Soluble expression of cloned phage K11 RNA polymerase gene in Escherichia coli at a low temperature.

The gene 1 of the Klebsiella phage K11 encoding the phage RNA polymerase was amplified using the polymerase chain reaction of the Pfu DNA polymerase, cloned and expressed under the control of tac promoter in Escherichia coli. Although the gene was efficiently expressed in E. coli BL21 cells at 37 degrees C, most of the K11 RNA polymerase produced was insoluble, in contrast to soluble expression of the cloned T7 RNA polymerase gene. Coexpression of the bacterial chaperone GroES and GroEL genes together did not help solubilize the K11 RNA polymerase. When the temperature of cell growth was lowered, however, solubility of the K11 RNA polymerase was increased substantially. It was found much more soluble when expressed at 25 degrees C than at 30 and 37 degrees C. Thus, the cloned K11 RNA polymerase gene was expressed in E. coli mostly to the soluble form at 25 degrees C. The protein was purified to homogeneity by chromatography using DEAE-Sephacel and Affigel-blue columns and was found to be active in vitro with the K11 genome or a K11 promoter. The purified K11 RNA polymerase showed highly stringent specificity for the K11 promoter. Low-level cross-reactivity was shown with the SP6 and T7 consensus promoters, while no activity shown with the T3 consensus promoter at all.     

Mechanism of RNA synthesis initiation by the vesicular stomatitis virus polymerase

The minimal RNA synthesis machinery of non-segmented negative-strand RNA viruses comprises a genomic RNA encased within a nucleocapsid protein (N-RNA), and associated with the RNA-dependent RNA polymerase (RdRP). The RdRP is contained within a viral large (L) protein, which associates with N-RNA through a phosphoprotein (P). Here, we define that vesicular stomatitis virus L initiates synthesis via a de-novo mechanism that does not require N or P, but depends on a high concentration of the first two nucleotides and specific template requirements. Purified L copies a template devoid of N, and P stimulates L initiation and processivity. Full processivity of the polymerase requires the template-associated N protein. This work provides new mechanistic insights into the workings of a minimal RNA synthesis machine shared by a broad group of important human, animal and plant pathogens, and defines a mechanism by which specific inhibitors of RNA synthesis function.     

Requirements and functions of vesicular stomatitis virus L and NS proteins in the transcription process in vitro

The L and NS proteins of vesicular stomatitis virus were purified from transcribing ribonucleoprotein complex and were used to study their requirements and functions during reconstitution of RNA synthesis in vitro. The requirements for L and NS proteins for optimal RNA synthesis were found to be catalytic and stoichiometric, respectively. Addition of increasing amounts of NS protein to N-RNA template and saturating L protein, the ratio of N-mRNA to leader RNA synthesis increased linearly. In contrast, when the concentration of L protein was increased the corresponding ratio remained constant. These results, coupled with the observation that the L protein is involved in the initiation of RNA synthesis, suggest that the NS protein is involved in the RNA chain elongation step. The NS protein possibly interacts with both the L protein and the template N-RNA and unwinds the latter to facilitate the movement of L protein on the template RNA.     

Creation of a T7 autogene. Cloning and expression of the gene for bacteriophage T7 RNA polymerase under control of its cognate promoter

The coding sequence for bacteriophage T7 RNA polymerase has been cloned and expressed under control of a cognate T7 promoter, a configuration referred to as an autogene. Cloning a T7 autogene in a derivative of plasmid pBR322 in Escherichia coli was achieved by a combination of blocking initiation at the T7 promoter with bound lac repressor and inhibiting the polymerase itself by T7 lysozyme. Neither type of inhibition by itself was sufficient to control the autogene. Upon unblocking the T7 promoter with added inducer. T7 RNA polymerase produced its own mRNA, leading to autocatalytic production of polymerase protein. T7 autogenes may be useful for developing high-level gene expression systems in a variety of cell types, with little if any need for the host cell RNA polymerase.     

利用重组噬菌体诱导表达的大肠杆菌表达系统

将编码噬菌体T7RNA聚合酶的基因克隆至噬菌体M13mpl8RFDNA中,置于lac启动子的控制之下,得到了可表达T7 RNA聚合酶的重组噬菌体M13HEP。利用该噬菌体感染含T7启动子表达质粒的宿主菌以提供T7RNA聚合酶,可以诱导T7启动子控制下的外源基因的表达。该噬茵体诱导表达系统已成功地表达了多种外源基因,特别是一些表达产物对宿主菌有毒性的基因。同时,通过细菌接合将F',因子从大脑杆菌XL1-blue转至大肠杆菌HMS174,构建了新的大脑杆菌菌株HMSl74F,,使得T7表达质粒构建、表达及单链制备可以在同一菌株中完成,得到了一个完整的T7表达系统。     

Action of intact AP (apurinic/apyrimidinic) sites and AP sites associated with breaks on the transcription of T7 coliphage DNA by Escherichia coli RNA polymerase.

The effect of apurinic/apyrimidinic (AP) sites in DNA on RNA and protein synthesis was studied in vitro using T7 coliphage DNA. Initiation of RNA synthesis by Escherichia coli RNA polymerase was synchronized and heparin was used to prevent reinitiation. When the T7 DNA contained AP sites, the rate of RNA synthesis was decreased but it remained higher than the values calculated on the assumption that an AP site in the transcribed strand is a complete block to the enzyme progression. Moreover, after the time taken by an unimpeded enzyme to go from promoter to terminator, the rate of RNA synthesis remained elevated and the number of complete RNA molecules (7000 nucleotides) continued to increase for some time. These results suggest that, if the E. coli RNA polymerase is stopped by an AP site, most often, after a pause, the enzyme resumes elongation of the RNA chain which is continuous over the AP site. Sometimes however, RNA synthesis is definitively interrupted during the pause; the probability of interruption has been estimated to be 0.3 in our experimental conditions. When a nick is placed 5' to the AP site by an AP endonuclease, the results are similar: most often, the RNA chain is synthesized without interruption past the nick in the template strand. The pause of the E. coli RNA polymerase at this combined lesion appears to be shorter than when the AP site is intact. To investigate whether a nucleotide is placed in the RNA chain in front of the AP site in the template strand by E. coli RNA polymerase, RNA synthesis was taken to completion before using this RNA for protein synthesis and measuring the activity of gene-1 product, T7 RNA polymerase. The result suggests that, after pausing, the E. coli RNA polymerase places a nucleotide in the RNA chain when passing over an AP site. The mechanism of the delayed lethality of T7 coliphages treated with monofunctional alkylating agents, which is due to the appearance of AP sites, is discussed.