Genomic Mapping of Human Chromosome Paints on the Threatened Masked Titi Monkey (Callicebus personatus)Rodrigues, L.R.R.; Pieczarka, J.C.; Pissinati, A.; de Oliveira, E.H.C.; das Dores Rissino, J.; Nagamachi, C.Y.
doi: 10.1159/000323956pmid: 21311179
Callicebus is a complex genus of neotropical primates thought to include 29 or more species. Currently, the genus is divided into 5 species groups: donacophilus, cupreus, moloch, torquatus and personatus. However, the phylogenetic relationships among the species are still poorly understood. This genus is karyotypically diverse and shows extensive variation in diploid number (2n = 16 to 50). To foster a better understanding of the chromosomal diversities and phylogenetic relationships among the species of Callicebus, we performed a chromosome-painting analysis on the Callicebus personatus genome using human probes, and compared the resulting hybridization map to those of previously mapped titi species. We detected 38 hybridization signals per haploid autosomal set of C. personatus. Few ancestral syntenies were conserved without rearrangement, but 4 human associations (HSA20/13, 3c/8b, 1b/1c and 21/3a/15a/14) were demonstrated to be apomorphic traits for C. persona tus. G-banding suggested that these associations are shared with C. nigrifrons and C. coimbrai (personatus group), while C. personatus is linked with C. pallescens (donacophilus group) by 2 synapomorphies: HSA10b/11 (submetacentric) and an inversion of HSA1a.
Chromosomal Polymorphisms in African Vlei Rats, Otomys irroratus (Muridae: Otomyini), Detected by Banding Techniques and Chromosome Painting: Inversions, Centromeric Shifts and Diploid Number VariationEngelbrecht, A.; Taylor, P.J.; Daniels, S.R.; Rambau, R.V.
doi: 10.1159/000323416pmid: 21228562
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.
Extended Cytogenetic Maps of Sheep Chromosome 1 and Their Cattle and River Buffalo Homoeologues: Comparison with the OAR1 RH Map and Human Chromosomes 2, 3, 21 and 1qDi Meo, G.P.; Goldammer, T.; Perucatti, A.; Genualdo, V.; Iannuzzi, A.; Incarnato, D.; Rebl, A.; Di Berardino, D.; Iannuzzi, L.
doi: 10.1159/000323796pmid: 21282943
Cytogenetic maps are useful tools for several applications, such as the physical anchoring of linkage and RH maps or genome sequence contigs to specific chromosome regions or the analysis of chromosome rearrangements. Recently, a detailed RH map was reported in OAR1. In the present study, we selected 38 markers equally distributed in this RH map for identification of ovine genomic DNA clones within the ovine BAC library CHORI-243 using the virtual sheep genome browser and performed FISH mapping for both comparison of OAR1 and homoeologous chromosomes BBU1q–BBU6 and BTA1–BTA3 and considerably extending the cytogenetic maps of the involved species-specific chromosomes. Comparison of the resulting maps with human-identified homology with HSA2q, HSA3, HSA21 and HSA1q reveals complex chromosome rearrangements differentiating human and bovid chromosomes. In addition, we identified 2 new small human segments from HSA2q and HSA3q conserved in the telomeric regions of OAR1p and homoeologous chromosome regions of BTA3 and BBU6, and OAR1q, respectively. Evaluation of the present OAR1 cytogenetic map and the OAR1 RH map supports previous RH assignments with 2 main exceptions. The 2 loci BMS4011 and CL638002 occupy inverted positions in these 2 maps.
Identification of the Sex Chromosomes of Brown Trout (Salmo trutta) and Their Comparison with the Corresponding Chromosomes in Atlantic Salmon (Salmo salar) and Rainbow Trout (Oncorhynchus mykiss)Li, J.; Phillips, R.B.; Harwood, A.S.; Koop, B.F.; Davidson, W.S.
doi: 10.1159/000323410pmid: 21252487
Males are the heterogametic sex in salmonid fishes. In brown trout (Salmo trutta) the sex-determining locus, SEX, has been mapped to the end of linkage group BT-28, which corresponds to linkage group AS-8 and chromosome SSA15 in Atlantic salmon (Salmo salar). We set out to identify the sex chromosomes in brown trout. We isolated Atlantic salmon BAC clones containing microsatellite markers that are on BT-28 and also on AS-8, and used these BACs as probes for fluorescent in situ hybridization (FISH) analysis. SEX is located on the short arm of a small subtelocentric/acrocentric chromosome in brown trout, which is consistent with linkage analysis. The acrocentric chromosome SSA15 in Atlantic salmon appears to have arisen by a centric fusion of 2 small acrocentric chromosomes in the common ancestor of Salmo sp. We speculate that the fusion process that produced Atlantic salmon chromosome SSA15 disrupted the ancestral sex-determining locus in the Atlantic salmon lineage, providing the impetus either for the relocation of SEX or selection pressure for a novel sex-determining gene to arise in this species. Thus, the sex-determining genes may differ in Atlantic salmon and brown trout.
Insights into the Meiotic Behavior and Evolution of Multiple Sex Chromosome Systems in SpidersKrál, J.; Kořínková, T.; Forman, M.; Krkavcová, L.
doi: 10.1159/000323497pmid: 21282941
A characteristic feature of spider karyotypes is the predominance of unusual multiple X chromosomes. To elucidate the evolution of spider sex chromosomes, their meiotic behavior was analyzed in 2 major clades of opisthothele spiders, namely, the entelegyne araneomorphs and the mygalomorphs. Our data support the predominance of X<sub>1</sub>X<sub>2</sub>0 systems in entelegynes, while rare X<sub>1</sub>X<sub>2</sub>X<sub>3</sub>X<sub>4</sub>0 systems were revealed in the tuberculote mygalomorphs. The spider species studied exhibited a considerable diversity of achiasmate sex chromosome pairing in male meiosis. The end-to-end pairing of sex chromosomes found in mygalomorphs was gradually replaced by the parallel attachment of sex chromosomes in entelegynes. The observed association of male X univalents with a centrosome at the first meiotic division may ensure the univalents’ segregation. Spider meiotic sex chromosomes also showed other unique traits, namely, association with a chromosome pair in males and inactivation in females. Analysis of these traits supports the hypothesis that the multiple X chromosomes of spiders originated by duplications. In contrast to the homogametic sex of other animals, the homologous sex chromosomes of spider females were already paired at premeiotic interphase and were inactivated until prophase I. Furthermore, the sex chromosome pairs exhibited an end-to-end association during these stages. We suggest that the specific behavior of the female sex chromosomes may have evolved to avoid the negative effects of duplicated X chromosomes on female meiosis. The chromosome ends that ensure the association of sex chromosome pairs during meiosis may contain information for discriminating between homologous and homeologous X chromosomes and thus act to promote homologous pairing. The meiotic behavior of 4 X chromosome pairs in mygalomorph females, namely, the formation of 2 associations, each composed of 2 pairs with similar structure, suggests that the mygalomorph X<sub>1</sub>X<sub>2</sub>X<sub>3</sub>X<sub>4</sub>0 system originated by the duplication of the X<sub>1</sub>X<sub>2</sub>0 system via nondisjunctions or polyploidization.
Composition and Epigenetic Markers of Heterochromatin in the Aphid Aphis nerii (Hemiptera: Aphididae)Mandrioli, M.; Azzoni, P.; Lombardo, G.; Manicardi, G.C.
doi: 10.1159/000323510pmid: 21273762
A detailed karyotype analysis of the oleander aphid Aphis nerii focusing on the distribution, molecular composition and epigenetic modifications of heterochromatin was done in order to better understand the structure and evolution of holocentric/holokinetic chromosomes in aphids. The female karyotype (2n = 8) consisted of 3 pairs of autosomes and a pair of X chromosomes that were the longest elements in the karyotype and carried a single, terminally located nucleolar organizer region. Males showed 2n = 7 chromosomes due to the presence of a single X chromosome. Heterochromatin was located in the X chromosomes only and consisted of 4 satellite DNAs that have been identified. A. nerii constitutive heterochromatin was enriched in mono-, di- and tri-methylated H3 histones and HP1 proteins but, interestingly, it lacked DNA methylation that was widespread in euchromatic chromosomal regions. These results suggest that aphid heterochromatin is assembled and condensed without any involvement of DNA methylation.
Partial Duplication of 18q Including a Distal Critical Region for Edwards Syndrome in a Patient with Normal Phenotype and Oligoasthenospermia: Case ReportQuiroga, R.; Monfort, S.; Oltra, S.; Ferrer-Bolufer, I.; Roselló, M.; Mayo, S.; Martinez, F.; Orellana, C.
doi: 10.1159/000322719pmid: 21228546
Several authors have attempted to construct a phenotype map for duplications of different portions of chromosome 18 to identify a possible critical region (CR) for Edwards Syndrome. Partial duplications of 18q have been reported in the literature involving the distal CR in patients with some clinical features of Edwards Syndrome. Here, we describe a phenotypically normal male with a large duplication on chromosome 18 that involves the proposed distal CR. The lack of clinical features is remarkable, except for pathological semen analysis, which suggests that terminal 17.4 Mb of 18q do not contain the Edwards Syndrome CR. Alternatively, unknown modifier factors or undetected somatic mosaicism might cause incomplete penetrance of this duplication.