[Reduced Expression of the Tissue-Specific Oct-IL Isoform Exerts an Antitumor Effect on Namalwa Burkitt's Lymphoma Cells].

Increased expression levels of the Oct-1 transcription factor is considered to be one of the key markers of poor cancer prognosis. In addition to the ubiquitous Oct-1A isoform, which is found in all cells, there also exists a tissue-specific Oct-1L isoform, which is expressed in hematopoietic cells. Oct-1L increases cell resistance to different stresses and also regulates the expression of genes controlling differentiation of hematopoietic and immune system cells. The tissue-specific Oct-1L isoform levels are significantly increased in the B-cell lymphoblastoma Namalwa and Raji lines and the T-cell lymphoblastoma Jurkat line compared to normal B and T cells. Apparently, aberrant Oct-1L overexpression not only enhances stress resistance but also leads to the disruption of developmental pathways in the cells promoting their malignant transformation. We report here that targeted suppression of the tissue-specific Oct-1L isoform expression reduces the proliferation rate of Namalwa B-lymphoblastic Burkitt's lymphoma cells, significantly increases cell death rate under hypoxic conditions, and makes cells more sensitive to chemotherapeutic agents such as docetaxel and doxorubicin. These results indicate that targeted therapy aimed at the suppression of the Oct-1 isoforms with increased expression levels in tumor cells rather than the total Oct-1, thus avoiding the traumatic effects of total Oct-1 knockdown, may be promising. Selective suppression of Oct-1 isoforms is a promising strategy in the treatment of lymphoid tumors and may contribute to mitigating the disease course and increasing survival rates in cancer patients.

[POU2F1 (Oct-1) Differently Autoregulates the Alternative Promoters of Its Own Gene by Binding to Different Regulatory Sites].

The POU2F1 gene, which plays an important role in regulating the mammalian genome and development, has both a ubiquitous (U) and a tissue-specific (L) promoter and is subject to intricate regulation. Regions of POU2F1 gene were found to contain multiple binding sites for its product POU2F1 (Oct-1), a transcription factor. Interspecies homology in these regions was found to exceed 90% among the human, mouse, rat, pig, and dog genomes, almost all of the Oct-1 binding sites being identical. Some of the sites cluster in the vicinity of each of the two alternative promoters, while others are in the 5' noncoding region 6 kb upstream of the transcription start site. The presence of Oct-1 at the sites was demonstrated by chromatin immunoprecipitation and the electrophoretic mobility shift assay (EMSA). A POU2F1 knockdown activated the U promoter and downregulated the L promoter in Namalwa cells, while Oct-1 overexpression exerted an opposite effect. Thus, Oct-1 acts via negative feedback to autoregulate the U promoter through low-affinity Oct-1 binding sites and positive feedback to autoregulate the L promoter through high-affinity canonical (oct) sites when increasing in concentration in a natural context.

Differentiation of IMR32 Neuroblastoma Is Accompanied by a Global Change in the Transcriptome.

Neuroblastoma is one of the most common cancers in infants and is often multidrug-resistant. One of the methods of treating neuroblastomas is to create conditions for their differentiation. In this work, we performed a full-transcriptome analysis of gene expression in an undifferentiated and differentiated in vitro human neuroblastoma cell line IMR-32 and identified the signaling pathways and biological processes that undergo the greatest changes during differentiation. The results obtained show that a complex heterogeneous population of nerve cells is formed at different stages of differentiation. In the cell population of differentiating neuroblastoma, the expression of genes in which cortical neuronal progenitor cells are enriched increases; at the same time, there are cells expressing markers of early postmitotic neurons. Cells differentiate in several different directions according to the type of synaptic mediator. At the same time, the differentiation of IMR-32 cells is accompanied by an increase in the transcription of genes that suppress the differentiation of nerve cells, Sox2 and PROM1, the expression of which is normally suppressed during in vivo differentiation.

GSK3 Kinase Inhibitor, CHIR, Suppress Transcription of Tissue Specific POU2F1 Isoform in Burkitt Namalwa Lymphoma Cells.

POU2F1 (Oct-1) is a transcription factor, the overexpression of which is found in many human malignant tumors; a significant increase in its level in cells determines the malignant potential of the tumor. POU2F1 is represented in cells by several isoforms that are transcribed from alternative promoters. In Burkitt's B-cell lymphoma Namalwa, the concentration of tissue-specific isoform Oct-1L is several times higher than in normal B cells. We tested the potential to inhibit the transcription of individual Oct-1 isoforms using the GSK3 kinase inhibitor CHIR, an aminopyrimidine derivative. We have shown that CHIR specifically affects the expression of the tissue-specific isoform Oct-1L, significantly reducing the level of mRNA and Oct-1L protein. However, CHIR does not change the amount of mRNA and protein of the ubiquitous isoform Oct-1A in Namalwa tumor cells. The results obtained show that it is possible to develop a system for selective inhibition of Oct-1 transcription factor isoforms in human cells to suppress drug resistance of tumor cells with a high POU2F1 content.

Thapsigargin, Inhibitor of Sarco-Endoplasmic Ca2+-ATPase, Effectively Suppresses the Expression of S100A4 Protein in Human Breast Cancer Cell Line.

Thapsigargin (SERCA ATPase inhibitor) inhibited the S100A4 metastatic marker expression in MDA-MB231 breast cancer cells. We found that S100A4 gene transcription is regulated by Ca2+ signaling pathways. We found that the synthesis of S100A4 mRNA and S100A4 protein in MDA-MB231 cells was effectively suppressed by thapsigargin at a concentration of 0.4-4 µM with retaining cell viability. We assume that the change in the gene transcription in response to disturbance of Ca2+ homeostasis is directly involved in the remodeling of Ca2+ signaling pathways.

The Expression Level of S100A4 Protein Affects the Migration Activity of Breast Cancer Cells.

Reduced expression of metastatic marker protein S100A4 in triple-negative breast cancer cells MDA-MB-231 leads to a decrease in the migration ability of cells and increases the sensitivity of the modified cells to docetaxel therapy. Cells capable of migration differ from the immotile cells in the content of the S100A4 protein in the cell, and this difference persists after the treatment of cells with the agents that reduce the intracellular level of S100A4. The presence of exogenous S100A4 protein in culture medium reduces the content of this protein in breast cancer cells. The results of the study show that the ability of breast cancer cells to migrate depends on the S100A4 protein concentration in the cell.

Studying of the Mechanisms of Combined Effect of Dexamethasone, Doxorubicin, and Docetaxel on Breast Cancer Cells.

The sensitivity of MDA-MB231 breast cancer cells to the effects of pharmacological agents was evaluated by their motility and viability. Dexamethasone, doxorubicin, or docetaxel administered separately in their effective concentration suppressed cell motility (in 16 h) and caused cell death (in 48 h). The strength of the effects increased in the following order: dexa methasone

Increased level of Oct-1 protein in tumor cells modulates cellular response to anticancer drugs.

The effect of overexpression of Oct-1 protein isoforms on the cell response to two anticancer drugs camptothecin and dexamethasone was studied. The effect of Oct-1 isoforms on regulated gene transcription was estimated by the difference in the level of mRNA in Burkitt's lymphoma cells (Namalwa line) untransfected and stably transfected with Oct-1 isoforms. The response to anticancer drugs of the Oct-1 target genes involved in the development of apoptosis depended, firstly, on the type of drug, secondly, on the concentration of Oct-1 in cells. and, thirdly, on the Oct-1 isoform with which these cells were transfected.

Involvement of transcription factor Oct-1 in the regulation of JAK-STAT signaling pathway in cells of Burkitt lymphoma.

We studied the role of transcription factor Oct-1 in the regulation of expression of genes of the JAK-STAT signaling pathway in the Namalwa Burkitt's lymphoma cell line. Overexpression of Oct-1 isoforms (Oct-1A, Oct-1L, and Oct-1X) causes a decrease in the activity of four genes involved in the JAK-STAT signaling pathway-IFNAR2, STAT1, STAT2, and STAT4. As a result of our research, it was found that genes STAT2 and STAT4 are direct targets for Oct-1 protein.

Transcription factor Oct-1 stimulates the release of Mts1/S100A4 protein by the cancer cells.

The effect of the transcription factor Oct-1 (POU2F1) on the expression of the tumor cell marker metastasin (Mts1/S100A4) was studied. Comparative analysis of various tumor lines showed no clear correlation between the expression level of Mts1/S100A4 and the content of Oct-1. However, at stable transfection of tumor cells with Oct-1A, Oct-1L, and Oct-1X isoforms we detected an elevated level of Oct-1, which stimulated Mts1/S100A4 secretion. These findings extend our understanding of the molecular mechanisms of the tumorigenic effect of Oct-1.

The level of the Phf10 protein, a PBAF chromatin-remodeling complex subunit, correlates with the Mts1/S100A4 expression in human cancer cell lines.

Mts1 (S100A4) protein is a marker of metastatic tumor cells, which is associated with a poor diagnostic prognosis for cancer progression. Therefore, it is important to study the S100A4 gene expression. According to our preliminary data, PHF10, a PBAF remodeling complex component, can play an important role in the transcription regulation of the S100A4 gene. We studied the expression of S100A4 and the total PHF10 protein in some cell lines. We have found that, in the cell lines studied, the PHF10 expression is correlated with the S100A4 expression.

New alternative promoter in regulation of the Oct-1 human gene transcription.

For the first time, the presence of a new alternative promoter in the gene of the oct-1 transcription factor from which a previously unknown mRNA isoform Oct-1X, with 5'-terminus different from the previously described isoforms, was demonstrated. The nucleotide sequence of the Oct-1X cDNA was determined and the presence of a long open reading frame which starts with the first ATG codon of the second exon was demonstrated. A protein shortened on its N-terminus is assumed to be the product of a new mRNA isoform. Expression of the new isoform was studied in various human cell lines; the results indicate the ubiquitous nature of the Oct-1X expression. Therefore, in the work, the third alternative promoter of human oct-1 gene (earlier, a ubiquitous promoter U and an inducible tissue-specific promoter L were described) contributing to the fine regulation of mRNA isoform synthesis and formation of structural and functional diversity of Oct-1 protein isoforms in cells was revealed.

[The new isoform of Oct-1 transcription factor is transcribed from alternative promoter].

The Oct-1 transcription factor belongs to the family of highly conserved POU-domain proteins that participate in regulation of housekeeping and tissue-specific gene expression. Several isoforms of Oct-1 were described previously. We have found the new alternative promoter of Oct-1 gene and the corresponding mRNA Oct-1X. This mRNA encodes the alternative Oct-1 isoform that has truncated N-terminus comparing to isoforms Oct-1A and Oct-1L. We explored the abundance of this isoform in human tissues and cell lines and demonstrated that it is ubiquitously expressed but its expression strongly varies in different tissues. By co-transfection and double luciferase assay we have demonstrated that Oct-1X is the activator of housekeeping (histone H2B) and tissue-specific genes (B29) transcription.