Meiotic pairing and segregation of achiasmate sex chromosomes in eutherian mammals: the role of SYCP3 protein

In most eutherian mammals, sex chromosomes synapse and recombine during male meiosis in a small region called pseudoautosomal region. However in some species sex chromosomes do not synapse, and how these chromosomes manage to ensure their proper segregation is under discussion. Here we present a study of the meiotic structure and behavior of sex chromosomes in one of these species, the Mongolian gerbil (Meriones unguiculatus). We have analyzed the location of synaptonemal complex (SC) proteins SYCP1 and SYCP3, as well as three proteins involved in the process of meiotic recombination (RAD51, MLH1, and γ-H2AX). Our results show that although X and Y chromosomes are associated at pachytene and form a sex body, their axial elements (AEs) do not contact, and they never assemble a SC central element. Furthermore, MLH1 is not detected on the AEs of the sex chromosomes, indicating the absence of reciprocal recombination. At diplotene the organization of sex chromosomes changes strikingly, their AEs associate end to end, and SYCP3 forms an intricate network that occupies the Y chromosome and the distal region of the X chromosome long arm. Both the association of sex chromosomes and the SYCP3 structure are maintained until metaphase I. In anaphase I sex chromosomes migrate to opposite poles, but SYCP3 filaments connecting both chromosomes are observed. Hence, one can assume that SYCP3 modifications detected from diplotene onwards are correlated with the maintenance of sex chromosome association. These results demonstrate that some components of the SC may participate in the segregation of achiasmate sex chromosomes in eutherian mammals.     

Meiotic behaviour of sex chromosomes and polymeiosis in three species of insectivores

A study of male meiosis has been carried out on air-dried testicular preparations from three insectivore species: Crocidura russula, Neomys anomalus and Talpa occidentalis.Two particularities in relation to the meiotic process were found. The sex-chromosomes show a special allocycly. In the zygotene and pachytene stages, only some cells (a maximum of 50% in some individuals) present a typical sex-vesicle. In the majority of cells in these stages, the X-chromosome appears unfolded, isopycnotic or negatively heteropycnotic, with the ends of the arms together. The Y-chromosome is more condensed and it is associated with the ends of the X-chromosome. At diakinesis and metaphase I the sex chromosomes show end-to-end pairing. A second interesting feature in these species is the existence of spontaneous polymeiosis in a relative high frequency.The origin of this phenomenon, and the influence of these two particularities on fertility and the relation with the phylogeny of these species are discussed.     

Meiotic chromosomes of man

A study of human meiotic chromosomes led to a classification of the bivalents according to their dimension, general characteristics and chiasma frequency. Particular attention was paid to the X and Y chromosomes. The consistency of pattern shapes in individual chromosomes at diakinesis indicated the potential for karyotyping the meiotic chromosomes of man.     

Meiotic pairing as a polo match

In C.?elegans, meiotic chromosome pairing is initiated by association of chromosomal sites known as pairing centers (PCs) with the nuclear periphery. The Dernburg and Zetka laboratories have shown that recruitment of Polo kinases to PCs at the nuclear envelope is essential to promote PC complex aggregation, pairing, and synapsis.     

Meiotic pairing and segregation of translocation quadrivalents in yeast

Meiotic pairing and segregation were studied in three different heterozygous reciprocal translocation strains of the baker’s yeast, Saccharomyces cerevisiae. Pachytene translocation quadrivalents were identified by a combination of immunofluorescence and fluorescence in situ hybridization and the karyotypes of meiotic products were determined by pulsed-field gel electrophoresis. The translocations differed with respect to the relative sizes of the chromosomes involved and the positions of translocation breakpoints, and produced translocation quadrivalents of widely different shapes. This allowed us to study the influence of the morphology of quadrivalents on their segregation behaviour. In all cases alternate predominated over adjacent segregation. 3:1 disjunction of chromosomes was more frequent when translocation breakpoints were close to the centromeres. If a translocation breakpoint was distant from the centromere, the occurrence of an intervening chiasma influenced the pattern of segregation. In general, quadrivalent formation and segregation resembled the behaviour of translocation heterozygotes in most higher eukaryotes. We therefore conclude that, although chromosome condensation does not occur in yeast metaphase, centromere orientation and chromosome disjunction are governed in a way similar to that of higher eukaryotes. Received: 6 February 1998; in revised form: 19 May 1998 / Accepted: 23 May 1998     

Meiotic association and segregation of the achiasmatic giant sex chromosomes in the male field vole (Microtus agrestis)

Controversy exists regarding the meiotic behaviour of the giant sex chromosomes during spermatogenesis in the field vole, Microtus agrestis. Both univalents and bivalents have been observed between diakinesis and metaphase I. These differences seem to be dependent on the technique used. The present study employs electron microscopy of serially sectioned testes tubules and light microscopy of microspread preparations to re-examine the behaviour of sex chromosomes during meiosis. In microspreads, about one-third of the early pachytene nuclei examined showed end joining of the X and Y axes. The longitudinal heterogeneity of the chromosomes in the form of axial thickenings allowed the detection of two different end-joining patterns. In the remaining early pachytene cells as well as in all mid to late pachytene cells seen, the X and Y axes had, though near to each other, no contact in the form of a synaptonemal complex. If a synaptonemal complex is a prerequisite for genetic exchange, the sex chromosomes in M. agrestis males must be achiasmatic. The analysis of serial sections through an early pachytene and a late prophase I nucleus with the electron microscope revealed that the sex chromosomes occupied a common area. By metaphase I, the centromeres of the X and Y were oriented towards opposite spindle poles while the chromosomes remained attached to one another by their distal segments at the level of the metaphase I plate. As a consequence of the large size of the sex chromosomes their centromeres lay close to the spindle poles. In anaphase I the sex chromosomes maintained their metaphase position until the autosomes approached the spindle poles. During autosomal migration a medial constriction developed where the sex chromosomes were mutually associated, the X and Y became separated, and joined the autosomes. In metaphase II the chromatids of the sex chromosomes lay side by side and exhibited a delayed separation in the subsequent anaphase. It is suggested that heterochromatin, which represents a major part of both sex chromosomes, plays a role in the association of the two achiasmatic sex chromosomes in metaphase I and in the delayed separation of the chromatids of the sex chromosomes in anaphase II.Dedicated to Prof. C.-G. Arnold (Erlangen) on the occasion of his 60th birthday     

Meiotic chromosomes of the spermatocytes ejaculated by bulls

The Sperling and Kaden (1971) approach was used in studies of the bull meiotic chromosomes. The number of meiocytes in the ejaculates of normal bulls ranged from 0.0001 to 0.0114% of the whole set of cellular elements in the ejaculate. Two of the studied bulls had a chromosomal abnormality in somatic cells (60, XX/60, XY mosaic). These bulls displayed no deviation as concerns the quantity of meiocytes in their ejaculates. In two other bulls examined, with cryptorchism and azoospermia, about 0.0017 and 4.75% meiocytes were counted in the ejaculate, respectively. A comparative analysis of ejaculated chromosomes and meiotic chromosomes obtained from the normal testes by biopsy did not reveal any differences in the chromosomal morphology. Various premeiotic and meiotic stages, from spermatogonium A and B to metaphase 1, were identified in the bull ejaculates. This technique may be valuable in cytogenetic diagnosis of meiotic abnormalities in sires.     

Meiotic sex chromosome inactivation

X chromosome inactivation is most commonly studied in the context of female mammalian development, where it performs an essential role in dosage compensation. However, another form of X-inactivation takes place in the male, during spermatogenesis, as germ cells enter meiosis. This second form of X-inactivation, called meiotic sex chromosome inactivation (MSCI) has emerged as a novel paradigm for studying the epigenetic regulation of gene expression. New studies have revealed that MSCI is a special example of a more general mechanism called meiotic silencing of unsynapsed chromatin (MSUC), which silences chromosomes that fail to pair with their homologous partners and, in doing so, may protect against aneuploidy in subsequent generations. Furthermore, failure in MSCI is emerging as an important etiological factor in meiotic sterility.     

Joint classification and pairing of human chromosomes

We reexamine the problems of computer-aided classification and pairing of human chromosomes, and propose to jointly optimize the solutions of these two related problems. The combined problem is formulated into one of optimal three-dimensional assignment with an objective function of maximum likelihood. This formulation poses two technical challenges: 1) estimation of the posterior probability that two chromosomes form a pair and the pair belongs to a class and 2) good heuristic algorithms to solve the three-dimensional assignment problem which is NP-hard. We present various techniques to solve these problems. We also generalize our algorithms to cases where the cell data are incomplete as often encountered in practice.     

Meiotic pairing: a place to hook up

At one end of each Caenorhabditis elegans chromosome is a locus required for meiotic crossing over. Recent studies have shown that these sites mediate chromosome pairing and synapsis during meiosis, and that each site contains binding sites for a non-canonical C2H2 zinc finger protein.     

Meiotic drive and sex chromosome cycling

Sex-linked meiotic drive is found in a broad variety of taxa, including insects, birds, and mammals. In populations of some species, we see four types of sex chromosomes segregating: normal and driving X chromosomes and susceptible and resistant Y chromosomes. A theoretical analysis shows that a stable four-chromosome equilibria is a more common outcome in these systems than previously recognized. Cycling of sex chromosome frequencies and associated changes in the sex ratio are other predicted outcomes. The absence of cycling in nature may be due to migration among populations.     

Plant sex determination and sex chromosomes

Sex determination systems in plants have evolved many times from hermaphroditic ancestors (including monoecious plants with separate male and female flowers on the same individual), and sex chromosome systems have arisen several times in flowering plant evolution. Consistent with theoretical models for the evolutionary transition from hermaphroditism to monoecy, multiple sex determining genes are involved, including male-sterility and female-sterility factors. The requirement that recombination should be rare between these different loci is probably the chief reason for the genetic degeneration of Y chromosomes. Theories for Y chromosome degeneration are reviewed in the light of recent results from genes on plant sex chromosomes.