Identification of the Hfq-binding site on DsrA RNA: Hfq binds without altering DsrA secondary structure

DsrA RNA regulates the translation of two global regulatory proteins in Escherichia coli. DsrA activates the translation of RpoS while repressing the translation of H-NS. The RNA-binding protein Hfq is necessary for DsrA to function in vivo. Although Hfq binds to DsrA in vitro, the role of Hfq in DsrA-mediated regulation is not known. One hypothesis was that Hfq acts as an RNA chaperone by unfolding DsrA, thereby facilitating interactions with target RNAs. To test this hypothesis, we have examined the structure of DsrA bound to Hfq in vitro. Comparison of free DsrA to DsrA bound to Hfq by RNase footprinting, circular dichroism, and thermal melt profiles shows that Hfq does not alter DsrA secondary structures, but might affect its tertiary conformation. We identify the site on DsrA where Hfq binds, which is a structural element in the middle of DsrA. In addition, we show that although long poly(U) RNAs compete with DsrA for binding to Hfq, a short poly(U) stretch present in DsrA is not necessary for Hfq binding. Finally, unlike other RNAs, DsrA binding to Hfq is not competed with by poly(A) RNA. In fact, DsrA:poly(A):Hfq may form a stable ternary complex, raising the possibility that Hfq has multiple RNA-binding sites.     

Comparison of the structure of ribosomal 5S RNA from E. coli and from rat liver using X-ray scattering and dynamic light scattering

The structures of eukaryotic ribosomal 5S RNA from rat liver and of prokaryotic 5S RNA from E. coli (A-conformer) have been investigated by scattering methods. For both molecules, a molar mass of 44,500±4,000 was determined from small angle X-ray scattering as well as from dynamic light scattering. The shape parameters of the two rRNAs, volume V _c, surface O _c, radius of gyration R _s, maximum dimension of the molecule L, thickness D, and cross section radius of gyration R _sq, agree within the experimental error limits. The mean values are V _c=57±3 nm³, O _c=165±10 nm², R _s=3.37±0.05 nm, L=10.8±0.7 nm, D=1.57±0.07 nm, R _sa=0.92±0.01 nm.Identical structures for the E. coli 5S rRNA and the rat liver 5S rRNA at a resolution of 1 nm can be deduced from this agreement and from the comparison of experimental X-ray scattering curves and of experimental electron distance distribution function. The flat shape model derived for prokaryotic and eukaryotic 5S rRNA shows a compact region and two protruding arms. Double helical stems are eleven-fold helices with a mean base pair distance of 0.28 nm. Combining the shape information obtained from X-ray scattering with the information about the frictional behaviour of the molecules, deduced from the diffusion coefficients D _20,w ⁰ =(5.9±0.2)·10^-7 cm²s^-1 and (6.2±0.2)·10^-7 cm²s^-1 for rat liver 5S rRNA and E. coli 5S rRNA, respectively, a solvation shell of about 0.3 nm thickness around both molecules is determined. This structural similarity and the consensus secondary structure pattern derived from comparative sequence analyses suggest that all 5S rRNAs may indeed have conserved essentially the same type of folding of their polynucleotide strands during evolution, despite having very different sequences.     

Structural organization of the 16S ribosomal RNA from E. coli. Topography and secondary structure.

Extensive studies in our laboratory using different ribonucleases resulted in valuable data on the topography of the E.coli 16S ribosomal RNA within the native 30S subunit, within partially unfolded 30S subunits, in the free state, and in association with individual ribosomal proteins. Such studies have precise details on the accessibility of certain residues and delineated highly accessible RNA regions. Furthermore, they provided evidence that the 16S rRNA is organized in its subunit into four distinct domains. A secondary structure model of the E.coli 16S rRNA has been derived from these topographical data. Additional information from comparative sequence analyses of the small ribosomal subunit RNAs from other species sequenced so far has been used.     

Separation of E. coli tRNA-Tyr precursor RNA from E. coli tRNA by hydroxyapatite chromatography

An assay procedure is described for triosephosphate isomerase based on measurement of the ellipticity of l-glyceraldehyde 3-phosphate remaining when d,l-glyceraldehyde 3-phosphate is the source of substrate and d-glyceraldehyde 3-phosphate is converted by triosephosphate isomerase to dihydroxyacetone phosphate. The assay method has advantages over the conventional coupled-enzyme assays in that it circumvents the difficulties posed by instability of the coupling enzymes and their cofactors, as well as by inhibitors of triosephosphate isomerase which may be present in preparations of the coupling enzymes. Although the method is not suited for routine assays during purification or in most clinical applications, it has advantages for detailed kinetic studies where pH, temperature, or other factors cause the coupled-enzyme assay procedures to be unreliable.     

Structural and functional exchangeability of 5 S RNA species from the eubacterium E.coli and the thermoacidophilic archaebacterium Sulfolobus solfataricus.

The role of 5 S RNA within the large ribosomal subunit of the extremely thermophilic archaebacterium Sulfolobus solfataricus has been analysed by means of in vitro reconstitution procedures. It is shown that Sulfolobus 50 S subunits reconstituted in the absence of 5 S RNA are inactive in protein synthesis and lack 2-3 ribosomal proteins. Furthermore, it has been determined that in the course of the in vitro assembly process Sulfolobus 5 S RNA can be replaced by the correspondent RNA species of E.coli; Sulfolobus reconstituted particles containing the eubacterial 5 S molecule are stable and active in polypeptide synthesis at high temperatures.     

Predicting stable functional peptides from the intergenic space of E. coli

Expression of synthetic proteins from intergenic regions of E. coli and their functional association was recently demonstrated (Dhar et al. in J Biol Eng 3:2, 2009. doi:10.1186/1754-1611-3-2). This gave birth to the question: if one can make ‘user-defined’ genes from non-coding genome—how big is the artificially translatable genome? (Dinger et al. in PLoS Comput Biol 4, 2008; Frith et al. in RNA Biol 3(1):40–48, 2006a; Frith et al. in PLoS Genet 2(4):e52, 2006b). To answer this question, we performed a bioinformatics study of all reported E. coli intergenic sequences, in search of novel peptides and proteins, unexpressed by nature. Overall, 2500 E. coli intergenic sequences were computationally translated into ‘protein sequence equivalents’ and matched against all known proteins. Sequences that did not show any resemblance were used for building a comprehensive profile in terms of their structure, function, localization, interactions, stability so on. A total of 362 protein sequences showed evidence of stable tertiary conformations encoded by the intergenic sequences of E. coli genome. Experimental studies are underway to confirm some of the key predictions. This study points to a vast untapped repository of functional molecules lying undiscovered in the non-expressed genome of various organisms.     

Purification of histidine-tagged T4 RNA ligase from E. coli

Here we report the construction of a histidine-tagged T4 RNA ligase expression plasmid (pRHT4). The construct, when overexpressed in BL21 (DE3) cells, allows the preparation of large quantities of T4 RNA ligase in high purity using only a single purification column. The histidine affinity tag does not inhibit enzyme function, and we were able to purify 1-3 mg pure protein/g cell pellet. A simple purification procedure ensures that the enzyme is de-adenylated to levels comparable to those found for many commercial preparations. The purified protein has very low levels of RNase contamination and functioned normally in a variety of activity assays.     

Qβ噬菌体RNA复制酶基因的克隆及在大肠杆菌中的表达

构建了带有Qβ噬菌体RNA复制酶cDNA基因的重组表达质粒pKK-Rep,采用电泳分析的方法考察了不同浓度的IPTG、不同的葡萄糖浓度对pKK-Rep在E.coli JM109中表达RNA复制酶蛋白的影响。结果表明,0.01mmol/L IPTG可以有效诱导pKK-Rep表达RNA复制酶蛋白,但表达的RNA复制酶蛋白大多数为不溶性蛋白。在培养基中添加0.02%的葡萄糖对该RNA复制酶蛋白的组成型表达无明显的影响,但当葡萄糖浓度增加至0.04%-1.0%时,这种组成型表达量显著降低。采用MDV－poly( )RNA作为模板来体外检测可溶性表达蛋白的活性,结果表明其具有体外特异扩增RNA模板的活性。     

RNase E, an RNA processing enzyme from Escherichia coli.

An activity, RNase E, was purified about 100-fold from Escherichia coli cells, it can process p5 rRNA from a 9 S RNA molecule which accumulates in a mutant of E. coli defective in the maturation of 5 S rRNA. The enzyme requires Na+, K+, or NH4+, and Mg2+ or Mn2+. The molecular weight of the enzyme is about 70,000 and its pH optimum is 7.6 to 8.0. Its temperature optimum is around 30 degrees C, and it can be irreversibly inactivated at 50 degrees C. It has a very high degree of specificity but the reaction can be inhibited by nonspecific RNAs. We interpret its mode of action in producing p5 RNA as being accomplished in two steps, 9 S RNA is first processed to 7 S and 4 S, and subsequently 7 S is further processed to p5.     

Stability and maturation of E. coli ribosomal RNA.

The kinetics of rRNA maturation were investigated in a rifampicin permeable strain of E. coli during exponential growth in glucose minimal medium. The method used involves isotopic labelling of rRNA, and separation of precursor and mature forms by gel electrophoresis. The maturation of both 16s and 23s rRNA was found to follow first order kinetics. The mean life time of the precursors was found to be about 1.5 min. In glucose minimal medium all pulse label in precursors was recovered in mature rRNA, i.e. nascent rRNA is stable.