Michelle Orane Schemberger

Bio: Michelle Orane Schemberger is an academic researcher from Ponta Grossa State University. The author has contributed to research in topics: Parodontidae & Chromosome. The author has an hindex of 6, co-authored 12 publications receiving 157 citations. Previous affiliations of Michelle Orane Schemberger include Federal University of Paraná.

Differentiation of repetitive DNA sites and sex chromosome systems reveal closely related group in Parodontidae (Actinopterygii: Characiformes).

Abstract: Parodon and Apareiodon lack sufficiently consistent morphological traits to be considered a monophyletic group in Parodontidae. Species within this family are either sex-homomorphic or sex-heteromorphic (i.e., lacking a differentiated sex chromosome system, ZZ/ZW or ZZ/ZW1W2). In this study, a DNA fragment from the heterochromatin segment of the W chromosome of Apareiodon ibitiensis (named WAp) was microdissected and used for in situ mapping of nine Parodontidae species. The species were also characterized using a satellite DNA probe (pPh2004). The species were phylogenetically clustered according to 17 characters, which were examined by both classical and molecular cytogenetic techniques. Given the present results, the single ZZ/ZW sex chromosome system seems to have been derived from a paracentric inversion of a terminal WAp site onto the proximal regions of the short arms of a metacentric chromosome pair, followed by WAp site amplification. We reason that these events restrained recombination and favored differentiation of the W chromosome in some species. Moreover, co-hybridization experiments targeting the WAp and pPh2004 repetitive DNA sites of A. affinis suggest that the ZZ/ZW1W2 sex chromosomes of this species may have arisen from a translocation between the proto-sex chromosome and an autosome. Our phylogenetic analysis corroborates the hypothesis of sex chromosome differentiation and establishes groups of closely related species. The phylogenetic reorganization in response to these new data supports the presence of internal monophyletic groups within Parodontidae.

DNA transposon invasion and microsatellite accumulation guide W chromosome differentiation in a Neotropical fish genome.

Abstract: Sex chromosome differentiation is subject to independent evolutionary processes among different lineages. The accumulation of repetitive DNAs and consequent crossing-over restriction guide the origin of the heteromorphic sex chromosome region. Several Neotropical fish species have emerged as interesting models for understanding evolution and genome diversity, although knowledge of their genomes is scarce. Here, we investigate the content of repetitive DNAs between males and females of Apareiodon sp. based on large-scale genomic data focusing on W sex chromosome differentiation. In Apareiodon, females are the heterogametic sex (ZW) and males are the homogametic sex (ZZ). The genome size estimate for Apareiodon was 1.2 Gb (with ~ 42× and ~ 47× coverage for males and females, respectively). In Apareiodon sp., approximately 36% of the genome was composed of repetitive DNAs and transposable elements (TEs) were the most abundant class. Read coverage analysis revealed different amounts of repetitive DNAs in males and females. The female-enriched clusters were located on the W sex chromosome and were mostly composed of microsatellite expansions and DNA transposons. Landscape analysis of TE contents demonstrated two major waves of invasions of TEs in the Apareiodon genome. Estimation of TE insertion times correlated with in situ locations permitted the inference that helitron, Tc1-mariner, and CMC EnSpm DNA transposons accumulated repeated copies during W chromosome differentiation between 20 and 12 million years ago. DNA transposons and microsatellite expansions appeared to be major players in W chromosome differentiation and to guide modifications in the genome content of the heteromorphic sex chromosomes.

Chromosomal markers in Parodontidae: an analysis of new and reviewed data with phylogenetic inferences

Abstract: The taxonomy of the family Parodontidae is confused, with many open questions regarding the most appropriate generic groupings. Studies on the organization, structure, composition, and in situ location of chromosomal features have led to consistent advances in the understanding of genome evolution. Among the species of Parodontidae, the consistent chromosomal divergences can be helpful in taxonomic classification, such as heteromorphic chromosome sex, karyotypic formulae, and number/location of the repetitive DNAs. Molecular analysis of repetitive sequences of satellite DNA and their physical mapping in the chromosomes of different species in a single group may be used to infer evolutionary divergence and cladistic grouping. In the present study, rDNA and the satellite DNA pPh2004 were mapped by fluorescent in situ hybridization on the chromosomes of some species of Parodontidae. These results were analyzed and reviewed together with other chromosomal markers and previously published data, to formulate inferences about the diversification of the genomes and propose a clustering of some Parodontidae species. This analysis indicated that the species Apareiodon affinis, Parodon moreirai, Parodon hilarii, Parodon nasus, and Parodon pongoensis have an apomorphic state for satellite DNA pPh2004 in Parodontidae in relation to previously studied species of Apareiodon.

Construction and Characterization of a Repetitive DNA Library in Parodontidae (Actinopterygii: Characiformes): A Genomic and Evolutionary Approach to the Degeneration of the W Sex Chromosome

Abstract: Repetitive DNA sequences, including tandem and dispersed repeats, comprise a large portion of eukaryotic genomes and are important for gene regulation, sex chromosome differentiation, and karyotype evolution. In Parodontidae, only the repetitive DNAs WAp and pPh2004 and rDNAs were previously studied using fluorescence in situ hybridization. This study aimed to build a library of repetitive DNA in Parodontidae. We isolated 40 clones using Cot-1; 17 of these clones exhibited similarity to repetitive DNA sequences, including satellites, minisatellites, microsatellites, and class I and class II transposable elements (TEs), from Danio rerio and other organisms. The physical mapping of the clones to chromosomes revealed the presence of a satellite DNA, a Helitron element, and degenerate short interspersed element (SINE), long interspersed element (LINE), and tc1-mariner elements on the sex chromosomes. Some clones exhibited dispersed signals; other sequences were not detected. The 5S rDNA was detected ...

전사인자(transcription factor)와 기관지천식

Abstract: Adr1p Carbon source-responsive zinc-finger transcription factor, required for transcription of the glucose-repressed gene ADH2, of peroxisomal protein genes, and of genes required for ethanol, glycerol, and fatty acid utilization (Direct: ChIP-on-chip) Cat8p derepression of a variety of genes under non-fermentative growth conditions, active after diauxic shift, binds carbon source responsive elements Hap4p Subunit of the heme-activated, glucose-repressed Hap2p/3p/4p/5p CCAAT-binding complex, a transcriptional activator and global regulator of respiratory gene expression; provides the principal activation function of the complex Indirect: Microarrays-Wild type vs. TF mutant) Stp1/Stp2 Homologous transcription factors, activated by proteolytic processing in response to signals from the SPS sensor system for external amino acids; activates transcription of amino acid permease genes and may have a role in tRNA processing

Dynamics of vertebrate sex chromosome evolution: from equal size to giants and dwarfs.

Abstract: The Y and W chromosomes of mammals and birds are known to be small because most of their genetic content degenerated and were lost due to absence of recombination with the X or Z, respectively. Thus, a picture has emerged of ever-shrinking Ys and Ws that may finally even fade into disappearance. We review here the large amount of literature on sex chromosomes in vertebrate species and find by taking a closer look, particularly at the sex chromosomes of fishes, amphibians and reptiles where several groups have evolutionary younger chromosomes than those of mammals and birds, that the perception of sex chromosomes being doomed to size reduction is incomplete. Here, sex-determining mechanisms show a high turnover and new sex chromosomes appear repeatedly. In many species, Ys and Ws are larger than their X and Z counterparts. This brings up intriguing perspectives regarding the evolutionary dynamics of sex chromosomes. It can be concluded that, due to accumulation of repetitive DNA and transposons, the Y and W chromosomes can increase in size during the initial phase of their differentiation.

Tracking the evolution of sex chromosome systems in Melanoplinae grasshoppers through chromosomal mapping of repetitive DNA sequences

Abstract: The accumulation of repetitive DNA during sex chromosome differentiation is a common feature of many eukaryotes and becomes more evident after recombination has been restricted or abolished. The accumulated repetitive sequences include multigene families, microsatellites, satellite DNAs and mobile elements, all of which are important for the structural remodeling of heterochromatin. In grasshoppers, derived sex chromosome systems, such as neo-XY♂/XX♀ and neo-X1X2Y♂/X1X1X2X2♀, are frequently observed in the Melanoplinae subfamily. However, no studies concerning the evolution of sex chromosomes in Melanoplinae have addressed the role of the repetitive DNA sequences. To further investigate the evolution of sex chromosomes in grasshoppers, we used classical cytogenetic and FISH analyses to examine the repetitive DNA sequences in six phylogenetically related Melanoplinae species with X0♂/XX♀, neo-XY♂/XX♀ and neo-X1X2Y♂/X1X1X2X2♀ sex chromosome systems. Our data indicate a non-spreading of heterochromatic blocks and pool of repetitive DNAs (C 0 t-1 DNA) in the sex chromosomes; however, the spreading of multigene families among the neo-sex chromosomes of Eurotettix and Dichromatos was remarkable, particularly for 5S rDNA. In autosomes, FISH mapping of multigene families revealed distinct patterns of chromosomal organization at the intra- and intergenomic levels. These results suggest a common origin and subsequent differential accumulation of repetitive DNAs in the sex chromosomes of Dichromatos and an independent origin of the sex chromosomes of the neo-XY and neo-X1X2Y systems. Our data indicate a possible role for repetitive DNAs in the diversification of sex chromosome systems in grasshoppers.

Numeric and structural chromosome polymorphism in Rineloricaria lima (Siluriformes: Loricariidae): fusion points carrying 5S rDNA or telomere sequence vestiges

Abstract: The karyotypes and chromosome polymorphism in Rineloricaria lima have been examined using both conventional (Giemsa-staining, C-banding and silver impregnation) and fluorescence in situ hybridization with 18S rDNA, 5S rDNA and telomeric (TTAGGG)n probes protocols. A variation in chromosome number of 2n = 70–66 was detected in the analyzed populations, with the fundamental number (FN) ranging from 72 to 74. The 2n = 70 chromosomes and karyotypic formula 2st + 68a (NF = 72) was establish the start point of the current polymorphism. Based on this karyotype, seven fusioned and/or inverted chromosomes types (without vestiges of interstitial telomeric sites—ITS; with ITS and; carrying 5S rDNA fusion points) were described and eight karyotypes were established. It was hypothesized that one Rineloricaria branch, originally having a diploid number of 2n = 54 which appears the ancestral 2n for Loricariidae, diversified through centric fissions generating unstable sites at the break points. These unstable sites may have triggered Robertsonian fusions generating the currently observed polymorphism of 70–66 chromosomes. The formation of the chromosomes variants could have possibly led to the formation of different gametic combinations (balanced and unbalanced), which may have generated alterations in the FN above 72. These results demonstrate an important case that ITS and 5S rDNA were observed in fused chromosomes, implying that rDNA could serve as breakpoint for the fusion in Rinelocaria. Thus, all these mechanisms promote an increase in variability and assist in the maintenance of the observed polymorphism.