Diagrammatic representation for chromosomal mutagenesis studies IV. Radiation-induced rearrangements in Ateles sp. (Primate,Platyrhini)

In order to study the induction of rearrangements by γ-rays in relation to chromosomal size and morphology, experiments were conducted in an Ateles, a species with a rather unusual karyotype among primates. It possesses some very large chromosomes, which tend to be too rarely affected, especially by intrachanges like inversions. Both their large size and their characteristic banding pattern suggest that this low involvement is not due to difficulty of analysis. This suggests very strongly that chromosomal involvement in rearrangements is not a function of size. The possible role of other factors involved in chromosomal rearrangements like chromosome position during interphase are discussed.     

Probable involvement of immunoglobulin superfamily genes in most recurrent chromosomal rearrangements from ataxia telangiectasia

Summary From the chromosomal analysis of 9461 lymphocytes from 57 patients affected by ataxia telangiectasia, it is concluded that bands 7p14, 7q35, 14q12, and 14qter, which are frequently recombined in rearrangements are also too frequently involved in rearrangements with a few other chromosome sites. Among these sites, the most frequently involved are bands 2p11, 2p12, 22q12, and 22q13.2, or the proximal parts of adjacent R-bands. The same rearrangements were observed in a large series of control lymphocytes but their frequencies were much lower than in ataxia telangiectasia. All these recurrent sites of rearrangements, except 22q13.2, are known to be near or at immunoglobulin genes or partially homologous genes like T-cell receptor genes and antigen Leu-2/T8. It is supposed that the rearrangements observed correspond to the visualization at the chromosomal level of illegitimate rearrangements between these genes, and by analogy, that another similar structure may exist on band 22q13.2.     

The non-random occurrence of Robertsonian fusion in the house mouse

Chromosomal rearrangements such as Robertsonian (Rb) fusions constitute a major phenomenon in the evolution of genome organization in a wide range of organisms. Although proximate mechanisms for the formation of Rb fusion are now well identified, the evolutionary forces that drive chromosomal evolution remain poorly understood. In the house mouse, numerous chromosomal races occur in nature, each defined by a unique combination of Rb fusions. Among the 106 different Rb fusions that were reported from natural populations, the low involvement of chromosome 19 in Rb fusions is striking, prompting the question of the randomness of chromosomal involvement in Rb fusions. We uncover a significant quadratic relationship between chromosome size and probability of fusing, which has never previously been in this species. It appears that fusions involving chromosome 19 are not particularly infrequent, given the expected low fusion probability associated with the chromosome's size. The results are discussed, assessing selective processes or constraints that may operate on chromosome size.     

Chromosomal evolution in the lizard genus Varanus (reptilia).

The karyotypes have been determined of 16 of the 32 species of the genus Varanus, including animals from Africa, Israel, Malaya and Australia. A constant chromosome number of 2n = 40 was observed. The karyotype is divided into eight pairs of large chromosomes and 12 paris of microchromosomes. A series of chromosomal rearrangements have become established in both size groups of the karyotype and are restricted to centromers shifts, probably caused by pericentric inversion. Species could be placed in one of six distinct karyotype groups which are differentiated by these rearrangements and whose grouping does not always correspond with the current taxonomy. An unusual sex chromosome system of the ZZ/ZW type was present in a number of the species examined. The evolutionary significance of these chromosomal rearrangements, their origin and their mode of establishment are discussed and related to the current taxonomic groupings. The most likely phylogenetic model based on chromosome morphology, fossil evidence and the current distribution of the genus Varanus is presented.     

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.     

Chromosomal rearrangements breakpoints clusterization: is the clonal selection involved

Certain types of cancer are often correlate with certain chromosomal rearrangements. The chimaeric genes are formed as a result of this rearrangements, and the chimaeric proteins are the products of their expression. The breakpoints of such translocation are often clustered in the genome. Moreover, such breakpoint clusters often contain specific genomic elements like topoisomerase II consensus sites, nuclear matrix attachment regions and DNA sequences, which can make up secondary non-canonical structure. In this review we discuss whether breakpoints may be induced by chromatin structure. Furthermore, we bring up not touched upon literature question about the relation between the breakpoint clusters and the domain organization of corresponding proteins. We also consider possible mechanisms of chromosomal rearrangements.     

Chromosomal evolution in Primates: Tentative phylogeny from Microcebus murinus (Prosimian) to man

Summary The karyotypes of more than 60 species of Primates are studied and compared, with the use of almost all existing banding techniques. There is a very close analogy of chromosome banding between the Simians studied and man. The quantitative or qualitative variations detected all involve the heterochromatin. It is very likely that all the euchromatin (nonvariable R and Q bands) is identical in all the species.Approximately 70% of the bands are common to the Simians and to the Lemurs (Prosimians). In the remaining 30%, technical difficulties prevented a valuable comparison, but this does not exclude the possibility that a complete analogy may exist.Thus, it is very likely that chromosomal evolutions of the Simians, and probably of all the Primates, has occurred without duplication or deficiency of the euchromatin.Approximately 150 rearrangements could be identified and related to the human chromosomes. The types of rearrangements vary from one group (suborder, family, genus) to another. For instance, Robertsonian translocations are preponderant among the Lemuridae (44/57) but are nonexistent among the Pongidae. Chromosome fissions are very frequent among the Cercopithecidae (10/23), but were not found elsewhere, and pericentric inversions are preponderant in the evolution of Pongidae and man (17/28).This suggests that the chromosomal evolution may be directed by the genic constitution (favouring the occurrence of a particular type of rearrangement, by enzymatic reaction), by the chromosomal morphology (the probability that Robertsonian translocations will be formed depends at least partially on the number of acrocentrics), and by the reproductive behaviour of the animals.Reconstitution of the sequence of the chromosomal rearrangements allowed us to propose a fairly precise genealogy of many Primates, giving the positions of the Catarrhines, the Platyrrhines, and the Prosimians. It was also possible to reconstruct the karyotypes of ancestors that died out several dozen million years ago.The possible role of chromosomal rearrangements in evolution is discussed. It appears necessary to consider different categories of rearrangements separately, depending on their behaviour. The nonfavoured rearrangements, such as pericentric inversions, need to occur in an isolated small population for implanting, by an equivalent of genic derivation.The favoured rearrangements, e.g., Robertsonian translocations, may occur and diffuse in panmictic populations, and accumulate. Their role of gametic barrier could be much more progressive.For discrimination between these two categories, it was necessary to differentiate the selective advantage or disadvantage of the rearrangement itself. It was not possible to show that chromosomal rearrangements play a direct role in modification of the phenotype by position effect.Comparison of the rearrangements that have occurred during evolution and those detected in the human population shows a strong correlation for some of them. In particular, a large proportion of pericentric inversions can be regarded as reverse mutations, because they reproduce ancestral chromosomes.     

Systematics and phylogeny of West African gerbils of the genus Gerbilliscus (Muridae: Gerbillinae) inferred from comparative G- and C-banding chromosomal analyses

Comparative analysis of the G- and C-banding patterns in six morphologically similar species of the genus Gerbilliscus(G. gambianus, G. guineae, G. kempi, Gerbilliscus sp., G. robustus and G. leucogaster) and one belonging to the genus Gerbillurus (G. tytonis) from 27 West, East and South African localities was carried out. Our study revealed that 17 rearrangements comprising seven fissions, five translocations and five inversions occurred in the evolution of this group, with 1-13 rearrangements differentiating the various species. In addition the unusually large sex chromosomes appear to be species-specific as judged by size and morphology reflecting structural rearrangements as well as the variable presence of a large amount of C-heterochromatin found in each species at a particular chromosomal location. These karyotypic features allow us to recognize five distinct species in West Africa (compared to the two recognized in recent taxonomic lists) and to roughly delimit their geographical distributions. The pattern of phylogenetic relationships inferred from a cladistic analysis of the chromosomal data is in good agreement with recent molecular phylogenetic studies that recognize a West African species group within the genus Gerbilliscus, and the monophyly of both Gerbilliscus and Gerbillurus.     

A high degree of macronuclear chromosome polymorphism is generated by variable DNA rearrangements in Paramecium primaurelia during macronuclear differentiation.

DNA rearrangements in Paramecium lead to the formation of macronuclear chromosomes, the sizes of which range from 50 and 800 kb (1 kb is 10(3) base-pairs). This process does not appear to be a simple size reduction of the micronuclear chromosomes by specific and reproducible DNA sequence elimination and chromosomal breakage followed by chromosomal amplification. On the contrary, this process generates a variety of different, but sequence-related, macronuclear chromosomes from a unique set of micronuclear chromosomes. This paper describes an attempt to understand the nature of the diversity of the macronuclear chromosomes and the mechanisms of their production. The structure of three macronuclear chromosomes, 480, 250 and 230 kb in size, have been determined utilizing chromosome-jumping and YAC-cloning techniques. The two smallest chromosomes correspond roughly to the two halves of the longest chromosome. The main contribution to the diversity arises from the chromosomal ends and is due to variable positions of the telomere addition sites and/or to variable rearrangements of DNA sequences. The 480 kb chromosome contains a region of variable length, which is likely to be due to a variable deletion, located at the position of telomerization seen in the two small chromosomes. A model of chromosomal breakage is proposed to rationalize this result where micronuclear DNA is first amplified, broken and degraded to various extent from the newly formed ends, which subsequently are either telomerized or religated. Potential implications of these processes for gene expression is discussed. Known phenotypes that have a macronuclear determinism could be explained by this type of process.     

Diagrammatic representation for chromosomal mutagenesis studies. II. Radiation-induced rearrangements in Macaca fascicularis

A qualitative study is presented of chromosomal rearrangements induced in peripheral blood lymphocytes of Macaca fascicularis, after exposure to gamma-irradiation at 2 Gy and 3 Gy. The use of a new diagrammatic representation allowed us to compare, for each type of rearrangement, the distribution of the observed break-points with the theoretical random distribution. It was concluded that chromosomal mutagenesis does not occur at random: an excess of involvement of small chromosomes is found for dicentrics and reciprocal translocations; an excess of telomeric breaks exists in dicentrics and paracentric inversions. In our sample of 27 pericentric inversions, the larger chromosomes are too frequently involved, 2 different inversions are observed at least twice and 7 (or 8) reproduce chromosomes of other primates.     

Chromosomal rearrangements associated with morphological mutants provide a means for genetic variation of Candida albicans.

At frequencies as high as 1.4%, the pathogenic yeast Candida albicans spontaneously gave rise to morphological mutants exhibiting more than 20 different types of abnormal colonies; approximately two-thirds of the mutants were stable, while the other one-third were unstable and produced mixtures of different colonial forms at very high rates. Abnormal electrophoretic karyotypes were observed for all of the 14 mutants that were examined, indicating that they were associated with different types of single and multiple gross chromosomal rearrangements. Because C. albicans is asexual and does not go through a meiotic cycle, we suggest that the high frequency of chromosomal rearrangements provides a means for genetic variation in this organism.     

Delayed chromosomal instability induced by DNA damage.

DNA damage induced by ionizing radiation can result in gene mutation, gene amplification, chromosome rearrangements, cellular transformation, and cell death. Although many of these changes may be induced directly by the radiation, there is accumulating evidence for delayed genomic instability following X-ray exposure. We have investigated this phenomenon by studying delayed chromosomal instability in a hamster-human hybrid cell line by means of fluorescence in situ hybridization. We examined populations of metaphase cells several generations after expanding single-cell colonies that had survived 5 or 10 Gy of X rays. Delayed chromosomal instability, manifested as multiple rearrangements of human chromosome 4 in a background of hamster chromosomes, was observed in 29% of colonies surviving 5 Gy and in 62% of colonies surviving 10 Gy. A correlation of delayed chromosomal instability with delayed reproductive cell death, manifested as reduced plating efficiency in surviving clones, suggests a role for chromosome rearrangements in cytotoxicity. There were small differences in chromosome destabilization and plating efficiencies between cells irradiated with 5 or 10 Gy of X rays after a previous exposure to 10 Gy and cells irradiated only once. Cell clones showing delayed chromosomal instability had normal frequencies of sister chromatid exchange formation, indicating that at this cytogenetic endpoint the chromosomal instability was not apparent. The types of chromosomal rearrangements observed suggest that chromosome fusion, followed by bridge breakage and refusion, contributes to the observed delayed chromosomal instability.     

Potential Role of Transposable Elements in the Rapid Reorganization of the Fusarium oxysporum Genome

The activity of several families of transposable elements (TEs) in the genome of Fusarium oxysporum represents a potential source of karyotypic instability. We investigated transposon-mediated chromosome rearrangements by analyzing the karyotypes of a set of strains in which transposition events had occurred. We uncovered exceptional electrophoretic karyotype (EK) variability, in both number and size of chromosomal bands. We showed that EK differences result from chromosomal translocations, large deletions, and even more complex rearrangements. We also revealed many duplicated chromosomal regions. By following transposition of two elements and analyzing the distribution of different families of TEs on whole chromosomes, we find (i) no evidence of chromosomal breakages induced by transposition, (ii) a clustering of TEs in some regions, and (iii) a correlation between the high level of chromosomal polymorphism and the concentration of TEs. These results suggest that chromosome length polymorphisms likely result from ectopic recombination between TEs that can serve as substrates for these changes.     

Accumulating postzygotic isolation genes in parapatry: a new twist on chromosomal speciation

Chromosomal rearrangements can promote reproductive isolation by reducing recombination along a large section of the genome. We model the effects of the genetic barrier to gene flow caused by a chromosomal rearrangement on the rate of accumulation of postzygotic isolation genes in parapatry. We find that, if reproductive isolation is produced by the accumulation in parapatry of sets of alleles compatible within but incompatible across species, chromosomal rearrangements are far more likely to favor it than classical genetic barriers without chromosomal changes. New evidence of the role of chromosomal rearrangements in parapatric speciation suggests that postzygotic isolation is often due to the accumulation of such incompatibilities. The model makes testable qualitative predictions about the genetic signature of speciation.     

Chromosomal evolution in Malagasy lemurs. IV. Chromosome banding studies in the genuses Phaner, Varecia, Lemur, Microcebus, and Cheirogaleus.

The karotypes of five species of Malagasy lemurs are described and compared with those of 12 previously studied species or subspecies. Based on these studies, phylogenetic relationships among nearly all the species of Cheirogaleidae and Lemuridae are proposed. The karyotype of the common ancestor is identical or very similar to that of Microcebus. Nearly 60 chromosomal changes, including five intrachromosomal rearrangements of the X chromosome, have been detected during the evolution of these two families. The possible evolutionary role of the different chromosomal rearrangements is discussed.     

Yeast genome analysis identifies chromosomal translocation,gene conversion events and several sites of Ty element insertion

Paired end mapping of chromosomal fragments has been used in human cells to identify numerous structural variations in chromosomes of individuals and of cancer cell lines; however, the molecular, biological and bioinformatics methods for this technology are still in development. Here, we present a parallel bioinformatics approach to analyze chromosomal paired-end tag (ChromPET) sequence data and demonstrate its application in identifying gene rearrangements in the model organism Saccharomyces cerevisiae. We detected several expected events, including a chromosomal rearrangement of the nonessential arm of chromosome V induced by selective pressure, rearrangements introduced during strain construction and gene conversion at the MAT locus. In addition, we discovered several unannotated Ty element insertions that are present in the reference yeast strain, but not in the reference genome sequence, suggesting a few revisions are necessary in the latter. These data demonstrate that application of the chromPET technique to a genetically tractable organism like yeast provides an easy screen for studying the mechanisms of chromosomal rearrangements during the propagation of a species.     

Genome rearrangements by nonlinear transposons in maize.

Transposable elements have long been considered as potential agents of large-scale genome reorganization by virtue of their ability to induce chromosomal rearrangements such as deletions, duplications, inversions, and reciprocal translocations. Previous researchers have shown that particular configurations of transposon termini can induce chromosome rearrangements at high frequencies. Here, we have analyzed chromosomal rearrangements derived from an unstable allele of the maize P1 (pericarp color) gene. The progenitor allele contains both a full-length Ac (Activator) transposable element and an Ac terminal fragment termed fAc (fractured Ac) inserted in the second intron of the P1-rr gene. Two rearranged alleles were derived from a classical maize ear twinned sector and were found to contain a large inverted duplication and a corresponding deficiency. The sequences at the junctions of the rearrangement breakpoints indicate that the duplication and deletion structures were produced by a single transposition event involving Ac and fAc termini located on sister chromatids. Because the transposition process we describe involves transposon ends located on different DNA molecules, it is termed nonlinear transposition (NLT). NLT can rapidly break and rejoin chromosomes and thus could have played an important role in generating structural heterogeneity during genome evolution.     

Sequence Features Contributing to Chromosomal Rearrangements in Neisseria gonorrhoeae

Through whole genome sequence alignments, breakpoints in chromosomal synteny can be identified and the sequence features associated with these determined. Alignments of the genome sequences of Neisseria gonorrhoeae strain FA1090, N. gonorrhoeae strain NCCP11945, and N. gonorrhoeae strain TCDC-NG08107 reveal chromosomal rearrangements that have occurred. Based on these alignments and dot plot pair-wise comparisons, the overall chromosomal arrangement of strain NCCP11945 and TCDC-NG08107 are very similar, with no large inversions or translocations. The insertion of the Gonococcal Genetic Island in strain NCCP11945 is the most prominent distinguishing feature differentiating these strains. When strain NCCP11945 is compared to strain FA1090, however, 14 breakpoints in chromosomal synteny are identified between these gonococcal strains. The majority of these, 11 of 14, are associated with a prophage, IS elements, or IS-like repeat enclosed elements which appear to have played a role in the rearrangements observed. Additional rearrangements of small regions of the genome are associated with pilin genes. Evidence presented here suggests that the rearrangements of blocks of sequence are mediated by activation of prophage and associated IS elements and reintegration elsewhere in the genome or by homologous recombination between IS-like elements that have generated inversions.     

Chromosomal size conservation through the cell cycle supports karyotype stability in Trypanosoma cruzi

The Trypanosoma cruzi karyotype shows an extensive chromosomal size polymorphism. Absence of condensed mitotic chromosomes and chromatin fragility are characteristic features of T. cruzi which would allow DNA breaks and chromosomal rearrangements during cell proliferation. We have investigated by pulsed field gel electrophoresis (PFGE) eventual changes in chromosomal size during exponential and stationary phases of T. cruzi epimastigotes in culture, in G0 trypomastigotes and throughout the cell cycle in synchronized epimastigotes. T. cruzi molecular karyotype was stable throughout the cell cycle and during differentiation. Thus, the chromosomal size polymorphism previously reported in T. cruzi contrasts with the stability of the molecular karyotype observed here and suggests that chromosomal rearrangements leading to changes in chromosomal size are scarce events during the clonal propagation of this parasite.