Expression of CASC8 RNA in Human Pancreatic Cancer Cell Lines.

A lot of long non-coding RNAs (lncRNAs) are expressed in human cells in a number of transcripts of different lengths and composition of exons. In case of cancer-associated lncRNAs, an actual task is to determine their specific isoforms, since each transcript can perform its own function in carcinogenesis and might have a unique expression profile in various types of tumors. For the first time, we analyzed the expression of CASC8 lncRNA in human pancreatic ductal adenocarcinoma cell lines and found an abundant isoform that was previously considered as the minor one in this type of cancer. We also revealed extremely high expression levels of all CASC8 transcripts in MIA PaCa-2 cells and, conversely, the lack of this lncRNA in PANC-1. This allows to use them as convenient models for further in vitro studies.

Comparative Analysis of Long Noncoding RNA Expression in Human Hepatocyte Cell Lines and Liver.

Long noncoding RNAs (lncRNAs) are promising biomarkers and potential targets for liver cancer therapy. Stable hepatocyte lines are used in vitro to investigate functions of lncRNAs which amount in cell fluctuates during carcinogenesis. For the first time we compared gene expression of known lncRNAs in human conditional normal liver cells HepaRG and cancer cell lines Huh7 and HepG2. We showed that relative amounts of these lncRNAs in HepaRG are close to analogous variables measured for liver samples from healthy donors. Obtained data demonstrate exclusive peculiarities of HepaRG and confirm its reasonable application as a model of normal human hepatocytes for studying functions of lncRNAs.

Non-Coding RNAs As Transcriptional Regulators In Eukaryotes.

Non-coding RNAs up to 1,000 nucleotides in length are widespread in eukaryotes and fulfil various regulatory functions, in particular during chromatin remodeling and cell proliferation. These RNAs are not translated into proteins: thus, they are non-coding RNAs (ncRNAs). The present review describes the eukaryotic ncRNAs involved in transcription regulation, first and foremost, targeting RNA polymerase II (RNAP II) and/or its major proteinaceous transcription factors. The current state of knowledge concerning the regulatory functions of SRA and TAR RNA, 7SK and U1 snRNA, GAS5 and DHFR RNA is summarized herein. Special attention is given to murine B1 and B2 RNAs and human Alu RNA, due to their ability to bind the active site of RNAP II. Discovery of bacterial analogs of the eukaryotic small ncRNAs involved in transcription regulation, such as 6S RNAs, suggests that they possess a common evolutionary origin.

Small Noncoding 6S RNAs of Bacteria.

Small noncoding RNAs (ncRNAs) are non-translated transcripts with lengths below 300 nucleotide residues. Regulation of cellular processes under the influence of these ncRNAs is the most various in eukaryotic cells, but numerous ncRNAs are also found in bacteria. One of the best-known small prokaryotic ncRNAs is 6S RNA - it has been detected in all branches of bacteria. Due to their conserved secondary structure including a large central "loop" flanked by long double-helical arms, 6S RNAs can bind holoenzymes of RNA polymerase (RNAP) and inhibit their activity. This inhibits transcription of many genes. According to data of comparative transcriptome analysis, the 6S RNA-dependent regulation of transcription affects the expression level of hundreds of genes involved in various cellular processes. 6S RNA has the unique feature of serving as a transcription template for the synthesis of short product RNAs (pRNAs) complementary to the central part of the molecule. The length and abundance of pRNAs vary depending on the physiological status of the cell. The synthesis of pRNAs is of great importance because it releases RNAP and provides reversibility of the inhibition. A similar mechanism has been described for the noncoding mouse B2 RNA that inhibits the activity of RNAP II. This finding can be taken as evidence for the common evolutionary origin of the ncRNA-dependent regulation of RNAP and its immense significance for cells. This review summarizes the state of knowledge about the main features and functions of 6S RNAs from various bacterial species with a special focus on the peculiarities of pRNA synthesis. The majority of functional insights on 6S RNAs have been gained for E. coli 6S RNA as the best-studied model system.