细菌RNA结合蛋白Hfq的DNA压缩和复制作用研究进展

RNA结合蛋白(RNA-Binding Protein)Hfq是一种重要的细菌转录后调节因子,之前对Hfq的研究大多集中在该蛋白对小分子非编码RNA (Small Non-Coding RNA,sRNA)和mRNA的作用上。Hfq最典型的功能是促进sRNA与其靶标mRNA碱基配对,在转录后介导对RNA的稳定性和翻译的调控。此外,Hfq也能与多种蛋白质直接或间接相互作用。然而,近年来的研究表明,除了RNA和蛋白质,Hfq还可以与DNA相互作用,在DNA压缩(DNA Compaction)和DNA复制(DNA Replication)等多种DNA代谢过程中发挥直接或间接的调控作用。额外的靶标和功能的鉴定将进一步夯实Hfq作为细菌中多种代谢途径核心调控因子的重要地位,也表明该蛋白的功能并不局限于其在RNA和蛋白质代谢中的作用。本文总结了Hfq在DNA代谢调控中的近几年最新研究进展,并展望了其前景。     

Cycling of the Sm-like protein Hfq on the DsrA small regulatory RNA

Small RNAs (sRNAs) regulate bacterial genes involved in environmental adaptation. This RNA regulation requires Hfq, a bacterial Sm-like protein that stabilizes sRNAs and enhances RNA-RNA interactions. To understand the mechanism of target recognition by sRNAs, we investigated the interactions between Hfq, the sRNA DsrA, and its regulatory target rpoS mRNA, which encodes the stress response sigma factor. Nuclease footprinting revealed that Hfq recognized multiple sites in rpoS mRNA without significantly perturbing secondary structure in the 5' leader that inhibits translation initiation. Base-pairing with DsrA, however, made the rpoS ribosome binding site fully accessible, as predicted by genetic data. Hfq bound DsrA four times more tightly than the DsrA.rpoS RNA complex in gel mobility-shift assays. Consequently, Hfq is displaced rapidly from its high-affinity binding site on DsrA by conformational changes in DsrA, when DsrA base-pairs with rpoS mRNA. Hfq accelerated DsrA.rpoS RNA association and stabilized the RNA complex up to twofold. Hybridization of DsrA and rpoS mRNA was optimal when Hfq occupied its primary binding site on free DsrA, but was inhibited when Hfq associated with the DsrA.rpoS RNA complex. We conclude that recognition of rpoS mRNA is stimulated by binding of Hfq to free DsrA sRNA, followed by release of Hfq from the sRNA.mRNA complex.     

The RNA‐binding protein Hfq is important for ribosome biogenesis and affects translation fidelity

Ribosome biogenesis is a complex process involving multiple factors. Here, we show that the widely conserved RNA chaperone Hfq, which can regulate sRNA‐mRNA basepairing, plays a critical role in rRNA processing and ribosome assembly in Escherichia coli. Hfq binds the 17S rRNA precursor and facilitates its correct processing and folding to mature 16S rRNA. Hfq assists ribosome assembly and associates with pre‐30S particles but not with mature 30S subunits. Inactivation of Hfq strikingly decreases the pool of mature 70S ribosomes. The reduction in ribosome levels depends on residues located in the distal face of Hfq but not on residues found in the proximal and rim surfaces which govern interactions with the sRNAs. Our results indicate that Hfq‐mediated regulation of ribosomes is independent of its function as sRNA‐regulator. Furthermore, we observed that inactivation of Hfq compromises translation efficiency and fidelity, both features of aberrantly assembled ribosomes. Our work expands the functions of the Sm‐like protein Hfq beyond its function in small RNA‐mediated regulation and unveils a novel role of Hfq as crucial in ribosome biogenesis and translation.     

Dynamic Refolding of OxyS sRNA by the Hfq RNA Chaperone

The Sm protein Hfq chaperones small non-coding RNAs (sRNAs) in bacteria, facilitating sRNA regulation of target mRNAs. Hfq acts in part by remodeling the sRNA and mRNA structures, yet the basis for this remodeling activity is not understood. To understand how Hfq remodels RNA, we used single-molecule Förster resonance energy transfer (smFRET) to monitor conformational changes in OxyS sRNA upon Hfq binding. The results show that E. coli Hfq first compacts OxyS, bringing its 5′ and 3 ends together. Next, Hfq destabilizes an internal stem-loop in OxyS, allowing the RNA to adopt a more open conformation that is stabilized by a conserved arginine on the rim of Hfq. The frequency of transitions between compact and open conformations depend on interactions with Hfqs flexible C-terminal domain (CTD), being more rapid when the CTD is deleted, and slower when OxyS is bound to Caulobacter crescentus Hfq, which has a shorter and more stable CTD than E. coli Hfq. We propose that the CTDs gate transitions between OxyS conformations that are stabilized by interaction with one or more arginines. These results suggest a general model for how basic residues and intrinsically disordered regions of RNA chaperones act together to refold RNA.     

Competition among Hfq-binding small RNAs in Escherichia coli

A major class of small bacterial RNAs (sRNAs) regulate translation and mRNA stability by pairing with target mRNAs, dependent upon the RNA chaperone Hfq. Hfq, related to the Lsm/Sm families of splicing proteins, binds the sRNAs and stabilizes them in vivo and stimulates pairing with mRNAs in vitro. Although Hfq is abundant, the sRNAs, when induced, are similarly abundant. Therefore, Hfq may be limiting for sRNA function. We find that, when overexpressed, a number of sRNAs competed with endogenous sRNAs for binding to Hfq. This correlated with lower accumulation of the sRNAs (presumably a reflection of the loss of Hfq binding), and lower activity of the sRNAs in regulating gene expression. Hfq was limiting for both positive and negative regulation by the sRNAs. In addition, deletion of the gene for an expressed and particularly effective competitor sRNA improved the regulation of genes by other sRNAs, suggesting that Hfq is limiting during normal growth conditions. These results support the existence of a hierarchy of sRNA competition for Hfq, modulating the function of some sRNAs.     

Spectroscopic observation of RNA chaperone activities of Hfq in post-transcriptional regulation by a small non-coding RNA

Hfq protein is vital for the function of many non-coding small (s)RNAs in bacteria but the mechanism by which Hfq facilitates the function of sRNA is still debated. We developed a fluorescence resonance energy transfer assay to probe how Hfq modulates the interaction between a sRNA, DsrA, and its regulatory target mRNA, rpoS. The relevant RNA fragments were labelled so that changes in intra- and intermolecular RNA structures can be monitored in real time. Our data show that Hfq promotes the strand exchange reaction in which the internal structure of rpoS is replaced by pairing with DsrA such that the Shine-Dalgarno sequence of the mRNA becomes exposed. Hfq appears to carry out strand exchange by inducing rapid association of DsrA and a premelted rpoS and by aiding in the slow disruption of the rpoS secondary structure. Unexpectedly, Hfq also disrupts a preformed complex between rpoS and DsrA. While it may not be a frequent event in vivo, this melting activity may have implications in the reversal of sRNA-based regulation. Overall, our data suggests that Hfq not only promotes strand exchange by binding rapidly to both DsrA and rpoS but also possesses RNA chaperoning properties that facilitates dynamic RNA-RNA interactions.     

Conserved arginines on the rim of Hfq catalyze base pair formation and exchange

The Sm-like protein Hfq is required for gene regulation by small RNAs (sRNAs) in bacteria and facilitates base pairing between sRNAs and their mRNA targets. The proximal and distal faces of the Hfq hexamer specifically bind sRNA and mRNA targets, but they do not explain how Hfq accelerates the formation and exchange of RNA base pairs. Here, we show that conserved arginines on the outer rim of the hexamer that are known to interact with sRNA bodies are required for Hfq’s chaperone activity. Mutations in the arginine patch lower the ability of Hfq to act in sRNA regulation of rpoS translation and eliminate annealing of natural sRNAs or unstructured oligonucleotides, without preventing binding to either the proximal or distal face. Stopped-flow FRET and fluorescence anisotropy show that complementary RNAs transiently form a ternary complex with Hfq, but the RNAs are not released as a double helix in the absence of rim arginines. RNAs bound to either face of Hfq quench the fluorescence of a tryptophan adjacent to the arginine patch, demonstrating that the rim can simultaneously engage two RNA strands. We propose that the arginine patch overcomes entropic and electrostatic barriers to helix nucleation and constitutes the active site for Hfq’s chaperone function.     

建立基于RNA免疫共沉淀技术的鼠疫耶尔森菌Hfq蛋白相关sRNA的体内验证方法

目的：建立RNA免疫共沉淀方法,为鼠疫耶尔森菌Hfq蛋白相关非编码小RNA（sRNA）提供体内验证方法。方法：首先在RNA结合蛋白Hfq下游加入Flag标签,用Flag标签抗体进行免疫共沉淀,获得蛋白-RNA复合物,然后从沉淀的蛋白-RNA复合物中分离得到纯化的RNA;通过Western印迹检测各步骤Hfq蛋白的表达,再利用Northern印迹检测目的sRNA--RyhB1和RyhB2。结果：构建了带有Flag标签的RNA结合蛋白Hfq的载体,此载体转导入hfq缺失株后与鼠疫菌野生株的生长曲线无明显差异;通过RNA-蛋白免疫共沉淀技术鉴定出已知与鼠疫菌Hfq蛋白结合的2个sRNA--RyhB1和RyhB2。结论：建立了利用RNA-蛋白免疫共沉淀鉴定与鼠疫菌Hfq蛋白结合的sRNA的技术,为细菌sRNA的验证、功能研究和体内蛋白质与RNA相互作用研究提供了有利工具。     

Mutations in Interaction Surfaces Differentially Impact E. coli Hfq Association with Small RNAs and Their mRNA Targets

The RNA chaperone protein Hfq is required for the function of all small RNAs (sRNAs) that regulate mRNA stability or translation by limited base pairing in Escherichia coli. While there have been numerous in vitro studies to characterize Hfq activity and the importance of specific residues, there has been only limited characterization of Hfq mutants in vivo. Here, we use a set of reporters as well as co-immunoprecipitation to examine 14 Hfq mutants expressed from the E. coli chromosome. The majority of the proximal face residues, as expected, were important for the function of sRNAs. The failure of sRNAs to regulate target mRNAs in these mutants can be explained by reduced sRNA accumulation. Two of the proximal mutants, D9A and F39A, acted differently from the others in that they had mixed effects on different sRNA/mRNA pairs and, in the case of F39A, showed differential sRNA accumulation. Mutations of charged residues at the rim of Hfq interfered with positive regulation and gave mixed effects for negative regulation. Some, but not all, sRNAs accumulated to lower levels in rim mutants, suggesting qualitative differences in how individual sRNAs are affected by Hfq. The distal face mutants were expected to disrupt binding of ARN motifs found in mRNAs. They were more defective for positive regulation than negative regulation at low mRNA expression, but the defects could be suppressed by higher levels of mRNA expression. We discuss the implications of these observations for Hfq binding to RNA and mechanisms of action.     

Effect of salt and RNA structure on annealing and strand displacement by Hfq

The Sm-like protein Hfq promotes the association of small antisense RNAs (sRNAs) with their mRNA targets, but the mechanism of Hfq''s RNA chaperone activity is unknown. To investigate RNA annealing and strand displacement by Hfq, we used oligonucleotides that mimic functional sequences within DsrA sRNA and the complementary rpoS mRNA. Hfq accelerated at least 100-fold the annealing of a fluorescently labeled molecular beacon to a 16-nt RNA. The rate of strand exchange between the oligonucleotides increased 80-fold. Therefore, Hfq is very active in both helix formation and exchange. However, high concentrations of Hfq destabilize the duplex by preferentially binding the single-stranded RNA. RNA binding and annealing were completely inhibited by 0.5 M salt. The target site in DsrA sRNA was 1000-fold less accessible to the molecular beacon than an unstructured oligonucleotide, and Hfq accelerated annealing with DsrA only 2-fold. These and other results are consistent with recycling of Hfq during the annealing reaction, and suggest that the net reaction depends on the relative interaction of Hfq with the products and substrates.     

Requirement of upstream Hfq-binding (ARN)x elements in glmS and the Hfq C-terminal region for GlmS upregulation by sRNAs GlmZ and GlmY{dagger}

Hfq is an important RNA-binding protein that helps bacteria adapt to stress. Its primary function is to promote pairing between trans-acting small non-coding RNAs (sRNAs) and their target mRNAs. Identification of essential Hfq-binding motifs in up-stream regions of rpoS and fhlA led us to ask the question whether these elements are a common occurrence among other Hfq-dependent mRNAs as well. Here, we confirm the presence of a similar (ARN)(x) motif in glmS RNA, a gene controlled by two sRNAs (GlmZ and GlmY) in an Hfq-dependent manner. GlmZ represents a canonical sRNA:mRNA pairing system, whereas GlmY is non-canonical, interfacing with the RNA processing protein YhbJ. We show that glmS interacts with both Hfq-binding surfaces in the absence of sRNAs. Even though two (ARN)(x) motifs are present, using a glmS:gfp fusion system, we determined that only one specific (ARN)(x) element is essential for regulation. Furthermore, we show that residues 66-72 in the C-terminal extension of Escherichia coli Hfq are essential for activation of GlmS expression by GlmY, but not with GlmZ. This result shows that the C-terminal extension of Hfq may be required for some forms of non-canonical sRNA regulation involving ancillary components such as additional RNAs or proteins.     

Major role for mRNA binding and restructuring in sRNA recruitment by Hfq

Bacterial small RNAs (sRNAs) modulate gene expression by base-pairing with target mRNAs. Many sRNAs require the Sm-like RNA binding protein Hfq as a cofactor. Well-characterized interactions between DsrA sRNA and the rpoS mRNA leader were used to understand how Hfq stimulates sRNA pairing with target mRNAs. DsrA annealing stimulates expression of rpoS by disrupting a secondary structure in the rpoS leader, which otherwise prevents translation. Both RNAs bind Hfq with similar affinity but interact with opposite faces of the Hfq hexamer. Using mutations that block interactions between two of the three components, we demonstrate that Hfq binding to a functionally critical (AAN)(4) motif in rpoS mRNA rescues DsrA binding to a hyperstable rpoS mutant. We also show that Hfq cannot stably bridge the RNAs. Persistent ternary complexes only form when the two RNAs are complementary. Thus, Hfq mainly acts by binding and restructuring the rpoS mRNA. However, Hfq binding to DsrA is needed for maximum annealing in vitro, indicating that transient interactions with both RNAs contribute to the regulatory mechanism.     

细菌RNA稳定性调控相关元件的研究进展

RNA降解体（细菌RNA降解的主要执行者）是一种多亚基的蛋白质复合物,主要由RNA解螺旋酶、聚核苷酸磷酸化酶（polynucleotide phosphorylase,PNPase）、内切核酸酶（ribonuclease E,RNase E）以及糖酵解途径中的烯醇化酶、磷酸果糖激酶等组成,参与核糖体RNA（ribosome RNA,rRNA）的加工以及信使RNA（messenger RNA,mRNA）的降解。此外,RNA分子伴侣Hfq和调控小RNA（small RNA,sRNA）在RNA稳定性调控中也发挥着重要作用。综述了细菌RNA稳定性调控相关功能元件,特别是降解体蛋白及RNA分子伴侣Hfq的最新进展,以期为研究细菌RNA稳定性及其参与的代谢调控提供理论参考。