Meiosis in a sterile male mouse with an isoYq marker chromosome

A male mouse with a metacentric Y chromosome of twice the normal size has been studied chromosomally in bone marrow mitoses, spermatogonial mitoses, and diakinesis-metaphase I primary spermatocytes. A low frequency of nondisjunction for this chromosome (2%) was noted in both bone marrow and spermatogonial mitoses. In spermatogonial mitoses, loss of the Y chromosome had occurred to the extent that 12% of spermatogonia were XO, resulting in 17% XO primary spermatocytes. Hardly any stages beyond the primary spermatocyte stage were encountered, which agrees with testis weights of approximately 30% of normal. Surface-spread pachytene spermatocytes yielded few cells that were analyzable for their total complement of synaptonemal complexes. The Y chromosome showed complete fold-back pairing and was located far away from the X chromosome. X and Y chromosomes were paired in 14.5% of the diakinesis-MI spermatocytes that contained a Y chromosome. The origin of this chromosome is discussed against the background of localization of the gene for the testis-determining factor on the short arm of the mouse Y chromosome.     

Deficiency of X and Y chromosomal pairing at meiotic prophase in spermatocytes of sterile interspecific hybrids between laboratory mice (Mus domesticus) and Mus spretus

The normal association between the X and Y chromosomes at metaphase I of meiosis, as seen in air-dried light microscope preparations of mouse spermatocytes, is frequently lacking in the spermatocytes of the sterile interspecific hybrid between the laboratory mouse strains C57BL/6 and Mus spretus. The purpose of this work is to determine whether the separate X and Y chromosomes in the hybrid are asynaptic, caused by failure to pair, or desynaptic, caused by precocious dissociation. Unpaired X-Y chromosomes were observed in air-dried preparations at diakinesis, just prior to metaphase I. Furthermore, immunocytology and electron microscopy studies of surface-spread pachytene spermatocytes indicate that the X and Y chromosomes frequently fail to initiate synapsis as judged by the failure to form a synaptonemal complex between the pairing regions of the X and Y Chromosomes. Several additional chromosomal abnormalities were observed in the hybrid. These include fold-backs of the unpaired X or Y cores, associations between the autosome and sex chromosome cores, and autosomal univalents. The occurrence of abnormal autosomal and XY-autosomal associations was also correlated with cell degeneration during meiotic prophase. The primary breakdown in hybrid spermatogenesis occurs at metaphase I (MI), with the appearance of degenerated cells at late MI. In those cells, the X and Y are decondensed rather than condensed as they are in normal mouse MI spermatocytes. These results, in combination with the previous genetic analysis of spermatogenesis in hybrids and backcrosses with fertile female hybrids, suggest that the spermatogenic breakdown in the interspecific hybrid is primarily correlated with the failure of XY pairing at meiotic prophase, asynapsis, followed by the degeneration of spermatocytes at metaphase I. Secondarily, the failure of XY pairing can be accompanied by failure of autosomal pairing, which appears to involve an abnormal sex vesicle and degeneration at pachytene or diplotene.by C. Heyting     

Unpaired chromosomes at meiosis: cause or effect of gametogenic insufficiency?

Pairing failure at meiosis has been postulated as a cause of gametogenic arrest in both heterozygous translocation carriers and males whose spermatocytes exhibit univalent X and Y chromosomes. The present investigation is a survey of pachytene translocation configurations, at the electron microscopic level, in six stocks of mice, comprising a total of 464 spermatocytes and 343 oocytes. Univalence of the X and Y chromosomes was studied in the same stocks, as well as in three additional homozygous translocation stocks. Fully paired as well as asynaptic configurations were found in all translocation stocks, and the proportions of each configuration differed considerably between spermatocytes and oocytes of mice carrying the same translocation. In both spermatocytes and oocytes, other pairing anomalies were more frequent in cells with asynapsed than with fully synapsed configurations, and spermatocytes with univalent sex chromosomes had a higher proportion of autosomal anomalies than did spermatocytes with XY bivalents. It is concluded that pairing failure at meiosis is primarily a symptom, rather than a cause, of gametogenic arrest, and that chromosome rearrangements, even if they appear to be balanced, may affect the rate of atresia by interfering with the normal rate of meiotic progression. Once pairing failure is established, it could secondarily increase the probability of gametogenic failure.     

The behavior and morphology of the X and Y chromosomes during prophase I in the Sitka deer mouse (Peromyscus sitkensis)

Surface-spread, silver-stained primary spermatocytes from individuals of the Sitka deer mouse (Peromyscus sitkensis) were analyzed by electron microscopy. Pairing of the X and Y chromosomes is initiated at early pachynema and is complete by mid pachynema. The pattern of sex chromosome pairing is unique in that it is initiated at an interstitial position, with subsequent synapsis proceeding in a unidirectional fashion towards the telomeres of the homologous segments. One-third the length of the X and two-thirds the length of the Y are involved in the synaptonemal complex of the sex bivalent. Various morphological complexities develop in the heteropycnotic (unpaired) segments as pachynema progresses, but desynapsis is not initiated until diplonema. Analysis of C-banded diakinetic nuclei indicated that sex chromosome pairing involves the heterochromatic short arm of the X and the long arm of the heterochromatic Y. An interstitial chiasma between the X and Y was observed in the majority of the diakinetic nuclei. The observation of a substantial pairing region and chiasma formation between the sex chromosomes of these deer mice is interpreted as indicating homology between the short arm of the X and the long arm of the Y.     

The morphological sequence of XY pairing in the Norway rat Rattus norvegicus

The sequence of XY pairing at meiotic prophase in the Norway rat, Rattus norvegicus, has been studied in spread preparations of spermatocytes obtained from pubertal males. As in most mammals, sex chromosome pairing is delayed in relation to that of the autosomes. At one stage in pachytene, the Y is fully paired in synaptonemal complex association with about one-third of the X. Observation in spread preparations at pachytene and diplotene and in air-dried metaphase I preparations indicates that the long arm of the Y pairs with the short arm of the X. Pairing of the Y with both ends of the X is seen in about 4% of pachytene spermatocytes. The possibility that XY pairing in the rat may be nonhomologous (Ashley 1983) is considered, and the view is expressed that the XY synaptonemal complex may be incomplete in fine structural detail, thus not providing for the effective pairing required in true reciprocal recombination. The same mechanism that excludes crossing over from heterochromatic regions of autosomes may also operate to minimize or prevent crossing over in the sex pair of mammals.     

The chromosomes of Micromys minutus (Rodentia, Murinae). II. Pairing pattern of X and Y chromosomes in meiotic prophase

Both light and electron microscopy were used to study the pairing behavior of the sex chromosomes of the harvest mouse, Micromys minutus, in surface-spread pachytene spermatocytes. The XY pairing pattern is very exceptional in that the site of synaptic initiation is located interstitially in the short arms of the X and the Y, next to their centromeric regions. From this tiny euchromatic site, synapsis proceeds unidirectionally along the homologous heterochromatic short arms of the X and the Y toward the ends of the chromosomes. After pairing of the short arm is concluded, synapsis begins between the nonhomologous long arms of the X and the Y in the immediate vicinity of the centromeres and progresses unidirectionally toward the end of the long arm of the Y. A synaptic complex develops between the constitutive heterochromatin of the long arm of the Y and the euchromatin of the long arm of the X. Analysis of C-banded and distamycin A/DAPI-stained diakineses revealed a trefoil-like XY bivalent, which was interpreted to be the result of an interstitial chiasma occurring in the paired short arms of the X and the Y. A conspicuous, electron-dense body, about 1 micron in diameter, was found closely associated with the centromeres of the X and the Y in numerous pachytene spermatocytes. A review of the literature showed that comparable XY-associated bodies have been found in only eight other mammals to date.     

Electron microscopic observations on the synaptonemal complex of spermatocytes of the Giant Panda (Ailuropoda melanoleuca)

Surface-spread and silver-stained preparations of spermatocytes from a giant panda were observed by electron microscopy for synaptonemal complex karyotyping. Ten pachytene spermatocyte nuclei were selected for length quantitation of SC. The mean relative lengths and centromeric indices of each SC agreed closely with those of the mitotic chromosomes. The pairing between lateral elements of autosomal chromosomes starts at early zygotene and leads progressively along their length to complete pairing at pachytene. The whole Y is paired with 1/3 length of X at mid-pachytene. The morphology of X and Y chromosome axes and the nonhomologous pairing of X and Y is discussed.     

The influence of the Robertsonian translocation Rb(X.2)2Ad on anaphase I non-disjunction in male laboratory mice

A Robertsonian translocation in the mouse between the X chromosome and chromosome 2 is described. The male and female carriers of the Rb(X.2)2Ad were fertile. A homozygous/hemizygous line was maintained. The influence of the X-autosomal Robertsonian translocation on anaphase I non-disjunction in male mice was studied by chromosome counts in cells at metaphase II of meiosis and by assessment of aneuploid progeny. The results conclusively show that the inclusion of Rb2Ad in the male genome induces non-disjunction at the first meoitic division. In second metaphase cells the frequency of sex-chromosomal aneuploidy was 10.8%, and secondary spermatocytes containing two or no sex chromosome were equally frequent. The Rb2Ad males sired 3.9% sex-chromosome aneuploid progeny. The difference in aneuploidy frequencies in the germ cells and among the progeny suggests that the viability of XO and XXY individuals is reduced. The pairing configurations of chromosomes 2, Rb2Ad and Y were studied during meiotic prophase by light and electron microscopy. Trivalent pairing was seen in all well spread nuclei. Complete pairing of the acrocentric autosome 2 with the corresponding segment of the Rb2Ad chromosome was only seen in 3.2% of the cells analysed in the electron microscope. The pairing between the X and Y chromosome in the Rb2Ad males corresponded to that in males with normal karyotype. Reasons for sex-chromosomal non-disjunction despite the normal pairing pattern between the sex chromosomes may be seen in the terminal chiasma location coupled with the asynchronous separation of the sex chromosomes and the autosomes.(ABSTRACT TRUNCATED AT 250 WORDS)     

The staining of constitutive heterochromatin,and A-T and G-C rich DNA in lymphocytes and primary spermatocytes of the Chinese hamster

The staining of male Chinese hamster chromosomes at meiotic prophase with several banding techniques is described. C-banding results only occasionally in well-differentiated pachytene and diakinesis bivalents. Meiotic C-bands are small compared with those in somatic metaphase chromosomes. In mice C-bands mainly consist of highly repetitive satellite DNA, whereas in Chinese hamsters the majority of the DNA in C-bands is not or hardly repetitive. Especially in Chinese hamsters both the degree of chromatin despiralisation and the folding pattern of the chromatin drastically reduce the distinction of C-bands in late meiotic prophasc chromosomes. In contrast to the situation in mice, C-heterochromatin associations are never observed in Chinese hamster spermatocytes. It is assumed that the presence of satellite DNA rather than constitutive heterochromatin is the basis for the associations of the paracentromeric chromosome regions in mice. The location and behaviour of AT- and GC-rich DNA in Chinese hamster primary spermatocytes is studied with base-specific fluorochromes (H 33258 and Chromomycin A₃ for AT-and GC-rich DNA respectively), in combination with a pretreatment with base-specific non-fluorescent antibiotics (Actinomycin D and Netropsin for GC-and AT-rich DNA respectively). No indications are found for the clustering of AT-or GC-rich DNA in Chinese hamster pachytene nuclei. A comparison of banding patterns observed in somatic metaphases and in diakinesis gives some information about the partial homology of the X and Y chromosome. The results are conflicting. The short arm of the Y chromosome is homologous with a part of the X chromosome. According to the C-band pattern the long arm of the X chromosome is involved in the pairing with Y, whereas fluorescence banding patterns indicate that it is the short arm of X.     

Spermatogenesis in XO,Sxr mice: role of the Y chromosome

The goal of this investigation was to evaluate the role of the Y chromosome in spermatogenesis by a quantitative and qualitative analysis of spermatogenesis as it occurs in the absence of a significant portion of the Y chromosome, i.e., in XO,Sxr male mice. Although these mice have the testis-determining portion of the Y chromosome on their single X chromosome, they lack most of the Y chromosome. Since it was found that all sperm-specific structures were assembled in a normal spatial and temporal pattern in spermatids of XO,Sxr mice, the genes controlling these structures cannot be located on the Y chromosome outside of the Sxr region, and are more likely to be on autosomes or on the X chromosome. In spite of the assembly of the correct sperm-specific structures, spermatogenesis was not quantitatively normal in XO,Sxr mice and significantly reduced numbers of spermatids were found in the seminiferous tubules of these mice. Furthermore, two size classes of spermatids were found in the testes of XO,Sxr mice, normal and twice-normal size. These findings are suggestive of abnormalities of meiosis in XO,Sxr spermatocytes, which lack one of the two sex chromosomes, and may not implicate function of specific genes on the Y chromosome. Morphological abnormalities of spermatids, which were not unique to XO,Sxr mice, were observed and these may be due to either a defective testicular environment because of reduced numbers of germ cells or to the lack of critical Y chromosome-encoded products. Since pachytene spermatocytes of XO,Sxr mice exhibited a sex vesicle, it can be concluded that the assembly of this structure does not depend on the presence of either a complete Y chromosome or the pairing partner for the X chromosome.     

褐家鼠精母细胞中联会复合体的研究 Ⅱ.性染色体配对形态和行为的研究

用表面铺展-AgNO_3和PTA染色技术,对雄性褐家鼠性染色体配对形态和行为进行研究表明:X和Y轴在减数分裂前期Ⅰ的不同阶段固缩速度不同;性染色体在配对之前轴心增粗、配对延迟到早粗线期;性染色体首次配对起始区发生在X和Y短臂端粒区,其次配对起始区发生在X与Y长臂的端粒区或长臂的中间区;在中粗线期几乎整条Y与约1/3 X配对形成X-YSC;配对区的侧生组分分为两股,其中一股发生泡状变形,不配对片段发生多种变形。本文对X和Y配对起始位点,配对的同源性及XY轴心增厚与变形机制作了讨论.     

The tricky path to recombining X and Y chromosomes in meiosis

Sex chromosomes are the Achilles' heel of male meiosis in mammals. Mis-segregation of the X and Y chromosomes leads to sex chromosome aneuploidies, with clinical outcomes such as infertility and Klinefelter syndrome. Successful meiotic divisions require that all chromosomes find their homologous partner and achieve recombination and pairing. Sex chromosomes in males of many species have only a small region of homology (the pseudoautosomal region, PAR) that enables pairing. Until recently, little was known about the dynamics of recombination and pairing within mammalian X and Y PARs. Here, we review our recent findings on PAR behavior in mouse meiosis. We uncovered unexpected differences between autosomal chromosomes and the X-Y chromosome pair, namely that PAR recombination and pairing occurs later, and is under different genetic control. These findings imply that spermatocytes have evolved distinct strategies that ensure successful X-Y recombination and chromosome segregation.     

On the homology between the X and the Y chromosomes of the Chinese hamster

The chiasmatic association of the heteromorphic sex chromosomes in the spermatocytes of the Chinese hamster was observed in squash and/or air-dried preparations. The pairing arm of the Y was invariably its short arm. Although the X in diakinesis did not show distinct long and short arm as in mitotic metaphase, the DNA replication patterns of the sex chromosomes in spermatogonia suggested that the distal segment of the long arm of the X is homologous to the short arm of the Y.     

Illegitimate pairing of the X and Y chromosomes in Sxr mice

X/Y male mice carrying the sex reversal factor, Sxr, on their Y chromosomes typically produce 4 classes of progeny (recombinant X/X Sxr male male and X/Y non-Sxr male male, and non-recombinant X/X female female and X/Y Sxr male male) in equal frequencies, these deriving from obligatory crossing over between the chromatids of the X and Y during meiosis. Here we show that X/Y males that, exceptionally, carry Sxr on their X chromosome, rather than their Y, produce fewer recombinants than expected. Cytological studies confirmed that X-Y univalence is frequent (58%) at diakinesis as in X/Y Sxr males, but among those cells with X-Y bivalents only 38% showed normal X-Y pseudo-autosomal pairing. The majority of such cells (62%) instead showed an illegitimate pairing between the short arms of the Y and the Sxr region located at the distal end of the X, and this can be understood in terms of the known homology between the testis-determining region of the Y short arm and that of the Sxr region. This pairing was sufficiently tenacious to suggest that crossing over took place between the 2 regions, and misalignment and unequal exchange were suggested by indications of bivalent asymmetry. Metaphase II cells deriving from meiosis I divisions in which the normal X-Y exchange had not occurred were also found. The cytological data are therefore consistent with the breeding results and suggest that normal pseudo-autosomal pairing and crossing over is not a prerequisite for functional germ cell formation.(ABSTRACT TRUNCATED AT 250 WORDS)     

On the nature and extent of XY pairing at meiotic prophase in man

Evidence is presented that pairing between the human X and Y chromosomes could be more extensive at early pachytene than has previously been supposed and could involve even the entire euchromatic portion of the Y chromosome. Following desynapsis over the major part of the X and Y axes, a small paired segment of Xp and Yp remains into late pachytene. Association between the distal tips of Xq and Yq can also be observed in about one half of the spermatocytes examined. A hypothesis linking meiotic pairing to early replicating sites along the chromosomes is proposed.     

Suppressor T cells arising in mice undergoing a graft-vs-host response.

We investigated the ability of mice to generate antibody-forming cells when undergoing a graft-vs-host reaction. (C57BL/6 X DBA/2)F1 mice (BDF1) injected with C57BL/6 spleen cells generated suppressor T cells which inhibit antibody synthesis by BDF1 spleen cells in vitro. These T cells arose from the donor inoculum. They differ from helper T cells in size and they act directly on antigen reactive B cells. The suppressor T cells were specifically directed against components of the H-2 region of the reciprocal parental strain (DBA/2 = H-2d) in the hybrid F1 mouse.     

Recombination between the X and Y chromosomes and the Sxr region of the mouse.

The Sxr (sex-reversed) region that carries a copy of the mouse Y chromosomal testis-determining gene can be attached to the distal end of either the Y or the X chromosome. During male meiosis, Sxr recombined freely between the X and Y chromosomes, with an estimated recombination frequency not significantly different from 50% in either direction. During female meiosis, Sxr recombined freely between the X chromosome to which it was attached and an X-autosome translocation. A male mouse carrying the original Sxra region on its Y chromosome, and the shorter Sxrb variant on the X, also showed 50% recombination between the sex chromosomes. Evidence of unequal crossing-over between the two Sxr regions was obtained: using five markers deleted from Sxrb, 3 variant Sxr regions were detected in 159 progeny (1.9%). Four other variants (one from the original cross and three from later generations) were presumed to have been derived from illegitimate pairing and crossing-over between Sxrb and the homologous region on the short arm of the Y chromosome. The generation of new variants throws light on the arrangement of gene loci and other markers within the short arm of the mouse Y chromosome.     

Synaptonemal complex analysis of X-7 translocations in male mice: R2 and R6 quadrivalents

Synaptonemal complexes of surface-spread spermatocytes of mice heterozygous for reciprocal translocations R2 or R6 between the X-chromosome and chromosome 7 were examined by light and electron microscopy (EM). Measurements of the lengths of all chromosome axes involved in the translocation configurations and of the extent of synapsis were used to calculate the position of the break points of the two translocations. The breaks for R2 were determined to be at 62% of the 7 as measured from the centromere, and at 27% of the X. Quadrivalents were formed almost exclusively. The break points for R6 were calculated to be at 30% of the 7 as measured from the centromere, and at 75% of the X. Although in R6 the break in the X lies within the potential pairing region of the sex chromosomes, univalent Ys were rarely observed (6%). The EM sample of 76 nuclei contained: 42% quadrivalents, 52% heteromorphic bivalents, 4% trivalent plus Y univalent, and 2% X7-7 bivalent plus two univalents (7X and Y). Nonhomologous synapsis occurred in the quadrivalents of both R2 and R6. In R6 nonhomologous synapsis of the X portion of the 7X with the 7 involved up to 14% of the length of the 7. Methods are discussed for determining the position of the break points in the presence of nonhomologous synapsis. It is proposed that the high percentage of bivalents is due to premature desynapsis of the 7X from the 7 and that the X portion of the 7X axis confers its property of premature desynapsis on that portion of the 7 to which it is attached.