A number of human diseases, such as arthritis and atherosclerosis, include characteristic pathology in specific anatomical locations. Here we show transcriptomic differences in synovial fibroblasts from different joint locations and that HOX gene signatures reflect the joint-specific origins of mouse and human synovial fibroblasts and synovial tissues. Alongside DNA methylation and histone modifications, bromodomain and extra-terminal reader proteins regulate joint-specific HOX gene expression. Anatomical transcriptional diversity translates into joint-specific synovial fibroblast phenotypes with distinct adhesive, proliferative, chemotactic and matrix-degrading characteristics and differential responsiveness to TNF, creating a unique microenvironment in each joint. These findings indicate that local stroma might control positional disease patterns not only in arthritis but in any disease with a prominent stromal component.
Cytogenetic investigations of the nucleolar-organizing regions (NORs) show that there is variation in the transcriptional activity of rDNA in many organisms. As a consequence, genetic polymorphism of these regions has been detected. The aim of the present study was to evaluate the hypothetic genetic mechanisms determining the NORs polymorphism of the domestic horse chromosomes. Molecular cytogenetic analyses were carried out on Hucul horses and the following techniques were used: fluorescence in situ hybridization (FISH), telomere primed in situ synthesis (PRINS), in situ nick-translation with HpaII, silver staining (AgNOR) and C-banding technique (CBG). The obtained results suggest that variation in the number and size of silver deposits is related to the number of rDNA copies, DNA methylation and the localization of ribosomal DNA loci in telomeric regions. Moreover, we have found that chromosome pairs 28 and 31 are characterized by higher variation in the NORs number.
Although the phenomenon of sexual dimorphism is widespread in vertebrates, the molecular mechanism of sex-determination is not the same across animal phyla, in contrast to other areas of developmental biology. Recent extensive studies, however, have given proof of evolutionarily conserved function in genes which share a novel DNA binding DM domain, primarily identified in two invertebrate sex regulatory genes: doublesex of Drosophila melanogaster and mab-3 of Caenorhabditis elegans. Their mammalian autosomal homologue, DMRT1, first isolated in humans, was further discovered in genomes of various vertebrate species and appears to be involved in similar aspects of sexual development. Its precise role is still speculated, thus identification of sex reversal mutations, functional studies as well as determination of the sex-specific expression profile during embryogenesis are still being undertaken. Is this a sex determining rather than a sex differentiating gene? Is it involved in a dosage-sensitive mechanism? On what level does it function in the hierarchy of the sexual regulatory gene cascade? Recent results are discussed in this paper.
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