Mammalian MutS homologue 5 is required for chromosome pairing in meiosis.

MSH5 (MutS homologue 5) is a member of a family of proteins known to be involved in DNA mismatch repair. Germline mutations in MSH2, MLH1 and GTBP (also known as MSH6) cause hereditary non-polyposis colon cancer (HNPCC) or Lynch syndrome. Inactivation of Msh2, Mlh1, Gtmbp (also known as Msh6) or Pms2 in mice leads to hereditary predisposition to intestinal and other cancers. Early studies in yeast revealed a role for some of these proteins, including Msh5, in meiosis. Gene targeting studies in mice confirmed roles for Mlh1 and Pms2 in mammalian meiosis. To assess the role of Msh5 in mammals, we generated and characterized mice with a null mutation in Msh5. Msh5-/- mice are viable but sterile. Meiosis in these mice is affected due to the disruption of chromosome pairing in prophase I. We found that this meiotic failure leads to a diminution in testicular size and a complete loss of ovarian structures. Our results show that normal Msh5 function is essential for meiotic progression and, in females, gonadal maintenance.

Genetic analysis of chromosome pairing, recombination, and cell cycle control during first meiotic prophase in mammals.

Meiosis is a double-division process that is preceded by only one DNA replication event to produce haploid gametes. The defining event in meiosis is prophase I, during which chromosome pairs locate each other, become physically connected, and exchange genetic information. Although many aspects of this process have been elucidated in lower organisms, there has been scant information available until now about the process in mammals. Recent advances in genetic analysis, especially in mice and humans, have revealed many genes that play essential roles in meiosis in mammals. These include cell cycle-regulatory proteins that couple the exit from the premeiotic DNA synthesis to the progression through prophase I, the chromosome structural proteins involved in synapsis, and the repair and recombination proteins that process the recombination events. Failure to adequately repair the DNA damage caused by recombination triggers meiotic checkpoints that result in ablation of the germ cells by apoptosis. These analyses have revealed surprising sexual dimorphism in the requirements of different gene products and a much less stringent checkpoint regulation in females. This may provide an explanation for the 10-fold increase in meiotic errors in females compared with males. This review provides a comprehensive analysis of the use of genetic manipulation, particularly in mice, but also of the analysis of mutations in humans, to elucidate the mechanisms that are required for traverse through prophase I.

Control of spermatogenesis in mice by the cyclin D-dependent kinase inhibitors p18(Ink4c) and p19(Ink4d).

Male mice lacking both the Ink4c and Ink4d genes, which encode two inhibitors of D-type cyclin-dependent kinases (Cdks), are infertile, whereas female fecundity is unaffected. Both p18(Ink4c) and p19(Ink4d) are expressed in the seminiferous tubules of postnatal wild-type mice, being largely confined to postmitotic spermatocytes undergoing meiosis. Their combined loss is associated with the delayed exit of spermatogonia from the mitotic cell cycle, leading to the retarded appearance of meiotic cells that do not properly differentiate and instead undergo apoptosis at an increased frequency. As a result, mice lacking both Ink4c and Ink4d produce few mature sperm, and the residual spermatozoa have reduced motility and decreased viability. Whether or not Ink4d is present, animals lacking Ink4c develop hyperplasia of interstitial testicular Leydig cells, which produce reduced levels of testosterone. The anterior pituitary of fertile mice lacking Ink4c or infertile mice doubly deficient for Ink4c and Ink4d produces normal levels of luteinizing hormone (LH). Therefore, the failure of Leydig cells to produce testosterone is not secondary to defects in LH production, and reduced testosterone levels do not account for infertility in the doubly deficient strain. By contrast, Ink4d-null or double-null mice produce elevated levels of follicle-stimulating hormone (FSH). Because Ink4d-null mice are fertile, increased FSH production by the anterior pituitary is also unlikely to contribute to the sterility observed in Ink4c/Ink4d double-null males. Our data indicate that p18(Ink4c) and p19(Ink4d) are essential for male fertility. These two Cdk inhibitors collaborate in regulating spermatogenesis, helping to ensure mitotic exit and the normal meiotic maturation of spermatocytes.

Colony-stimulating factor-1 plays a major role in the development of reproductive function in male mice.

Colony-stimulating factor-1 (CSF-1) is the principal regulator of cells of the mononuclear phagocytic lineage that includes monocytes, tissue macrophages, microglia, and osteoclasts. Macrophages are found throughout the reproductive tract of both males and females and have been proposed to act as regulators of fertility at several levels. Mice homozygous for the osteopetrosis mutation (csfm[op]) lack CSF-1 and, consequently, have depleted macrophage numbers. Further analysis has revealed that male csfm(op)/csfm(op) mice have reduced mating ability, low sperm numbers, and 90% lower serum testosterone levels. The present studies show that this low serum testosterone is due to reduced testicular Leydig cell steroidogenesis associated with severe ultrastructural abnormalities characterized by disrupted intracellular membrane structures. In addition, the Leydig cells from csfm(op)/ csfm(op) males have diminished amounts of the steroidogenic enzyme proteins P450 side chain cleavage, 3beta-hydroxysteroid dehydrogenase, and P450 17alpha-hydroxylase-lyase, with associated reductions in the activity of all these steroidogenic enzymes, as well as in 17beta-hydroxysteroid dehydrogenase. The CSF-1-deficient males also have reduced serum LH and disruption of the normal testosterone negative feedback response of the hypothalamus, as demonstrated by the failure to increase LH secretion in castrated males and their lack of response to exogenous testosterone. However, these males are responsive to GnRH and LH treatment. These studies have identified a novel role for CSF-1 in the development and/or regulation of the male hypothalamic-pituitary-gonadal axis.

Macrophages: important accessory cells for reproductive function.

Macrophages are found throughout reproductive tissues. To determine their role(s), we have studied mice homozygous for a null mutation (Csfm(op)) in the gene encoding the major macrophage growth factor, colony-stimulating factor-1 (CSF-1). Both male and female Csfm(op)/Csfm(op) mice have fertility defects. Males have low sperm number and libido as a consequence of dramatically reduced circulating testosterone. Females have extended estrous cycles and poor ovulation rates. CSF-1 is the principal growth factor regulating macrophage populations in the testis, male accessory glands, ovary, and uterus. However, analyses of CSF-1 nullizygous mice suggest that the primary reproductive defect is in the development of feedback regulation of the hypothalamic-pituitary axis. Although not correlating with deficiencies of microglia populations, electrophysiological investigations indicate an impairment of neuronal responses. This suggests that microglia, under the influence of CSF-1, act to organize neuronal connectivity during development and that the absence of this function results in a perturbation of the hypothalamic-pituitary-gonadal axis. Macrophages also appear to have functions in the differentiated tissues of the reproductive system, including having a positive influence on steroidogenic cells. These data suggest that macrophages, through their trophic functions, can be considered as essential accessory cells for normal reproductive functioning.

Normal sexual function in male mice lacking a functional type I interleukin-1 (IL-1) receptor.

Previous studies have shown that macrophages and their cytokine products, particularly interleukin-1 (IL-1) and tumor necrosis factor-alpha (TNF alpha), regulate testicular Leydig cell steroidogenesis in vitro and in vivo. However, the data concerning IL-1 have been somewhat contradictory, showing both inhibitory and stimulatory effects of IL-1 depending on the experimental conditions. In the present studies, mice lacking a functional type I IL-1 receptor (IL-1R]; the only IL-1 receptor subtype capable of IL-1-induced signal transduction) were used to examine the role of this cytokine in vivo. The data show that the absence of IL-1 signal transduction has no effect on steroidogenic enzyme concentrations within the Leydig cells, and the males have normal serum testosterone concentrations. Moreover, epididymal sperm numbers are normal in IL-1RI nullizygous males in contrast to recent reports of a role for IL-1 in germ cell proliferation and DNA synthesis. Taken together these observations suggest that IL-1 signalling is not essential for Leydig cell function or spermatogenesis in vivo and highlight the need to reassess many of the current methods of experimental approaches for examining cytokine function in vitro.

Novel and diverse functions of the DNA mismatch repair family in mammalian meiosis and recombination.

The mismatch repair (MMR) family is a highly conserved group of proteins that function in genome stabilization and mutation avoidance. Their role has been particularly well studied in the context of DNA repair following replication errors, and disruption of these processes results in characteristic microsatellite instability, repair defects and, in mammals, susceptibility to cancer. An additional role in meiotic recombination has been described for several family members, as revealed by extensive studies in yeast. More recently, the role of the mammalian MMR family in meiotic progression has been elucidated by the phenotypic analysis of mice harboring targeted mutations in the genes encoding several MMR family members. This review will discuss the phenotypes of the various mutant mouse lines and, drawing from our knowledge of MMR function in yeast meiosis and in somatic cell repair, will attempt to elucidate the significance of MMR activity in mouse germ cells. These studies highlight the importance of comparative analysis of MMR orthologs across species, and also underscore distinct sexually dimorphic characteristics of mammalian recombination and meiosis.

Silastic implants for delivering physiological concentrations of progesterone to mice.

Silastic implants filled with progesterone in arachis oil were designed to provide a convenient and reliable method for the delivery of physiological concentrations of progesterone to mice. Placement of the implants in ovariectomized mice resulted in a rapid increase in circulating progesterone within 6 h; stable levels could be maintained for many days. Removal of the implants resulted in a very rapid fall in progesterone concentrations. The delivery of progesterone from the implants could be controlled by varying both the length of the implants and the concentration of progesterone internally. This allowed plasma progesterone concentrations to be maintained and controlled over the entire physiological range.

Silastic implants for delivery of oestradiol to mice.

Silastic implants containing oestradiol were developed for delivering a range of physiological concentrations of oestradiol to mice over long periods. The implants consisted of discrete lengths of Silastic tubing containing oestradiol in arachis oil, with a small reservoir of the oestradiol solution at either end of the implant. Studies showed that the release of oestradiol in vitro was proportional to the concentration of steroid within the implant. Implants containing oestradiol at concentrations from 1 to 100 micrograms ml-1 could induce biological responses in ovariectomized mice, ranging from minimal effects on uterine weight and vaginal smears to supraphysiological increases in uterine weight and rapid vaginal cornification. Studies of uterine vascular permeability indicated that significant effects occurred within a few hours of initial placement of the implant. These results suggest that the design of the Silastic implants described in this study provides a useful method for delivering controlled and easily manipulated physiological doses of oestradiol to mice.

Regulation of meiotic recombination and prophase I progression in mammals.

Meiosis is the process by which diploid germ cells divide to produce haploid gametes for sexual reproduction. The process is highly conserved in eukaryotes, however the recent availability of mouse models for meiotic recombination has revealed surprising regulatory differences between simple unicellular organisms and those with increasingly complex genomes. Moreover, in these higher eukaryotes, the intervention of physiological and sex-specific factors may also influence how meiotic recombination and progression are monitored and regulated. This review will focus on the recent studies involving mouse mutants for meiosis, and will highlight important differences between traditional model systems for meiosis (such as yeast) and those involving more complex cellular, physiological and genetic criteria.

Absence of colony stimulating factor-1 in osteopetrotic (csfmop/csfmop) mice disrupts estrous cycles and ovulation.

Colony stimulating factor-1 (CSF-1) is a hematopoietic growth factor required for the recruitment, proliferation, and differentiation of mononuclear phagocytes. In addition, CSF-1 is expressed in the female reproductive tract coincident with CSF-1 receptor localization on preovulatory oocytes, ovarian and uterine macrophages, decidual cells, and trophoblast. A role for CSF-1 in female reproduction was confirmed by studies on CSF-1-deficient, osteopetrotic (csfmop/csfmop) mice, which suffer from low pregnancy rates and smaller litter sizes compared to wild-type mice. The present study was designed to determine the exact causes of the preimplantation fertility defects in these mutant mice. Female csfmop/csfmop mice have extended estrous cycles compared to wild-type females, and s.c. administration of CSF-1 from birth restores estrous cyclicity. These mice fail to display the characteristic proestrous surge in circulating estradiol-17beta. However, concentrations of this hormone are normal during the remainder of the cycle. Furthermore, csfmop/csfmop females have significantly lower ovulation rates than wild-type mice, but the implantation rates of fertilized oocytes are normal. Serum pregnancy concentrations of progesterone are also normal in csfmop/csfmop females, in line with the relatively normal progression of pregnancy in these mice. Thus, the major effect of CSF-1 on female reproductive function is on the frequency and rate of ovulation, indicating a major role for this growth factor in regulating follicular development and ovulation.

The minimum requirements for oestradiol to induce uterine sensitivity for implantation and decidualization in mice.

Steroid-containing s.c. silastic capsules with known physiological release characteristics were used to study the control of implantation and the induction of uterine sensitivity in ovariectomized mice. In mated, ovariectomized animals maintained on progesterone, the implantation sites were detected after approximately 12 h of oestradiol exposure, and alkaline phosphatase activity at the implantation sites developed within 21 h. Implantation could be induced in > 60% of animals by 4 h exposure to an oestradiol implant, in which time approximately 1.6 ng oestradiol would have been delivered. Continuous delivery of a low dose of oestradiol near the threshold for implantation induced a full complement of implantation sites in the responding animals. The sensitivity of implantation to low amounts of oestradiol suggests that this response is at least as sensitive as either the induction of vaginal cornification or the stimulation of uterine weight. The minimum time for the induction of uterine sensitivity when oestradiol and progesterone treatment were started simultaneously was approximately 36 h. The use of slow-release oestradiol-containing capsules provides a good model to investigate the roles of oestradiol in initiating and defining the 'implantation window'.

Effect of the colony-stimulating factor-1 null mutation, osteopetrotic (csfm(op)), on the distribution of macrophages in the male mouse reproductive tract.

Macrophages are found throughout the male reproductive tract and its accessory glands. Mice homozygous for a null mutation (csfm(op)) in the gene for the mononuclear phagocytic growth factor colony-stimulating factor-1 (CSF-1) have a significantly lower density of macrophages, defined by the mononuclear phagocytic antigen F4/80, in the testis, cauda and caput epididymis, prostate, seminal vesicles, and vas deferens. These data indicate that CSF-1 is the major growth factor regulating the occurrence of macrophages in male reproductive tissues. The residual macrophages were correctly located in the tissue except in the caput epididymis, where they failed to take up positions adjacent to the tubular epithelium. Restoration of circulating CSF-1 concentrations in csfm(op)/csfm(op) males totally restored F4/80+ cell density in the testis and caput and cauda epididymis and partially restored their density in the vas deferens and seminal vesicles but failed to affect density in the prostate. This failure to correct all populations with circulating CSF-1 suggests the requirement for local synthesis of CSF-1 at appropriate developmental stages and/or its expression in a cell surface-associated form. The absence of macrophages in the testis and epididymis of csfm(op)/csfm(op) mice correlates with dysfunction in these tissues, suggesting that macrophages play important nonimmunological roles in these tissues.

Absence of colony-stimulating factor-1 in osteopetrotic (csfmop/csfmop) mice results in male fertility defects.

Previous studies have shown that the mononuclear phagocyte growth factor, colony-stimulating factor-1 (CSF-1), has an important role in female reproduction. Mating experiments with osteopetrotic (csfmop/csfmop) mice, which possess an inactivating mutation in the CSF-1 gene, suggested that there are male, as well as female, reproductive defects. In the present study, we have shown that male csfmop/csfmop mice have a sevenfold lower concentration of circulating testosterone (T) and a significantly lower intratesticular T concentration than wild-type mice. These lowered T concentrations were associated with a reduction in mating capability and a reduction in the number of viable sperm. Reconstitution of male csfmop/csfmop mice with either circulating T in the adult or circulating CSF-1 throughout the postnatal period completely restored viable sperm numbers and significantly restored sexual behavior. These observations, coupled with the close association of Leydig cells with testicular macrophages and the proposed function of these macrophages in the regulation of Leydig cell steroidogenesis, suggest that CSF-1-regulated testicular macrophages play an important role in male reproduction.

MutS homolog 4 localization to meiotic chromosomes is required for chromosome pairing during meiosis in male and female mice.

Msh4 (MutS homolog 4) is a member of the mammalian mismatch repair gene family whose members are involved in postreplicative DNA mismatch repair as well as in the control of meiotic recombination. In this report we show that MSH4 has an essential role in the control of male and female meiosis. We demonstrate that MSH4 is present in the nuclei of spermatocytes early in prophase I and that it forms discrete foci along meiotic chromosomes during the zygotene and pachytene stages of meiosis. Disruption of the Msh4 gene in mice results in male and female sterility due to meiotic failure. Although meiosis is initiated in Msh4 mutant male and female mice, as indicated by the chromosomal localization of RAD51 and COR1 during leptonema/zygonema, the chromosomes fail to undergo normal pairing. Our results show that MSH4 localization on chromosomes during the early stages of meiosis is essential for normal chromosome synapsis in prophase I and that it acts in the same pathway as MSH5.

Meiotic pachytene arrest in MLH1-deficient mice.

Germ line mutations in DNA mismatch repair genes including MLH1 cause hereditary nonpolyposis colon cancer. To understand the role of MLH1 in normal growth and development, we generated mice that have a null mutation of this gene. Mice homozygous for this mutation show a replication error phenotype, and extracts of these cells are deficient in mismatch repair activity. Homozygous mutant males show normal mating behavior but have no detectable mature sperm. Examination of meiosis in these males reveals that the cells enter meiotic prophase and arrest at pachytene. Homozygous mutant females have normal estrous cycles and reproductive and mating behavior but are infertile. The phenotypes of the mlh1 mutant mice are distinct from those deficient in msh2 and pms2. The different phenotypes of the three types of mutant mice suggest that these three genes may have independent functions in mammalian meiosis.

Mutation in the mismatch repair gene Msh6 causes cancer susceptibility.

Mice carrying a null mutation in the mismatch repair gene Msh6 were generated by gene targeting. Cells that were homozygous for the mutation did not produce any detectable MSH6 protein, and extracts prepared from these cells were defective for repair of single nucleotide mismatches. Repair of 1, 2, and 4 nucleotide insertion/deletion mismatches was unaffected. Mice that were homozygous for the mutation had a reduced life span. The mice developed a spectrum of tumors, the most predominant of which were gastrointestinal tumors and B- as well as T-cell lymphomas. The tumors did not show any microsatellite instability. We conclude that MSH6 mutations, like those in some other members of the family of mismatch repair genes, lead to cancer susceptibility, and germline mutations in this gene may be associated with a cancer predisposition syndrome that does not show microsatellite instability.