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 pairs of microchromosomes. A series of chromosomal rearrangements have become established in both size groups of the karyotype and are restricted to centromere 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 ZZjZW type was present in a number of the species examined.

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Karyotype description and evidence of multiple sex chromosome system X1X1X2X2/X1X2Y in Potamotrygon aff. motoro and P. falkneri (Chondrichthyes: Potamotrygonidae) in the upper Paraná River basin, Brazil

Neotropical Ichthyology ◽

10.1590/s1679-62252011000100020 ◽

2011 ◽

Vol 9 (1) ◽

pp. 201-208 ◽

Cited By ~ 8

Author(s):

Vanessa Paes da Cruz ◽

Cristiane Kioko Shimabukuro-Dias ◽

Claudio Oliveira ◽

Fausto Foresti

Keyword(s):

Sex Chromosome ◽

Chromosomal Rearrangements ◽

Chromosomal Evolution ◽

Nucleolus Organizer ◽

Banding Technique ◽

Nucleolus Organizer Regions ◽

Sex Chromosome System ◽

Upper Paraná River ◽

Upper Paraná River Basin ◽

Almost All

Cytogenetic analysis of Potamotrygon aff. motoro and P. falkneri indicated the occurrence of an X1X1X2X2/X1X2 Y multiple sex chromosome system in both species, with 2n = 66 chromosomes for females and 2n = 65 chromosomes for males. The nucleolus organizer regions (NORs) identified using Ag-NOR technique showed that both species have multiple Ag-NORs (5 to 7 chromosomes stained). C-banding technique indicated the presence of heterochromatic blocks in the centromeric regions of almost all chromosomes in both species. Through this study there was evidence of heterogeneity in the karyotypes, which suggests that chromosomal rearrangements such as inversions and/or translocations occurred during the chromosomal evolution in two species of this genus.

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Karyotypes of three species of Hyperophora Brunner von Wattenwyl, 1878 (Tettigoniidae, Phaneropterinae) enable morphologically similar species to be distinguished

Comparative Cytogenetics ◽

10.3897/compcytogen.v13i1.31803 ◽

2019 ◽

Vol 13 (1) ◽

pp. 87-93 ◽

Cited By ~ 1

Author(s):

Bruno Cansanção Silva ◽

Lucas Henrique Bonfim Souza ◽

Juliana Chamorro-Rengifo ◽

Douglas Araujo

Keyword(s):

Chromosome Number ◽

Diploid Number ◽

Sex Chromosome ◽

Acrocentric Chromosome ◽

Chromosome Morphology ◽

Similar Species ◽

Cerrado Biome ◽

Cytogenetic Studies ◽

Sex Chromosome System ◽

The Difference

Phaneropterinae is the largest subfamily of Tettigoniidae, distributed across the globe. There are few cytogenetic studies regarding this group, as in the case of the genus group Aniarae, which represents only two karyotyped species. The current study aims to analyze cytogenetically three species of Hyperophora Brunner von Wattenwyl, 1878 from Brazil. The male diploid number of Hyperophoraminor Brunner von Wattenwyl, 1891 and Hyperophoramajor Brunner von Wattenwyl, 1878 is 2n♂= 31, whereas Hyperophorabrasiliensis Brunner von Wattenwyl, 1878 has shown 2n♂= 29. These three species possess an X0 sex chromosome system and telo/acrocentric chromosome morphology. The only species found in the Pantanal biome, H.brasiliensis, can be chromosomally distinguished from the Cerrado biome species H.major and H.minor, due to the difference in chromosome number (2n♂= 29 and 2n♂= 31, respectively).

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Extraordinary and extensive karyotypic variation: A 48-fold range in chromosome number in the gall-inducing scale insect Apiomorpha (Hemiptera: Coccoidea: Eriococcidae)

Genome ◽

10.1139/g99-121 ◽

2000 ◽

Vol 43 (2) ◽

pp. 255-263 ◽

Cited By ~ 14

Author(s):

Lyn G Cook

Keyword(s):

Chromosome Number ◽

Chromosomal Rearrangements ◽

Chromosomal Polymorphism ◽

Chromosomal Evolution ◽

Scale Insect ◽

Closely Related Species ◽

Host Genus ◽

Species Complexes ◽

Species Groups ◽

Karyotypic Variation

Chromosome number reflects strong constraints on karyotype evolution, unescaped by the majority of animal taxa. Although there is commonly chromosomal polymorphism among closely related taxa, very large differences in chromosome number are rare. This study reports one of the most extensive chromosomal ranges yet reported for an animal genus. Apiomorpha Rübsaamen (Hemiptera: Coccoidea: Eriococcidae), an endemic Australian gall-inducing scale insect genus, exhibits an extraordinary 48-fold variation in chromosome number with diploid numbers ranging from 4 to about 192. Diploid complements of all other eriococcids examined to date range only from 6 to 28. Closely related species of Apiomorpha usually have very different karyotypes, to the extent that the variation within some species- groups is as great as that across the entire genus. There is extensive chromosomal variation among populations within 17 of the morphologically defined species of Apiomorpha indicating the existence of cryptic species-complexes. The extent and pattern of karyotypic variation suggests rapid chromosomal evolution via fissions and (or) fusions. It is hypothesized that chromosomal rearrangements in Apiomorpha species may be associated with these insects' tracking the radiation of their speciose host genus, Eucalyptus. Key words: Apiomorpha, cytogenetics, chromosomal evolution, holocentric.

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Chromosomal Evolution in the Diplodactylinae (Gekkonidae, Reptilia) .1. Evolutionary Relationships and Patterns of Change

Australian Journal of Zoology ◽

10.1071/zo9870507 ◽

1987 ◽

Vol 35 (5) ◽

pp. 507 ◽

Cited By ~ 11

Author(s):

M King

Keyword(s):

Pericentric Inversion ◽

Chromosomal Rearrangements ◽

Chromosomal Evolution ◽

Species Group ◽

Individual Species ◽

Ancestral Karyotype ◽

Chromosome Fusion ◽

Gross Chromosomal Rearrangements ◽

Extant Species ◽

Pericentric Inversions

A chromosomal analysis of 47 species of diplodactyline gekkos indicates that these are a monophyletic assemblage derived from a 2n = 38 acrocentric ancestral karyotype. Four major clades are present, the first possessing the ancestral karyotype. The remainder are defined by the possession of a series of shared derived chromosomal rearrangements, or by the type of chromosome change. The first of these derived clades includes the subgenus Strophurus, which has five fixed, presumed pericentric inversion differences. The second includes members of the D. vittatus species group. Here, a number of chromosome fusions have been established which appear to have been associated with speciation. The third derived clade is distinguished by 19 fixed, presumed pericentric inversions, and includes the genera, Oedura, Rhacodactylus, Bavayia, Pseudothecadactylus, Carphodactylus and Hoplodactylus. It is argued that the 2n=38 acrocentric karyotype common to many of the species is the ancestral karyomorph, and the modifications of this format have been achieved by both chromosome fusion and pericentric inversion. The decision that this is the ancestral karyomorph was based on its dominance in extant species; the fact that similar karyotypes are present in other gekkonid subfamilies (effective out-groups), that 2n =38 all acrocentric ancestral karyotypes are also found in some other lizard families, and that such a diversity of rearrangements was established, provide arguments against any other viable ancestral format. Two discrete modes of chromosomal repatterning are found in the Diplodactylinae: the fixation of presumptive multiple pericentric inversions, producing a karyomorph which characterises large groups of species; and the fixation of fusion or presumptive inversion differences which distinguish individual species or chromosome races. The latter appear to have been associated with speciation. It is clear that in certain groups, such as the Strophurus species group (the members of which all share a derived karyomorph defined by the presence of five inverted chromosomes), speciation has proceeded without gross chromosomal rearrangements.

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Extensive Sex Chromosome Polymorphism of Microtus thomasi/Microtus atticus Species Complex Associated with Cryptic Chromosomal Rearrangements and Independent Accumulation of Heterochromatin

Cytogenetic and Genome Research ◽

10.1159/000477114 ◽

2017 ◽

Vol 151 (4) ◽

pp. 198-207 ◽

Cited By ~ 3

Author(s):

Michail T. Rovatsos ◽

Juan A. Marchal ◽

Ismael Romero-Fernández ◽

Maria Arroyo ◽

Eva B. Athanasopoulou ◽

...

Keyword(s):

Sex Chromosomes ◽

Dna Sequences ◽

Sex Chromosome ◽

Chromosomal Rearrangements ◽

Chromosomal Evolution ◽

Chromosome Polymorphism ◽

Random Drift ◽

X Chromosomes ◽

Karyotypic Diversity ◽

Comparative Painting

The sibling species Microtus thomasi and M. atticus represent probably the highest karyotypic diversity within the genus Microtus and are an interesting model for chromosomal evolution studies. In addition to variation in autosomes, they show a high intraspecific variation in the size and morphology of both sex chromosomes. We analyzed individuals with different sex chromosome constitutions using 3 painting probes, 2 from Y chromosome variants and 1 from the small arm of the submetacentric X chromosome. Our comparative painting approach uncovered 12 variants of Y and 14 variants of X chromosomes, which demonstrates that the polymorphism of sex chromosomes is substantially larger than previously reported. We suggest that 2 main processes are responsible for this sex chromosome polymorphism: change of morphology from acrocentric to submetacentric or metacentric chromosomes and increase in size due to accumulation of repetitive DNA sequences, generating heterochromatic blocks. Strong genetic drift in small and fragmented populations of these 2 species could be related to the origin and maintenance of the large polymorphism of sex chromosomes. We proposed that a similar polymorphism variation combined with random drift fixing the biggest sex chromosomes could have occurred in the origin of some of the actual Microtus species with giant sex chromosomes.

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The karyotypes and evolution of ZZ/ZW sex chromosomes in the genus Characidium (Characiformes, Crenuchidae)

Comparative Cytogenetics ◽

10.3897/compcytogen.v12i3.28736 ◽

2018 ◽

Vol 12 (3) ◽

pp. 421-438 ◽

Cited By ~ 5

Author(s):

Marcela Baer Pucci ◽

Viviane Nogaroto ◽

Luiz Antonio Carlos Bertollo ◽

Orlando Moreira-Filho ◽

Marcelo Ricardo Vicari

Keyword(s):

Dna Sequences ◽

Sex Chromosome ◽

Chromosomal Rearrangements ◽

Neotropical Region ◽

Repeated Dna ◽

Neotropical Fish ◽

Karyotypic Formula ◽

Fish Group ◽

Sex Chromosome System

Available data on cytotaxonomy of the genus Characidium Reinhardt, 1867, which contains the greatest number of species in the Characidiinae (Crenuchidae), with 64 species widely distributed throughout the Neotropical region, were summarized and reviewed. Most Characidium species have uniform diploid chromosome number (2n) = 50 and karyotype with 32 metacentric (m) and 18 submetacentric (sm) chromosomes. The maintenance of the 2n and karyotypic formula in Characidium implies that their genomes did not experience large chromosomal rearrangements during species diversification. In contrast, the internal chromosomal organization shows a dynamic differentiation among their genomes. Available data indicated the role of repeated DNA sequences in the chromosomal constitution of the Characidium species, particularly, in sex chromosome differentiation. Karyotypes of the most Characidium species exhibit a heteromorphic ZZ/ZW sex chromosome system. The W chromosome is characterized by high rates of repetitive DNA accumulation, including satellite, microsatellite, and transposable elements (TEs), with a varied degree of diversification among species. In the current review, the main Characidium cytogenetic data are presented, highlighting the major features of its karyotype and sex chromosome evolution. Despite the conserved karyotypic macrostructure with prevalent 2n = 50 chromosomes in Characidium, herein we grouped the main cytogenetic information which led to chromosomal diversification in this Neotropical fish group.

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First cytogenetic information on four checkered beetles (Coleoptera, Cleridae)

Comparative Cytogenetics ◽

10.3897/compcytogen.v14i4.55358 ◽

2020 ◽

Vol 14 (4) ◽

pp. 541-547

Author(s):

Atılay Yağmur Okutaner

Keyword(s):

Chromosome Number ◽

Y Chromosome ◽

Chromosome Numbers ◽

Sex Chromosome ◽

Evolutionary Process ◽

Sex Chromosome System ◽

First Time

The karyotypes of four species of Cleridae (Coleoptera): Trichodes favarius (Illiger, 1802), Trichodes quadriguttatus Adams, 1817, Trichodes reichei (Mulsant et Rey, 1863), and Tilloidea transversalis (Charpentier, 1825) were reported for the first time with this study. The chromosome numbers of these four species were determined as 2n = 18, sex chromosome system Xyp, and all chromosomes were metacentric (the except y chromosome). Together with this study, the chromosome data of only 17 species are available in this family. It is remarkable that all of them display the same chromosome number and similar karyotypes. This may make the effect of karyotypical features important in interpreting the evolutionary process of Cleridae.

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Lineage-specific patterns of chromosome evolution are the rule not the exception in Polyneoptera insects

Proceedings of The Royal Society B Biological Sciences ◽

10.1098/rspb.2020.1388 ◽

2020 ◽

Vol 287 (1935) ◽

pp. 20201388 ◽

Cited By ~ 2

Author(s):

Terrence Sylvester ◽

Carl E. Hjelmen ◽

Shawn J. Hanrahan ◽

Paul A. Lenhart ◽

J. Spencer Johnston ◽

...

Keyword(s):

Chromosome Number ◽

Genome Size ◽

Sex Chromosomes ◽

Chromosome Evolution ◽

Sex Chromosome ◽

Genome Structure ◽

Rates Of Evolution ◽

A Genome ◽

Sex Chromosome System ◽

Insect Group

The structure of a genome can be described at its simplest by the number of chromosomes and the sex chromosome system it contains. Despite over a century of study, the evolution of genome structure on this scale remains recalcitrant to broad generalizations that can be applied across clades. To address this issue, we have assembled a dataset of 823 karyotypes from the insect group Polyneoptera. This group contains orders with a range of variations in chromosome number, and offer the opportunity to explore the possible causes of these differences. We have analysed these data using both phylogenetic and taxonomic approaches. Our analysis allows us to assess the importance of rates of evolution, phylogenetic history, sex chromosome systems, parthenogenesis and genome size on variation in chromosome number within clades. We find that fusions play a key role in the origin of new sex chromosomes, and that orders exhibit striking differences in rates of fusions, fissions and polyploidy. Our results suggest that the difficulty in finding consistent rules that govern evolution at this scale may be due to the presence of many interacting forces that can lead to variation among groups.

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Chromosomal Evolution and Evolutionary Relationships of Lebiasina Species (Characiformes, Lebiasinidae)

International Journal of Molecular Sciences ◽

10.3390/ijms20122944 ◽

2019 ◽

Vol 20 (12) ◽

pp. 2944 ◽

Cited By ~ 6

Author(s):

Sassi ◽

Oliveira ◽

Bertollo ◽

Nirchio ◽

Hatanaka ◽

...

Keyword(s):

Sex Chromosome ◽

Distribution Patterns ◽

Chromosomal Evolution ◽

Evolutionary Relationships ◽

Comparative Genomic ◽

Banding Patterns ◽

Rdna Sites ◽

Sex Chromosome System ◽

High Level ◽

Chromosomal Sequences

We present the first cytogenetic data for Lebiasina bimaculata and L. melanoguttata with the aim of (1) investigating evolutionary events within Lebiasina and their relationships with other Lebiasinidae genera and (2) checking the evolutionary relationships between Lebiasinidae and Ctenoluciidae. Both species have a diploid number 2n = 36 with similar karyotypes and microsatellite distribution patterns but present contrasting C-positive heterochromatin and CMA3+ banding patterns. The remarkable interstitial series of C-positive heterochromatin occurring in L. melanoguttata is absent in L. bimaculata. Accordingly, L. bimaculata shows the ribosomal DNA sites as the only GC-rich (CMA3+) regions, while L. melanoguttata shows evidence of a clear intercalated CMA3+ banding pattern. In addition, the multiple 5S and 18S rDNA sites in L. melanogutatta contrast with single sites present in L. bimaculata. Comparative genomic hybridization (CGH) experiments also revealed a high level of genomic differentiation between both species. A polymorphic state of a conspicuous C-positive, CMA3+, and (CGG)n band was found only to occur in L. bimaculata females, and its possible relationship with a nascent sex chromosome system is discussed. Whole chromosome painting (WCP) and CGH experiments indicate that the Lebiasina species examined and Boulengerella maculata share similar chromosomal sequences, thus supporting the relatedness between them and the evolutionary relationships between the Lebiasinidae and Ctenoluciidae families.

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Chromosomal Evolution in Aspredinidae (Teleostei, Siluriformes): Insights on Intra- and Interspecific Relationships with Related Groups

Cytogenetic and Genome Research ◽

10.1159/000511125 ◽

2020 ◽

Vol 160 (9) ◽

pp. 539-553

Author(s):

Milena Ferreira ◽

Isac S. de Jesus ◽

Patrik F. Viana ◽

Caroline Garcia ◽

Daniele A. Matoso ◽

...

Keyword(s):

Evolutionary Dynamics ◽

Sex Chromosome ◽

Chromosomal Evolution ◽

Nucleotide Sequencing ◽

Molecular Cytogenetic ◽

System A ◽

The Family ◽

Sex Chromosome System ◽

Acrocentric Chromosomes ◽

Systematic Relationships

The family Aspredinidae comprises a clade of complex systematic relationships, both from molecular and morphological approaches. In this study, conventional and molecular cytogenetic studies coupled with nucleotide sequencing were performed in 6 Aspredininae species (Amaralia hypsiura, Bunocephalus cf. aloikae, Bunocephalus amaurus, Bunocephalus aff. coracoideus, Bunocephalus verrucosus, and Platystacus cotylephorus) from different locations of the Amazon hydrographic basin. Our results showed highly divergent diploid numbers (2n) among the species, ranging from 49 to 74, including the occurrence of an XX/X0 sex chromosome system. A neighbor-joining phylogram based on the cytochrome c oxidase I (COI) showed that Bunocephalus coracoideus is not a monophyletic clade, but closely related to B. verrucosus. The karyotypic data associated with COI suggest an ancestral karyotype for Aspredinidae with a reduced 2n, composed of bi-armed chromosomes and a trend toward chromosomal fissions resulting in higher diploid number karyotypes, mainly composed of acrocentric chromosomes. Evolutionary relationships were discussed under a phylogenetic context with related species from different Siluriformes families. The karyotype features and chromosomal diversity of Aspredinidae show an amazing differentiation, making this family a remarkable model for investigating the evolutionary dynamics in siluriforms as well as in fish as a whole.

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