Vol 53, No 2 (2019)

At present, pharmacologically significant proteins are synthesized in different expression systems, from bacterial to mammalian and insect cell cultures. The plant expression systems (especially suspension cell culture) combine the simplicity and low cost of bacterial systems with the ability to perform eukaryotic-type posttranslational protein modifications. A low (compared with bacterial systems) yield of the target recombinant protein is one of the shortcomings of the plant expression systems. In this review, methods, developed over the past two decades, to increase the level of recombinant gene expression and methods to prevent silencing, caused by a random insertion of the target gene into heterochromatin region, are considered. The emergence of CRISPR/Cas technologies led to the creation of a new approach to increase the gene expression level, directional insertion of “pharmaceutical” protein genes in specific, knowingly transcriptionally active genome regions. The plant cell housekeeping gene loci, actively expressed throughout the interphase, are these regions. The organization of some housekeeping genes, most promising for transferring recombinant protein genes in their loci, is considered in detail.

Bacterial chromosomes are widely thought of as circular DNA molecules. However, linear bacterial chromosomes, as well as linear mitochondrial and plastid chromosomes, are fairly common. The most frequent causes of linearization are reparation system defects, incorporation of plasmids in the genome, and recombination compromising the circular topology of chromosomes. Genomes of some bacterial species had undergone frequent linearization–circularization events, which resulted in an increased variability of gene content at linear chromosome ends. Similarly to eukaryotes, bacteria that have linear genomes face the problem of end replication, which different species solve in a variety of ways. A theoretically important issue is the adaptive value of chromosome linearization. This review discusses theories concerning the evolution of linear genomes and supporting experiments. The most common mechanisms of linear bacterial genomes replication and possible ways of their emergence are also considered.

Many human genes that control human embryonic development and differentiation of human cells form chromosomal contact with rRNA gene clusters, which are involved in the epigenetic regulation of many genes. The sites of rRNA gene contact often fall on extended (up to 50 kb) regions containing a chromatin mark, H3K27ac histone, typical for superenhancers, as well as on pericentromeric and subtelomeric regions of chromosomes. We found that the DUX4 genes located in the subtelomeric region of human chromosome 4 are surrounded by regions that are often in contact with the rRNA genes. The 25 kb region of this chromosome, presented in version hg19 of the sequenced human genome, contains several copies of the DUX4 gene. The sites of rRNA gene contacts located around this region contain methylation sites as well as CTCF binding sites. It is assumed that the rRNA gene contacts are important in silencing these DUX4 gene copies.

Multiple sclerosis is a chronic disease of the central nervous system, combining in its pathogenesis both autoimmune and neurodegenerative components, and is characterized by a highly heterogeneous clinical phenotype. Genetic susceptibility to the development of the most common relapsing-remitting course of the disease is extensively studied, while the genetic architecture of the aggressive primary progressive course of multiple sclerosis remains poorly understood. We analyzed the association of polymorphic variants in miRNA genes MIR146A, MIR196A2, and MIR499A with the risk of primary progressive multiple sclerosis one by one and in biallelic combinations with variants of immune-related genes; the analysis was performed in comparison with healthy individuals and with relapsing-remitting multiple sclerosis patients. The allele MIR196A2*C was useful in discriminating between two main courses of multiple sclerosis, one by one and in combination with alleles of the IFNAR2, IL7RA, IL6, PVT1, CD86, CCL5, and PSMB9 genes. The data presented in the current work may be used for the construction of a biomarker panel, to differentiate primary progressive and relapsing-remitting courses of multiple sclerosis on the initial stages of the disease.

The type 2 interleukin-1 receptor (IL-1R2) is one of natural IL-1β singling inhibitors in mammals. We cloned and sequenced the IL-1R2 gene in V. variegatus (VvIL-1R2). The phylogenetic analysis showed that the molecular structure VvIL-1R2 is similar to that of its orthologues in other vertebrates. The expression levels of VvIL-1R2 are relatively high in the peripheral blood leukocytes (PBLs), gill, and spleen. In addition, peculiar expression patterns for his molecule were detected at various developmental stages, implying that in flatfishes the IL-1R2 may have be important for embryonic development and metamorphosis. In PBLs, the treatment with pathogen-associated molecular patterns (PAMPs) induced a significant and rapid up-regulation of VvIL-1R2, pointing at its involvement in the immune responses against bacterial and viral pathogens.

The CRISPR/Cas9 nuclease system can effectively suppress the replication of the hepatitis B virus (HBV), while covalently closed circular DNA (cccDNA), a highly resistant form of the virus, persists in the nuclei of infected cells. The most common outcome of DNA double-strand breaks (DSBs) in cccDNA caused by CRISPR/Cas9 is double-strand break repair by nonhomologous end-joining, which results in insertion/deletion mutations. Modulation of the DNA double-strand break repair pathways by small molecules was shown to stimulate CRISPR/Cas9 activity and may potentially be utilized to enhance the elimination of HBV cccDNA. In this work, we used inhibitors of homologous (RI-1) and nonhomologous (NU7026) end-joining and their combination to stimulate antiviral activity of CRISPR/Cas9 on two cell models of HBV in vitro, i.e., the HepG2-1.1merHBV cells containing the HBV genome under the tet-on regulated cytomegalovirus promoter and the HepG2-1.5merHBV cells containing constitutive expression of HBV RNA under the wild-type promoter. The treatment of the cells with RI-1 or NU7026 after lentiviral transduction of CRISPR/Cas9 drops the levels of cccDNA compared to the DMSO-treated control. RI-1 and NU7026 resulted in 5.0–6.5 times more significant reduction in the HBV cccDNA level compared to the mock-control. In conclusion, the inhibition of both homologous and nonhomologous DNA double-strand break repair pathways increases the elimination of HBV cccDNA by CRISPR/Cas9 system in vitro, which may potentially be utilized as a therapeutic approach to treat chronic hepatitis B.

Cortexin is a clinically approved cerebral cortex polypeptide complex in calves. The mechanism of cortexin action is not understood well. Two cortexin derivatives, short peptides EDR and DS with neuroprotective activity, were synthesized. According to the data of molecular modeling, these peptides are able to bind to the histone H1.3 protein. This can affect the conformation of histone H1.3, which leads to a change in the chromatin structure in the loci of some genes, in particular Fkbp1b encoding the FK506-binding protein. Electrophysiological processes associated with the Ca²⁺ exchange are disturbed in the pyramidal neurons of the hippocampus during aging of the brain. The Fkbp1b gene encodes peptidyl-prolyl cis-trans isomerase, regulating the release of calcium ions from the sarcoplasmic and endoplasmic reticulum of neurons. The activation of the Fkbp1b gene transcription under treatment with short peptides can promote the synthesis of its protein product and the activation of the Ca²⁺ release from organelles of the sarcoplasmic and endoplasmic reticulum of neurons, which, in turn, can lead to an increase in the functional activity of neurons.