[Selection of microRNA for providing tumor specificity of transgene expression in cancer gene therapy].

The use of tumor-specific microRNA loss to inhibit transgene expression in normal cells is considered as a way to increase the specificity of gene-therapeutic antitumor drugs. This method assumes the introduction of recognition sites of suppressed in tumor cells microRNAs into transgene transcipt. In the presented work, the efficiency of the strategy for providing the tumor specificity of transgene expression depending on parameters of microRNA expression in normal and tumor cells was studied. It was established that microRNA suppression in tumor cells and the determination of absolute microRNA levels in tumor and normal cells are not sufficient for the adequate estimation of the possibility of specific microRNA usage in the scheme of cancer gene therapy, and particularly do not allow to exclude a significant decrease in the efficiency of the gene-therapeutic drug upon the introduction of microRNA recognition sites. These parameters are only suitable for the preliminary selection of microRNA. The effect of introduction of microRNA recognition sites on transgene expression level in target tumor cells should be validated experimentally. It is suggested that this should be done directly in the cancer gene therapy scheme with monitoring of the therapeutic transgene activity.

mTOR-dependent transcriptional repression of Pdcd4 tumor suppressor in lung cancer cells.

Programmed cell death 4 (Pdcd4) tumor suppressor is frequently lost in tumors of various origins including lung cancer, and its loss contributes to tumor progression. However molecular mechanisms underlying Pdcd4 suppression in lung cancer cells remain largely unexplored. Here we investigated molecular mechanisms of Pdcd4 suppression in lung cancer cells. Besides enhanced mTOR-dependent proteasomal degradation of Pdcd4 protein, we found that Pdcd4 transcription is negatively regulated by mTOR signaling, and localized cis-acting element in Pdcd4 promoter responsible for this effect. In conclusion, we described a novel molecular mechanism of Pdcd4 suppression in cancer cells consisting from mTOR signaling-dependent transcriptional repression of Pdcd4.

Nanoantibodies for detection and blocking of bioactivity of human vascular endothelial growth factor A(165).

Nanoantibodies (single-domain antibodies, nanobodies) derived from noncanonical single-chain immunoglobulins provide an attractive tool for in vitro and in vivo diagnostics as well as for development of targeted drugs for clinical use. Nanoantibodies against several clinically important targets have been developed and are actively investigated. However, no development of nanoantibodies against vascular endothelial growth factor VEGF-A(165) has been reported. We describe here the generation of nanoantibodies derived from single-chain Bactrian camel immunoglobulins directed against VEGF-A(165). We demonstrate that these nanoantibodies are suitable for enzyme-linked immunoassay to quantify human VEGF-A(165) as well as for blocking its activity. Our results provide a basis for diagnostic kit development for quantification of VEGF-A(165), which emerges as a biomarker useful in various pathological conditions. In addition, the nanoantibodies might be used for development of therapeutic molecules targeting VEGF-A(165)-dependent pathological neoangiogenesis.

Interaction between MAK-V protein kinase and synaptopodin.

MAK-V protein kinase (also known as HUNK) was discovered more than decade ago but its functions and molecular mechanisms of action still remain mostly unknown. In an attempt to associate MAK-V with particular chains of molecular events, we searched for proteins interacting with the C-terminal domain of MAK-V protein kinase. We identified synaptopodin as a protein interaction partner for MAK-V and confirmed this interaction in various ways. Because synaptopodin is important for dendritic spine formation and plays a role in synaptic plasticity, our results might have significant impact on future studies for understanding the role of MAK-V in cells of the nervous system.

[Pdcd4 tumor suppressor: properties, functions, and their application to oncology].

Inactivation of tumor suppressors and activation of protooncogenes are critical events in malignant cell transformation and tumor progression. Pdcd4 encodes a protein with tumor suppressor functions, which accounts for an increased interest to Pdcd4 as a potential diagnostic and prognostic marker, as well as a target for antineoplastic therapy. This review summarizes well-known properties and functions of Pdcd4 tumor suppressor and mechanisms of its regulation in tumor cells. It is also focused to the role of Pdcd4 in cellular transformation and tumor progression, as well as on its potential practical application in oncology.

[The role of DNA methylation and histone modifications in structural maintainance of heterochromatin domains (chromocenters)].

The effects of DNA methylation inhibitor 5-azacytidine (5-aza-C) and histone acetylation inhibitor trichostatine A (TSA) on the structure of pericentric heterochromatin in cultured mouse cells (L929) has been studied. After 48 h of 5-aza-C treatment, about 85% of the cells demonstrate transformation of chromocenters from ovoid to elongated structures. Hypotonic treatment of these cells reveals tandemly arranged DAPI-positive globules, well distinguishable by light microscopy. The same globular units can be revealed in hypotonic-treated control cells. 48 h of TSA treatment causes dramatic decrease in HP 1alpha content in the cells. Chromocenters in 25% of treated cells became highly decondenced and can not be reliably detected by light and electron microscopy. 85% of cells demonstrate globular chromocenters with low HP 1alpha content. Hypotonic treatment causes transformation of compact chromocenters into ring-like structures, which can be either single or clustered. Rings are formed by uniform fiber, in which no globular subunits are detected. The data obtained are discussed concerning several mechanisms of heterochromatin structure maintenance and the roles of epigenetic marks in them.

A Novel Hybrid Promoter ARE-hTERT for Cancer Gene Therapy.

describe a novel hybrid tumor-specific promoter, ARE-hTERT, composed of the human TERT gene promoter (hTERT) and the antioxidant response element (ARE) from the human GCLM gene promoter. The hybrid promoter retains the tumor specificity of the basal hTERT promoter but is characterized by an enhanced transcriptional activity in cancer cells with abnormal activation of the Nrf2 transcription factor and upon induction of oxidative stress. In the in vitro enzyme-prodrug cancer gene therapy scheme, ARE-hTERT promoter-driven expression of CD : UPRT (yeast cytosine deaminase : uracil phosphoribosyltransferase) chimeric protein induced a more pronounced death of cancer cells either upon treatment with 5-fluorouracil (5FC) alone or when 5FC was combined with chemotherapeutic drugs as compared to the hTERT promoter. The developed hybrid promoter can be considered a better alternative to the hTERT promoter in cancer gene therapy schemes.