Translating translation: Regulated protein translation as a biomedical intervention

Altering the cellular response to internal and external stressors is essential for survival, hence the process of translation is exquisitely regulated to rapidly change the proteomic profile upon physiological challenges. We recently reported that genetic and pharmacological manipulation of translation may be beneficial in the treatment of Parkinson disease (PD). Using two Drosophila models of PD, we showed that altering the regulation of protein translation is sufficient to ameliorate the phenotypes of these models, including neurodegeneration, mitochondrial defects and behavioral deficits. Previous studies implicating translation regulation in lifespan extension further implicates this as an important mechanism that can mediate cell protective pathways, not just for age-related diseases such as PD, but also of aging itself. As such, translation regulation represents a convergent target for therapeutic interventions. Here we highlight the therapeutic potential of translation regulation in disease and describe how determining profiles of protein synthesis may help in the fight for disease prevention and healthy aging.     

The Shine-Dalgarno-like sequence is a negative regulatory element for translation of tobacco chloroplast rps2 mRNA: an additional mechanism for translational control in chloroplasts

Most prokaryotic mRNAs contain within the 5' untranslated region (UTR), a Shine-Dalgarno (SD) sequence, which is complementary to the 3' end of 16S rRNA and serves as a major determinant for correct translational initiation. The tobacco chloroplast rps2 mRNA possesses an SD-like sequence (GGAG) at a proper position (positions -8 to -5 from the start codon). Using an in vitro translation system from isolated tobacco chloroplasts, the role of this sequence in translation was examined. Unexpectedly, the mutation of the SD-like element resulted in a large increase in translation. Internal and external deletions within the 5' UTR revealed that the region from -20 to -5 was involved in the negative regulation of translation. Scanning mutagenesis assays confirmed the above result. Competition assays suggested the existence of a trans-acting factor(s) involved in translational regulation. In this study, we discuss a possible mechanism for the negative regulation of rps2 mRNA translation.     

λN gene expression regulated by translation termination in ribosome L24 mutant

Although the initiation and elongation steps of protein synthesis have been extensively char-acterized in Escherichia coli (E. coli), the translation termination is still less well understood. However, recent experiment result might have provided some hints for our deeper understanding of the termination mechanism. (i) Not only does the translation stop codon act as a signal for ter-mination, but also its context influences the translation termination[13]; (ii) the structure similar-ity betwee…     

A cis-element in the 5' untranslated region of the preproinsulin mRNA (ppIGE) is required for glucose regulation of proinsulin translation

Insulin production in pancreatic beta cells is predominantly regulated through glucose control of proinsulin translation. Previously, this was shown to require sequences within the untranslated regions (UTRs) of the preproinsulin (ppI) mRNA. Here, those sequences were found to be sufficient for specific glucose-regulated proinsulin translation. Furthermore, an element 40-48 bp from the 5' end of the ppI mRNA specifically bound a factor present in islets of Langerhans. Glucose-responsive factor binding to this cis-element exhibited temporal and glucose-concentration-dependent patterns that paralleled proinsulin biosynthesis. Mutating this cis-element abolished the ability of ppI mRNA UTRs to confer glucose regulation upon translation. Like the rat 5'UTR, the human ppI 5'UTR conferred glucose regulation of translation. However alternative splicing of the human 5'UTR that disrupts the cis-element abolished glucose-regulated translation. These data indicate that glucose regulation of cis-element/trans-acting factor interaction is a key component of the mechanism by which glucose regulates insulin production.     

Regulation of RpoS by a novel small RNA: the characterization of RprA

Translational regulation of the stationary phase sigma factor RpoS is mediated by the formation of a double-stranded RNA stem-loop structure in the upstream region of the rpoS messenger RNA, occluding the translation initiation site. The interaction of the rpoS mRNA with a small RNA, DsrA, disrupts the double-strand pairing and allows high levels of translation initiation. We screened a multicopy library of Escherichia coli DNA fragments for novel activators of RpoS translation when DsrA is absent. Clones carrying rprA (RpoS regulator RNA) increased the translation of RpoS. The rprA gene encodes a 106 nucleotide regulatory RNA. As with DsrA, RprA is predicted to form three stem-loops and is highly conserved in Salmonella and Klebsiella species. Thus, at least two small RNAs, DsrA and RprA, participate in the positive regulation of RpoS translation. Unlike DsrA, RprA does not have an extensive region of complementarity to the RpoS leader, leaving its mechanism of action unclear. RprA is non-essential. Mutations in the gene interfere with the induction of RpoS after osmotic shock when DsrA is absent, demonstrating a physiological role for RprA. The existence of two very different small RNA regulators of RpoS translation suggests that such additional regulatory RNAs are likely to exist, both for regulation of RpoS and for regulation of other important cellular components.     

基于翻译调控的细菌耐药研究进展

由于抗生素的大量使用,细菌耐药问题凸显,直接威胁人类生命健康和世界经济发展。过去对于细菌耐药的遗传和分子机制研究较为透彻,而对应的调控机制研究相对较少。翻译调控作为生命体最重要的调控方式之一,在细菌耐药研究领域的重要性尚未被学术界充分重视。本文介绍了影响翻译过程的抗生素的主要作用机制,重点从核糖体的修饰和突变、tRNA总量的动态调控、tRNA氨酰化、tRNA甲基化、核糖体保护蛋白和翻译因子这几个方面概述了基于翻译调控的细菌耐药研究进展,为研究者们提供了一个基于翻译调控角度研究细菌耐药的新视角,同时也为开发靶向细菌翻译调控的新型抗生素提供一些新思路。     

Protein translation, 2008

The important role that regulation of protein translation plays in determining longevity in invertebrate organisms became widely appreciated in 2007, with the publication of several papers discussed in last year's review. During 2008, several studies have further strengthened the idea that regulation of translation is one component of a highly evolutionarily conserved pathway that modifies longevity. Importantly, studies published this year also began to provide insights into specific mechanisms by which altered mRNA translation does (and in some cases does not) slow aging in invertebrate model organisms.     

真核生物mRNA翻译起始机制研究进展

在真核生物中,mRNA翻译是一个复杂的多步骤过程,包括起始、延伸和终止3个阶段。其中,起始阶段的调控是影响mRNA翻译的关键。目前已经发现,mRNA翻译起始方式有多种,以最早发现的m ⁷G帽依赖性扫描机制最为经典,但当细胞处于逆境,经典起始机制受到抑制时,其他类型的起始机制会将其替代以保证翻译的顺利进行。本文对目前已发现的真核生物mRNA不同翻译起始机制特别是经典起始机制的替代机制进行了综述,旨在为深入认识真核生物基因在翻译水平上的表达调控提供参考。     

MnSOD基因表达调控的研究进展

MnSOD是生物体内重要的氧自由基清除剂, 具有抗氧化和抗肿瘤作用。MnSOD基因的表达调控是一个复杂的过程, 多种转录因子、细胞信号分子和细胞信号通路参与其中。MnSOD基因的表达调控包括转录调控、转录后调控和翻译调控3个方面。转录调控是MnSOD基因表达调控的第一个层次, 在MnSOD基因表达的过程中起重要作用。它主要是通过调节与MnSOD基因转录相关的转录因子活性来实现的, 例如特异蛋白-1 (SP-1)、激活蛋白-2(AP-2)、激活蛋白-1(AP-1)、核因子-卡巴B(NF-κB)等。药物和金属离子就是通过改变这些转录因子的活性来调控MnSOD基因表达的, 另外某些基因的突变和缺失也能改变这些转录因子的活性。转录后调控主要体现在改变mRNA的稳定性或mRNA的翻译上。翻译调控则是对MnSOD多肽的编辑、修饰并与相应的金属离子结合及定位的调控。近年来发现了一种线粒体MnSOD的锰转运因子, 它对MnSOD活性的调控起重要作用。文章综述了这一研究领域的一些进展, 着重讨论了MnSOD基因的转录调控和翻译调控, 并展望了MnSOD基因表达调控的研究方向。     

Structure of the chloroplast ribosome: novel domains for translation regulation

Gene expression in chloroplasts is controlled primarily through the regulation of translation. This regulation allows coordinate expression between the plastid and nuclear genomes, and is responsive to environmental conditions. Despite common ancestry with bacterial translation, chloroplast translation is more complex and involves positive regulatory mRNA elements and a host of requisite protein translation factors that do not have counterparts in bacteria. Previous proteomic analyses of the chloroplast ribosome identified a significant number of chloroplast-unique ribosomal proteins that expand upon a basic bacterial 70S-like composition. In this study, cryo-electron microscopy and single-particle reconstruction were used to calculate the structure of the chloroplast ribosome to a resolution of 15.5 Å. Chloroplast-unique proteins are visualized as novel structural additions to a basic bacterial ribosome core. These structures are located at optimal positions on the chloroplast ribosome for interaction with mRNAs during translation initiation. Visualization of these chloroplast-unique structures on the ribosome, combined with mRNA cross-linking, allows us to propose a model for translation initiation in chloroplasts in which chloroplast-unique ribosomal proteins interact with plastid-specific translation factors and RNA elements to facilitate regulated translation of chloroplast mRNAs.     

A minimal element in 5'UTR of insulin mRNA mediates its translational regulation by glucose

Glucose induced translation of insulin in pancreatic beta cells is mediated by the 5'UTR of insulin mRNA. We determined the minimal sequence/structure in the 5'UTR of rat insulin gene1 for this regulation. We show that specific factors in the pancreatic islets bind to the 5'UTR of the insulin mRNA upon glucose stimulation. We identified a minimal 29-nucleotide element in the 5'UTR that is sufficient to form the complex, and confer glucose mediated translation activation. Conserved residues in the predicted stem loop region of the un-translated region (UTR) seem to be important for the complex formation and the translation regulation.     

Utilization of Messenger in Adenovirus-2-infected Cells at Normal and Elevated Temperatures

THE regulation of protein synthesis in eukaryotic cells appears to be distinctly different from that in prokaryotes. The long-lived messenger RNA in eukaryotes suggests that control of protein synthesis occurs partially at the level of translation and regulation at the level of initiation of translation of messenger RNA has been found under several different conditions in mammalian cells^1–6.     

Mutations in the rpIJ leader of Escherichia coli that abolish feedback regulation

We have isolated mutants that fail to exhibit biosynthetic feedback regulation of a rpIJ-lacZ fusion. Analysis of these mutants and of others that were isolated earlier indicates that crucial sequences for both translational feedback regulation and efficient translation lie closely intermingled in the central region of the rpIJ mRNA leader 70-195 bases upstream from the translation start of rpIJ. We suggest that our point mutations define a region of the rpIJ leader mRNA to which L10 binds in effecting autogenous translational regulation.