[Association of Polymorphic Genome Variants in the 2q32.1 Locus with the Development of Vasovagal Syncope].

The vasovagal syncope (VVS) is the most common form of syncope. The mechanisms of VVS development are not entirely clear. It is known that there is a genetic predisposition to this disease, but the data on the roles of individual genes are quite contradictory.

Vasovagal Syncope Is Associated with Variants in Genes Involved in Neurohumoral Signaling Pathways.

Vasovagal syncope (VVS) is the most common cause of sudden loss of consciousness. VVS results from cerebral hypoperfusion, due to abnormal autonomic control of blood circulation, leading to arterial hypotension. It is a complex disease, and its development is largely associated with genetic susceptibility.

[MiRNA miR-375 as a Multifunctional Regulator of the Cardiovascular System].

MicroRNA (miRNA) miR-375 acts as a multifunctional regulator of the activity of many physiological and pathological cellular processes by interacting with a large number of target genes. MiR-375 is involved in the regulation of the differentiation and functioning of cells of the nervous and immune systems, bone and adipose tissue, and even the life cycle of a number of viruses. Changes in miR-375 expression have been found in carcinogenesis, inflammation, and autoimmune and cardiovascular diseases.

Towards Understanding the Genetic Nature of Vasovagal Syncope.

Syncope, defined as a transient loss of consciousness caused by transient global cerebral hypoperfusion, affects 30-40% of humans during their lifetime. Vasovagal syncope (VVS) is the most common cause of syncope, the etiology of which is still unclear. This review summarizes data on the genetics of VVS, describing the inheritance pattern of the disorder, candidate gene association studies and genome-wide studies.

[The Myocardial Infarction Associated Variant in the MIR196A2 Gene and Presumable Signaling Pathways to Involve miR-196a2 in the Pathological Phenotype].

The heritable component of susceptibility to myocardial infraction (MI) remains unexplained, possibly due to the minor effects of genes, which are not obviously associated with the disease. These genes may be integrated in miRNA regulated networks associated with myocardial infarction. A systematic review of the literature led us to selecting rs2910164 (MIR146A), rs11614913 (MIR196A2), and rs3746444 (MIR499А) variants to study the association with the MI phenotype.