the concentrations or time points studied for either toxicant. Using mRNA differential display, a number of novel cDNAs were detected when cells were cultured with either cadmium or the PCBs, demonstrating that changes in gene expression accompany the changes in Sertoli cell structure. We propose that Sertoli cells in culture and mRNA differential display provide a sensitive morphological and biochemical assay system to detect early direct effects of low concentrations of toxicants on mammalian Sertoli cells.

Tissue-specific protein-DNA interactions of the mouse protamine 2 gene promoter

During spermiogenesis, the haploid phase of spermatogenesis, the genome is packaged into a highly compacted form and this process requires replacement of histones by protamines. In the mouse, protamines are encoded by two genes, which are transcriptionally regulated in testis. To understand the regulation of transcription of the mouse protamine 2 (mP2) gene, the tissue-distribution of sequence-specific interactions between nuclear proteins and promoter DNA sequences have been analyzed. Protein binding to the promoter region from -370 to +65 was studied using DNase I footprinting and gel shift assays. Five protein binding sites were identified, which are recognized by nuclear proteins from either testis or liver. Site 1 from -64 to -48, contains part of a cAMP responsive element (CRE), which in testis is recognized by CREM tau, an activator of post-meiotic transcription. Testicular protein(s) also binds to three other promoter domains: site 2, -87 to -67, a region containing a CAAT box, and sites 4 and 5, -239 to -210 and -328 to -311, sequences with similarity to consensus steroid hormone responsive elements (HRE). In contrast, interactions between the mP2 promoter and nuclear factors from liver, a tissue in which the mP2 gene is not transcribed, are observed at sites 1, 2, and 4, as well as at an additional region at site 3, -202 to -175. Because occupancy at site 3 appears to correlate with inactivation of the gene in non-testicular tissues, whereas testicular protein binding at site 5 appears to be associated with active transcription, we conclude that the mP2 promoter displays intricate tissue-specific patterns of protein/DNA interactions at key regulatory elements.

Molecular cloning of mouse somatic and testis-specific H2B histone genes containing a methylated CpG island

We have isolated a mouse testis-specific H2B histone gene based on the unusual methylation of the CpG island of rat testis-specific H2B gene in somatic tissues. After digestion of genomic DNA with the methylation-sensitive restriction enzyme Hha I, we found that, among 10-20 copies of mouse H2B histone genes, at least three copies are methylated in somatic tissues, but not in testis. Cloning and sequence analysis of two methylated H2B genes revealed that one gene, MTH2B, is strikingly similar to the testis-specific histone H2B (TH2B) gene of rat and the other, psH2B, is a pseudogene of the somatic-type H2B gene. Northern blot analysis revealed that the expression of the MTH2B gene is testis-specific. During spermatogenesis, the MTH2B gene is expressed predominantly in pachytene spermatocytes, as observed in the expression of rat TH2B gene. Interestingly, the MTH2B gene is largely unmethylated in embryonic stem cells, but methylated in F9 embryonal carcinoma cells. The psH2B pseudogene is methylated in somatic tissues and F9 cells, but only partially methylated in embryonic stem cells. Methylation of the psH2B pseudogene seems to be attributed to its location within the context of repetitive sequences including the B1 element. The unmethylation of both H2B histone genes in the testis explains how CpG islands of those histone genes can be maintained during evolution despite heavy methylation in somatic tissues.

In postmeiotic male germ cells poly (A) shortening accompanies translation of mRNA encoding gamma enteric actin but not cytoplasmic beta and gamma actin mRNAs

In the mammalian testis the cytoplasmic beta and gamma actins are expressed in all stages of germ-cell differentiation, whereas gamma enteric actin is expressed in germ cells solely in postmeiotic stages. Northern blot analysis of mouse testicular RNAs reveals actin mRNAs of about 2.1, 1.5, and 1.4 kB. The 2.1-kB mRNAs encode the cytoplasmic beta and gamma actins, whereas the two faster-migrating actin mRNAs encode gamma enteric actin. When postmitochondrial mouse testis extracts are fractionated by sucrose gradient centrifugation, the 1.5-kB gamma enteric actin mRNA is primarily found in the nonpolysomal fraction, whereas the 1.4-kB gamma enteric actin is polysomal. When the poly (A) tails are removed, the nonpolysomal and polysomal gamma enteric actin mRNAs both migrate at 1.3 kB, indicating that the difference in electrophoretic mobilities of the two gamma enteric actin mRNAs is caused by poly (A) length differences. The nonpolysomal and polysomal forms of the cytoplasmic beta and gamma actins show similar electrophoretic mobilities before and after deadenylation. Sequence comparison of the 3' untranslated region of the mouse gamma enteric actin to the 3' untranslated regions of other testicular mRNAs that undergo partial deadenylation reveals three highly-conserved sequence elements. These data demonstrate that the poly (A) shortening of polysomal mRNAs previously seen only with testis-specific mRNAs that are stored as mRNPs also occurs with mRNAs of widely-expressed genes that are expressed in postmeiotic male germ cells. The mRNAs all contain specific conserved sequence elements in their 3' untranslated regions.

Developmental expression of glutathione peroxidase, catalase, and manganese superoxide dismutase mRNAs during spermatogenesis in the mouse

We have examined in mouse testis the steady-state levels of mRNAs encoding glutathione peroxidase (GSHPx), catalase (CAT), and superoxide dismutase 2 (SOD-2), three enzymes essential for the antioxidant protection of cells. In RNA preparations derived from prepuberal and adult testes and from isolated populations of meiotic and post-meiotic germ cells, one major GSHPx mRNA of about 0.8 kilobases (kb) and one major CAT mRNA of about 2.4 kb were detected. Three SOD-2 mRNAs of about 2.2, 1.2, and 1.0 kb were found in testis. In contrast to GSHPx and CAT, the mRNA levels of SOD-2 were higher in testis than in liver. SOD-2 mRNA levels are developmentally and translationally regulated with maximal levels of expression in early post-meiotic germ cells, whereas the levels of GSHPx and CAT mRNAs are relatively constant in both prepuberal and adult testes. These data suggest that translational regulation plays a more prominent role for SOD-2 expression than for GSHPx or CAT expression in the mammalian testis.

Germ cell-specific DNA and RNA binding proteins p48/52 are expressed at specific stages of male germ cell development and are present in the chromatoid body

Proteins homologous to the Xenopus oocyte mRNA binding proteins mRNP3+4 and designated p48/52 have been identified in male mouse germ cells (1993: Dev Biol 158:90-100). Western and North-western blots of extracts from testes and isolated germ cells indicate that p48/52 are present during meiosis but reach their highest levels postmeiotically at a time when many mRNAs are stored. Here we analyze the cellular and subcellular distribution of p48/52 in rat and mouse testes by LM and EM immunocytochemistry using an anti-mRNP3+4 antibody. Immunolabeling was found to be predominantly cytoplasmic and specific to germ cells at certain periods during their development. p48/52 were first detected in early pachytene spermatocytes at stage V of the seminiferous cycle and progressively increased during the remainder of meiotic prophase to a post-meiotic peak in steps 1-8 round spermatids; thereafter, labeling gradually declined as elongated spermatids underwent nuclear condensation and elongation. A proportionally higher concentration of cytoplasmic immunolabeling was found within the lacunae of the anastomotic granulofilamentous network of the chromatoid body. The pattern of synthesis of these mRNA binding proteins together with their association with the chromatoid body suggests a role as germ cell-specific mRNA stabilizing and/or storage proteins.

Differential expression of ornithine decarboxylase, poly(ADP)ribose polymerase, and mitochondrial mRNAs following testosterone administration to hypophysectomized rats

The mRNAs of the nuclear encoded genes, ornithine decarboxylase (ODCase) and poly(ADP)ribose polymerase (PADPRP), and the mitochondrial encoded genes, cytochrome oxidase I and II (COI and COII) and ATPase 6, are differentially expressed during spermatogenesis (Alcivar et al., 1989: Biol Reprod 41:1133; 1989: Dev Biol 135:263; 1991: Biol Reprod 46:201). In this study, we use Northern blotting to examine the steady state levels of ODCase, PADPRP, COI, COII, and ATPase 6 mRNAs in testes of hypophysectomized male rats following testosterone administration. Four weeks after hypophysectomy, rats received 24 cm subcutaneous implants of testosterone-filled polydimethylsiloxane (PDS) and were killed at 3, 7, 14, 28, and 56 days thereafter. After hypophysectomy, the steady state levels for the PADPRP, COI, COII, and ATPase 6 mRNAs were not significantly different from controls, although hypophysectomy caused a 44% loss of preleptotene spermatocytes and an 88% loss of pachytene spermatocytes, the testicular cell types expressing the highest levels of these mRNAs. In contrast, the levels of the two ODCase mRNAs were greatly decreased after hypophysectomy and mirrored the number of germinal cells present in the testis. After testosterone treatment, ODCase mRNA levels remained low 3 days after treatment and gradually increased at days 14, 28, and 56. No major hybridization signal changes in PADPRP, COI, COII, and ATPase mRNA were observed after testosterone treatment. We conclude that the steady state mRNA levels for the housekeeping ODCase gene respond differently after hypophysectomy and testosterone treatment of male rats than the PADPRP and mitochondrial DNA transcripts.

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.

Testis/brain RNA-binding protein attaches translationally repressed and transported mRNAs to microtubules

We have previously identified a testicular phosphoprotein that binds to highly conserved sequences (Y and H elements) in the 3' untranslated regions (UTRs) of testicular mRNAs and suppresses in vitro translation of mRNA constructs that contain these sequences. This protein, testis/brain RNA-binding protein (TB-RBP) also is abundant in brain and binds to brain mRNAs whose 3' UTRs contain similar sequences. Here we show that TB-RBP binds specific mRNAs to microtubules (MTs) in vitro. When TB-RBP is added to MTs reassembled from either crude brain extracts or from purified tubulin, most of the TB-RBP binds to MTs. The association of TB-RBP with MTs requires the assembly of MTs and is diminished by colcemid, cytochalasin D, and high levels of salt. Transcripts from the 3' UTRs of three mRNAs that contain the conserved sequence elements (transcripts for protamine 2, tau protein, and myelin basic protein) are linked by TB-RBP to MTs, whereas transcripts that lack the conserved sequences do not bind TB-RBP. We conclude that TB-RBP serves as an attachment protein for the MT association of specific mRNAs. Considering its ability to arrest translation in vitro, we propose that TB-RBP functions in the storage and transportation of mRNAs to specific intracellular sites where they are translated.

Testis-brain RNA-binding protein, a testicular translational regulatory RNA-binding protein, is present in the brain and binds to the 3' untranslated regions of transported brain mRNAs

Previous studies have demonstrated that a phosphoprotein in testis binds to transcript c, a sequence containing two highly conserved elements, Y and H, in the 3' untranslated region (UTR) of mouse protamine 2 mRNA (mP2) and represses its translation in vitro. When gel-retardation assays were performed with cytoplasmic extracts prepared from seven different mouse tissues, we found that brain in addition to testis contains a protein that binds to transcript c. Both the testis and brain proteins are found exclusively in the nonpolysomal fractions of their postmitochondrial extracts. The testis and brain proteins appear to be identical according to numerous criteria: the complexes they form with transcript c have identical mobility in native gels, identical optimal pH, identical lability to increased salt concentrations, identical chromatographic properties, identical molecular sizes as judged from UV crosslinking, and identical peptide mapping as revealed by V8 digestion of the UV crosslinked protein-RNA complexes. In addition to binding to the same conserved sequence in the 3'UTR of mP2, the phosphoprotein from testis and brain, hereafter called testis-brain RNA-binding protein (TB-RBP), also specifically binds to a similar sequence in the 3'UTR of brain Tau mRNA. Since TB-RBP binds to the 3'UTRs of several translationally regulated mRNAs in testis and since numerous transported brain mRNAs also contain the same conserved binding elements, we propose that TB-RBP plays a role in mRNA storage, translocation, and/or localization in brain and testis.

Poly (A) binding protein is bound to both stored and polysomal mRNAs in the mammalian testis

RNA-binding proteins that bind to the 3' untranslated region of mRNAs play important roles in regulating gene expression. Here we examine the association between the 70 kDa poly (A) binding protein (PABP) and stored (RNP) and polysomal mRNAs during mammalian male germ cell development. PABP mRNA levels increase as germ cells enter meiosis, reaching a maximum in the early postmeiotic stages, and decreasing to a nearly nondetectable level towards the end of spermatogenesis. Most of the PABP mRNA is found in the nonpolysomal fractions of postmitochondrial extracts, suggesting that PABP mRNA is either inefficiently translated or stored as RNPs during spermatogenesis. Virtually all of the testicular PABP is bound to either polysomal or nonpolysomal mRNAs, with little, if any, free PABP detectable. Analysis of several specific mRNAs reveals PABP is bound to both stored (RNP) and translated forms of the mRNAs. Western blot analysis and immunocytochemistry indicate PABP is widespread in the mammalian testis, with maximal amounts detected in postmeiotic round spermatids. The presence of PABP in elongating spermatids, a cell type in which PABP mRNA is nearly absent, suggests that PABP is a stable protein in the later stages of male germ cell development. The high level of testicular PABP in round spermatids and in mRNPs suggests a role for PABP in the storage as well as in the subsequent translation of developmentally regulated mRNAs in the mammalian testis.

A mouse homologue of the Xenopus germ cell-specific ribonucleic acid/deoxyribonucleic acid-binding proteins p54/p56 interacts with the protamine 2 promoter

Recent evidence indicates that a member of the Y box-binding family of transcriptional regulators is identical to p56, a predominant protein of messenger ribonucleoprotein complexes. The p56 protein is highly enriched in oocytes and testis, and a functional RNA binding mouse cytoplasmic homologue has been cloned and partially characterized. Because few potential testis-specific transcriptional regulators have been identified, the testis-enriched Y box-binding proteins represent trans-acting elements of a unique model system for the study of haploid gene expression. The 5' flanking region of the testis-specific, haploid-expressed mouse protamine 2 gene contains an element with a 9-of-12 nucleotide identity with the previously defined Y box consensus sequence. We have investigated the possible role of Y box-binding proteins in transcriptional regulation of protamine 2 using specific antibodies and DNA-protein binding assays. Western blot analyses with two different anti-p54/p56 antibodies demonstrate that a mouse homologue of Xenopus p54/p56 is present in transcriptionally active mouse testis nuclear extracts. Our results further indicate that the Xenopus Y box-binding proteins bind to an element 5' to the mouse protamine 2 gene. Similarly, binding of the mouse testis homologue to the protamine 2 Y box element is demonstrated by gel mobility shift and antibody supershift analyses. The demonstrated interactions between testis-enriched Y box-binding proteins and protamine 2 transcriptional control elements therefore represent a unique system for functional studies to determine the mechanism of regulation of haploid gene expression.

In male mouse germ cells, copper-zinc superoxide dismutase utilizes alternative promoters that produce multiple transcripts with different translation potential

Copper-zinc superoxide dismutase (SOD-1) is an enzyme that is widely expressed in eukaryotic cells and performs a vital role in protecting cells against free radical damage. In mouse testis, three different sizes of SOD-1 mRNAs of about 0.73, 0.80, and 0.93 kilobases (kb) are detected. The 0.73-kb mRNA is found in early stages of male germ cells and in all somatic tissues. The mRNAs of 0.80 and 0.93 kb are exclusively detected in post-meiotic germ cells. RNase H digestions and Northern blot analyses reveal that the three SOD-1 mRNAs are derived from two transcripts, a ubiquitously expressed transcript and a post-meiotic transcript, which differ by 114-120 nucleotides. RNase protection assays demonstrate that the additional nucleotides present in the post-meiotic mRNA are solely in the 5'-untranslated region. Using a probe derived from the 5'-untranslated region of the 0.93-kb SOD-1 mRNA, we have established that it originates from an alternative upstream promoter contiguous with the somatic SOD-1 promoter. Polysomal gradient analysis of the three mouse testis SOD-1 mRNAs reveals that the 0.93-kb SOD-1 mRNA is primarily non-polysomal, while the 0.80- and 0.73-kb SOD-1 mRNAs are mostly polysome associated. A faster migrating form of the 0.93-kb SOD-1 mRNA is present on polysomes as a result of partial deadenylation. In a cell-free translation system, the 0.73-kb SOD-1 mRNA translates about 2-fold more efficiently than the 0.93-kb SOD-1 mRNA. These data demonstrate that male germ cells transcribe two size classes of SOD-1 mRNAs with different translation potential by utilizing two different promoters, post-meiotic SOD-1 mRNAs undergo adenylation changes, and one of the post-meiotic SOD-1 mRNAs is transcribed during mid-spermiogenesis and translated days later in a partially deadenylated form.

Heterogeneity in the 5' untranslated region of mouse cytochrome cT mRNAs leads to altered translational status of the mRNAs

Previous studies have shown that the differential regulation of mouse somatic cytochrome c (cyt cS) and testicular cytochrome c (cyt cT) during spermatogenesis is accompanied by changes in mRNA length [Hake et al. (1990) Development, 110, 249-257]. When analyzed by polysomal gradient sedimentation, cytochrome cT sediments in two broad size classes: non-polysomal mRNAs are about 0.6 to 0.75 kb and polysomal mRNAs range from 0.7 to 0.9 kb. Both classes of mRNAs shorten to about 0.5 kb following deadenylation. Oligonucleotide-directed cleavage of the cytochrome cT RNAs by RNase H reveals that the size heterogeneity of cytochrome cT mRNAs resides in the 5' untranslated regions (UTRs). Ribonuclease protection assays reveal that multiple cytochrome cT mRNAs are transcribed from six different transcriptional start sites spanning a region of 59 nucleotides in the 5'UTR from +1 to +59. Transcripts derived from the first and second transcriptional initiation sites are not loaded onto polysomes as efficiently as those transcripts initiated from the other start sites. Each of the longer mRNAs has an upstream open reading frame, which starts at +8 and ends at +136 in the 5'UTR of the cytochrome cT transcript. Computer analysis suggests that the lengthened 5'UTR sequences allow additional hairpin structures to be formed. Since the upstream open reading frame and the additional stem loop structure are absent in the 5' UTRs of the cytochrome cT mRNAs initiated from the four downstream start sites, we suggest that these sequences in the two longest cytochrome cT transcripts hinder their loading onto polysomes.

The genes encoding the somatic and testis-specific isotypes of the mouse cytochrome c genes map to paralogous regions of chromosomes 6 and 2

Using mouse probes specific to cytochrome cs and to cytochrome cT, the single-copy genes encoding these two proteins have been mapped to paralogous chromosomal regions by analysis of restriction fragment length variants in interspecific crosses. The gene for cytochrome cs, Cycs, maps to a position between Tcrb and Cbl-1 on proximal mouse Chromosome 6, and the gene for cytochrome cT, Cyct, maps between Gad-1 and Sfpi-1 on mouse Chromosome 2.

Synthesis and processing of mammalian protamines and transition proteins

Mouse and rat seminiferous tubule fragment cultures were used to examine synthesis and processing of mammalian protamines and transition proteins. The tubule fragments were incubated with [3H]-arginine, [3H]-histidine, [35S]-cysteine, or [32P]-PO4, and radiolabeled proteins were analyzed by acid/urea polyacrylamide gel electrophoresis and fluorography or autoradiography. Newly synthesized protamines were recovered from sonication-resistant nuclei (SRN) and could not be detected in cytoplasmic fractions, indicating that protamines are deposited into nuclei immediately after synthesis. Newly synthesized mouse protamine 1 (mP1) and the precursor to mouse protamine 2 (pre-mP2) migrated more slowly during electrophoresis than their predominant testicular forms, identified by staining with Coomassie blue R-250. Within 1 hour of synthesis, the electrophoretic mobilities of mP1 and pre-mP2 increased to match those of their predominant forms. These changes are consistent with initial charge-neutralizing modifications of the newly synthesized protamines, followed by removal of at least some of the modifying ligands, to unmask protamine basicity. Steady-state phosphorylation rates were high for rat protamine 1 (rP1) and were independent of phosphate content; both rP1 molecules of low and high phosphate content were rapidly phosphorylated. Pre-mP2-3, a major processing intermediate derived by proteolysis of pre-mP2, was also rapidly phosphorylated. Like the protamines, transition protein 2 (TP2) was rapidly phosphorylated and increased in electrophoretic mobility soon after synthesis. In contrast, transition protein 1 (TP1) was not phosphorylated and did not exhibit multiple electrophoretic forms.