Biogênese, estabilidade e localização sub-celular de RNAs não-codificadores longos expressos em regiões intrônicas do genoma humano / Biogenesis, stability and sub-cellular localization of long non-coding RNAs expressed in intronic regions of the human genome

Trabalhos recentes indicam que a maior parte do transcriptoma de células de mamíferos é composto por RNAs não-codificadores de proteínas (ncRNAs). Nosso grupo tem identificado e caracterizado ncRNAs longos (>200 nt), sem splicing, expressos em regiões intrônicas de genes codificadores de proteína. Contudo, a biogênese, processamento e localização sub-celular desta classe de RNAs permanecem desconhecidos. Este trabalho teve como objetivos i) investigar a contribuição da RNA Polimerase II (RNAP II) na transcrição de ncRNAs intrônicos, ii) avaliar a meia-vida destes ncRNAs em relação a mRNAs, e iii) verificar a distribuição sub-celular de ncRNAs intrônicos. Os resultados obtidos indicaram que ncRNAs intrônicos são predominantemente transcritos pela RNAP II a partir de regiões promotoras funcionalmente semelhantes as que controlam a transcrição de mRNAs. Ensaios de estabilidade revelaram que, em média, ncRNAs intrônicos possuem meia-vida igual ou maior (3,4h a 4,2h) do que mRNAs (3,1h). A maior parte dos ncRNAs intrônicos possui estrutura cap 5', sugerindo que sejam estabilizados para desempenhar papéis na biologia da célula que não dependam de um rápido turnover. A maior parte dos ncRNAs intrônicos é exportada para o citoplasma, indicando que devam exercer alguma função biológica neste compartimento. Em conjunto, este trabalho fornece informações novas a respeito da biogênese, estabilidade e localização sub-celular ncRNAs intrônicos expressos em células humanas, contribuindo para avançar o conhecimento sobre esta classe de transcritos celulares.

Recent studies have shown that most of the mammalian transcriptome is comprised of non-coding RNAs (lncRNAs). Our group has identified and characterized long (>200 nt), unspliced lncRNAs expressed in intronic regions of protein coding genes. However, the biogenesis, processing, stability and subcellular localization of members from this RNA class remain unknown. The aims of this work were i) to investigate the contribution of RNA Polymerase II (RNAP II) to the transcription of intronic, ii) to evaluate the half-life of these ncRNAs relative to mRNAs, and iii) determine their subcellular distribution. Our results indicate that intronic ncRNAs are predominantly transcribed by RNAP II from promoter regions functionally similar to those that control the transcription of mRNAs. Stability assays revealed that intronic ncRNAs have an average half-life equal or greater (3.4h to 4.2h) than mRNAs (3.1h). The majority of intronic ncRNAs have 5' cap modification suggesting that these transcripts are stabilized, possibly to exert roles in the biology of the cell that does not depend on a rapid turnover. Although intronic ncRNAs do not encode proteins, most of these transcripts are transported to the cytoplasm which indicates that they may perform some biological function in this compartment. Altogether, this study reveals with novel information regarding the biogenesis, stability and subcellular localization of intronic ncRNAs expressed in human cells, thus contributing to advance the knowledge on this class of cellular transcripts.

Immunohistochemical localization of galectin-3 in the granulomatous lesions of paratuberculosis-infected bovine intestine

The presence of galectin-3 was immunohistochemically quantified in bovine intestines infected with paratuberculosis (Johne's disease) to determine whether galectin-3 was involved in the formation of granulation tissue associated with the disease. Mycobacterium avium subsp. paratuberculosis infection was histochemically confirmed using Ziehl-Neelsen staining and molecularly diagnosed through rpoB DNA sequencing. Galectin-3 was detected in the majority of inflammatory cells, possibly macrophages, in the granulomatous lesions within affected tissues, including the ileum. These findings suggest that galectin-3 is associated with the formation of chronic granulation tissues in bovine paratuberculosis, probably through cell adhesion and anti-apoptosis mechanisms.

Molecular characterization of mutation associated with rifampicin and isoniazid resistance in Mycobacterium tuberculosis isolates.

Nucleotide changes in catalase peroxidase (Kat G) gene and gene encoding the beta subunit of RNA polymerase (rpo B), responsible for isoniazid and rifampicin drug resistance were determined in the clinical isolates of Mycobacterium tuberculosis by PCR-RFLP, Line probe assay and DNA sequencing. PCR-RFLP test was performed by HapII cleavage of an amplified fragment of Kat G gene to detect the transversion 315AGC-->ACC(Ser-->Thr) which is associated with INH drug resistance. The Line probe assay kit was evaluated to detect the mutation in 81bp RMP resistance determining region of rpo B gene associated with RMP drug resistance. These results were validated by DNA sequencing and drug susceptibility test. Kat G S 315 T mutation was found in 74.19% strains of M. tuberculosis from Delhi. This mutation was not found in any of the susceptible strains tested. The line probe assay kit and DNA sequencing identified 18 isolates as RMP resistant with specific mutation, while one of the RMP resistant strain was identified as RMP susceptible, with a concordance of 94.73% with the phenotypic drug susceptibility result. Majority (8 of 19, 42.1%) of resistant isolates involved base changes at codon 531 of rpo B gene. Both PCR-RFLP and Line probe assay test can be used in many of the clinical microbiology laboratories for early detection of isoniazid and rifampicin drug resistance in clinical isolates of M. tuberculosis.

Paracoccidioides brasiliensis RNA biogenesis apparatus revealed by functional genome analysis

The RNA biogenesis machinery of Paracoccidioides brasiliensis was assessed by comparative analyses of PbAESTs (P. brasiliensis assembled expressed sequence tags (ESTs)) with sequences from Saccharomyces cerevisiae MIPS database. PbAESTs related to almost all categories of S. cerevisiae RNA biogenesis were found. Two of the 12 S. cerevisiae RNA Pol II core subunits, Rpb3 and Rpb7, were found, probably reflecting the growth phase from which the cDNA libraries used in ESTs generation were constructed, as well as the low abundance of some of these transcripts. We have also found orthologs to TATA-box-binding protein (TBP), and at least one subunit of each TBP-associated factors (TFII) in P. brasiliensis transcriptome, except TFIIB. Genes associated to the chromatin remodeling complex, as well as transcription factors probably involved in the control of genes associated to a sexual cycle and virulence, were also identified. With respect to the pre-mRNA processing, 65 PbAEST orthologs to S. cerevisiae basal splicing machinery and 21 orthologs of 5'- and 3'-end formation processes were found. Components involved in RNA interference were detected, suggesting that this gene expression regulation mechanism is probably used by P. brasiliensis. Twelve PbAESTs related to Pol I and Pol III machineries were assigned as S. cerevisiae orthologs. Finally, 25 and 10 PbAESTs associated to rRNA and tRNA processing, respectively, were detected. Taken together, our results enable us to depict, for the first time, a global view of transcription and RNA processing in P. brasiliensis.

RNA polymerase II dependent genes that do not code for protein.

In recent years more and more examples of RNA polymerase II dependent non-coding transcripts have been described. Although these have frequently been ignored as "selfish DNA elements", it is becoming increasingly clear that many, if not all, of them have very important biological roles. Examples of such "genes" from Drosophila, mammals, other vertebrates, yeast etc. are considered. Although the specific mechanisms through which these non-coding transcripts function in the cell are not clear, comparisons reveal certain common themes, particularly the importance of secondary structures, rather than the primary base sequence of these transcripts. While some of these transcripts may function as ribozymes or as anti-sense regulators, most others may function more directly through their specific protein-binding properties. Since RNA is believed to be the first "living" molecule, it is very likely that some genes even today function only through this class of molecules. It is expected that instead of being ignored as examples of "selfish DNA", a more positive search for their functions will help unravel the significance of this novel class of genes.

Analysis of RNA polymerase gene mutation in three isolates of rifampicin resistant Mycobacterium tuberculosis.

Drug resistance in tuberculosis (TB) has become a major public health threat, particularly when the disease cannot be 100% controlled by BCG vaccination. In Thailand, resistance to rifampicin, a major component of multidrug regimens of treatment, is the common cause of tuberculosis recurrence. The mechanism of rifampicin resistance involves alterations of the RNA polymerase subunit beta (rpo B) gene. Mutations in rpo B gene were often found to cluster within a region of 23 amino acids starting from amino acid residue 511 to residue 533. Direct PCR sequencing was utilized to compare base changes in rpo B gene in three rifampicin resistant phenotypes of M. tuberculosis isolated from Thai patients. The sequences showed one base substitution at codon 531 resulting in an amino acid change from serine (TCG) to leucine (TTG) in a multidrug resistant isolate compared to that of a sensitive isolate, whereas a point mutation at codon 516 causing a change from aspartic acid (GAC) to tyrosine (TAC) was detected in a multidrug resistant isolate from a HIV positive patient. In an isolate resistant only to rifampicin a double mutation at codon 531 changing serine (TCG) to phenylalanine (TTT) was found. No mutations were observed in the same region in streptomycin, ethambutol or isoniazid resistant isolates. This finding reports two new types of mutation (GAC to TAC at codon 516 and TCG to TTT at codon 531) and confirms a direct correlation between rpo B gene alteration and rifampicin resistant phenotype in M. tuberculosis.