The functional Hfq-binding module of bacterial sRNAs consists of a double or single hairpin preceded by a U-rich sequence and followed by a 3' poly(U) tail

Hfq-dependent sRNAs contain, at least, an mRNA base-pairing region, an Hfq-binding site, and a Rho-independent terminator. Recently, we found that the terminator poly(U) of Escherichia coli sRNAs is essential for Hfq binding and therefore for riboregulation. In this study, we tried to identify additional components within Hfq-binding sRNAs required for efficient Hfq binding by using SgrS as a model. We demonstrate by mutational and biochemical studies that an internal hairpin and an immediately upstream U-rich sequence also are required for efficient Hfq binding. We propose that the functional Hfq-binding module of SgrS consists of an internal hairpin preceded by a U-rich sequence and a Rho-independent terminator with a long poly(U) tail. We also show that the Rho-independent terminator alone can act as a functional Hfq-binding module when it is preceded by an internal U-rich sequence. The 3' region of most known sRNAs share the features corresponding to either a double- or single-hairpin-type Hfq-binding module. We also demonstrate that increasing the spacing between the base-pairing region and the Hfq-binding module reduces or impairs the silencing ability. These findings allowed us to design synthetic Hfq-binding sRNAs to target desired mRNAs.     

Mechanisms of polar arrest of a replication fork

A DNA replication terminator sequence blocks an approaching replication fork when the moving replisome approaches from just one direction. The mechanism underlying polar arrest has been debated for years, but recent work has helped to reveal how a replication fork is blocked in Escherichia coli . Early work suggested that asymmetric interaction between terminator protein and terminator DNA contributes to polar fork arrest. A later study demonstrated that if the terminator DNA is partially unwound, the resulting melted DNA could bind tightly to the terminator protein, suggesting a mechanism for polar arrest that involves a locked complex. However, recent evidence suggests that the terminator protein–DNA contacts are not sufficient for polar arrest in vivo . Furthermore, polar arrest of a replication fork still occurs in the absence of a locked complex between the terminator protein and DNA. In E. coli and Bacillus subtilis , the bound terminator protein makes protein–protein contacts with the replication fork helicase, and these contacts are critical in blocking progression of the advancing fork. Thus, we propose that interactions between the replication fork helicase and terminator protein are the primary mechanism for polar fork arrest in bacteria, and that this primary mechanism is modulated by asymmetric contacts between the terminator protein and its cognate DNA sequence. In yeast, terminator sequences are present in rDNA non-transcribed spacers and a region immediately preceding the mating type switch locus Mat1, and the mechanism of polar arrest at these regions is beginning to be elucidated.     

牛凝乳酶原基因在大肠杆菌中表达调控的研究

Shine-Dalgarno序列与起始密码子之问的距离与组成对凝乳酶原基因表达有明显的影响,可导致其表达水平有15倍之差。SD序列至ATG之间为15bp不利于表达,表达质粒中sD-ATG在7-11bp之间都有可能获得高效表达;但决定因素不是简单的长度,而是RBS附近可能的二级结构即△G的大小、SD序列及ATG中参与配对的碱基数目。将pTLC23中凝乳酶原cDNA3＇端端非翻译区插入终止密码子TGA与转录终止子rrnBT₁T₂之间适当位置可提高凝乳酶原基因的表达,这可能是因为这段序列能形成由53个碱基对和8个碱基组成的稳定的mRNA二级结构,起到转录终止子的作用,而一般认为串联终止子对终止转录更为有效。     

Nucleotide sequence of the gene coding for yeast cytoplasmic aspartyl-tRNA synthetase (APS); mapping of the 5'' and 3'' termini of AspRS mRNA.

A 3.8 Kb DNA fragment, which contains the structural gene of aspartyl-tRNA synthetase (AspRS) and its flanking regions, has been fully sequenced by the combined M13/dideoxy chain terminator method. From the single open reading frame of correct length (1671 bp) we deduced an amino acid sequence consistent with that of several peptides of AspRS. No significant internal sequence repeats were observed in the primary structure of the protein. The AspRS gene (APS) has a codon usage pattern typical of non abundant proteins. S1 nuclease analysis of APS mRNA showed a major start 17 bases downstream from a "TATA box" and stops near an RNA polymerase terminator sequence.     

Termination of DNA replication in vitro at a sequence-specific replication terminus

The replication terminus of the drug resistance factor R6K has been cloned into the plasmid vectors pBR313 and pBR322. When the exogenously added DNA is replicated in vitro using cell extracts prepared from Escherichia coli, the plasmid replication terminus temporarily arrests the progression of the unidirectionally moving replication fork at or near the cloned terminator sequence. When the relative location of the terminator sequence is changed with respect to the replication origin, the point of arrest of the replication fork shifts correspondingly to the new location of the terminator. Termination of replication takes place in vitro regardless of whether the cell extracts used in the in vitro reaction are prepared from E. coli with a resident terminus sequence containing plasmid. From these observations we conclude that the termination of replication in vitro is identical or very similar to that observed in vivo, membrane association is not necessary for the activity of the replication terminus and the terminus sequence does not code for a transacting factor necessary for termination of replication. Therefore, any transacting factor which may be needed for the termination of replication must be coded by the host chromosome.