Role of the Chromocenter in Nonrandom Meiotic Segregation of Nonhomologous Chromosomes inDrosophila melanogasterFemales

The evidence supporting universal significance of physical links between pericentromeric regions of homologous chromosomes for their bipolar orientation during the first meiotic division is discussed. The pericentromeric chiasmata between homologs or (in the absence of the latter) chromocentric links between nonhomologs, which are preserved until prometaphase, compensate for the disturbed binding between homologous pericentromeric regions in both structural or locus mutants. When the links between nonhomologs are involved, interchromosomal effects on chromosome disjunction and nonhomologous pairing were revealed by the genetic methods. An explanation suggested for genetic events observed during Drosophilameiosis conforms with the original, cytogenetically proved model of the orderly two-ring chromocenter formation and reorganization.     

Pericentromeric chromatin reorganisation follows the initiation of recombination and coincides with early events of synapsis in cereals

The reciprocal exchange of genetic information between homologous chromosomes during meiotic recombination is essential to secure balanced chromosome segregation and to promote genetic diversity. The chromosomal position and frequency of reciprocal genetic exchange shapes the efficiency of breeding programmes and influences crop improvement under a changing climate. In large genome cereals, such as wheat and barley, crossovers are consistently restricted to subtelomeric chromosomal regions, thus preventing favourable allele combinations being formed within a considerable proportion of the genome, including interstitial and pericentromeric chromatin. Understanding the key elements driving crossover designation is therefore essential to broaden the regions available for crossovers. Here, we followed early meiotic chromatin dynamism in cereals through the visualisation of a homologous barley chromosome arm pair stably transferred into the wheat genetic background. By capturing the dynamics of a single chromosome arm at the same time as detecting the undergoing events of meiotic recombination and synapsis, we showed that subtelomeric chromatin of homologues synchronously transitions to an open chromatin structure during recombination initiation. By contrast, pericentromeric and interstitial regions preserved their closed chromatin organisation and become unpackaged only later, concomitant with initiation of recombinatorial repair and the initial assembly of the synaptonemal complex. Our results raise the possibility that the closed pericentromeric chromatin structure in cereals may influence the fate decision during recombination initiation, as well as the spatial development of synapsis, and may also explain the suppression of crossover events in the proximity of the centromeres.     

Chromocentral nature of interchromosome connections coorienting nonhomologous chromosomes in meiosis of <Emphasis Type="Italic">Drosophila melanogaster</Emphasis> females

Data are presented in favor of universal significance of physical connections between pericentromeric regions of homologs in their orientation to the opposite poles of the first meiotic division in Drosophila melanogaster. Disturbances in the formation of such connections caused by structural or locus mutations are compensated for by the presence of pericentromeric chiasmata between homologs or (in the case of their absence) by chromocentral connections between nonhomologs being preserved up to the prometaphase. In the latter case, an interchromosome effect on chromosome disjunction and nonhomologous pairing is registered by genetic methods. Inhibition of the formation of the division spindle fibers during prometaphase of meiosis 1 by the long-term action of colcemide promotes the retention of connections between paired nonexchanged homologs and between nonhomologous chromosomes with abnormal homologous pairing because of heterozygosity for numerous inversions and transpositions (X and autosome 2). These connections are registered cytologically. Cytologically registered are also connections between normal X chromosomes and metacentric compounds by the arms of autosome 2 (C(2L)RM, C(2R)RM), which is the known case of the interchromosome effect on chromosome nondisjunction. It is supposed that cytologically detected associations between compounds are realized through a normal mechanism, as a result of interaction and formation of orienting connections between the homologous pericentromeric regions of these compounds. Cytological evidence is presented for colocation of compounds in the chromocentrally organized nucleus of somatic and germline cells.     

Unusual case of 18p- syndrome: diagnosis using a cloned DNA fragment

The patient with atypical clinic picture of 18p- syndrome is described. The in situ hybridization technique was used to localize chromosome 18-specific cloned sequence to metaphase chromosomes of the proband. The predominant hybridization was found in pericentromeric regions of homologous chromosome 18. The amount of pericentromeric DNA measured by in situ hybridization was different in homologous chromosomes and the number of radioactive grains was statistically greater in the normal chromosome 18 than in the chromosome 18p-. The cause of asymmetrical hybridization of probes to homologous chromosomes 18 is discussed. The results obtained indicate that this probe may be useful in clinical cytogenetics for identification of chromosome 19 in metaphase and interphase cells, determination of breakpoints or studies of pericentromeric DNA polymorphisms.     

18p− Syndrome: an unusual case and diagnosis by in situ hybridization with chromosome 18-specific alphoid DNA sequence

Summary A patient with an atypical clinical picture of 18p^– syndrome is described. By the in situ hybridization technique we localized the chromosome 18-specific cloned repetitive sequence to metaphase chromosomes of the patient. The predominant hybridization of the probe was found in pericentromeric regions of homologous chromosomes 18. The amount of pericentromeric DNA measured by in situ hybridization differed between homologous chromosomes; and the number of radioactive grains was statistically greater in the normal chromosome 18 than in the aberrant chromosome 18p^–. The results indicate that this probe may be useful in clinical cytogenetics for identification of aberrant chromosomes, localization of breakpoints, and studies of C-band DNA polymorphism of chromosome 18.     

Synaptonemal complex spreading in Allium cepa and A. fistulosum

The general features and fine structure of homologous chromosome alignment and pairing have been investigated in two species of Allium (A. fistulosum and A. cepa), which have similar karyotypes but very different patterns of chiasma distribution. Although there is no support for the occurrence of a general pre-meiotic alignment of homologous chromosomes, both species show some alignment of homologues as an immediate prelude to synaptonemal complex (SC) formation. In both species pairing usually commences at sub-terminal sites and is succeeded by numerous separate intercalary initiations of pairing in interstitial and distal regions and then in proximal regions. The last parts to pair, in both species, are pericentromeric and telomeric regions. There is, therefore, no evident relationship between the sequence of pairing and chiasma distribution in these species. Regularly alternating convergences and divergences of aligned axial cores (ACs), termed multiple association sites, are frequently observed. It is proposed that these represent potential pairing initiation sites and from observations on their spatial distribution it is argued that they may be evenly distributed through most of the genome. Small spherical or ellipsoid nodules are found at association sites and between closely aligned ACs which persist in the SC segments present during zygotene, but most of them disappear abruptly at the end of zygotene. These are termed zygotene nodules (ZN) and it is proposed that they are involved in matching corresponding sites on homologous chromosomes as well as possibly having a recombinational role. Their composition, structure, mode of action and relationship to pachytene recombination nodules are at present unknown.     

Cloned fragment of human alphoid DNA--a molecular marker of the pericentromeric region of chromosome 18

From the library of cloned fragments of human DNA we have isolated two recombinant plasmids containing alphoid DNA sequences pBRHS13, pBRHS65. Both cloned sequences hybridized in situ predominantly to pericentromeric regions of chromosome 18 and with less intensity to pericentromeric regions of chromosomes 2, 9, 20, and were characterized by populational copy number polymorphism in homologous chromosomes. These sequences may appear very useful in the diagnostics and cytogenetic analysis of chromosomal aberrations and in studies of polymorphisms of heterochromatic regions of human chromosomes.     

Genetic linkage and heterogeneity in type I Charcot-Marie-Tooth disease (hereditary motor and sensory neuropathy type I).

The segregation patterns of DNA markers from the pericentromeric regions of chromosomes 1 and 17 were studied in seven pedigrees segregating an autosomal dominant gene for Charcot-Marie-Tooth neuropathy type I (CMT I; hereditary motor and sensory neuropathy I). A multilocus analysis with four markers (pMCR-3, pMUC10, FY, and pMLAJ1) spanning the pericentromeric region of chromosome 1 excluded the CMT I gene from this region in six pedigrees but gave some evidence for linkage to the region of Duffy in one pedigree. Linkage of the CMT I gene to markers in the pericentromeric region of chromosome 17 (markers pA10-41, pEW301, p3.6, and pTH17.19) was established; however, in these seven pedigrees homogeneity analysis with chromosome 17 markers detected significant genetic heterogeneity. This analysis suggested that three of the seven pedigrees are not linked to this same region. Overall, two of the seven CMT I pedigrees were not linked to markers tested from chromosomes 1 or 17. These results confirm genetic heterogeneity in CMT I and implicate the existence of a third autosomal locus, in addition to a locus on chromosome 17, and a probable locus on chromosome 1. This evidence of etiological heterogeneity, supported by statistical tests, will have to be taken into consideration when fine-structure genetic maps of the regions around CMT I are constructed.     

A high-density cytogenetic map of the Aegilops tauschii genome incorporating retrotransposons and defense-related genes: insights into cereal chromosome structure and function

Aegilops tauschii (Coss.) Schmal. (2n = 2x = 14, DD) (syn. A. squarrosa L.; Triticum tauschii) is well known as the D-genome donor of bread wheat (T. aestivum, 2n = 6x = 42, AABBDD). Because of conserved synteny, a high-density map of the A. tauschii genome will be useful for breeding and genetics within the tribe Triticeae which besides bread wheat also includes barley and rye. We have placed 249 new loci onto a high-density integrated cytological and genetic map of A. tauschii for a total of 732 loci making it one of the most extensive maps produced to date for the Triticeae species. Of the mapped loci, 160 are defense-related genes. The retrotransposon marker system recently developed for cultivated barley (Hordeum vulgare L.) was successfully applied to A. tauschii with the placement of 80 retrotransposon loci onto the map. A total of 50 microsatellite and ISSR loci were also added. Most of the retrotransposon loci, resistance (R), and defense-response (DR) genes are organized into clusters: retrotransposon clusters in the pericentromeric regions, R and DR gene clusters in distal/telomeric regions. Markers are non-randomly distributed with low density in the pericentromeric regions and marker clusters in the distal regions. A significant correlation between the physical density of markers (number of markers mapped to the chromosome segment/physical length of the same segment in microm) and recombination rate (genetic length of a chromosome segment/physical length of the same segment in microm) was demonstrated. Discrete regions of negative or positive interference (an excess or deficiency of crossovers in adjacent intervals relative to the expected rates on the assumption of no interference) was observed in most of the chromosomes. Surprisingly, pericentromeric regions showed negative interference. Islands with negative, positive and/or no interference were present in interstitial and distal regions. Most of the positive interference was restricted to the long arms. The model of chromosome structure and function in cereals with large genomes that emerges from these studies is discussed.     

Pericentromeric effects shape the patterns of divergence, retention, and expression of duplicated genes in the paleopolyploid soybean

The evolutionary forces that govern the divergence and retention of duplicated genes in polyploids are poorly understood. In this study, we first investigated the rates of nonsynonymous substitution (Ka) and the rates of synonymous substitution (Ks) for a nearly complete set of genes in the paleopolyploid soybean (Glycine max) by comparing the orthologs between soybean and its progenitor species Glycine soja and then compared the patterns of gene divergence and expression between pericentromeric regions and chromosomal arms in different gene categories. Our results reveal strong associations between duplication status and Ka and gene expression levels and overall low Ks and low levels of gene expression in pericentromeric regions. It is theorized that deleterious mutations can easily accumulate in recombination-suppressed regions, because of Hill-Robertson effects. Intriguingly, the genes in pericentromeric regions-the cold spots for meiotic recombination in soybean-showed significantly lower Ka and higher levels of expression than their homoeologs in chromosomal arms. This asymmetric evolution of two members of individual whole genome duplication (WGD)-derived gene pairs, echoing the biased accumulation of singletons in pericentromeric regions, suggests that distinct genomic features between the two distinct chromatin types are important determinants shaping the patterns of divergence and retention of WGD-derived genes.     

Alteration of poly(ADP-ribose) metabolism affects murine sperm nuclear architecture by impairing pericentric heterochromatin condensation

The mammalian sperm nucleus is characterized by unique properties that are important for fertilization. Sperm DNA retains only small numbers of histones in distinct positions, and the majority of the genome is protamine associated, which allows for extreme condensation and protection of the genetic material. Furthermore, sperm nuclei display a highly ordered architecture that is characterized by a centrally located chromocenter comprising the pericentromeric chromosome regions and peripherally positioned telomeres. Establishment of this unique and well-conserved nuclear organization during spermiogenesis is not well understood. Utilizing fluorescence in situ hybridization (FISH), we show that a large fraction of the histone-associated sperm genome is repetitive in nature, while a smaller fraction is associated with unique DNA sequences. Coordinated activity of poly(ADP-ribose) (PAR) polymerase and topoisomerase II beta has been shown to facilitate DNA relaxation and histone to protamine transition during spermatid condensation, and altered PAR metabolism is associated with an increase in sperm histone content. Combining FISH with three-dimensional laser scanning microscopy technology, we further show that altered PAR metabolism by genetic or pharmacological intervention leads to a disturbance of the overall sperm nuclear architecture with a lower degree of organization and condensation of the chromocenters formed by chromosomal pericentromeric heterochromatin.     

Chromosome 'speed dating' during meiosis of polyploid Brassica hybrids and haploids

Given their tremendous importance for correct chromosome segregation, the number and distribution of crossovers are tightly controlled during meiosis. In this review, we give an overview of crossover formation in polyploid Brassica hybrids and haploids that illustrates or underscores several aspects of crossover control. We first demonstrate that multiple targets for crossover formation (i.e. different but related chromosomes or duplicated regions) are sorted out during meiosis based on their level of relatedness. In euploid Brassica napus (AACC; 2n = 38), crossovers essentially occur between homologous chromosomes and only a few of them form between homeologues. The situation is different in B. napus haploids in which crossovers preferentially occur between homeologous chromosomes and a few can then form between more divergent duplicated regions. We then provide evidence that the frequency of crossovers between a given pair of chromosomes is influenced by the karyotypic and genetic composition of the plants that undergo meiosis. For instance, genetic evidence indicates that the number of crossovers between exactly the same pairs of homologous A chromosomes gets a boost in Brassica digenomic tetraploid (AACC) and triploid (AAC) hybrids. Increased autosyndesis within B. napus haploids as compared to monoploid B. rapa and B. oleracea is another illustration of this process. All these observations may suggest that polyploidization overall boosts up crossover machinery and/or that the number of crossovers is modulated through inter-bivalents or univalent-bivalent cross-talk effects. The last part of this review gives an up-to-date account of what we know about the genetic control of homologous and homeologous crossover formation among Brassica species.     

Polymorphism of heterochromatic regions of flax chromosomes

The C-banding technique was used to study flax chromosomes (Linum usitatissimum L., 2n = 30). Heterochromatin was located mainly in pericentromeric regions of chromosomes. In spite of small size (1.5-3.5 microm), all 15 pairs of homologous chromosomes were identified on the basis of the C-banding pattern and morphology. An idiogram of C-banded chromosomes of L usitatissimum L. is presented. Polymorphism of chromosomal heterochromatic regions was studied in karyotypes of three flax samples: L usitatissimum L., accession K-603 (L usitatissimum var. usitatissimum), and accession K-594 (L. usitatissimum var. humile (Mill.)). A common C-banding pattern was observed in all forms studied, although there were some distinctions in the individual band size. The fibre flax (accession K-603) karyotype had the C-banding pattern similar to that of L usitatissimum L., but some intercalary and telomeric C-bands were somewhat larger, and a satellite (NOR) was observed in the short arm of chromosome I. In crown flax, (K-594) chromosomal C-banding pattern exhibited smaller pericentromeric and larger intercalary bands; telomeric bands were present on almost all chromosomes. Thus, the intraspecies polymorphism revealed in the chromosomal C-banding pattern makes possible the use of C-bands as chromosome markers in the studies of genetic and genomic polymorphism of this species.     

Comparative FISH analysis of distribution of B chromosome repetitive DNA in A an d B chromosomes in two subspecies of Podisma sapporensis (Orthoptera, Acrididae)

FISH analysis of B chromosome repetitive DNA distribution in A and B chromosomes of two subspecies of Podisma sapporensis (P. s. sapporensis and P. s. krylonensis) was performed. In the B chromosomes, C-positive regions contained homologous DNA repeats present also in some C-positive A chromosome regions. Most C-negative regions contained DNA repeats characteristic of A chromosome euchromatic regions. The two subspecies analyzed differed in the location of A chromosome regions enriched with repeats homologous to repeats of B chromosomes. The only common region enriched with these B chromosome repeats in both subspecies was the X chromosome pericentromeric region. The origin of B chromosomes in P. sapporensis is discussed.     

A new gypsy-type retrotransposon, RIRE7: preferential insertion into the tandem repeat sequence TrsD in pericentromeric heterochromatin regions of rice chromosomes

A portion of an insertion sequence present in a member of the RIRE3 family of retrotransposons in Oryza sativa L. cv. IR36 was found to have an LTR sequence followed by a PBS sequence complementary to the 3'-end region of tRNAMet, indicative of another rice retrotransposon (named RIRE7). Cloning and sequencing of PCR-amplified fragments that made up all parts of the RIRE7 sequence showed that RIRE7 is a gypsy-type retrotransposon with partial homology in the pol region to the rice gypsy-type retrotransposons RIRE2 and RIRE3 identified in rice previously. Interestingly, various portions of the RIRE7 sequence were homologous to several DNA segments present in the centromere regions of cereal chromosomes. Further cloning and nucleotide sequencing of fragments flanking RIRE7 copies showed that RIRE7 was inserted into a site within a tandem repeat sequence that has a unit length of 155 bp. The tandem repeat sequence, named TrsD, was homologous to tandem repeat sequences RCS2 and CentC, previously identified in the centromeric regions of rice and maize chromosomes. Fluorescence in situ hybridization (FISH) analysis of the metaphase chromosomes of O. sativa cv. Nipponbare showed that both RIRE7 and TrsD sequences were present in the centromere regions of the chromosomes. The presence of RIRE7 and the TrsD sequences in the centromere regions of several chromosomes was confirmed by the identification of several YAC clones whose chromosomal locations are known. Further FISH analysis of rice pachytene chromosomes showed that the TrsD sequences were located in a pericentromeric heterochromatin region. These findings strongly suggest that RIRE7 and TrsD are components of the pericentromeric heterochromatin of rice chromosomes.     

拟南芥DNA探针的比较基因组原位杂交揭示的拟南芥与远缘植物基因组间的同源性

采用生物素标记的拟南芥基因组DNA探针在75%杂交严谨度下对双子叶植物番茄、蚕豆和单子叶植物水稻、玉米、大麦的染色体进行了比较基因组荧光原位杂交（comparative genomic in situ hybridization,cGISH）分析,以揭示拟南芥与远缘植物基因组间的同源性.cGISH信号代表了拟南芥基因组DNA中的重复DNA与靶物种染色体上同源序列的杂交.探针DNA在所有靶物种的全部染色体上都产生了杂交信号.杂交信号为散在分布,并呈现随基因组增大,杂交信号增多,且分布更加分散的趋势.所有靶物种的核仁组织区（NOR）都显示了明显强于其他区域的杂交信号,表明拟南芥基因组DNA探针可用于植物NOR的物理定位.在所有的靶物种中,信号主要分布在染色体的臂中间区和末端,着丝粒或近着丝粒区有少数信号分布.大麦染色体显示了与C-和N-带不同的独特的cGISH信号带型,表明此探针可用于不同植物染色体的识别.这些结果表明,拟南芥基因组与远缘植物基因组之间,除rDNA和端粒重复序列外,还存在其它同源的重复DNA;一些重复DNA序列在被子植物分歧进化为单子叶和双子叶植物之前就已存在,虽经历了长期的进化过程,至今在远缘物种之间仍保持了较高的同源性.结果还提示,大基因组中古老而保守的重复DNA在进化过程中发生了明显的扩增.     

Role for rodent Smc6 in pericentromeric heterochromatin domains during spermatogonial differentiation and meiosis

Chromatin structure and function are for a large part determined by the six members of the structural maintenance of chromosomes (SMC) protein family, which form three heterodimeric complexes: Smc1/3 (cohesin), Smc2/4 (condensin) and Smc5/6. Each complex has distinct and important roles in chromatin dynamics, gene expression and differentiation. In yeast and Drosophila, Smc6 is involved in recombinational repair, restarting collapsed replication forks and prevention of recombination in repetitive sequences such as rDNA and pericentromeric heterochromatin. Although such DNA damage control mechanisms, as well as highly dynamic changes in chromatin composition and function, are essential for gametogenesis, knowledge on Smc6 function in mammalian systems is limited. We therefore have investigated the role of Smc6 during mammalian spermatogonial differentiation, meiosis and subsequent spermiogenesis. We found that, during mouse spermatogenesis, Smc6 functions as part of meiotic pericentromeric heterochromatin domains that are initiated when differentiating spermatogonia become irreversibly committed toward meiosis. To our knowledge, we are the first to provide insight into how commitment toward meiosis alters chromatin structure and dynamics, thereby setting apart differentiating spermatogonia from the undifferentiated spermatogonia, including the spermatogonial stem cells. Interestingly, Smc6 is not essential for spermatogonial mitosis, whereas Smc6-negative meiotic cells appear unable to finish their first meiotic division. Importantly, during meiosis, we find that DNA repair or recombination sites, marked by γH2AX or Rad51 respectively, do not co-localize with the pericentromeric heterochromatin domains where Smc6 is located. Considering the repetitive nature of these domains and that Smc6 has been previously shown to prevent recombination in repetitive sequences, we hypothesize that Smc6 has a role in the prevention of aberrant recombination events between pericentromeric regions during the first meiotic prophase that would otherwise cause chromosomal aberrations leading to apoptosis, meiotic arrest or aneuploidies.     

Co-evolution of plant LTR-retrotransposons and their host genomes

zTransposable elements (TEs), particularly, long terminal repeat retrotransposons (LTR-RTs), are the most abundant DNA components in all plant species that have been investigated, and are largely responsible for plant genome size variation. Although plant genomes have experienced periodic proliferation and/or recent burst of LTRretrotransposons, the majority of LTR-RTs are inactivated by DNA methylation and small RNA-mediated silencing mechanisms, and/or were deleted/truncated by unequal homologous recombination and illegitimate recombination, as suppression mechanisms that counteract genome expansion caused by LTR-RT amplification. LTR-RT DNA is generally enriched in pericentromeric regions of the host genomes, which appears to be the outcomes of preferential insertions of LTR-RTs in these regions and low effectiveness of selection that purges LTR-RT DNA from these regions relative to chromosomal arms. Potential functions of various TEs in their host genomes remain blurry; nevertheless, LTR-RTs have been recognized to play important roles in maintaining chromatin structures and centromere functions and regulation of gene expressions in their host genomes.