Folic acid supplementation reduces multigenerational sperm miRNA perturbation induced by in utero environmental contaminant exposure.

Persistent organic pollutants (POPs) can induce epigenetic changes in the paternal germline. Here, we report that folic acid (FA) supplementation mitigates sperm miRNA profiles transgenerationally following in utero paternal exposure to POPs in a rat model. Pregnant founder dams were exposed to an environmentally relevant POPs mixture (or corn oil) ± FA supplementation and subsequent F1-F4 male descendants were not exposed to POPs and were fed the FA control diet. Sperm miRNA profiles of intergenerational (F1, F2) and transgenerational (F3, F4) lineages were investigated using miRNA deep sequencing. Across the F1-F4 generations, sperm miRNA profiles were less perturbed with POPs+FA compared to sperm from descendants of dams treated with POPs alone. POPs exposure consistently led to alteration of three sperm miRNAs across two generations, and similarly one sperm miRNA due to POPs+FA; which was in common with one POPs intergenerationally altered sperm miRNA. The sperm miRNAs that were affected by POPs alone are known to target genes involved in mammary gland and embryonic organ development in F1, sex differentiation and reproductive system development in F2 and cognition and brain development in F3. When the POPs treatment was combined with FA supplementation, however, these same miRNA-targeted gene pathways were perturbed to a lesser extend and only in F1 sperm. These findings suggest that FA partially mitigates the effect of POPs on paternally derived miRNA in a intergenerational manner.

Stability of the human sperm DNA methylome to folic acid fortification and short-term supplementation.

STUDY QUESTION: Do short-term and long-term exposures to low-dose folic acid supplementation alter DNA methylation in sperm? SUMMARY ANSWER: No alterations in sperm DNA methylation patterns were found following the administration of low-dose folic acid supplements of 400 µg/day for 90 days (short-term exposure) or when pre-fortification of food with folic acid and post-fortification sperm samples (long-term exposure) were compared. WHAT IS KNOWN ALREADY: Excess dietary folate may be detrimental to health and DNA methylation profiles due to folate's role in one-carbon metabolism and the formation of S-adenosyl methionine, the universal methyl donor. DNA methylation patterns are established in developing male germ cells and have been suggested to be affected by high-dose (5 mg/day) folic acid supplementation. STUDY DESIGN, SIZE, DURATION: This is a control versus treatment study where genome-wide sperm DNA methylation patterns were examined prior to fortification of food (1996-1997) in men with no history of infertility at baseline and following 90-day exposure to placebo (n = 9) or supplement containing 400 µg folic acid/day (n = 10). Additionally, pre-fortification sperm DNA methylation profiles (n = 19) were compared with those of a group of post-fortification (post-2004) men (n = 8) who had been exposed for several years to dietary folic acid fortification. PARTICIPANTS/MATERIALS, SETTING, METHODS: Blood and seminal plasma folate levels were measured in participants before and following the 90-day treatment with placebo or supplement. Sperm DNA methylation was assessed using the whole-genome and genome-wide techniques, MassArray epityper, restriction landmark genomic scanning, methyl-CpG immunoprecipitation and Illumina HumanMethylation450 Bead Array. MAIN RESULTS AND THE ROLE OF CHANCE: Following treatment, supplemented individuals had significantly higher levels of blood and seminal plasma folates compared to placebo. Initial first-generation genome-wide analyses of sperm DNA methylation showed little evidence of changes when comparing pre- and post-treatment samples. With Illumina HumanMethylation450 BeadChip arrays, no significant changes were observed in individual probes following low-level supplementation; when compared with those of the post-fortification cohort, there were also few differences in methylation despite exposure to years of fortified foods. LARGE SCALE DATA: Illumina HumanMethylation450 BeadChip data from this study have been submitted to the NCBI Gene Expression Omnibus under the accession number GSE89781. LIMITATIONS, REASONS FOR CAUTION: This study was limited to the number of participants available in each cohort, in particular those who were not exposed to early (pre-1998) fortification of food with folic acid. While genome-wide DNA methylation was assessed with several techniques that targeted genic and CpG-rich regions, intergenic regions were less well interrogated. WIDER IMPLICATIONS OF THE FINDINGS: Overall, our findings provide evidence that short-term exposure to low-dose folic acid supplements of 400 µg/day, over a period of 3 months, a duration of time that might occur during infertility treatments, has no major impact on the sperm DNA methylome. STUDY FUNDING/COMPETING INTERESTS: This work was supported by a grant to J.M.T. from the Canadian Institutes of Health Research (CIHR: MOP-89944). The authors have no conflicts of interest to declare.

Haploinsufficiency of the paternal-effect gene Dnmt3L results in transient DNA hypomethylation in progenitor cells of the male germline.

STUDY QUESTION: How does haploinsufficiency of the paternal-effect gene Dnmt3L affect DNA methylation establishment and stability in the male germline? SUMMARY ANSWER: Reduced expression of DNMT3L in male germ cells, associated with haploinsufficiency of the paternal-effect gene Dnmt3L, results in abnormal hypomethylation of prenatal germline progenitor cells. WHAT IS KNOWN ALREADY: The DNA methyltransferase regulator Dnmt3-Like (Dnmt3L) is a paternal-effect gene required for DNA methylation acquisition in male germline stem cells and their precursors. In males, DNMT3L deficiency causes meiotic abnormalities and infertility. While Dnmt3L heterozygous males are fertile, they have abnormalities in X chromosome compaction and postmeiotic gene expression and sire offspring with sex chromosome aneuploidy. It has been proposed that the paternal effects of Dnmt3L haploinsufficiency are due to epigenetic defects in early male germ cells. DNA methylation is an essential epigenetic modification essential for normal germ cell development. Since patterns of DNA methylation across the genome are initially acquired in prenatal male germ cells, perturbations in methylation could contribute to the epigenetic basis of the paternal effects in Dnmt3L(+/-) males. STUDY DESIGN, SIZE, DURATION: This is a cross-sectional study of DNA methylation in Dnmt3L(+/+) versus Dnmt3L(+/-) male germ cells collected from mice at 16.5 days post-coitum (dpc), Day 6 and Day 70 (n = 3 per genotype, each n represents a pool of 2-20 animals). Additionally, DNA methylation was compared in enriched populations of spermatogonial stem cells (SSC)/progenitor cells from Dnmt3L(+/+) and Dnmt3L(+/-) males following ≈ 2 months in culture. MATERIALS, SETTING, METHODS: DNA methylation at intergenic loci along chromosomes 9 and X was examined by quantitative analysis of DNA methylation by real-time polymerase chain reaction at the time of initial acquisition of epigenetic patterns in the prenatal male germline (16.5 dpc) and compared with patterns in early post-natal spermatogonia (Day 6) and in spermatozoa in mice. DNA methylation status at CpG-rich sites across the genome was assessed in spermatogonial precursors from Day 4 male mice using restriction landmark genomic scanning. MAIN RESULTS AND THE ROLE OF CHANCE: At 16.5 dpc, 42% of intergenic loci examined along chromosome 9 and 10% of those along chromosome X were hypomethylated in Dnmt3L heterozygotes. By Day 6 and in spermatozoa, germ cell DNA methylation was similar in heterozygous and wild-type mice. DNA methylation stability of acquired patterns in wild-type and Dnmt3L(+/-) SSC/progenitor cell culture was analyzed at numerous loci across the genome in cells cultured in vitro and collected at passages 6-28. While the methylation of most loci was stable in culture over time, differences at ≈ 1% of sites were found between Dnmt3L(+/-) and Dnmt3L(+/+) cultures. LIMITATIONS, REASONS FOR CAUTION: Evaluation of DNA methylation in SSCs can only be performed after a period of culture limiting the investigation to changes observed during culture when compared with DNA methylation differences between genotypes that could be present at the beginning of culture establishment. WIDER IMPLICATIONS OF THE FINDINGS: The DNA methylation defects described here in prenatal male germline progenitor cells and SSC culture are the earliest epigenetic perturbations yet identified for a mammalian paternal-effect gene and may influence downstream epigenetic events in germ cells at later stages of development. Together, the results provide evidence of a 'window' of susceptibility in prenatal male germ cell precursors for the induction of epimutations due to genetic perturbations and, potentially, in utero environmental exposures.

Developmental acquisition of genome-wide DNA methylation occurs prior to meiosis in male germ cells.

The development of germ cells is a highly ordered process that begins during fetal growth and is completed in the adult. Epigenetic modifications that occur in germ cells are important for germ cell function and for post-fertilization embryonic development. We have previously shown that male germ cells in the adult mouse have a highly distinct epigenetic state, as revealed by a unique genome-wide pattern of DNA methylation. Although it is known that these patterns begin to be established during fetal life, it is not known to what extent DNA methylation is modified during spermatogenesis. We have used restriction landmark genomic scanning (RLGS) and other techniques to examine DNA methylation at multiple sites across the genome during postnatal germ cell development in the mouse. Although a significant proportion of the distinct germ cell pattern is acquired prior to the type A spermatogonial stage, we find that both de novo methylation and demethylation occur during spermatogenesis, mainly in spermatogonia and spermatocytes in early meiotic prophase I. Alterations include predominantly non-CpG island sequences from both unique loci and repetitive elements. These modifications are progressive and are almost exclusively completed by the end of the pachytene spermatocyte stage. These studies better define the developmental timing of genome-wide DNA methylation pattern acquisition during male germ cell development.

Sex-specific promoters regulate Dnmt3L expression in mouse germ cells.

BACKGROUND: Dnmt3L, a member of the DNA methyltransferase 3 family, lacks enzymatic activity but is required for de-novo methylation of imprinted genes in oocytes and for transposon repression in male germ cells. METHODS: We used northern blots, RT-PCR, 5' rapid amplification of complementary DNA (cDNA) ends (RACE), RNase H mapping, real-time/quantitative RT-PCR and in situ hybridization to identify and characterize Dnmt3L transcripts produced during germ cell development. RESULTS: Mouse Dnmt3L uses three sex-specific promoters, not the single promoter previously thought. A promoter active in prospermatogonia drives transcription of an mRNA encoding the full-length protein in perinatal testis, where de-novo methylation occurs. Late pachytene spermatocytes activate a second promoter in intron 9 of the Dnmt3L gene. After this stage, the predominant transcripts are three truncated mRNAs, which appear to be non-coding. We could also detect similar adult testis transcripts in humans. In the mouse ovary, an oocyte-specific promoter located in an intron of the neighbouring autoimmune regulator (Aire) gene produces a transcript with the full open reading frame (ORF). This is the only Dnmt3L transcript found in growing oocytes and is absent in the oocytes of Dnmt3L-/- females. CONCLUSIONS: Sex-specific promoters control Dnmt3L expression in the mouse germ line, mirroring the situation at the Dnmt1 and Dnmt3A loci.

A unique configuration of genome-wide DNA methylation patterns in the testis.

In the mammalian lifecycle, the two periods of genome-wide epigenetic reprogramming are in the early embryo, when somatic patterns are set, and during germ cell development. Although some differences between the reprogrammed states of somatic and germ cells have been reported, overall patterns of genomic methylation are considered to be similar. Using restriction landmark genomic scanning to examine approximately 2,600 loci distributed randomly throughout the genome, we find that the methylation status of testicular DNA is highly distinct, displaying eightfold the number of hypomethylated loci relative to somatic tissues. Identification and analysis of >300 loci show that these regions are generally located within nonrepetitive sequences that are away from CpG islands and 5' regions of genes. We show that a contributing factor for these differences is that the methylation state of non-CpG-island DNA is correlated with the regional level of GC content within chromosomes and that this relationship is inverted between the testis and somatic tissues. We also show that in Dnmt3L-deficient mice, which exhibit infertility associated with abnormal chromosomal structures in germ cells, this unique testicular DNA methylation pattern is not established. These special properties of testicular DNA point to a broad, distinct epigenetic state that may be involved in maintaining a unique chromosomal structure in male germ cells.

Reproductive epigenetics.

Epigenetics refers to covalent modifications of DNA and core histones that regulate gene activity without altering DNA sequence. To date, the best-characterized DNA modification associated with the modulation of gene activity is methylation of cytosine residues within CpG dinucleotides. Human disorders associated with epigenetic abnormalities include rare imprinting diseases, molar pregnancies, and childhood cancers. Germ cell development and early embryo development are critical times when epigenetic patterns are initiated or maintained. This review focuses on the epigenetic modification DNA methylation and discusses recent progress that has been made in understanding when and how epigenetic patterns are differentially established in the male and female germlines, the mouse, and human disorders associated with abnormalities in epigenetic programming in germ cells and early embryos, as well as genetic and other modulators (e.g. nutrition and drugs) of reproductive epigenetic events.

Infertility and testicular defects in hormone-sensitive lipase-deficient mice.

The 84-kDa hormone-sensitive lipase (gene designation Lipe; EC 3.1.1.3) is a cholesterol esterase and triglyceride hydrolase that functions in the release of fatty acids from adipocytes. The role of hormone-sensitive lipase in other tissues such as the testis, where a specific 120-kDa testis-specific isoform is expressed, is unknown. To study this, we examined the fertility and testicular histology of gene-targeted hormone-sensitive lipase-deficient mice. Homozygous hormone-sensitive lipase-deficient male mice are infertile and have decreased testis weights; female homozygotes are fertile. Testicular abnormalities, detected at the light and electron microscopic levels, included the presence of multinucleated round and elongating spermatids, vacuolization of the seminiferous epithelium, asynchronization of the spermatogenic cycle, sloughing of postmeiotic germ cells from the seminiferous epithelium into the lumen, and a marked reduction in the numbers of late spermatids. Extensive nuclear head deformation was noted in late spermatids as well as the sharing of a common acrosome in multinucleated cells. In some multinucleated cells, nuclei were separated from their acrosomes, with the acrosomes remaining attached to areas of ectoplasmic specializations, suggesting defects in intercellular cytoplasmic bridge integrity. Although the lumen of the epididymis was essentially devoid of spermatozoa and filled instead with spherical degenerating cells, the epididymal epithelial cells appeared normal. The few late spermatids present in the epididymis were abnormal. There was no morphological evidence, as judged by the absence of lipid droplets of triacylglycerol or cholesteryl ester accumulation in the testis. Together, the data suggest that hormone-sensitive lipase deficiency results in abnormalities in spermiogenesis that are incompatible with normal fertility. We speculate that a metabolite downstream from the hormone-sensitive lipase reaction may be essential for membrane stabilization and integrity in the seminiferous epithelium and, in particular, may play an important role in the maintenance of intercellular cytoplasmic bridges between postmeiotic germ cells.

Genomic imprinting disrupted by a maternal effect mutation in the Dnmt1 gene.

Maintenance of genomic methylation patterns in mammalian somatic cells depends on DNA methyltransferase-1 (Dnmt1). Mouse oocytes and preimplantation embryos lack Dnmt1 but express a variant of this protein called Dnmt1o. We eliminated Dnmt1o by deletion of the oocyte-specific promoter and first exon from the Dnmt1 locus. Homozygous animals were normal, but most heterozygous fetuses of homozygous females died during the last third of gestation. Although genomic methylation patterns were established normally in Dnmt1o-deficient oocytes, embryos derived from such oocytes showed a loss of allele-specific expression and methylation at certain imprinted loci. Transient nuclear localization of Dnmt1o in 8-cell embryos suggests that this variant of Dnmt1 provides maintenance methyltransferase activity specifically at imprinted loci during the fourth embryonic S phase.

Deoxyribonucleic acid hypomethylation of male germ cells by mitotic and meiotic exposure to 5-azacytidine is associated with altered testicular histology.

Genomic methylation patterns originate during gametogenesis and are postulated to be involved in important developmental events, including gene regulation, embryogenesis, and genomic imprinting. In previous work, treatment of male rats with 5-azacytidine, a drug that blocks DNA methylation, resulted in abnormal embryo development when germ cells were exposed throughout spermatogenesis, encompassing mitotic, meiotic, and postmeiotic development, but not if they were only exposed postmeiotically. To explore the mechanisms underlying the effects of 5-azacytidine on sperm function, we determined the effects of the drug on testicular morphology, assessed whether exposure of meiotic spermatocytes resulted in abnormal pregnancy outcome, and examined the role of germ cell genomic demethylation in mediating the effects of 5-azacytidine on spermatogonia and spermatocytes. Male Sprague Dawley rats were treated three times a week with saline or 5-azacytidine (2.5 and 4.0 mg/kg) for 6 weeks (meiotic and postmeiotic germ cell exposure) and 11 weeks (mitotic, meiotic, and postmeiotic exposure). Six weeks of paternal treatment with the highest dose of 5-azacytidine resulted in an increase in preimplantation loss (corpora lutea minus implantation sites) without affecting testicular morphology or altering sperm DNA methylation levels. Eleven weeks of 5-azacytidine treatment at doses that cause preimplantation loss resulted in severe abnormalities of the seminiferous tubules, such as degeneration and loss of germ cells, atrophy of seminiferous tubules, presence of multinuclear giant cells, and sloughing of immature germ cells into the lumen, and a 22-29% decrease in genomic methylation levels in epididymal sperm. On closer evaluation of testicular histology using terminal deoxynucleotidyl transferase-mediated deoxy-UTP nick end-labeling detection in situ, both 6 and 11 weeks of 5-azacytidine treatment resulted in an increase over the control value in the number of apoptotic germ cells in the seminiferous tubules. Analysis of DNA methylation levels in isolated germ cells of treated males indicated that spermatogonia were more susceptible to the hypomethylating effects of 5-azacytidine than were spermatocytes. These studies provide evidence of an association between demethylation of germ cell DNA and alterations in testicular histology.

I. Abnormalities in cells of the testis, efferent ducts, and epididymis in juvenile and adult mice with beta-hexosaminidase A and B deficiency.

Beta-hexosaminidase (Hex) is a lysosomal enzyme that exists as two major isoenzymes: Hex A (subunit structure, alphabeta) and Hex B (betabeta). The presence of Hex in the testis and epididymis suggests important roles for the enzyme and its substrates in male fertility and reproductive functions. Disruption of the Hexb gene encoding the beta-subunit of Hex has led to the generation of a mouse model of human Sandhoff disease that survives to adulthood, enabling us to analyze the effects of Hex A and Hex B deficiency on epithelial cellular morphology of the male reproductive tract. At 1 and 3 months of age, the testes, efferent ducts, and epididymides of Hex-deficient (Hexb -/-) and wild-type (Hexb +/+) mice were perfuse fixed and analyzed by routine light and electron microscopy (LM and EM, respectively) as well as with immunocytochemistry employing antibodies to lysosomal proteins. In the testis, the morphological appearance and topographical arrangement of the cell types of the seminiferous epithelium of Hexb -/- mice were similar to those of wild-type animals at both ages. Both Sertoli and germ cells appeared to be unaffected. However, at both ages, myoid cells and macrophages showed an increased number of lysosomes in their cytoplasm as compared with the number seen in controls. The epithelial cells of the efferent ducts also showed an accumulation of lysosomes that increased with age as compared with controls. Principal cells of the entire epididymis revealed an increase in the size and number of lysosomes at 1 month of age as compared with those of controls, and by 3 months, these lysosomes often filled the supranuclear and basal regions of the cells. Narrow cells of the distal initial segment and intermediate zone, normally slender cells showing several lysosomes, became greatly enlarged and entirely filled with lysosomes in Hexb -/- mice. Clear cells of the caput, corpus, and cauda regions also showed a progressive increase in the size and number of lysosomes with age as compared with controls; the clear cells of the mutant mice were often enlarged and at times bulged into the lumen. Some basal cells of each epididymal region in Hexb -/- mice were similar to controls at 1 and 3 months, showing few lysosomes, while others showed an accumulation of lysosomes. Lysosomes of all affected epithelial cells were of varying sizes, but many large ones were present, apparently resulting from lysosomal fusion. Although pale stained, their identification as lysosomes was confirmed by EM immunocytochemistry with anti-cathepsin D and anti-Hex A antibodies. Predominantly in the proximal initial segment, large, pale cellular aggregates were noted in the LM analysis at the base of the epithelium, which by EM analysis were identified as belonging to two different cell types, narrow cells and halo cells. Taken together, these data reveal an increase in the size and number of lysosomes in all epithelial cell types lining the efferent ducts and entire epididymis as well as in myoid cells and macrophages of the testis. In the light of data showing epididymal defects restricted predominantly to the initial segment in Hexa -/- (Hex A-deficient) mice, our data on the Hexb -/- mice demonstrate a major role for Hex that can be fulfilled by either Hex A or Hex B in the epididymis.

II. Characterization and development of the regional- and cellular-specific abnormalities in the epididymis of mice with beta-hexosaminidase A deficiency.

Beta-hexosaminidase (Hex) is a lysosomal enzyme that exists as two isoenzymes: Hex A (subunit structure alphabeta) and Hex B (betabeta). Its presence in the testis and epididymis suggests important roles for Hex and its substrates in male fertility and reproductive functions. Disruption of the Hexa gene encoding the alpha-subunit of Hex has led to the generation of a mildly affected mouse model of human Tay-Sachs disease, allowing us the opportunity to analyze the effects of isolated Hex A deficiency on epithelial cellular morphology of the male reproductive tract. At 5 weeks and at 3, 5, and 12 months, the testes, efferent ducts and epididymides of Hex A-deficient (Hexa -/-) and wild-type (Hexa +/+) mice were perfuse fixed and analyzed by routine light and electron microscopy as well as with immunocytochemistry employing antibodies to lysosomal enzymes. In the testis, the seminiferous epithelium of Hexa -/- mice appeared comparable to that of wild-type mice in appearance and topographical arrangement of its cell types at all ages examined. Also, no differences were noted for the efferent ducts. In contrast, there were striking abnormalities in the epididymides of the mutant mice; however, the abnormalities were mainly restricted to the initial segment and intermediate zone. Principal cells of these regions at 5 weeks showed a dramatic increase in the number of lysosomes as compared with those from wild-type animals, and this progressed with increasing age. Furthermore, unlike the few small lysosomes present in wild-type mice, those of Hexa -/- mice were at times enlarged and often filled the supranuclear and basal regions of these cells. In the light microscope, large, dense cellular aggregates were noted at the base of the epithelium in the proximal initial segment that corresponded in the electron microscope to two different cell types, both of which increased in size with age. One aggregate was considered to belong to narrow cells on the basis of the presence of numerous cup-shaped vesicles characteristic of these cells; they appeared to be dislocated from the upper half of the epithelium. In the distal initial segment and intermediate zone, narrow cells were readily identified, but rather than being slender as in the control animals, they were greatly enlarged and filled with pale lysosomes in mutant mice. The second type of cellular aggregate noted in the proximal initial segment corresponded to halo cells. They contained numerous small and large lysosomes and small, Golgi-related, dense, core granules characteristic of halo cells. On the basis of the large size of these cells, they appeared to be actively internalizing substances from the intercellular space. In contrast, principal and clear cells of the caput, corpus, and cauda regions did not appear to show a significant increase in number or size of lysosomes as compared with those of wild-type animals. All structures identified as lysosomes in the various cell types were immunoreactive for cathepsin D. The present data thus reveal that isolated Hex A deficiency results in region- and cell-specific abnormalities in the epididymis but in no apparent abnormalities in the testis or efferent ducts. Specific roles for Hex A that cannot be compensated for by other isozymes of Hex appear to exist within lysosomes of epithelial cells predominantly of the initial segment and intermediate zone. Taken together, the results also suggest that the inability to degrade endocytosed substrates normally acted upon by Hex A in lysosomes of principal and narrow cells leads to their accumulation, eventual fusion, and increased size.

Cellular immunolocalization of occludin during embryonic and postnatal development of the mouse testis and epididymis.

Cellular junctions in the testis and epididymis play crucial roles for the development and maturation of spermatozoa. In the testis, tight junctions between Sertoli cells form a functional blood testis barrier between 10 and 16 days of age, whereas the tight junctional blood epididymal barrier between adjacent epithelial cells is formed between days 18 and 21. In the present study, occludin, a constituent integral membrane protein of tight junctions, was localized by immunofluorescent confocal microscopy in embryonic (days 13.5-18.5), postnatal (days 5-23) and adult (day 70) mouse testes and epididymides to correlate its expression with the onset of tight junctions and eventual formation of these barriers. At embryonic days 13.5 and 16.5, low diffuse cytoplasmic levels of occludin were observed in cells of the testicular cords. By embryonic day 18.5, the level of occludin was still low but appeared as a filiform-like network streaming toward the center of the cord. At postnatal days 5 and 7 immunostaining became more intense and appeared to outline the periphery of Sertoli cells of seminiferous tubules. Postnatal day 14 marked the appearance of an intense, focal band-like localization of occludin at the base of the tubules, correlating with the appearance of a functional blood-testis barrier. By day 23 and in adults, expression of occludin was noted at the base of the tubule appearing as intense, wavy, discontinuous bands similar in appearance irrespective of the stage of the seminiferous epithelium cycle. In the developing epididymis, intense cytoplasmic immunostaining was present in epithelial cells of many epididymal tubules at embryonic day 13.5. By embryonic day 16.5, intense occludin immunostaining appeared along the lateral plasma membranes of epithelial cells, whereas at embryonic day 18.5, immunostaining was punctate and apically located, suggesting the presence of tight junctions by this age; similar immunostaining was noted at postnatal days 5 and 7. In the adult epididymis, distinct punctate apical staining was observed between adjacent principal cells of all epididymal regions except the proximal initial segment, where occludin was found only in association with narrow cells. These results indicate that in the epididymis, the appearance of occludin at apical sites between adjacent epithelial cells occurs during embryonic development suggesting that tight junctions form earlier than in the testis. While occludin was expressed in a similar pattern between Sertoli cells at all stages of the cycle in the adult testis, its expression in the adult epididymis was cell- and region-specific. Taken together these data suggest that different factors regulate occludin expression in the testis and epididymis.

Acquisition of the H19 methylation imprint occurs differentially on the parental alleles during spermatogenesis.

The imprinted mouse H19 gene is hypomethylated on the expressed maternal allele and hypermethylated on the silent paternal allele. A 2-kb region of differential methylation located from -2 to -4 kb relative to the H19 transcriptional start site has been proposed to act as the imprinting mark since hypermethylation in this region is inherited from sperm and retained on the paternal allele throughout development. Here, we describe a temporal analysis of the methylation patterns at the H19 locus during postnatal male germ cell development. The 2-kb region is methylated on the paternal allele throughout spermatogenesis, suggesting that methylation is acquired in this region prior to the resumption of mitosis in postnatal male mice. Likewise, more than half of the maternal alleles are hypermethylated prior to the resumption of mitosis. However, the remaining maternal alleles are not hypermethylated until the completion of meiosis I, indicating that de novo methylation in this region is a continuous process. Sequences proximal to the H19 promoter, which are methylated in spermatozoa and on the paternal allele in somatic cells, are differentially methylated in diploid, mitotic spermatogonia. The maternal allele becomes hypermethylated in this region during meiotic prophase. Thus, the parental H19 alleles acquire methylation differentially in the male germline.

Sialidase-mediated depletion of GM2 ganglioside in Tay-Sachs neuroglia cells.

Tay-Sachs disease is a severe, inherited disease of the nervous system caused by accumulation of the brain lipid GM2 ganglioside. Mouse models of Tay-Sachs disease have revealed a metabolic bypass of the genetic defect based on the more potent activity of the enzyme sialidase towards GM2. To determine whether increasing the level of sialidase would produce a similar effect in human Tay-Sachs cells, we introduced a human sialidase cDNA into neuroglia cells derived from a Tay-Sachs fetus and demonstrated a dramatic reduction in the accumulated GM2. This outcome confirmed the reversibility of GM2 accumulation and opens the way to pharmacological induction or activation of sialidase for the treatment of human Tay-Sachs disease.

Origin and roles of genomic methylation patterns in male germ cells.

The epigenetic modification of DNA by methylation at cytosine residues is initiated in the germ line and is required for normal embryonic development in mammals. Marked differences in genomic methylation between male and female gametes arise during gametogenesis and have been implicated in genomic imprinting. While DNA methylation patterns for different types of gene sequences are known to change during spermatogenesis, the precise role(s) of DNA methylation in the normal development of male germ cells is poorly understood. The expression of the one known active form of DNA methyltransferase is highly regulated during spermatogenesis and may provide insight into mechanisms underlying the establishment of methylation patterns in germ cells.

Characterization of the testis and epididymis in mouse models of human Tay Sachs and Sandhoff diseases and partial determination of accumulated gangliosides.

Beta-hexosaminidase (Hex) is an essential lysosomal enzyme whose activity is higher in the epididymis than in other tissues. The enzyme is also present in sperm and has been postulated to be required for fertilization. To better understand the role of Hex in reproduction, we have examined the testes and epididymides of mouse models of human Tay Sachs and Sandhoff diseases, produced by targeted disruption of the Hexa (alpha-subunit) or Hexb (beta-subunit) genes, respectively, encoding the enzymes Hex A (structure, alphabeta) and Hex B (betabeta). Testis weight, morphology, and sperm counts were unaffected in Hex-deficient mice. In the epididymis of the Hex A-deficient Hexa-/- mice, there was a large increase in the size and number of lysosomes in the initial segment/intermediate zone. In Hexb-/- mice (Hex A and B-deficient), the epididymal defects were much more extensive and the cytoplasm of all cell types throughout the efferent ducts and epididymis was filled with pale, uncondensed, enlarged lysosomes. In contrast to the brain where GM2 ganglioside accumulates, both mutant mice accumulated two non-GM2 gangliosides in the epididymis. The major accumulated species was characterized by electrospray ionization tandem mass spectrometry. The Hexa-/- male mice were fertile; however, litter sizes were reduced. The Hexb-/- males were able to sire normal sized litters up to nine weeks of age and remained healthy until 16-20 weeks of age. The extensive abnormalities in the Hexb-/- mice, in contrast to region-specific effects in the Hexa-/-mice, indicate an important and novel role for the Hex B isozyme in the epididymis and a region-specific role for Hex A in the initial segment/intermediate zone. In contrast to other reports, our results indicate that Hex is not essential for fertilization in young adult male mice. To explain the extensive epididymal abnormalities in the Hexb-/- mice, we propose that substrates for Hex, such as testis-derived glycolipids, cannot be catabolized and accumulate in lysosomes, leading to epididymal dysfunction and abnormalities in the epididymal luminal environment that supports sperm maturation.

Transcription factor GATA-4 is expressed in a sexually dimorphic pattern during mouse gonadal development and is a potent activator of the Müllerian inhibiting substance promoter.

Mammalian gonadal development and sexual differentiation are complex processes that require the coordinated expression of a specific set of genes in a strict spatiotemporal manner. Although some of these genes have been identified, the molecular pathways, including transcription factors, that are critical for the early events of lineage commitment and sexual dimorphism, remain poorly understood. GATA-4, a member of the GATA family of transcription factors, is present in the gonads and may be a regulator of gonadal gene expression. We have analyzed the ontogeny of gonadal GATA-4 expression by immunohistochemistry. GATA-4 protein was detected as early as embryonic day 11.5 in the primitive gonads of both XX and XY mouse embryos. In both sexes, GATA-4 specifically marked the developing somatic cell lineages (Sertoli in testis and granulosa in ovary) but not primordial germ cells. Interestingly, abundant GATA-4 expression was maintained in Sertoli cells throughout embryonic development but was markedly down-regulated shortly after the histological differentiation of the ovary on embryonic day 13.5. This pattern of expression suggested that GATA-4 might be involved in early gonadal development and possibly sexual dimorphism. Consistent with this hypothesis, we found that the Müllerian inhibiting substance promoter which harbors a conserved GATA element is a downstream target for GATA-4. Thus, transcription factor GATA-4 may be a new factor in the cascade of regulators that control gonadal development and sex differentiation in mammals.