Autosomal and sex chromosomal polymorphisms with multiple rearrangements and a new karyotype in the genus Rhipidomys (Sigmodontinae, Rodentia)

Two diploid numbers and five karyomorphs were found in ten specimens of Rhipidomys (Sigmodontinae, Rodentia) from three states in Brazil: 2n = 50 from Amazonas, and 2n = 44 from Mato Grosso and Bahia. CBG, GTG, and RBG-banding and Ag-NOR analyses were performed, as well as fluorescence in situ: hybridization with (T2AG3)7 probes. The new diploid number of 2n = 50 was associated with two different fundamental numbers (FN = 71 and 72) as a result of pericentric inversions and addition/deletion of constitutive heterochromatin. The samples from two localities (Aripuan? and Vila Rica) in the state of Mato Grosso shared 2n = 44 and FN = 52, but their karyotypes differed because of pericentric inversions. Although the single specimen from Bahia had the same diploid number as the samples from Mato Grosso, its karyotype and FN were completely distinctive. Karyological comparison of GTG-banding patterns revealed total homology between the karyotypes of the specimens from Bahia and Mato Grosso, implying the occurrence of 14 autosomal pericentric inversions. Homologies between ten of the autosomes in the karyotypes with 2n = 50 (FN = 72) and 2n = 44 (from Vila Rica, MT) were demonstrated. The differentiation between 2n = 44 and 2n = 50 involved five pericentric inversions, addition/deletion of constitutive heterochromatin in both autosomes and sex chromosomes, at least one Robertsonian rearrangement and other not detected rearrangements. Despite the remarkable number of rearrangements, interstitial telomeric sites (ITS) were not detected. Sex chromosomes also exhibited polymorphism in size and morphology.     

Cytogenetics and karyosystematics of South American oryzomyine rodents (Cricetidae: Sigmodontinae). IV. Karyotypes of Venezuelan, Trinidadian, and Argentinian water rats of the genus Nectomys.

Bone marrow chromosomes were studied in South American water rats of the genus Nectomys from Venezuela, Trinidad, and Argentina. Specimens of N. squamipes from western and southern Venezuela showed a 2n = 52-53 karyotype, whereas a 2n = 56-57 karyotype was found in specimens from northeastern Argentina. In both cases, odd karyotypes can be explained by the presence of a supernumerary chromosome. In contrast, water rats from northeastern Venezuela and Trinidad showed a strikingly reduced 2n = 16-17 polymorphic chromosome complement. Six different karyomorphs were found among the latter, which may have resulted from a combination of pericentric inversions in two pairs of autosomes and a centromeric fusion in another autosomal pair. It is proposed that the new 2n = 16-17 cytotypes belong to a species of its own, for which the name N. palmipes is suggested.     

Chromosomal and protein evolution in morphologically similar species of Praomys sensu lato (Rodentia, Muridae)

Evidence of extensive chromosomal evolution in a biologically and economically important group of African murids of the Praomys/Mastomys complex was provided by examination of G- and C-band chromosomal data on P. coucha (2n = 32), P. fumatus (2n = 38), P. hildebrandti (2n = 32), P. jacksoni (2n = 28), P. misonnei (2n = 36), and P. cf. tullbergi (2n = 35). A coding system was developed for the chromosomal characters, and analyses were performed by a computer program to find the shortest tree with a minimum of 35 autosomal rearrangements (pericentric inversions, complex translocations, centric fusions, centric fissions, tandem fusions, euchromatic additions, and heterochromatic additions). The resulting phylogenetic hypothesis differs from traditionally accepted hypotheses regarding this complex group of rodents. The cytogenetic data show that 1) there is no support for the dichotomy of Mastomys/Praomys previously based on morphology, 2) the 2n = 32 species from eastern Africa (P. hildebrandti) is distinct from the 2n = 32 species from southern Africa (P. natalensis), and 3) there is a close association between P. jacksoni and P. cf. tullbergi. Polyacrylamide gel electrophoresis of liver membrane proteins demonstrated few differences in protein mobilities between species and even fewer between individuals of the same species taken from different habitats and localities in Kenya. Monoclonal antibodies produced against liver proteins of one species and tested for reactivity to other species confirmed the evolutionary similarity of species of this complex. This immunologic approach may provide a robust data set for future phylogenetic studies of muroid rodents.(ABSTRACT TRUNCATED AT 250 WORDS)     

Chromosomal polymorphisms in African vlei rats, Otomys irroratus (Muridae: Otomyini), detected by banding techniques and chromosome painting: inversions, centromeric shifts and diploid number variation

Pericentric inversions are important for evolutionary biology because of their potential role in speciation. They may result in reproductive isolation due to illegitimate pairing of homologues at meiosis which leads to the production of aneuploid gametes (containing deletions or duplications of chromosomal segments), and consequently mediate chromosomal divergence. In this study, we describe the prevalence of pericentric inversions in the African vlei rat, Otomys irroratus (OIR). The species is characterized by intraspecific chromosomal variation (2n = 23-32) across its distribution in southern Africa. Here, we analyzed 55 individuals collected from 7 localities in South Africa by G- and C-banding and chromosome painting with flow sorts of Myotomys unisulcatus. Of the 55 specimens that were analyzed, 47% contained inversions or centromeric shifts on 4 autosomes (OIR1, 4, 6 and 10) which were present singly in specimens (i.e. none of the specimens contained all 4 inversions concurrently). These inversions were found in both homozygous and heterozygous state over a wide geographic range suggesting that they are floating polymorphisms. Given the potential role of inversions in post-mating isolation (through production of aneuploid gametes), the prevalence of inversions as floating polymorphisms in the vlei rats suggests that they are probably retained in the population through suppression of recombination in the inverted regions of the chromosomes.     

On the robertsonian polymorphism found in the Japanese raccoon dog (Nyctereutes procyonoides viverrinus)

Karyotypes of 39 Japanese raccoon dogs (NPV) which appeared in the literature and of 7 previously unreported specimens were examined. Thirty four individuals showed the standard karyotype 2K = 26M + 10A + (M)X + (A)Y + Bs (2n = 38 + Bs), where Bs are supernumerary chromosomes. The remaining 11 individuals had 2K = 25M + 12A + XY + Bs (2n = 39 + Bs) and one was 2K = 23M + 16A + XY + Bs (2n = 41 + Bs). The G- and C-banding analyses of both somatic and germ cells revealed that these karyotypes with odd numbers are heterozygous (M/A) for a single Robertsonian rearrangement of chromosomes 2, 5, 6, 8, or 11, and one is M/A heterozygous for three autosomes: 5, 6, and 11.     

Microdensitometric evaluation of the DNA content,as ploidy parameter,of spermatozoa in the polymorphic chromosomal system of Akodon molinae cabrera (rodentia,cricetidae)

The influence of chromosome variability on the production of euploid spermatozoa was investigated in a suitable biological model, the Akodon molinae system. This consists of individuals whose chromosome constitution is 2n = 42, 2n = 43, or 2n = 44. The only difference between these three karyotypes occurs through a Robertsonian rearrangement combined with two pericentric inversions. Thus, the animals with 2n = 42 (simple homozygotes or SH) have two large metacentric chromosomes number 1; animals with 2n = 43 (heterozygotes or Ht) have a chromosome 1 and two subterminal chromosomes la and lb homologues of the long and short arms of the chromosome 1, respectively; animals with 2n = 44 (double homozygotes or DH) have a pair of la and a pair of lb chromosomes. The gametic euploidy frequency correlated with each chromosome constitution was evaluated on the basis of the DNA content of spermatozoa, which was determined microdensitometrically after the Feulgen reaction, taking into account the site of the spermatozoa along the male genital tract. A comparative assessment of gametic aneuploidy frequency in caput epididymis versus vas deferens demonstrated (1) a falloff in euploid production in passing from the 2n = 42 to the 2n = 44 chromosome forms, alongside a high degree of intragroup variability, and (2) a lower aneuploidy frequency in the vas deferens than in caput epididymis in all the forms considered. These two features, taken together with similar results in the mouse chromosome variability system, suggest that a selection mechanism is operative against aneuploid spermatozoa in the epididymis. This finding is of interest in a wider perspective, since it might turn out to be valid for many mammals.     

Further insights into the ancestral murine karyotype: the contribution of the Otomys-Mus comparison using chromosome painting

The African vlei rat, Otomys irroratus, comprises several distinct chromosomal races that may be grouped into two major cytogenetic clades. Recognition of these clades is underpinned by a complex chromosomal rearrangement involving three different autosomes in the unfused state. We have used unidirectional fluorescence in situ hybridization (FISH) of mouse chromosome-specific painting probes to molecularly define the components of this rearrangement as well as to establish the chromosomal homologies between the mouse and the vlei rat genomes. This has allowed for the detection of 41 autosomal segments of conserved synteny. Nine mouse chromosomes were conserved in toto (MMU3, 4, 6, 7, 11, 12, 14, 18, 19) with a further seven (MMU2, 5, 8, 9, 10, 13, 16) showing homology to two discrete regions in the vlei rat genome. Two mouse autosomes (MMU15, 17) correspond to three regions in O. irroratus with MMU1 being the most fragmented showing five sites of hybridization in this species. By mapping these data to published sequence-based phylogenies we are able to confirm most of the published putative ancestral murine chromosomal states. Our data further indicate that MMU15a+ MMU13b+MMU10b+MMU17b was present in the murine ancestral karyotype suggesting an ancestral 2n = 52 rather than the 2n = 54 previously postulated.     

Chromosomal evolution in Cervidae

On the basis of chromosome data obtained on 30 species and 20 subspecies of Cervidae, a report is submitted on the karyosystematics of this family. The primitive karyotype of Cervidae may be inferred to be composed of 35 acrocentric pairs (2n = 70 FN = 70). During the phyletic evolution of this family different types of chromosome rearrangements were probably selected and the group may have differentiated karyologically into three branches: (1) the Cervinae that fixed a centric fusion resulting in a metacentric pair of autosomes (2n = 68, FN = 70), as shown by the basic karyotype of Cervus elaphus, and where Robertsonian fusions are the preeminent type of chromosome rearrangement; (2) the Odocoileinae, in which pericentric inversions and Robertsonian fusions were favored, yielding first a submetacentric X and then a submetacentric autosome pair. The most representative karyotype is 2n = 70, FN = 74--as in Odocoileus hemionus; and (3) the Muntiacinae, in which centric and tandem fusions were the most common chromosome rearrangements. While Muntiacus reevesi has a karyotype 2n = 46, FN = 46, the chromosome number drops down to 2n = 6 in the females of the M. muntjak vaginalis subspecies group and M. rooseveltorum. Therefore, while the karyotypes are conserved within the subfamilies Cervinae and Odocoileinae; the subfamily Muntiacinae appears to be the most chromosomally diversified group. The few karyological data on the Moschus berezovskii suggest that the Moschinae should be placed in a separate family, the Moschidae.     

Mitotic and meiotic analysis in Arctocephalus australis (Otariidae)

The karyotype with C-, G- and NOR-banding of Arctocephalus australis is reported for the first time. The chromosomal number is 2n = 36. The X chromosome, identified in G-banded metaphases from males, is metacentric and the Y chromosome is a minute chromosome, also metacentric. Pachytene spermatocytes were used for synaptonemal complexes analysis with a surface spreading technique. A total of 17 autosomal synaptonemal complexes are observed plus the XY pair. During early pachytene, the X and Y axes are thickened and remain unpaired. As pachytene advances, a short SC is formed between the gonosomes, as it is common among eutherian mammals. The particular asymmetrical appearance of the synaptonemal complex in the sex pair is described and compared to other cases among mammals.     

A polymorphic structural rearrangement in the chromosomes of two populations of orangutan

A rearranged chromosome 9 was found in 12 of 23 specimens of orangutan, 4 of Bornean and 8 of Sumatran origin. Nine animals were heterozygous, and 3 were homozygous carriers for the variant chromosome, which was also traced in 4 other animals not studied by us. This type of chromosome rearrangement has been previously described (Seuánez et al., 1976) and is probably the same chromosome shown by Lucas et al. (1973) and reported by Turleau et al. (1975) in other specimens. There is obviously a very high incidence of this variant chromosome 9 in Pongo pygmaeus, and it is unlikely that it could result from independent rearrangements occurring in unrelated specimens from two geographically isolated populations (Sumatran and Bornean). It is concluded that the rearrangement is of ancient origin and that it has been maintained in the populations of Pongo as a balanced polymorphism. This type of complex rearrangement resulting from two pericentric inversions, one inside the other, is compared with certain sporadic pericentric inversions in the human complement, with pericentric inversions which are polymorphic in other mammals, and with pericentric inversions involved in chromosome evolution in the Hominoidea.     

Unusual C-band patterns in three karyotypically rearranged forms of Scapteromys (Rodentia, Cricetidae) from Brazil

Chromosome studies of 30 specimens of the rodent Scapteromys collected at nine localities in southern Brazil revealed the occurrence of three karyotypic taxa with 2n = 36 (one locality), 34 (two localities), and 24 (six localities), although all three had 40 autosomal arms (AN). The G-band analysis indicated that this reduction in diploid number was mainly due to Robertsonian translocations which have occurred along a gradient, possibly in two independent evolutive routes. The C-bands occur on one autosomal pair and on the X and Y in the 2n = 36 and 34 forms and on the X and Y chromosomes only in the 2n = 24 taxon. The broad genomic reorganization which has occurred in this genus, in which the chromosomes do not have large amounts of constitutive heterochromatin, argues against the idea that a large amount of constitutive heterochromatin favors chromosome evolution and speciation.     

Meiosis and speciation: A study in a speciatingMus terricolor complex

The three chromosomal species of theMus terricolor complex possess 2n = 40 chromosomes. We show that their karyotypes differ in stable heterochromatin variations fixed in homozygous condition as prominent short arms in autosomes 1, 3 and 6. The three chromosomal species exhibit a high incidence of polymorphisms for Robertsonian fusions and pericentric inversions. Breeding experiments and histological analysis of testis show that heterozygosity for pericentric inversions and Robertsonian fusions had no effect on fertility. Meiotic analysis shows normal overall progression of meiosis in the heterozygotes, which is consistent with their normal gametogenesis. Nevertheless, both the inversion and fusion heterozygotes had undergone some alterations in the regular process of homologous synapsis, and it appeared that certain features of the meiotic system circumvented the potential negative effects of these polymorphic chromosomal rearrangements. The results indicate that the attributes of the meiotic system in a given organism could modulate the potential of a chromosomal rearrangement as reproductive barrier. The meiotic modulation hypothesis offers an explanation for the contradictory effects of the similar kinds of chromosomal mutations reported in different species.     

<Emphasis Type="Italic">Ctenomys lami</Emphasis>: The highest chromosome variability in<Emphasis Type="Italic">Ctenomys</Emphasis> (Rodentia,Ctenomyidae) due to a centric fusion/fission and pericentric inversion system

Ctenomys lami Freitas, 2001 is an endemic species of rodent inhabiting the Coastal Plain of southern Brazil, along a narrow line of old dunes formed in the Pleistocene. This species has five different diploid numbers (2n=54, 55a, 55b, 56a, 56b, 57 and 58) and ten different autosomal fundamental numbers (FNa=74, 75, 76, 77, 78, 79, 80, 81, 82, and 84). In a sample of 102 specimens, the combined 2n and FNa formed 26 different karyotypes. The diploid number variation was due to Robertsonian rearrangements that occur in pairs 1 and 2, and the variation of NFas was due to pericentric inversions. The distribution of diploid number variation along the 78 km line of collection sites reveals four population blocks: block A with 2n=54, 55a, and 56a; block B with 2n=57 and 58; block C with 2n=54 and 55a; and block D with 2n=56b and 55b. The inversion system lacks geographic structure with a random distribution of inversions along the population blocks. A very narrow hybrid zone is hypothesized between blocks A and B. Blocks B and C are separated by a geographic barrier, and another hybrid zone is found between blocks C and D. My findings suggest that this species is undergoing a process of speciation due to geographic isolation.     

Dog chromosome-specific paints reveal evolutionary inter- and intrachromosomal rearrangements in the American mink and human

Forty chromosome-specific paint probes of the domestic dog (Canis familiaris, 2n = 78) were used to delineate conserved segments on metaphase chromosomes of the American mink (Mustela vison, 2n = 30) by fluorescence in situ hybridisation. Half of the 38 canine autosomal probes each painted one pair of homologous segments in a diploid mink metaphase, whereas the other 19 dog probes each painted from two to five pairs of discrete segments. In total, 38 canine autosomal paints highlighted 71 pairs of conserved segments in the mink. These painting results allow us to establish a complete comparative chromosome map between the American mink and domestic dog. This map demonstrates that extensive chromosome rearrangements differentiate the karyotypes of the dog and American mink. The 38 dog autosomes could be reconstructed from the 14 autosomes of the American mink through at least 47 fissions, 25 chromosome fusions, and six inversions. Furthermore, comparison of the current dog/mink map with the published human/dog map discloses 23 cryptic intrachromosomal rearrangements in 10 regions of conserved synteny in the human and American mink genomes and thus further refined the human/mink comparative genome map.     

Karyology of the Savi pine vole, Microtus savii (De Sélys-Longchamps, 1838) (Rodentia, Arvicolidae): G-, C-, DA/DAPI-, and AluI-bands.

Specimens of the Savi pine vole (Microtus savii) were collected from three localities in central (Pisa and Viterbo) and southern Italy (Rosarno, Calabria) and were karyotyped using G-, C-, DA/DAPI-, and AluI-banding. All karyotypes had 2n = 54 chromosomes and seemingly identical autosomal banding. The sex chromosomes of the southern Italian specimens, M. savii brachycercus, showed additional large blocks of heterochromatin. In the northern specimens, M. savii savii, the X chromosome is metacentric, whereas in the southern specimens of M. savii brachycercus the X chromosome is a much larger submetacentric chromosome, and the Y chromosome is more than twice the size of the Y in the northern specimens. DA/DAPI staining reveals three levels of fluorescent intensity in the sex chromosomes of the Calabrian specimens. The sex chromosomes of M. savii brachycercus also have the only AluI bands seen in either chromosome set. These data suggest a heterogeneous origin and composition of the C-band regions of these chromosomes. Preliminary data suggest that fertility is reduced in crosses between the two karyomorphs.     

Cytogenetic features of the blood-sucking blackfly Wilhelmia paraequina Puri (Diptera: Simuliidae) from Armenia

Three blackfly Wilhelmia paraequina populations of Armenia (rivers Debet and Megriget, channel Megri) were studied. 2n = 6: IS + IIL, IIS + IL, IIIS + IIIL. Cytological maps of polytene chromosomes were constructed. High inversion polymorphism (95.63%) was observed, with 2.6 inversions per individual. Three inversions proved to be associated with male development: Y1 was characterized by a combination of two heterozygous inversions, IIL-3 + IIL-1, while Y2 had another combination of heterozygous inversions, IIL-5 + IIL-3. The X chromosome had a standard homozygous IIL disk sequence. The populations were shown to be similar in autosomal polymorphism. A tendency for differentiation was observed with respect to frequencies and types of sex-linked inversions: the sex determination system was Y1X-XX in the Debet and Megriget populations and Y2X-XX in the channel (Megri) population. On the strength of these findings, one W. paraequina morphotype was assumed to involve two cytotypes, A (Debet and Megriget populations) and B (Megri population).     

The origin of an unusual sex chromosome constitution in <Emphasis Type="Italic">Acomys</Emphasis> sp. (Rodentia,Muridae) from Tanzania

This paper describes a case which presents an evident variation from the “standard” XX/XY sex chromosomal constitution in a rodent, Acomys sp. This species known to be found in three localities of East Africa has only recently been separated from A. spinosissimus, its closest relative. In our study, five specimens of Acomys sp. and eight specimens of A. spinosissimus were live-trapped in five localities. Comparisons between the two taxa assed by G- banding show a complete homology in the chromosomal shape and banding pattern for 29 pairs of chromosomes corresponding to the complete autosomal set of A. spinosissimus. However, while all the A. spinosissimus analysed have 2n = 60 and a XY-XX system, in Acomys sp. males and females constitute mosaics for sex chromosomes in the bone marrow cells. Females (2n = 59, 60) have an excess (97%) of aneuploid cells with one single giant X chromosome, and males (2n = 60, 61) show X0/XY cells occurring in somatic tissues and XY cells in the germinal lineage. In addition, an odd heterochromatic submetacentric chromosome was identified in all the cells examined in two males and a female of Acomys sp. Since this chromosome was not related to sex determination and it is not present in all the analysed specimens, it can be considered as a B chromosome. Finally, the in situ fluorescence hybridisation (FISH) with telomeric probes showed a very intense interstitial telomeric signal (ITS) at the medial part on the long heterochromatic arm of the X chromosome. This could be due to recent chromosomal rearrangement.     

Chromosomal banding patterns in Akodon arviculoides (2n=14),Akodon sp.(2n=24 and 25), and two male hybrids with 19 chromosomes.

Chromosomal polymorphism resulting from two pericentric inversions in Akodon arviculoides (2n=14) has been described (YONENAGA, 1972a). In this paper the banding patterns are presented and identification of the inverted segments of the autosomal pairs 2 and 3 is made. The karyotype of Akodon sp., which varies in diploid number (2n-24 and 25), is described and shown to be due to the presence of a small submetacentric chromosome in the 2n=25 individuals. The karyotypes of two 2n=19 males studied show that they are hybrids between Akodon arviculoides (2n=14) and Akodon sp. (2n=24).     

The chromosome banding pattern in two cytotypes (2n = 36 and 38) of blind mole rats from Turkey (Mammalia: Spalaxidae)

Two cytotypes (2n = 36 and 38) of blind mole rats, Nannospalax xanthodon (Nordmann, 1840), from the Ayd?n and Manisa provinces in Turkey were investigated. Conventional chromosome staining, Ag-NOR staining and C-banding analysis were carried out. From the cytogenetic point of view, the particular phylogenetic position of these populations is supported by their low diploid numbers only, and the Cbanding pattern and the NORs distribution seem generally similar to populations with higher chromosome numbers. Several autosomal pairs with centromeric dark Cbands were observed in the 2n=36 cytotype. One autosomal pair possessed an interstitial dark C-band on the short arm; another pair possessed an interstitial dark Cband on the long arm. Whole C-heterochromatic short arms were observed in three subtelocentric autosomal pairs in the 2n=38 cytotype. Most of the other autosomal pairs possessed centromeric dark C-bands. Distinct dark C-bands were observed also in the presumed X chromosomes of both the cytotypes. The Ag-NOR regions were found on three autosomal pairs of both the cytotypes. These sites were located in telomeric areas of the short arms of two subtelocentric and one submetacentric pair.