Transcription Needs Translation Initiation of the Downstream Gene to Continue Downstream at Intercistronic Junctions in E. Coli.

We have reported a gal mutant called galE stop0, wherein the galE stop codon was changed to a sense codon. The experiment results demonstrated that preventing galE translation termination inhibited the production of galE 3' ends. This implies that when the galE translation termination was prevented, the galE 3' ends generation was reduced or impaired. We anticipated that the translation of galE would continue to galT, producing a chimeric protein GalE-GalT. This study verified that the chimeric protein was produced, but unexpectedly, we found that the GalT protein was also synthesized in the mutant, and its amount equaled that in the wild-type. In the wild-type, we also found that the GalE-GalT chimeric protein was produced in an amount equal to that of the GalE protein. These results suggest that translation termination of galE and translation initiation of galT occur independently, thus, corroborating our transcription-translation model: At the cistron junction, transcription, decoupled from translation due to the translation termination of galE, needs translation initiation of galT to continue downstream; otherwise, transcription would be terminated by Rho. RNase E-mediated transcript cleavage also produces the 3' ends of pre-galE mRNA. These findings indicated that RNase E produces the 3' end of mRNA and establishes gene expression polarity.

Application of evolutionary based in silico methods to predict the impact of single amino acid substitutions in vitelliform macular dystrophy.

Recent developments in high-throughput discovery and genotyping have generated a tremendous amount of information about the existence of single amino acid polymorphisms (SAPs). Detailed understanding of the SAPs that affect protein structure and function can provide us valuable insight into disease genotype-phenotype correlations. Functional variants of biological importance are likely to be missed in large-scale analysis. Over the past decade, numerous efforts are underway in understanding and characterizing the potential consequences of variants in assessing the risk associated with vitelliform macular dystrophy (VMD). Yet, in spite of this success, we conducted a first SAP analysis via evolutionary-based in silico pipeline to unravel functional SAPs from a pool, containing both functional and neutral ones. Furthermore, based on the prediction scores, a ranking system was developed to prioritize the functional SAPs in order to minimize the number of SAPs screened for further genotyping.