Translation of the genetic code requires attachment of tRNAs to their cognate amino acids. Errors during amino‐acid activation and tRNA esterification are corrected by aminoacyl‐tRNA ...synthetase‐catalyzed editing reactions, as extensively described for aliphatic amino acids. The contribution of editing to aromatic amino‐acid discrimination is less well understood. We show that phenylalanyl‐tRNA synthetase misactivates tyrosine and that it subsequently corrects such errors through hydrolysis of tyrosyl‐adenylate and Tyr‐tRNAPhe. Structural modeling combined with an in vivo genetic screen identified the editing site in the B3/B4 domain of the β subunit, 40 Å from the active site in the α subunit. Replacements of residues within the editing site had no effect on Phe‐tRNAPhe synthesis, but abolished hydrolysis of Tyr‐tRNAPhein vitro. Expression of the corresponding mutants in Escherichia coli significantly slowed growth, and changed the activity of a recoded β‐galactosidase variant by misincorporating tyrosine in place of phenylalanine. This loss in aromatic amino‐acid discrimination in vivo revealed that editing by phenylalanyl‐tRNA synthetase is essential for faithful translation of the genetic code.
In recent years, Bacillus subtilis, the model organism for gram-positive bacteria, has been a focal point for study of posttranscriptional regulation. In this bacterium, more than 70 regulatory RNAs ...have been discovered that respond to intracellular proteins, tRNAs, and small-molecule metabolites. In total, these RNA elements are responsible for genetic control of more than 4.1% of the genome-coding capacity. This pool of RNA-based regulatory elements is now large enough that it has become a worthwhile endeavor to examine their general features and to extrapolate these simple observations to the remaining genome in an effort to predict how many more may remain unidentified. Furthermore, both metabolite- and tRNA-sensing regulatory RNAs are remarkably widespread throughout eubacteria, and it is therefore becoming increasingly clear that some of the observations for B. subtilis gene regulation will be generally applicable to many different species.
Recent studies have shown that microRNAs (miRNAs) play roles in tumorigenesis and are reliable classifiers of certain cancer types and subtypes. However, the role of miRNAs in the pathogenesis and ...diagnosis of small cell carcinoma (SCLC), the majority of which represent the most aggressive lung tumors, has not been investigated.
In order to explore miRNA involvement in the pathogenesis of small cell lung carcinoma (SCLC) and the potential role of miRNAs in SCLC diagnosis, we compared the miRNA expression profile of a set of SCLC cell lines to that of a set of non-small cell lung cancer (NSCLC) cell lines and normal immortalized human bronchial epithelial cells (HBECs) using microarray analysis.
Our results show that miRNA profiles reliably distinguish SCLC cell lines from NSCLC and HBEC cell lines. Further analysis of the miRNA expression profile of the two subtypes of lung cancer cell lines indicates that the expression levels of the majority of the miRNAs that are differentially expressed in SCLC cells relative to NSCLC cells and HBECs show a progressive trend from HBECs to NSCLC cells to SCLC cells.
The distinctive miRNA expression signature of SCLCs relative to NSCLCs and HBECs suggests that miRNA profiles have the potential to serve as a diagnostic marker of SCLC lung tumors. The progressive trend of miRNA profile changes from HBECs to NSCLCs to SCLCs suggests a possible pathological relationship between SCLCs and NSCLCs, and suggests that the increasing dysregulation of miRNA expression may play a role in lung tumor progression. The specific role of these miRNAs in lung tumor pathogenesis and differentiation need to be investigated further in future studies.
Translation of the genetic code requires attachment of tRNAs to their cognate amino acids. Errors during amino-acid activation and tRNA esterification are corrected by aminoacyl-tRNA ...synthetase-catalyzed editing reactions, as extensively described for aliphatic amino acids. The contribution of editing to aromatic amino-acid discrimination is less well understood. We show that phenylalanyl-tRNA synthetase misactivates tyrosine and that it subsequently corrects such errors through hydrolysis of tyrosyl-adenylate and Tyr-tRNA(Phe). Structural modeling combined with an in vivo genetic screen identified the editing site in the B3/B4 domain of the beta subunit, 40 angstroms from the active site in the alpha subunit. Replacements of residues within the editing site had no effect on Phe-tRNA(Phe) synthesis, but abolished hydrolysis of Tyr-tRNA(Phe) in vitro. Expression of the corresponding mutants in Escherichia coli significantly slowed growth, and changed the activity of a recoded beta-galactosidase variant by misincorporating tyrosine in place of phenylalanine. This loss in aromatic amino-acid discrimination in vivo revealed that editing by phenylalanyl-tRNA synthetase is essential for faithful translation of the genetic code.
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