Molecular Genetic Abnormalities in the Pathogenesis of Hematologic Malignancies and Corresponding Changes in Cell Signaling Systems

Hematological disorders include a wide spectrum of malignancies of hematopoietic and lymphoid tissues. The genetic changes underlying the pathogenesis of the diseases are specific for each disease. High incidence of chromosomal aberrations (deletion, translocation, insertion) is one of the principal characteristics of oncohematological diseases. In addition, mutations in individual genes or blocking of normal regulation of gene functioning in relation to epigenetic events can occur. Progression of oncohematological diseases could be a result of accumulation of different genetic abnormalities. Modern classification of malignancies of hematopoietic and lymphoid tissues is based on the analysis of clinical data, morphological and functional characteristics of tumor cells and identification of specific cytogenetic and molecular-genetic changes. A large number of genetic abnormalities specific for certain types of hematological malignancies has been discovered to date. It allows to optimize the treatment strategy, as well as to design, test and introduce to the clinical practice a number of targeted drugs (inhibitors of chimeric proteins formed as a result of translocations and triggering the malignant cell transformation). Drugs based on monoclonal antibodies (Rituximab, Alemtuzumab, etc.) or low molecular weight compounds (Imatinib, Bortezomib, Carfilzomib) form this group of medications. The knowledge about not only specific gene abnormalities but also about the corresponding changes in cell efferent signaling pathways could be of great interest for the development of new targeted molecules or the repurposing of known chemotherapeutic agents. The present review compares genetic aberrations in diseases listed in the 2008 WHO classification (amended in 2016) of hematopoietic and lymphoid tissue malignancies and main changes in cell signaling pathways associated with malignant transformation of hematopoietic cells

Expression of Drosophila virilis Retroelements and Role of Small RNAs in Their Intrastrain Transposition

Transposition of two retroelements (Ulysses and Penelope) mobilized in the course of hybrid dysgenesis in Drosophila virilis has been investigated by in situ hybridization on polytene chromosomes in two D. virilis strains of different cytotypes routinely used to get dysgenic progeny. The analysis has been repeatedly performed over the last two decades, and has revealed transpositions of Penelope in one of the strains, while, in the other strain, the LTR-containing element Ulysses was found to be transpositionally active. The gypsy retroelement, which has been previously shown to be transpositionally inactive in D. virilis strains, was also included in the analysis. Whole mount is situ hybridization with the ovaries revealed different subcellular distribution of the transposable elements transcripts in the strains studied. Ulysses transpositions occur only in the strain where antisense piRNAs homologous to this TE are virtually absent and the ping-pong amplification loop apparently does not take place. On the other hand small RNAs homologous to Penelope found in the other strain, belong predominantly to the siRNA category (21nt), and consist of sense and antisense species observed in approximately equal proportion. The number of Penelope copies in the latter strain has significantly increased during the last decades, probably because Penelope-derived siRNAs are not maternally inherited, while the low level of Penelope-piRNAs, which are faithfully transmitted from mother to the embryo, is not sufficient to silence this element completely. Therefore, we speculate that intrastrain transposition of the three retroelements studied is controlled predominantly at the post-transcriptional level

Neuronal nitric oxide synthase contributes to the regulation of hematopoiesis

Nitric oxide (NO) signaling is important for the regulation of hematopoiesis. However, the role of individual NO synthase (NOS) isoforms is unclear. Our results indicate that the neuronal NOS isoform (nNOS) regulates hematopolesis in vitro and in vivo. nNOS is expressed in adult bone marrow and fetal liver and is enriched in stromal cells. There is a strong correlation between expression of nNOS in a panel of stromal cell lines established from bone marrow and fetal liver and the ability of these cell lines to support hematopoietic stem cells; furthermore, NO donor can further increase this ability. The number of colonies generated in vitro from the bone marrow and spleen of nNOS-null mutants is increased relative to wild-type or inducible- or endothelial NOS knockout mice. These results describe a new role for nNOS beyond its action in the brain and muscle and suggest a model where nNOS, expressed in stromal cells, produces NO which acts as a paracrine regulator of hematopoietic stem cells