The Role of Autophagy in the Development of Pathological Conditions of the Body.

Autophagy is the process of lysosomal elimination of the cell organelles, cytoplasmic sites, and pathogenic microorganisms that enter the cell. This process is associated with both cell death regulation and an increase in cell survival chances. Autophagy is involved in the development of various diseases (Crohn disease, cancer, atherosclerosis, etc.). For these reasons, it is of significant interest to establish the molecular targets involved in autophagy regulation and the factors that mediate its participation in pathogenesis. The review describes the potential molecular mechanisms involved in the regulation of autophagy, its contribution to the vital cell activity in a healthy organism, and pathologies.

[Transcription Factor Sp1 in the Expression of Genes Encoding Components of MAPK, JAK/STAT, and PI3K/Akt Signaling Pathways].

Sp1 is a transcription factor of the Sp/KLF family that binds to GC-rich motifs in regulatory regions of genes. Sp1 is involved in the regulation of cell proliferation, apoptosis and differentiation, and angiogenesis. A high level of SP1 expression, as well as its aberrant transcriptional activity due to post-translational modifications, is found in cells in oncological diseases, such as lung, breast, pancreatic, thyroid, gastric cancer, and glioma; congenital heart disease, as well as neurodegenerative disorders, including Huntington's and Parkinson's diseases. Binding of Sp1 to GC-rich motifs of the regulatory regions of the genes encoding components of the MAPK, p38, JAK/STAT, PI3K/Akt signaling pathways, is involved in the control of cell proliferation, differentiation, and death. In addition, kinases of these signaling pathways are able to change the transcriptional activity of Sp1 by phosphorylation of certain amino acid residues, which leads to a change in the efficiency of its binding to cofactors and DNA regulatory regions. This review presents data on the relationship between the Sp1 transcription factor and the activity of the MAPK, p38, JAK/STAT, and PI3K/Akt signaling pathways in normal tissues and in various pathologies, including malignant diseases.

Plasmolipin and Its Role in Cell Processes.

The mechanisms involved in the origin and development of malignant and neurodegenerative diseases are an important area of modern biomedicine. A crucial task is to identify new molecular markers that are associated with rearrangements of intracellular signaling and can be used for prognosis and the development of effective treatment approaches. The proteolipid plasmolipin (PLLP) is a possible marker. PLLP is a main component of the myelin sheath and plays an important role in the development and normal function of the nervous system. PLLP is involved in intracellular transport, lipid raft formation, and Notch signaling. PLLP is presumably involved in various disorders, such as cancer, schizophrenia, Alzheimer's disease, and type 2 diabetes mellitus. PLLP and its homologs were identified as possible virus entry receptors. The review summarizes the data on the PLLP structure, normal functions, and role in diseases.

[Plasmolipin and Its Role in Cell Processes].

The mechanisms involved in the origin and development of malignant and neurodegenerative diseases are an important area of modern biomedicine. A crucial task is to identify new molecular markers that are associated with rearrangements of intracellular signaling and can be used for prognosis and the development of effective treatment approaches. The proteolipid plasmolipin (PLLP) is a possible marker. PLLP is a main component of the myelin sheath and plays an important role in the development and normal function of the nervous system. PLLP is involved in intracellular transport, lipid raft formation, and Notch signaling. PLLP is presumably involved in various disorders, such as cancer, schizophrenia, Alzheimer's disease, and type 2 diabetes mellitus. PLLP and its homologs were identified as possible virus entry receptors. The review summarizes the data on the PLLP structure, normal functions, and role in diseases.

[Packaging of Subchromosomal-Size DNA Molecules in Chromatin Bodies in the Ciliate Macronucleus].

A fundamental difference between somatic nuclei (macronuclei) of ciliates and cell nuclei of higher eukaryotes is that the macronuclear genome is a huge number (up to tens or hundreds of thousands) of gene-sized (0.5-25 kb) or subchromosomal (up to 2000 kb) minichromosomes. Electron microscopy shows that macronuclear chromatin usually looks like chromatin bodies or fibrils 200-300 nm thick in the interphase. However, the question of how many DNA molecules are contained in an individual chromatin body remains open. The organization of chromatin in macronuclei was studied in the ciliates Didinium nasutum and three Paramecium sp, which differ in pulsed-field gel electrophoresis (PFGE) karyotype, and compared with the model of topologically associated domains (TADs) of higher eukaryotic nuclei. PFGE showed that the sizes of macronuclear DNAs ranged from 50 to 1700 kb, while the majority of the molecules were less than 500 kb in length. A comparative quantitative analysis of the PFGE and electron microscopic data showed that each chromatin body contained one minichromosome in P. multimicronucleatum in the logarithmic growth phase, while bodies in the D. nasutum macronucleus contained two or more DNA molecules each. Chromatin bodies aggregated during starvation, when activity of the macronuclei decreased, leading to an increase of chromatin body size or the formation of 200- to 300-nm fibrils of several chromatin bodies. A model was proposed to explain the formation of such structures. In terms of topological characteristics, macronuclear chromatin bodies with subchromosomal DNA molecules were found to correspond to higher eukaryotic TADs.

The Role of the MCTS1 and DENR Proteins in Regulating the Mechanisms Associated with Malignant Cell Transformation.

The mutations associated with malignant cell transformation are believed to disrupt the expression of a significant number of normal, non-mutant genes. The proteins encoded by these genes are involved in the regulation of many signaling pathways that are responsible for differentiation and proliferation, as well as sensitivity to apoptotic signals, growth factors, and cytokines. Abnormalities in the balance of signaling pathways can lead to the transformation of a normal cell, which results in tumor formation. Detection of the target genes and the proteins they encode and that are involved in the malignant transformation is one of the major evolutions in anti-cancer biomedicine. Currently, there is an accumulation of data that shed light on the role of the MCTS1 and DENR proteins in oncogenesis.

The Different Impact of ERK Inhibition on Neuroblastoma, Astrocytoma, and Rhabdomyosarcoma Cell Differentiation.

Aberrant ERK activity can lead to uncontrolled cell proliferation, immortalization, and impaired cell differentiation. Impairment of normal cell differentiation is one of the critical stages in malignant cell transformation. In this study, we investigated a relationship between ERK tyrosine kinase activity and the main differentiation features (changes in cell morphology and expression of genes encoding differentiation markers and growth factor receptors) in SH-SY5Y neuroblastoma, U-251 astrocytoma, and TE-671 rhabdomyosarcoma cells. ERK activity was assessed using a reporter system that enabled live measurements of ERK activity in single cells. We demonstrated that suppression of ERK activity by selective ERK inhibitors, in contrast to a commonly used differentiation inducer, retinoic acid, leads to significant changes in TE-671 cell morphology and expression of the myogenic differentiation marker genes PROM1, MYOG, and PAX7. There was a relationship between ERK activity and morphological changes at an individual cell level. In this case, SH-SY5Y cell differentiation induced by retinoic acid was ERK-independent. We showed that ERK inhibition increases the sensitivity of TE-671 cells to the EGF, IGF-1, and NGF growth factors, presumably by reducing basal ERK activity, and to the BDNF growth factor, by increasing expression of the TrkB receptor.

[High Expression Level of SP1, CSF1R, and PAK1 Correlates with Sensitivity of Leukemia Cells to the Antibiotic Mithramycin].

Acute myeloid leukemia (AML) is a genetically heterogeneous group of oncological diseases of the hematopoietic system, which are extremely difficult to treat. The development of new targeted drugs (Hylteritinib, Venetoclax) significantly improved the survival of patients, but resistance, as well as cytotoxic anti-leukemia drugs, often occurs. The search for new molecular targets for the development of effective approaches for the treatment of AML is very urgent. In blast cells of patients with AML, mutations, chromosomal rearrangements, and increased expression of a number of non-mutant genes, including transcription factor genes, are detected. The transcription factor Sp 1 binds to GC-rich regions of regulatory regions of various genes and thus controls their expression. Sp1 targets include genes responsible for proliferation, cell cycle regulation, and differentiation. In many malignant diseases, a high level of Sp1 gene expression is associated with an unfavorable prognosis, therefore, Sp1 is considered as a promising therapeutic target for cancer. In this paper, we estimated the expression levels of Sp1 in various malignant tissues. Increased Sp1 expression was detected in samples obtained from patients with AML, acute lymphoblastic leukemia, Ewing sarcoma, ovarian and kidney cancer. It is also shown that Sp1 expression correlates with the expression of genes encoding cytokine receptors and growth factors (CSF1R and IL6R), intracellular kinases (CSK, SYK, PAK1, ILK, JAK2), and transcription factor LMO2. The correlation between expression levels of Sp1 and CSF1R, SYK, Jak2 and LMO2 is also characteristic of transplanted human leukemia cells. We measured expression levels of Sp1, CSF1R, ILK, PAK1 in the cells of three transplantable lines of human leukemia and found increased levels of expression of these genes in Kasumi-1 cells. In addition, we showed that Kasumi-1 cells are most sensitive to Mitramycin, a drug that displaces Sp1 from its targets with DNA. Our data indicate the need to identify AML cells that are most sensitive to inhibition of Sp1 activity in order to assess the possibility of suppressing its activity in vivo.

Establishment of a FDC-P1 Murine Cell Line with Human KIT N822K Gene Overexpression.

The mechanism of resistance of leukemia cells to chemotherapeutic drugs remains poorly understood. New model systems for studying the processes of malignant transformation of hematopoietic cells are needed. Based on cytokine-dependent murine acute myeloid leukemia (AML) FDC-P1 cells, we generated a new cell line with ectopic expression of the KIT gene encoding mutant human receptor tyrosine kinase (N822K). We investigated the role played by overexpression of the mutant KIT in the survival of leukemia cells and their sensitivity to therapeutic drugs. We also generated a co-culture system consisting of FDC-P1 murine leukemia cells and a HS-5 human stromal cell line. Our data can be used for a further comprehensive analysis of the role of KIT N822K mutation in the cellular response to anti-leukemic drugs, growth factors, and cytokines. These data are of interest in the development of new effective therapeutic approaches to the treatment of acute leukemia.

[Inhibition of Non-Receptor Tyrosine Kinase JAK2 Reduces Neuroblastoma Cell Growth and Enhances the Action of Doxorubicin].

Novel treatments for various types of malignant diseases are warranted. In this study, we evaluated JAK2 inhibitors (Janus kinase 2) for suppressing the growth of malignant neuroblastoma and glioblastoma cells as well as breast and non-small cell lung cancers. Neuroblastoma and glioblastoma cells are the most sensitive to the JAK2 inhibitor AG490. A study of the relative expression of receptors that can activate JAK2 suggests that cell line sensitivity to AG490 may be mediated by IL6-R, IL11-R and/or CSF1-R. AG490 enhances the effect of doxorubicin on neuroblastoma cells. Our findings suggest the possible relevance of JAK2 inhibitors for neuroblastoma therapy, especially in combination with doxorubicin.

1-(4-Phenoxybenzyl) 5-Aminouracil Derivatives and Their Analogues - Novel Inhibitors of Human Adenovirus Replication.

Adenovirus infections are characterized by widespread distribution. The lack of causal therapy, which is effective in treating this group of diseases, explains the need for new therapeutic drugs. Notably, anti-adenoviral activity of [4-(phenoxy)benzyl]-5-(phenylamino)-6-azauracil, 1-[4-(phenoxy)benzyl]-5-(morpholino) uracil, 1-[4-(4-chlorophenoxy)benzyl]-5-(morpholino) uracil, and 1-[4-(4-fluorophenoxy)-benzyl]-5-(morpholino) uracil was observed.

The Role of TAL1 in Hematopoiesis and Leukemogenesis.

TAL1 (SCL/TAL1, T-cell acute leukemia protein 1) is a transcription factor that is involved in the process of hematopoiesis and leukemogenesis. It participates in blood cell formation, forms mesoderm in early embryogenesis, and regulates hematopoiesis in adult organisms. TAL1 is essential in maintaining the multipotency of hematopoietic stem cells (HSC) and keeping them in quiescence (stage G0). TAL1 forms complexes with various transcription factors, regulating hematopoiesis (E2A/HEB, GATA1-3, LMO1-2, Ldb1, ETO2, RUNX1, ERG, FLI1). In these complexes, TAL1 regulates normal myeloid differentiation, controls the proliferation of erythroid progenitors, and determines the choice of the direction of HSC differentiation. The transcription factors TAL1, E2A, GATA1 (or GATA2), LMO2, and Ldb1 are the major components of the SCL complex. In addition to normal hematopoiesis, this complex may also be involved in the process of blood cell malignant transformation. Upregulation of C-KIT expression is one of the main roles played by the SCL complex. Today, TAL1 and its partners are considered promising therapeutic targets in the treatment of T-cell acute lymphoblastic leukemia.

[Treatment with anti-cancer agents results in profound changes in lncRNA expression in colon cancer cells].

Using real-time RT-PCR in combination with bioinformatics, we have shown for the first time that the treatment of HCT-116 and HT-29 colon cancer cells with two anti-cancer agents (doxycycline or 3,3'-diindolylmethane) results in profound changes in the intracellular content of several lncRNAs (by up to 100 times). Since many of these RNAs are secreted by tumors into the bloodstream, the obtained results provide a basis for developing more sensitive protocols for serological monitoring of tumor relapse and metastasis, as well as for search of new anti-cancer drugs.

Lentiviral gene delivery to plasmolipin-expressing cells using Mus caroli endogenous retrovirus envelope protein.

Gene therapy is a promising method for treating malignant diseases. One of the main problems is target delivery of therapeutic genes. Here we show that lentiviral vector particles pseudotyped with Mus caroli endogenous retrovirus (McERV) envelope protein can be used for selective transduction of PLLP-expressing cells. As a therapeutic gene in McERV-pseudotyped vector particles we used miniSOG encoding the cytotoxic FMN-binding protein, which can generate reactive oxygen species under illumination. Significant cytotoxic effect (up to 80% of dead cells in population) was observed in PLLP-expressing cells transduced with McERV-pseudotyped vector particles and subjected to illumination. We demonstrated that the McERV-pseudotyped HIV-1 based lentiviral vector particles are an effective tool for selective photoinduced destruction of PLLP-expressing cells.

[Key molecular mechanisms associated with cell malignant transformation in acute myeloid leukemia].

Cancer, along with cardiovascular disorders, is one of the most important problems of healthcare. Pathologies of the hematopoietic system are the most prevalent in patients under 30 years of age, including acute myeloid leukemia (AML), which is widespread and difficult to treat. The review considers the mechanisms that play a significant role in AML cell malignant transformation and shows the contributions of certain genes to both remission and resistance of AML cells to various treatments.

[Abnormal expression of genes that regulate retinoid metabolism and signaling in non-small-cell lung cancer].

Retinoids are signaling molecules that control a wide variety of cellular processes and possess antitumor activity. This work presents a comprehensive description of changes in the expression of 23 genes that regulate retinoid metabolism and signaling in non-small-cell lung cancer tumors compared to adjacent normal tissues obtained using RT-PCR. Even at early stages of malignant transformation, a significant decrease in ADH1B, ADH3, RDHL, and RALDH1 mRNA levels was observed in 82, 79, 73, and 64% of tumor specimens, respectively, and a considerable increase in AKR1B10 mRNA content was observed in 80% of tumors. Dramatic changes in the levels of these mRNAs can impair the synthesis of all-trans retinoic acid, a key natural regulatory retinoid. Apart from that, it was found that mRNA levels of nuclear retinoid receptor genes RXRγ, RARα, RXRα, and gene RDH11 were significantly decreased in 80, 67, 57, and 66% of tumor specimens, respectively. Thus, neoplastic transformation of lung tissue cells is accompanied with deregulated expression of key genes of retinoid metabolism and function.

[Ribonuclease binase induces death in T-cell acute lymphoblastic leukemia cells by apoptosis].

Bacterial ribonuclease binase is a potential anticancer agent. In the present study, we have determined the toxic effect of binase towards cell lines of T-cell acute lymphoblastic leukemia Jurkat and CEMss. We have shown that binase induces apoptosis in these cells. At the same time, binase does not cause toxic effects in leukocytes of healthy donors, which suggests that binase activity towards leukemic cells is selective. We have found that the treatment of cancer cells with binase leads to a reduction in reactive oxygen species and transcription factor NFκB levels, and demonstrated that these effects are a common feature of the action of RNases on cancer cells.

[Downregulation of Human Adenovirus DNA Polymerase Gene by Modified siRNAs].

Human adenoviruses, in particular D8, D19, and D37, cause ocular infections. Currently, there is no available causally directed treatment, which efficiently counteracts adenoviral infectious diseases. In our previous work, we showed that gene silencing by means of RNA interference is an effective approach for downregulation of human species D adenoviruses replication. In this study, we compared the biological activity of siRNAs and their modified analogs targeting human species D adenoviruses DNA polymerase. We found that one of selectively 2'-O-methyl modified siRNAs mediates stable and long-lasting suppression of the target gene (12 days post transfection). We suppose that this siRNA can be used as a potential therapeutic agent against human species D adenoviruses.

Therapy of HIV Infection: Current Approaches and Prospects.

The human immunodeficiency virus type 1 (HIV-1) is the causative agent of one of the most dangerous human diseases - the acquired immune deficiency syndrome (AIDS). Over the past 30 years since the discovery of HIV-1, a number of antiviral drugs have been developed to suppress various stages of the HIV-1 life cycle. This approach has enables the suppression of virus replication in the body, which significantly prolongs the life of HIV patients. The main downside of the method is the development of viral resistance to many anti-HIV drugs, which requires the creation of new drugs effective against drug-resistant viral forms. Currently, several fundamentally new approaches to HIV-1 treatment are under development, including the use of neutralizing antibodies, genome editing, and blocking an integrated latent provirus. This review describes a traditional approach involving HIV-1 inhibitors as well as the prospects of other treatment options.

Hepatitis C virus: The role of N-glycosylation sites of viral genotype 1b proteins for formation of viral particles in insect and mammalian cells.

Hepatitis C virus (HCV) is characterized by considerable genetic variability and, as a consequence, it has 6 genotypes and multitude of subtypes. HCV envelope glycoproteins are involved in the virion formation; the correct folding of these proteins plays the key role in virus infectivity. Glycosylation at certain sites of different genotypes HCV glycoproteins shows substantial differences in functions of the individual glycans (Goffard et al., 2005; Helle et al., 2010) [1], [2]. In this study, differential glycosylation sites of HCV genotype 1b envelope proteins in insect and mammalian cells was demonstrated. We showed that part of glycosylation sites was important for folding of the proteins involved in the formation of viral particles. Point mutations were introduced in the protein N-glycosylation sites of HCV (genotype 1b) and the mutant proteins were analyzed using baculovirus expression system in mammalian and insect cells. Our data showed that, in contrast to HCV 1a and 2a, the folding of HCV 1b envelope proteins E2 (sites N1, N2, N10) and E1 (sites N1, N5) was disrupted, however that did not prevent the formation of virus-like particles (VLP) with misfolded glycoproteins having densities typical for HCV particles containing RNA fragments. Experimental data are supported by mathematical modeling of the structure of E1 mutant variants.