Semenova Ev

Ceruloplasmin decreases respiratory burst reaction during pregnancy

Abstract Testing of pregnant women reveals weakening of neutrophil-mediated effector functions, such as reactive oxygen species generation. This study provides data confirming the phenomenon, gained through application of the flow cytometry technique. Key factors influencing neutrophil functional activity in blood plasma of pregnant women have not been detected so far. At the same time, concentration of ceruloplasmin – a copper-containing glycoprotein – is known to increase in blood significantly during pregnancy. We observed the negative correlation between ceruloplasmin concentration in blood plasma of pregnant women and the intensity of respiratory burst of neutrophils. Fractionation of plasma using gel-filtration revealed that ceruloplasmin-containing fraction demonstrated suppression of the respiratory burst reaction. Partial elimination of ceruloplasmin from the blood of pregnant women, performed with the help of specific antibodies and followed by immunoprecipitation, leads to an increased respiratory burst reaction. On the contrary, addition of ceruloplasmin to blood samples of healthy donors noticeably decreases the respiratory burst reaction. The results presented prove that change in ceruloplasmin level in plasma is necessary and sufficient for modulating the ability of neutrophils to produce reactive oxygen species during pregnancy.

Detection of Inflammatory Processes during Various Diseases by the Method of Flow Cytofluorometry

Oxidative (respiratory) burst is an important manifestation of inflammation. Precise quantitative assessment of this reaction by flow cytometry made it possible to record and evaluate the severity of the inflammatory processes in a wide spectrum of diseases including diphtheria, hepatitis, pneumonia, bronchial asthma, arthritis, vasculitis, postoperative complications, tuberculosis, psoriasis, rheumatoid arthritis, systemic lupus erythematosus, and myocardial infarction. This approach can be employed as a highly sensitive method of detection of inflammatory reactions and monitoring of their course in various pathological processes.

Aberrant expression of the sox2 gene in malignant gliomas

Both genetic and epigenetic changes underlie the mechanisms of tumor initiation and progression. In this study, we analyzed sox2 gene expression and its epigenetic changes in primary cultures of malignant gliomas. The sox2 expression was detected in most (74%) gliomas, but not in morphologically normal brain tissue. These facts point to relationships between the sox2 transcription activity and the process of glioma malignant transformation. It was demonstrated that association of different areas of the sox2 gene with important epigenetic markers—posttranslational modifications of H3 histone H3K4ac and H3K9met3—did not correlate with sox2 expression. However, it suggests stochastic regulation of sox2 gene expression in malignant gliomas.

Genetic and epigenetic markers of gliomas

Malignant gliomas are aggressive and highly invasive tumors. Various genetic and epigenetic changes are common for these tumors. Mostly they concern the genes involved in cell-cycle regulation, apoptotic pathways, cell invasion, angiogenesis, and cell metabolism. The role of epigenetic mechanisms in glioma malignant transformation, despite recent progress, is uncertain and remains under intense study. This review describes the mechanisms of epigenetic regulation of gene expression, including posttranslational modifications of histones, DNA methylation in promoter regions, and microRNA regulation. The genetic and epigenetic factors driving the pathogenesis of gliomas in their possible mutual influence and the potential epigenetic targets that can be used for diagnostics and new therapeutic approaches are also discussed.

Role of human RAD51 recombinase in the cycle checkpoint and survival of a cell

The RAD 51 protein, a eukaryotic homologue of Escherichia coli RecA, plays a significant role in both mitotic and meiotic homologous recombination. Here, we demonstrate that short-term silencing of the Rad51 gene by specific small interfering RNA (siRNA) that inhibits cell proliferation and reduces the viability of most cells. Cells with suppressed expression of Rad51 gene have altered cell cycles and accumulate in the S and G2 phases. Our findings show that the disruption of homologous recombination leads to cell death. However, some cells, e.g., MCF-7 cells, are insensitive to the suppression of Rad51 gene expression.

Peculiarities of the formation and subsequent removal of the circulating immune complexes from the bloodstream during the process of digestion

Background: Large protein aggregates, known as circulating immune complexes (CICs), are formed in biological fluids as a result of the development of the bodys immune response to various provoking factors. The kinetic characteristics of the formation and removal of immune complexes (ICs), their physical parameters, the isotypic composition of immunoglobulins (Igs) and the antigenic component of the CICs may reflect certain aspects of certain pathological and metabolic processes taking place in humans and animals. The aim of this study is to assess the kinetic characteristics of the formation and removal of the CICs that form in blood after eating. We also analyze the changes in the isotypic composition of Igs of ICs that accompany this biological process in rodents and humans. Methods: We identified the CICs, which differed in size and class of Igs, using dynamic light scattering. To remove ICs from the plasma, we used immune-affinity sedimentation. Monoclonal antibodies for the Igs of different isotypes were added to the plasma samples to determine the isotypic composition of the ICs. Results: A large number of ICs were formed in the blood of rats and humans after eating (food CICs). In rats, food ICs are almost immediately filtered in the liver, without circulating in the bloodstream through the body. In humans, the level of food ICs in the blood increases for 3.5 h after ingestion, then within 7–8 h their gradual removal takes place. It was found that in the process of digestion in humans, the isotypic composition of Igs in the CICs changes and becomes more diverse. Conclusions: The molecular–cellular mechanisms of the formation and utilization of food CICs in humans and rodents do not match completely.

Study of chromatin decondensation factors in human spermatozoids by flow cytometry

To date, the mechanisms responsible for radical change of chromatin structure in male germ cells during fertilization are unclear. Evidence suggesting the existence of proteolytic nuclear enzymes in mature human spermatozoids are presented in this work. The possible role of these previously unknown proteases in decondensation of chromatin of spermatozoids in a fertilized ovum is discussed. Application of the flow cytometry technique has shown that treatment of human spermatozoid nuclei with SH-reagents leads not only to destruction of disulfide bonds between protamine molecules that is necessary for their effective utilization but also induces specific endogenous proteolytic activity that consequently results in rather fast decondensation of chromatin followed by proteolytic cleavage of nuclear proteins. A chromatin decondensation process can be almost totally blocked by serine protease inhibitors and components of seminal fluid. An original cytochemical approach of binding of fluorescently labeled protease inhibitor to the target of investigation has been used in order to visualize the localization of proteases in male germ cell nuclei. The results of our study suggest that one of the factors of chromatin reorganization involved in the formation of male pronucleus is endogenous nuclear protease of spermatozoids, which is activated by glutathione or other SH-components of ovum cytoplasm.