Heinz Winking

Robertsonian metacentrics in the mouse

A survey is given on the occurrence, the geographic origin and the arm composition of 27 Robertsonian fusion metacentric chromosomes of wild populations of the mouse. Their study is of twofold interest: a) it is possible to introduce these naturally occurring metacentrics in laboratory strains for experimental use. At present, altogether 34 metacentric chromosomes of different composition are available including 7 cases of metacentrics known from laboratory strains of the mouse. b) With the search for metacentrics in the mouse and with their identification insights are permitted in the role of Robertsonian changes in the course of mammalian evolution — Several separate populations of the mouse with different sets of multiple (up to 9) metacentrics have been found in Switzerland and Italy. Some of the individual metacentrics may occur in different populations. The participation of an acrocentric autosome in the formation of metacentrics seem to be at random, but the sex chromosomes are never included in a metacentric. — Homology of the arms involved in metacentrics is conserved, so that in meiosis of interpopulation hybrids long chains or rings are observed. They may include up to 16 metacentrics arranged according to the alternating homologies of their arms. — Reduction of fertility of single or multiple metacentric heterozygotes and of the interpopulation hybrids is due to mechanisms of segregational imbalance and subsequent prenatal elimination of fetal offspring, but it follows also the pattern of male limited hybrid sterility. — From an evolutionary view point, karyotype rearrangements of Robertsonian type may initiate reproductive isolation, which prepares the ground for further genetic diversification and, as in the case of the mouse, of incipient speciation.

Meiotic chromosomes and stages of sex chromosome evolution in fish: zebrafish, platyfish and guppy.

We describe SC complements and results from comparative genomic hybridization (CGH) on mitotic and meiotic chromosomes of the zebrafish Danio rerio, the platyfish Xiphophorus maculatus and the guppy Poecilia reticulata. The three fish species represent basic steps of sex chromosome differentiation: (1) the zebrafish with an all-autosome karyotype; (2) the platyfish with genetically defined sex chromosomes but no differentiation between X and Y visible in the SC or with CGH in meiotic and mitotic chromosomes; (3) the guppy with genetically and cytogenetically differentiated sex chromosomes. The acrocentric Y chromosomes of the guppy consists of a proximal homologous and a distal differential segment. The proximal segment pairs in early pachytene with the respective X chromosome segment. The differential segment is unpaired in early pachytene but synapses later in an ‘adjustment’ or ‘equalization’ process. The segment includes a postulated sex determining region and a conspicuous variable heterochromatic region whose structure depends on the particular Y chromosome line. CGH differentiates a large block of predominantly male-specific repetitive DNA and a block of common repetitive DNA in that region.

Loss of telomeric sites in the chromosomes of Mus musculus domesticus (Rodentia: Muridae) during Robertsonian rearrangements.

Mouse chromosomes possessing multiple Robertsonian rearrangements (Rb chromosomes) have been examined using fluorescencein situ hybridization with the telomeric consensus sequence (TTAGGG)n. No hybridization signals were detected at the primary constriction of Rb chromosomes. This observation leads us to conclude that the formation of Rb chromosomes in the mouse is invariably associated with the loss of telomeric regions. More significantly, a further alteration in regions flanking the primary constrictions was observed after hybridizing with a minor satellite DNA probe to Rb chromosomes. It seems likely that the breakpoints required for a Robertsonian process do not include telomeric sites exclusively but extend to the adjacent pericentromeric regions of the original acrocentric chromosomes. In contrast to previous reports, these observations demonstrate the elimination of substantial amounts of chromosomal DNA during the formation of mouse Rb chromosomes.

Cytological identification of two X-chromosome types in the wood lemming (Myopus schisticolor)

In the wood lemming (Myopus schisticolor) three genetic types of sex chromosome constitution in females are postulated: XX, X*X and X*Y (X*=X with a mutation inactivating the male determining effect of the Y chromosome). Males are all XY. It is shown in the present paper that the two types of X chromosomes, X and X*, exhibit differences in the G-band patterns of their short arms. In addition, it was demonstrated in unbanded chromosomes that the short arm in X* is shorter than in X. The origin of these differences is still obscure; but they allow to identify and to distinguish the individual types of sex chromosome constitution, as of XX versus X*X females and of X*Y females versus XY males, on the basis of G-banded chromosome preparations from somatic cells.

An extra segment in chromosome 1 of wild Mus musculus: a C-band positive homogeneously staining region

An extra segment in chromosome 1 between bands C5 and D has been found in wild mouse populations. Its size varies between 6.1% and 30.1% of the length of a standard chromosome 1. It differs among individuals and populations but is constant in a genetically homogeneous line. According to its staining properties and variation in length it is a homogeneously staining region (HSR), a kind of segment otherwise found only in cell lines under strong selection and in tumor cells. G-banding gives a homogeneous staining of medium intensity. With C-banding, staining is positive, though lighter than that of centromeric heterochromatin. Fluorescence is dull with Hoechst 33258 and bright with mithramycin. The extra segment does not contain mouse satellite DNA sequences in any quantity detectable by in situ hybridization. Such an extra segment was found in several European populations of mice from Spain to Russia. It is carried through the germ line. It has been introduced into a laboratory mouse strain, and, by recombination, inserted into a Robertsonian metacentric chromosome for easier handling and identification.

A comparative mapping study of fragile sites in the human and murine genomes

SummaryFragile sites on murine chromosomes were induced by the antimetabolites methotrexate (MTX), fluorodeoxyuridine (FdU), and aphidicolin (APD). To facilitate chromosome identification the analysis was performed on chromosomes of a CD/CD mouse that possesses nine pairs of Robertsonian translocation chromosomes of known arm composition. The pattern of induced fragile sites was rather similar for the different antimetabolites used. Many of them, e.g., 2B, 3B, 5B and 9D, are included in Giemsa-negative bands. On the X chromosome a fragile site was mapped to the region XC/D. Comparative mapping data with human fragile sites have been informative in most instances. Conservation of synteny within known linkage groups seems very likely.

Synaptonemal complexes of chains and rings in mice heterozygous for multiple Robertsonian translocations

Complex Robertsonian translocation heterozygosities in the mouse have been used to test different hypotheses regarding the correlation between male hybrid sterility and chromosomal abnormality. Synaptonemal complexes of meiotic super-chains and super-rings involving 15 to 18 metacentric chromosomes were studied in relation to spermatogenic histology. Both types of multivalents showed a characteristic pachytene pattern of alternating paired and non-paired segments. The amount of unpaired segments in rings was about 18% and in chains about 23% of the total length of multivalent chromosomes. The meiotic chains were associated with the proximal part of the X chromosomes in more than 60% of pachytene cells; a similar tight proximity of rings with X or Y chromosomes was never found. Complete arrest of germ cell maturation correlated with super-chains and inconspicuous testicular histology with super-rings. This demonstrates that an excessive amount of unpaired chromosomal axes does not leadper se to male infertility through gametogenic breakdown. On the contrary, the results clearly indicate spermatogenic impairment in this system of multimetacentric heterozygosity as a reflection of X chromosome super-chain interference.

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.

Polymorphic HSRs in chromosome 1 of the two semispecies Mus musculus musculus and M. m. domesticus have a common origin in an ancestral population.

HSRs (homogeneously staining regions) are the cytological correlates of DNA amplification. In the house mouse, Mus musculus, many populations are polymorphic for the presence or absence of HSRs on chromosome 1. In the semispecies M. m. domesticus the amplified DNA is present within one HSR, whereas in M. m. musculus chromosomes 1 with two HSRs are found. Hybridization of HSR-specific probes to Southern blots of HSR-carrying genomic DNAs from different localities and semispecies revealed similar complex band patterns. the remaining variation is restricted to sequences with a low degree of amplification. Variation is higher between semispecies than within one semispecies. It is assumed that HSRs are derived from one original amplification event and that unequal recombination is the mechanism underlying the length variation of HSRs present today in both semispecies. Evidence from G-banding and in situ hybridization shows that the two HSRs of M. m. musculus originated from a single HSR by means of a paracentric inversion, where one break-point was located within the single HSR and the second outside the HSR. As a consequence of the paracentric inversion the two HSRs of M. m. musculus are permanently linked together. Since exchange of genes between the two semispecies is restricted to a narrow hybrid zone the amplification that gave rise to the HSR most probably occurred prior to the divergence into the semispecies M. m. domesticus and M. m. musculus about 1 million years ago.

Implications of the genetic divergence between European wild mice with Robertsonian translocations from the viewpoint of mitochondrial DNA

*Department of Cytogenetics, National Institute of Genetics, Mishima, Shizuoka-ken, 411; ^Department of Biochemistry, Saitama Cancer Center Research Institute, Kitaadachi-gun, Saitama-lcen, 362; %Department of Variation Research, Primate Research Institute, Kyoto University, Inuyama, Aichi-lcen 484, Japan. %Institutfur Pathologic, Medizinische Hochschule Lubeck, Ratzeburger Allee 160, D-2400 Lubeck, Federal Republic of Germany (Professor Alfred Gropp died on 22 October 1983)