Germ line specific factors in chemical mutagenesis

Chemical mutagenesis test results have not revealed evidence of germ line specific mutagens. However, conventional assays have indicated that there are male-female differences in mutagenic response, as well as quantitative/qualitative differences in induced mutations which depend upon the particular cell stage exposed. Many factors inherent in the germ line can be speculated to influence chemical transport to, and interaction with, target cell populations to result in mutagenic outcomes. The level of uncertainty regarding the general operation of such factors, in combination with the limited availability of chemical test data designed to address comparative somatic and germ cell mutagenesis, leaves open the question of whether there are mutagens specifically affecting germ cells. This argues for a conservative approach to interpreting germ cell risk from somatic cell mutation analysis.     

Germ line polysomy in the grasshopper Atractomorpha similis

Nineteen Eastern Australian populations of the grasshopper Atractomorpha similis (Acridoidea, Pyrgomorphidae) were sampled and male meiotic chromosomes, as well as some male and female somatic mitoses, were examined. In fourteen of these populations, a proportion of the males were found to carry between one and ten extra copies of a particular autosome, the megameric chromosome (A9). Numbers of extra chromosomes varied between but not within the individual follicles of the testis. The extra chromosomes were not found in somatic tissue. In all, 20% of males from the field were germ-line polysomic and within these males, 91% of germ cells were polysomic. In meiosis, extra copies of A9 present as univalents lagged at anaphase I or II and subsequently formed micronuclei which degenerated early in spermiogenesis. As one extra univalent is the most common polysomic condition in natural populations, this elimination of univalents suggests that most polysomic males produce a large proportion of normal haploid sperm. In laboratory cultures, selection for increased frequency of germ-line polysomy, conducted over four generations, raised the proportion of polysomic males from 23% to 71%. Selection against polysomy reduced its frequency to 5%. These breeding experiments also showed that germ-line polysomy is equally transmissible through both the male and the female parent. Transmission data also suggested that these extra chromosomes can arise de novo, presumably by unequal disjunction in previously diploid lines. A computer model was devised, simulating the effects of repeated non-disjunction over a series of mitotic divisions. The behaviour of this model suggested that the distributions of extra chromosome numbers observed in the laboratory generations most probably resulted from such a series of non-disjunctions, occurring in an initially diploid cell population. It seems, therefore, that the transmission of polysomy occurs through the agency of heritable factors which determine the probability of non-disjunction and thus the accumulation of a particular autosome during a specific series of mitotic divisions in the embryonic germ-line.     

Germ line control of female sex determination in zebrafish

A major transition during development of the gonad is commitment from an undifferentiated “bi-potential” state to ovary or testis fate. In mammals, the oogonia of the developing ovary are known to be important for folliculogenesis. An additional role in promoting ovary fate or female sex determination has been suggested, however it remains unclear how the germ line might regulate this process. Here we show that the germ line is required for the ovary versus testis fate choice in zebrafish. When the germ line is absent, the gonad adopts testis fate. These germ line deficient testes have normal somatic structures indicating that the germ line influences fate determination of surrounding somatic tissues. In germ line deficient animals the expression of the ovary specific gene cyp19a1a fails to be maintained whereas the testis genes sox9a and amh remain expressed. Furthermore, we observed decreased levels of the ovary specific genes cyp19a1a and foxL2 in germ line deficient animals prior to morphological sex differentiation of the gonad. We propose that the germ line has a common role in female sex determination in fish and mammals. Additionally, we show that testis specification is sufficient for masculinization of the fish pointing to a direct role of hormone signaling from the gonad in directing sex differentiation of non-gonadal tissues.     

Germ line stem cell competition in postnatal mouse testes

Niche is believed to affect stem cell behavior. In self-renewing systems for which functional transplantation assays are available, it has long been assumed that stem cells are fixed in the niche and that ablative treatments to remove endogenous stem cells are required for successful donor engraftment. Our results demonstrate that enriched populations of donor stem cells can produce long-lasting spermatogenic colonies in testes of immature and mature, nonablated mice, albeit at a lower frequency than in ablated mice. Colonization of nonablated recipient testes by neonate, pup, and cryptorchid adult donor spermatogonial stem cells demonstrates that competition for niche begins soon after birth and that endogenous stem cells influence the degree and pattern of donor cell colonization. Thus, a dynamic relationship between stem cell and niche exists in the testis, as has been suggested for hematopoiesis. Therefore, similar competitive properties of donor stem cells may be characteristic of all self-renewing systems.     

Germ line development: lessons learned from pluripotent stem cells

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Germ line origins of de novo mutations in hemophilia B families

The germ line of origin for 13 of 14 de novo hemophilia B mutations has been determined. When added to previous reports, the origin, assuming no mosaicism, occurred in 43 female and 33 male gametes. Mutation rate estimates are twofold higher in males than in females. The pooled data also indicate that male and female germ lines have different mutation rates depending upon the type of mutation.     

Germ line imprinting in Drosophila: Epigenetics in search of function

Germ line imprinting produces parent-specific differences in the behavior of chromosomes or expression of genes. Epigenetic marks, placed on chromosomes in the parental germ line, govern classical imprinted effects such as chromosomal inactivation, chromosome elimination and mono-allelic expression. Germ line imprinting occurs in insects, plants and mammals. Several Drosophila systems display imprinted effects. In spite of this, many aspects of imprinting in flies, including the normal function of this process, remain mysterious. Transgenerational inheritance of epigenetic marks is a powerful force in genome regulation. Elucidation of the mechanism of imprint establishment and maintenance in a model organism, such as Drosophila, is thus of great interest. In this review we summarize the primary systems that have been used to study imprinting in flies and speculate on the origin and biological function of imprinting in Drosophila.     

Germ line specific DNA and chromosomes of the ciliate Stylonychia lemnae

The variation in DNA content of the micronucleus (germinal nucleus) of Stylonychia lemnae and its relation to the number of chromosomes was examined. Different populations possess similar amounts of micronuclear DNA but there are differences of ±30% between clones of the same population. However, the DNA content varies by about 100% in the micronuclei during the lifetime of a clone. The haploid micronucleus contains 35 or 36 chromosomes which persist in the developing macronucleus anlagen and grow to giant chromosomes. Besides this remaining subset, the micronucleus contains a variable number of germ line restricted chromosomes (mean about 140; range between 100 and 180). The somatic macronucleus eliminates these elements early in its development. The varying number of the germ line restricted chromosomes is responsible for the variation in the micronuclear DNA content.     

Germ line transmission of autonomous genetic elements in transgenic mouse strains

Upon microinjection into fertilized mouse eggs of circular molecules of plasmid pPyLT1 carrying the gene encoding the large T protein of polyoma virus within bacterial vector sequences, autonomous circular plasmids were stably maintained in low copy numbers in transgenic strains. These plasmids could be rescued in E. coli by transfection. Integrated forms could be detected neither in somatic tissues, nor in spermatozoa. Efficiency of paternal or maternal transmission was close to 100%. The plasmids had lost or had extensively rearranged the polyoma sequences. In addition, they had acquired defined segments of genomic mouse DNA, which might be responsible for correct segregation of daughter copies at both mitosis and meiosis (centromeric function).     

Germ line dependence of the deep orange maternal effect in Drosophila

Pole cell transplantations were used to determine the tissue specificity of maternal effects in Drosophila. The deep orange maternal effect is shown to be germ line autonomous. A cytoplasmic injection assay was used to determine when the dor⁺ substance could be detected in the developing oocyte. The dor⁺ substance is present during the early stages of vitellogenesis but could not be detected in the yolk of the embryo after blastoderm cellularization.     

Germ line abnormalities InDrosophila simulans transfected with the transposable P element

A strain ofDrosophila simulans was studied 40 generations after the transposable P element had been introduced into the genome by means of transformation. The genome also contained arosy transposon consisting of the wildtype allele of therosy gene flanked by P element DNA. During the 40 generations of evolution the number of P elements had increased to the level of 8–15 and the number ofrosy transposons to the level of 4–12. Continued transpositional activity in the germ line of the strain was evidenced by deletions occurring in therosy transposon and, in two independent sublines, by the transposition of therosy transposon from the X chromosome to the autosomes. Although at 25°C gonadal development and fertility appeared normal in both sexes, at 29°C both sexes were sterile. The sterile females had morphologically normal ovaries, but the sterile males often had shrunken, dysmorphic testes containing few or no immature sperm bundles. However, the sterility found in the transfected strain may not result directly from transpositional activity of the P element. The characteristics of theD. simulans strain infected with the P element are discussed in the context of factors that influence hybrid dysgenesis inD. melanogaster.     

Germ line recombination may be primarily a manifestation of DNA repair processes.

Several kinds of DNA repair and reactivation processes have been found to occur by recombination in E. coli and its phages. Recombinational repair appears to be a major mechanism for overcoming lesions induced by various agents including ultraviolet light, X-rays, [³²P]-decay, nitrous acid and psoralen-plus-light. When the lesions caused by the above agents are not repaired by recombinational repair or other accurate repair modes they generally lead to lethality. However a minority of these unrepaired lesions lead to mutations through replication errors or error-prone repair. In higher organisms accumulation of unrepaired lethal lesions or mutations in somatic cells may cause aging. Perpetuation of a species depends on preventing accumulation of these types of defects in the germ line. It is proposed that the recombinational acts occurring during meiosis may largely reflect the recombinational removal or repair of DNA lesions to conserve the germ line. It is further suggested that the repair function of recombination may be as significant as the better studied function of recombination, the generation of diversity. The ubiquitous occurrence of recombination in the biological world implies that it arose very early in evolution. The possibility that recombination initially arose as a repair process is discussed.     

Germ line development in the grasshopper Schistocerca gregaria: vasa as a marker

Vasa is a widely conserved germline marker, both in vertebrates and invertebrates. We identify a vasa orthologue, Sgvasa, and use it to study germline development in the grasshopper Schistocerca gregaria, a species in which no germ plasm has been identified. In adults, Sgvasa is specifically expressed in the ovary and testis. It is expressed at high levels during early oogenesis, but no detectable vasa RNA and little Vasa protein are present in mature unlaid eggs. None appears to be localized to any defined region of the egg cortex, suggesting that germline specification may not depend on maternal germ plasm expressing vasa. Vasa protein is expressed in most cleavage energids as they reach the egg surface and persists at high levels in most cells aggregating to form the embryonic primordium. However, after gastrulation, Vasa protein persists only in extraembryonic membranes and in cells at the outer margin of the late heart-stage embryo. In the embryo, it then become restricted to cells at the dorsal margin of the forming abdomen. In older embryos, these Vasa-positive cells move toward the midline; Vasa protein accumulates asymmetrically in their cytoplasm, a pattern closely resembling that of germ cells in late embryonic gonads. Thus, we suggest that the Vasa-stained cells in the abdominal margin are germ cells, as proposed by Nelson (1934), and not cardioblasts, as has been proposed by others.     

Germ line chimera produced by transfer of cultured chick primordial germ cells.

Intrinsic primordial germ cells (PGCs) from stage 27 (5-day-old) chick embryonic germinal ridges were cultured in vitro for a further 5 days, and shown to proliferate on stroma cells derived from the germinal ridge. To determine whether these cultured PGCs could colonize and contribute to the germ-line, PGCs were isolated by gentle pipetting, labeled with PKH26 fluorescent dye and injected into the blood stream of stage 17 (2.5-day-old) chick embryos. The recipient embryos were incubated until they reached stage 28. Thin sections of these embryos were analysed by fluorescent confocal laser microscopy. These analyses showed that the labeled donor PGCs had migrated into the germinal ridges of the recipient embryos, and transplanted PGCs had undergone at least 3-7 divisions. These results suggest that PGCs that had passed far beyond the migration stage in vivo were still able to migrate, colonize and proliferate in recipient chick embryonic gonads.