Reorganization of the X chromosome in voles of the genus Microtus

Comparative chromosomal analysis is a powerful tool in the investigation of the mechanisms of chromosomal evolution. The accuracy of the analysis depends on the availability of region-specific markers to follow the fate of the particular chromosomal region through the evolution of species. We have assigned 12 unique sequences to the euchromatic part of the vole X chromosome, which serve as reliable markers of chromosomal segments. Together with region-specific libraries and GTG banding, these markers allow us to delineate the homologous regions of the X chromosomes in five species of the genus Microtus. We found that X chromosomes of these species differ by numerous rearrangements and all rearrangements are clustered at specific breakpoints. Moreover, these breakpoints were found to colocalise with repetitive and/or duplicated DNA sequences. We suggest that clusters of repeated and/or duplicated DNA sequences have played a crucial role in the formation of rearrangement hot spots during evolution of the X chromosome in the subgenus Microtus.     

Repair and Reconstruction of Telomeric and Subtelomeric Regions and Genesis of New Telomeres: Implications for Chromosome Evolution

DNA damage repair within telomeres are suppressed to maintain the integrity of linear chromosomes, but the accidental activation of repairs can lead to genome instability. This review develops the concept that mechanisms to repair DNA damage in telomeres contribute to genetic variability and karyotype evolution, rather than catastrophe. Spontaneous breaks in telomeres can be repaired by telomerase, but in some cases DNA repair pathways are activated, and can cause chromosomal rearrangements or fusions. The resultant changes can also affect subtelomeric regions that are adjacent to telomeres. Subtelomeres are actively involved in such chromosomal changes, and are therefore the most variable regions in the genome. The case of Caenorhabditis elegans in the context of changes of subtelomeric structures revealed by long-read sequencing is also discussed. Theoretical and methodological issues covered in this review will help to explore the mechanism of chromosome evolution by reconstruction of chromosomal ends in nature.     

Comparative mapping of a gorilla-derived alpha satellite DNA clone on great ape and human chromosomes

We have isolated an alpha satellite DNA clone, pG3.9, from gorilla DNA. Fluorescence in situ hybridization on banded chromosomes under high stringency conditions revealed that pG3.9 identifies homologous sequences at the centromeric region of ten gorilla chromosomes, and, with few exceptions, also recognizes the homologous chromosomes in human. A pG3.9-like alphoid DNA is present on a larger number of orangutan chromosomes, but, in contrast, is present on only tow chromosomes in the chimpanzee. These results show that the chromosomal subsets of related alpha satellite DNA sequences may undergo different patterns of evolution.by J.B. Rattner     

利用染色体涂染方法建立人和白眉长臂猿(Hylobates hoolock)的比较染色体图谱

除人Y染色体外,本文采用生物素标记的人全部整条染色体特异探针与白眉长臂猿(Hylobates hoolock)有丝分裂中期分裂相进行染色体原位杂交即染色体涂染法以研究人和白眉长臂猿染色体之间的同源性。在白眉长臂猿18对常染色体上检测出了与人22对常染色体同源的59对染色体片段,确定了人和白眉长臂猿之间的精度较高的染色体连锁群。结果表明:自人与白眉长臂猿的祖先分歧以来,大量的染色体间重排(至少发生了39次易位)和染色体内的重排导致了二者核型的差异。根据杂交结果绘制了首份人和白眉长臂猿比较染色体图谱,并结合已有的人和白掌长臂猿(Hylobates lar)(2n=44)和合趾长臂猿(Hylobates syndactylus)(2n=50)的比较染色体图谱对长臂猿属的染色体进化作了初步的探讨。     

Breakage-fusion-bridge Cycles and Large Insertions Contribute to the Rapid Evolution of Accessory Chromosomes in a Fungal Pathogen

Chromosomal rearrangements are a major driver of eukaryotic genome evolution, affecting speciation, pathogenicity and cancer progression. Changes in chromosome structure are often initiated by mis-repair of double-strand breaks in the DNA. Mis-repair is particularly likely when telomeres are lost or when dispersed repeats misalign during crossing-over. Fungi carry highly polymorphic chromosomal complements showing substantial variation in chromosome length and number. The mechanisms driving chromosome polymorphism in fungi are poorly understood. We aimed to identify mechanisms of chromosomal rearrangements in the fungal wheat pathogen Zymoseptoria tritici. We combined population genomic resequencing and chromosomal segment PCR assays with electrophoretic karyotyping and resequencing of parents and offspring from experimental crosses to show that this pathogen harbors a highly diverse complement of accessory chromosomes that exhibits strong global geographic differentiation in numbers and lengths of chromosomes. Homologous chromosomes carried highly differentiated gene contents due to numerous insertions and deletions. The largest accessory chromosome recently doubled in length through insertions totaling 380 kb. Based on comparative genomics, we identified the precise breakpoint locations of these insertions. Nondisjunction during meiosis led to chromosome losses in progeny of three different crosses. We showed that a new accessory chromosome emerged in two viable offspring through a fusion between sister chromatids. Such chromosome fusion is likely to initiate a breakage-fusion-bridge (BFB) cycle that can rapidly degenerate chromosomal structure. We suggest that the accessory chromosomes of Z. tritici originated mainly from ancient core chromosomes through a degeneration process that included BFB cycles, nondisjunction and mutational decay of duplicated sequences. The rapidly evolving accessory chromosome complement may serve as a cradle for adaptive evolution in this and other fungal pathogens.     

Painting of defined chromosomal regions by in situ suppression hybridization of libraries from laser-microdissected chromosomes

"Painting" of defined chromosomal regions provides a powerful tool for cytogenetic analyses. Here, we demonstrate that chromosomal in situ suppression (CISS)-hybridization of DNA libraries derived by microcloning laser-microdissected chromosomal regions can be applied to achieve this goal. As an example, we used unbanded metaphase spreads from a female patient carrying a balanced translocation. t(1;7)(1qter----1p36::7q11----7qter). Fragments from the long arms of 130 translocation chromosomes were microdissected. After microcloning, human inserts with an average size of about 3 kb were pooled from 400 recombinant bacteriophage DNA clones and used as a complex probe set in CISS-hybridization experiments. This resulted in painting of the translocation chromosome along the region 7q35 to 1p31. Painted chromosomal subregions in normal chromosomes 1 and 7 were consistent with this finding. This approach may be used to perform painting of any chromosome regions for which microlibraries can be established. Possible applications include the definition of marker chromosomes in clinical and tumor cytogenetics and studies of chromosomal evolution, as well as studies of nuclear chromosome topography in animal and plant species.     

The genomics of long tandem arrays of satellite DNA in the human genome

At least 10% of DNA in the human genome consists of long arrays of repeated sequences, arranged in tandem head-to-tail arrays in a number of discrete, highly localized chromosomal regions. Different families of these so-called "satellite DNA" sequences have been defined, organized in diverged subsets on different chromosomes. The molecular, cytogenetic, and evolutionary analysis of the hierarchical organization of such sequences in the human and other complex genomes encompasses a variety of approaches, including chromosomal mapping, in situ hybridization, genetic linkage analysis, long-range restriction mapping, and DNA sequencing. Investigation of the organization of satellite arrays constitutes a necessary first step towards eventual elucidation of the origin, evolution, and maintenance of these sequences and their contribution to the structure and behavior of human chromosomes.     

Repetitive DNA, chromosome polymorphism and speciation of gerbils

Restriction analysis of DNA and differential staining of chromosomes in three species of the genus Meriones: M. tristrami. M. meridianus. M. inguiculatus was carried out. High extent of homology of the genomes under study was found at the molecular and chromosomal levels. Speciation of M. tristrami followed by numerous fissions of metacentric chromosomes is assumed to be connected with appearance of the short BspRI sequence. Possible mechanisms of the mammal genome evolution are discussed.     

Mapping of rRNA genes and telomeric sequences in Danube salmon (<Emphasis Type="Italic">Hucho hucho</Emphasis>) chromosomes using primed in situ labeling technique (PRINS)

In the current paper we described the application of primed in situ (PRINS) labeling approach for the chromosomal mapping of repetitive DNA sequences in Danube salmon (Hucho hucho) (2n = 82, NF = 112). PRINS was successfully performed with primers enabling amplification of 5S rRNA genes (minor rDNAs), NOR building DNA sequences (major rDNAs), and telomeric sequences. Two loci of 5S rRNA were observed on distinct chromosome pairs; the minor arrays were located interstitially on the long (q) arms of two large metacentrics (chromosomes No. 3) and the large clusters of 5S rDNAs were assigned to the short (p) arms of two subtelocentric chromosomes No. 18. Major rDNA clusters were observed on the p-arms of two submeta-subtelocentric chromosomes No. 10. These chromosomal areas were built with GC-rich chromatin what was proved in the course of chromomycin A(3) (CMA(3)) staining performed sequentially. Major and minor rDNA families were not co-localized in the Danube salmon chromosomes.The distinct hybridization signals at the ends of all the chromosomes were provided in the course of PRINS with (CCCTAA)( n ) primer. The chromosomal localization of rRNA genes and telomeric DNA sequences was discussed in the context of Salmonidae karyotype evolution.     

Meiotic drive of chromosomal knobs reshaped the maize genome.

Meiotic drive is the subversion of meiosis so that particular genes are preferentially transmitted to the progeny. Meiotic drive generally causes the preferential segregation of small regions of the genome; however, in maize we propose that meiotic drive is responsible for the evolution of large repetitive DNA arrays on all chromosomes. A maize meiotic drive locus found on an uncommon form of chromosome 10 [abnormal 10 (Ab10)] may be largely responsible for the evolution of heterochromatic chromosomal knobs, which can confer meiotic drive potential to every maize chromosome. Simulations were used to illustrate the dynamics of this meiotic drive model and suggest knobs might be deleterious in the absence of Ab10. Chromosomal knob data from maize's wild relatives (Zea mays ssp. parviglumis and mexicana) and phylogenetic comparisons demonstrated that the evolution of knob size, frequency, and chromosomal position agreed with the meiotic drive hypothesis. Knob chromosomal position was incompatible with the hypothesis that knob repetitive DNA is neutral or slightly deleterious to the genome. We also show that environmental factors and transposition may play a role in the evolution of knobs. Because knobs occur at multiple locations on all maize chromosomes, the combined effects of meiotic drive and genetic linkage may have reshaped genetic diversity throughout the maize genome in response to the presence of Ab10. Meiotic drive may be a major force of genome evolution, allowing revolutionary changes in genome structure and diversity over short evolutionary periods.     

Genomic distribution of heterochromatic sequences in equids: implications to rapid chromosomal evolution.

We describe a molecular model for rapid chromosomal evolution that proposes tandemly repeated DNA sequences as a driving force. A prediction of this model is that when extensive rearrangements of euchromatin have been facilitated by heterochromatin, genomes will be characterized by tandemly repeated sequences that have actively changed chromosomal fields by intragenomic movement. Alternatively, it is proposed that in conservative chromosomal lineage each class of tandemly repeated sequences will be restricted to a specific chromosomal field. To provide baseline data to test this model we examined four classes of tandemly repeated elements in six species of equids (Equus). Distribution of these sequences among species, as determined from slot blot analysis, and restriction site variation, shown by Southern blot hybridization, document that these sequences are in an evolutionarily dynamic state, and in situ hybridization documents extensive intragenomic movement among nonhomologous chromosomes and chromosomal fields. These data are interpreted as being compatible with the predictions of this model. Although this is clearly not the sole molecular factor driving chromosomal evolution, the model appears to be viable as an explanation of certain patterns of chromosomal evolution such as karyotypic megaevolution and some types of karyotypic orthoselection.     

Evolution of the genome size inAkodon (Rodentia,Cricetidae)

Nuclear DNA contents were estimated by microdensitometry in five species of Akodon rodents: Arodon molinae, A. dolores, A. mollis, A. azarae, Bolomys obscurus) and in three chromosomal varieties of A. molinae (2n = 42; 2n = 43, 2n = 22). The data obtained showed that the species with the highest DNA content was B. obscurus, followed in order of decreasing genome size by A. molinae, A. mollis, A. dolores and A. azarae. In A. molinae the forms with 2n = 42 chromosomes had the lowest and the forms with 2n = 44 the highest amount of DNA, while the forms with 2n = 43 had intermediate DNA contents. The variation in DNA amount detected in A. molinae was interpreted as a phenomenon of amplification occurring in the chromosomal areas involved in the chromosomal rearrangement giving rise to the polymorphism exhibited by this species. The DNA contents of shared chromosomes (chromosomes with similar size, morphology and G banding pattern, which are found in two or more phylogenetically related species), were compared and correlated with values of total nuclear DNA. The information obtained indicates that: (a) shared chromosomes have variable amounts of DNA: (b) in a given species there is a correlation between the amount of nuclear and chromosomal DNA in most shared chromosomes (and perhaps in most of the chromosomal complement), e.g., the higher the amount of nuclear DNA, the higher the content of DNA in shared chromosomes; (c) some chromosomes may undergo processes of amplification or deletion restricted to certain regions and usually related with mechanisms of chromosomal rearrangements.(ABSTRACT TRUNCATED AT 250 WORDS)     

Different patterns in molecular evolution of the Triticeae

A huge part of the genomes of most Triticeae species is formed by different families of repetitive DNA sequences. In this paper the phylogenetic distribution of two major classes of the repeats, retrotransposons and tandemly organized DNA sequences, are considered and compared with the evolution of gene-rich regions and generally accepted Triticeae phylogenetic relationships. In Hordeum, LTR-containing retrotransposons are dispersed along the chromosomes and are consistent with the existing picture of the phylogeny of Hordeum. Another retrotransposon class, LINEs, have evolved independently from LTR-retrotransposons. Different retrotransposon classes appear to have competed for genome space during the evolution of Hordeum. Another class of repeats, tandemly organized DNA sequences, tends to cluster at the functionally important regions of chromosomes, centromeres and telomeres. The distribution of a number of tandem DNA families in Triticeae is not congruent with generally accepted phylogenetic relationships. While natural selection is the dominant factor determining the structure of genic regions we suggest that the contribution of random events is important in the evolution of repetitive DNA sequences. The interplay of stochastic processes, molecular drive, and selection determines the structure of chromosomal regions, notably at centromeres and telomeres, stabilizing and differentiating species-specific karyotypes. Thus, the evolution of these regions may occur largely independently of the evolution of gene-rich regions.     

Intragenomic movement and concerted evolution of satellite DNA in Peromyscus: evidence from in situ hybridization.

Four DNA probes isolated from Peromyscus leucopus were used to examine intra- and interspecific variation in the chromosomal location of satellite DNA in the genus Peromyscus. All four probes hybridized to the centromeric regions of all chromosomes in all species of Peromyscus examined but did not hybridize to the majority of heterochromatic regions in closely related non-Peromyscus species. One probe contains a nonsatellite repetitive sequence. The implications of these data to the evolution of genome organization are discussed.     

B chromosomes of the Podisma sapporensis Shir. (Orthoptera, Acrididae) analysed by chromosome microdissection and FISH

The analysis of the distribution of repetitive DNA of the B chromosomes of Podisma sapporensis in the A and B chromosomes of the natural populations and in A chromosomes of three other species of the Podismini grasshoppers were made. DNA-libraries of the B chromosome and the euchromatic segment of the A chromosome of P. sapporensis were generated by meiotic chromosome microdissection followed by degenerated oligonucleotide primed polymerase chain reaction (DOP-PCR). Paints based on these DNA-libraries were used for FISH analysis to detect localization of homologous sequences in A and B chromosomes of P. sapporensis from different natural populations. On the basis of the FISH analysis the authors suggest that evolution of the B chromosomes in Podisma sapporensis was associated mainly with the insertions of "alien DNA sequences" into ancestral A chromosome and their further amplification. The number of initial sites of amplifications differed in the different Bs, the distance between these sites also varying. Karyotype evolution in P. sapporensis was associated partly with the insertion of "alien DNA sequences" into pericentromeric chromosomal regions. Insertion into the small short arms of the acrocentric chromosomes followed, with the DNA amplification leading to the formation of the additional C-heterochromatic arms or euchromatic-like regions of different size.     

The 1.688 repetitive DNA of Drosophila: concerted evolution at different genomic scales and association with genes

Concerted evolution leading to homogenization of tandemly repeated DNA arrays is widespread and important for genome evolution. We investigated the range and nature of the process at chromosomal and array levels using the 1.688 tandem repeats of Drosophila melanogaster where large arrays are present in the heterochromatin of chromosomes 2, 3, and X, and short arrays are found in the euchromatin of the same chromosomes. Analysis of 326 euchromatic and heterochromatic repeats from 52 arrays showed that the homogenization of 1.688 repeats occurred differentially for distinct genomic regions, from euchromatin to heterochromatin and from local arrays to chromosomes. We further found that most euchromatic arrays are either close to, or are within introns of, genes. The short size of euchromatic arrays (one to five repeats) could be selectively constrained by their role as gene regulators, a situation similar to the so-called "tuning knobs."     

新疆野生油菜细胞遗传学研究──Ⅱ．染色体的形态特征、过氧化物酶同工酶和mtDNA分析

对７０个不同编号的新疆野生油菜和黑芥进行了染色体形态特征、过氧化物酶同工酶和ｍｔＤＮＡ的研究,结果表明：新疆野生油菜的染色体数为２ｎ＝１８,不同于黑芥（Ｂ．ｎｉｇｒａ）尤嫩斯２ｎ＝１６。新疆野生油菜与黑芥的核型都为Ｂ型,但染色体比不同,新疆野生油菜的染色体比小于黑芥。用吉姆萨染色,新疆野生油菜带型不同于黑芥,最明显的差异是新疆野生油菜有一对染色体显全带,表示为组成型异染色质,而黑芥没有。过氧化物酶酶带的明显差异是新疆野生油菜比黑芥多一条酶带。ｍｔＤＮＡ分析表明,新疆野生油菜与黑芥都有主带ＤＮＡ分子,但新疆野生油菜还有两条质粒状ＤＮＡ带,而黑芥没有。由此认为新疆野生油菜与黑芥不是同一个种,但亲缘关系密切,并推测在黑芥的演化过程中,新疆野生油菜可能是最原始的类型,到现在或许还有少数的过渡类型。     

Some factors affecting the action of restriction endonucleases on human metaphase chromosomes

We have investigated whether restriction endonucleases produce bands on human chromosomes by extracting DNA, using staining methods which are stoichiometric for DNA. Restriction enzymes that produce C-band patterns appear to remove DNA extensively from chromosome arms. In general, however, those restriction enzymes that produce G-bands do not extract DNA from chromosomes, and their effects are believed to be due to conformational change in the chromosomal DNA; in these cases, the chromosomal regions affected appear to be determined by the chromosome structure and not by the specificity of the enzyme. DNA loss from chromosomes due to digestion by restriction enzymes may in some cases be uniform, although a G-banding pattern is visible after Giemsa staining.     

Restriction endonuclease and molecular analyses of three rat genomes with special reference to chromosome rearrangement and speciation problems

When differences are found between related species of organisms, it is often assumed that the differences themselves are causal factors either in speciation itself or in processes related to speciation. Two recent proposals on the functions of satellite DNA (Hatch et al., 1976 and Fry and Salser, 1977) are that (a) large amounts of satellite DNA are important in facilitating chromosome rearrangements and hence cytogenetic evolution, and (b) satellite DNA differences between homologous chromosomes lead to pairing difficulties and are important in generating infertility barriers and hence speciation. If these proposals were to have some generality, one could expect organisms with very low amounts of highly repeated DNA to exhibit few chromosome rearrangements and to be evolutionarily conservative in a cyto-genetic sense. — We have chosen two very closely related species of rat which are phenotypically almost indistinguishable and which have undergone massive genome reorganization. They differ by 11 major centric rearrangements (2n=32, 2n=50). We have characterised their genomes by restriction endonuclease digestions, thermal denaturations, analytical ultracentrifugations and reassociation techniques, and have found that they have virtually no highly repeated DNA. Thus the 11 major chromosomal rearrangements have been fixed in present day genomes with hardly any highly repeated DNA, centric or otherwise. — It appears therefore that a large amount of highly repeated DNA is not obligatory for the formation and fixation of chromosome rearrangements. In addition, the existing literature reveals that one can find almost any situation at all, from species groups with high amounts of satellite DNA and no gross chromosomal rearrangements, to ones such as those described here, with tiny amounts of highly repeated DNA and massive chromosomal reorganisation. Since direct experimental data indicates that satellite DNA differences per se between homologous chromosomes do not cause infertility, speculations concerning modes of speciation based on satellite DNA differences between otherwise homologous chromosomes would appear to be ill founded.     

Telomeres: more than chromosomal non-sticking ends

Telomeres are specialized natural ends of eukaryotic chromosomes that, contrary to the ends of broken chromosomes, are stable and do not fuse with the ends of other chromosomes. In addition, telomeres protect chromosomal ends from degradation, facilitate completion of chromosomal DNA replication, and contribute to chromosome positioning within nuclei. Telomeric DNA consists of repetitive sequences and specific associated proteins, including the telomere repeat-binding factors TRF1 and TRF2. A lack of TRF2 enables end-to-end chromosome fusion. A structural disruption of telomeres not only causes chromosomal mechanical instability but also activates a programmed cell death cascade.