Amplification of the uvrA gene product of Escherichia coli to 7% of cellular protein by linkage to the pL promoter of pKC30

Production of recombinant proteins in E. coli by the heat inducible expression system based on the phage lambda pL and/or pR promoters

The temperature inducible expression system, based on the pL and/or pR phage lambda promoters regulated by the thermolabile cI857 repressor has been widely use to produce recombinant proteins in prokaryotic cells. In this expression system, induction of heterologous protein is achieved by increasing the culture temperature, generally above 37 degrees C. Concomitant to the overexpression of heterologous protein, the increase in temperature also causes a variety of complex stress responses. Many studies have reported the use of such temperature inducible expression system, however only few discuss the simultaneous stress effects caused by recombinant protein production and the up-shift in temperature. Understanding the integral effect of such responses should be useful to develop improved strategies for high yield protein production and recovery. Here, we describe the current status of the heat inducible expression system based on the pL and/or pR lambda phage promoters, focusing on recent developments on expression vehicles, the stress responses at the molecular and physiological level that occur after heat induction, and bioprocessing factors that affect protein overexpression, including culture operation variables and induction strategies.

The UvrABC endonuclease system of Escherichia coli--a view from Baltimore

Nucleotide excision is initiated by the UvrABC endonuclease system in which the initial DNA interaction is with UvrA which was dimerized in the presence of ATP. Nucleoprotein formation most likely takes place on undamaged regions of DNA by (UvrA)2 which has been dimerized in the presence of ATP. Topological unwinding of DNA, driven by ATP binding, is increased by the presence of UvrB to approximately a single helical turn. The Uvr(A)2B complex translocates to a damaged site by the combined Uvr(A)2B helicase in which the driving force is provided by the UvrB-associated ATPase. The dual incision reaction is initiated by the binding of the UvrC protein to the Uvr(A)2B-nucleoprotein complex. The proteins in this post-incision nucleoprotein complex do not turn over and require the presence of the UvrD protein and DNA polymerase I under polymerizing conditions. The final integrity of the DNA strands is restored with polynucleotide ligase.

Characterization of the RAD10 gene of Saccharomyces cerevisiae and purification of Rad10 protein

The RAD10 gene of Saccharomyces cerevisiae is one of at least five genes required for damage-specific incision of DNA during nucleotide excision repair. This gene was previously cloned and sequenced [Weiss, W. A., & Friedberg, E. C. (1985) EMBO J. 4, 1575-1582; Reynolds et al. (1985) EMBO J. 4, 3549-3552]. In the present studies, we have mapped one major and three minor transcriptional start sites in the RAD10 gene. The locations of these sites relative to the translational start codon are remarkably similar to those previously identified in the yeast RAD2 gene [Nicolet et al. (1985) Gene 36, 225-234]. The two genes also share common sequences in these regions. However, in contrast to RAD2 [Robinson et al. (1986) Proc. Natl. Acad. Sci. U.S.A. 83, 1842-1846], RAD10 is not induced following exposure of cells to the DNA-damaging agent 4-nitroquinoline 1-oxide. Native RAD10 protein and also two different Rad10 fusion proteins are rapidly degraded in most Escherichia coli strains. However, following overexpression of the cloned RAD10 gene in yeast, native Rad10 protein was purified to greater than 90% homogeneity. A catalytic function has not been identified for the purified protein. RAD10 cells (untransformed with the cloned gene) contain fewer than 500 molecules per cell. This is similar to the levels of the UvrA, UvrB, and UvrC nucleotide excision repair proteins in E. coli.

The molecular genetics of the incision step in the DNA excision repair process

This review describes the evolution of research into the genetic basis of how different organisms use the process of excision repair to recognize and remove lesions from their cellular DNA. One particular aspect of excision repair, DNA incision, and how it is controlled at the genetic level in bacteriophage, bacteria, S. cerevisae, D. melanogaster, rodent cells and humans is examined. In phage T4, DNA is incised by a DNA glycosylase-AP endonuclease that is coded for by the denV gene. In E. coli, the products of three genes, uvrA, uvrB and uvrC, are required to form the UVRABC excinuclease that cleaves DNA and releases a fragment 12-13 nucleotides long containing the site of damage. In S. cerevisiae, genes complementing five mutants of the RAD3 epistasis group, rad1, rad2, rad3, rad4 and rad10 have been cloned and analyzed. Rodent cells sensitive to a variety of mutagenic agents and deficient in excision repair are being used in molecular studies to identify and clone human repair genes (e.g. ERCC1) capable of complementing mammalian repair defects. Most studies of the human system, however, have been done with cells isolated from patients suffering from the repair defective, cancer-prone disorder, xeroderma pigmentosum, and these cells are now beginning to be characterized at the molecular level. Studies such as these that provide a greater understanding of the genetic basis of DNA repair should also offer new insights into other cellular processes, including genetic recombination, differentiation, mutagenesis, carcinogenesis and aging.

A standardized vector system for manipulation and enhanced expression of genes in Escherichia coli

Different families of cloning and expression vectors were engineered on a standard plasmid. They contain several regulatory signals for transcription and/or translation initiation and termination. The plasmids in each series differ only in the number, type, and order of unique restriction cleavage sites clustered in front of a transcription terminator. The pLK30 plasmids are general cloning vectors and the corresponding pLK50 plasmids carry the lambda pL promoter. The pLK60 vectors carry the lambda pR promoter and translation initiation signals of the cro gene containing the Shine-Dalgarno sequence and initiation codon. The pLK70 series is similar to pLK60 except that additional 5'-translated cro sequences are included. The pLK80 plasmids have a lacZ gene fragment suitable for the construction of hybrid genes. The presence of translational stop signals in the pLK90 series facilitates the manipulation of genes truncated at the 3' end. This standardized pLK vector system offers great versatility in gene manipulation and in optimization of gene expression under the control of strong regulatable promoters. Measurement of expression levels under repressed conditions permits the identification of optimal promoter-gene configurations in constructions directing high-level expression.

The purification of the Escherichia coli UvrABC incision system

The UvrA, UvrB and UvrC proteins of Escherichia coli have been purified in good yields to homogeneity with rapid three- or four-step purification procedures. The cloned uvrA and uvrB genes were placed under control of the E. coli bacteriophage lambda PL promoter for amplification of expression. Expression of the uvrC gene could not be amplified by this strategy, however, subcloning of this gene into the replication-defective plasmid pRLM24 led to significant overproduction of the UvrC protein. The purified UvrA protein, with its associated ATPase activity, has a molecular weight of 114,000, the purified UvrB is an 84,000 molecular weight protein and the UvrC protein has a molecular weight of 67,000.

DNA and amino acid sequence analysis of structural and immunity genes of colicins Ia and Ib

The nucleotide sequences for colicin Ia and colicin Ib structural and immunity genes were determined. The two colicins each consist of 626 amino acid residues. Comparison of the two sequences along their lengths revealed that the two colicins are nearly identical in the N-terminal 426 amino acid residues. The C-terminal 220 amino acid residues of the colicins are only 60% identical, suggesting that this is the region most likely recognized by their cognate immunity proteins. The predicted proteins for the colicin immunity proteins would contain 111 amino acids for the colicin Ia immunity protein and 115 amino acids for the colicin Ib immunity protein. The colicin immunity proteins have no detectable DNA or amino acid homology but do exhibit a conservation of overall hydrophobicity. The colicin immunity genes lie distal to and in opposite orientation to the colicin structural genes. The colicin Ia immunity protein was purified to apparent homogeneity by a combination of isoelectric focusing and preparative sodium dodecyl sulfate-polyacrylamide gel electrophoresis. The N-terminal amino acid sequence of the purified Ia immunity protein was determined and was found to be in perfect agreement with that predicted from the DNA sequence of its structural gene. The Ia immunity protein is not a processed membrane protein.

Large-scale overproduction and rapid purification of the Escherichia coli ssb gene product. Expression of the ssb gene under lambda PL control

We report a rapid procedure for the large-scale purification of the Escherichia coli encoded single-strand binding (SSB) protein, helix-destabilizing protein which is essential for replication, recombination, and repair processes in E. coli. To facilitate the isolation of large quantities of the ssb gene product, we have subcloned the ssb gene into a temperature-inducible expression vector, pPLc28 [Remaut, E., Stanssens, P., & Fiers, W. (1981) Gene 15, 81-93], carrying the bacteriophage lambda PL promoter. A large overproduction of the ssb gene product results upon shifting the temperature of E. coli strains which carry the plasmid and also produce the thermolabile lambda cI857 repressor. After 5 h of induction, the ssb gene product represents approximately 10% of the total cell protein. The overexpression of the ssb gene and the purification protocol reported here enable one to isolate SSB protein (greater than 99% pure) with final yields of approximately 3 mg of SSB protein/g of cell paste. In fact, very pure (greater than 99%) SSB protein can be obtained after approximately 8 h, starting from frozen cells in the absence of any columns, although inclusion of a single-stranded DNA-cellulose column is generally recommended to ensure that the purified SSB protein possesses DNA binding activity. The ability to easily purify 1 g of SSB protein from 300-350 g of induced cells will facilitate physical studies requiring large quantities of this important protein.

Maximizing gene expression from plasmid vectors containing the lambda PL promoter: strategies for overproducing transcription termination factor rho

We have constructed two plasmids in which transcription of the rho gene from Escherichia coli K-12 is under the control of the lambda phage PL promoter. In p31-356, the normal rho promoter is deleted, but the remainder of the rho leader region, including the ribosome binding site, is present. In p39-AS, the rho leader is completely absent, and the lambda cII ribosome binding site replaces that of rho. Under noninducing conditions, expression of rho protein from these plasmids is repressed by the lambda cI protein in hosts carrying lambda cryptic prophage. Induction using mitomycin C or nalidixic acid in a cryptic lysogen carrying the cI+ repressor resulted in the overproduction of rho protein to levels of 3%-5% of the total cellular protein with p31-356, and to levels of approximately equal to 40% with p39-AS. The overproduced protein is functionally indistinguishable from the rho protein isolated from the K-12 strain W3110, and it can be obtained from cells harboring p39-AS in yields of up to 25 mg of rho per g of cells. In contrast to chemical induction, heat induction in four cryptic lambda lysogens carrying the thermolabile cI857 repressor failed to yield the same high levels of rho protein (with either plasmid). Our results show that chemical induction of PL-containing plasmid expression vectors can serve as a convenient and useful alternative to the commonly used method of heat induction.

High-level production of biologically active human alpha 1-antitrypsin in Escherichia coli

A cDNA clone containing the complete human alpha 1-antitrypsin sequence was isolated from a human liver cDNA bank by screening with a chemically synthesized oligonucleotide probe. DNA sequences encoding the alpha 1-antitrypsin mature polypeptide were inserted into an Escherichia coli expression vector that allows transcription from the efficient leftward promoter of bacteriophage lambda (PL) and initiation of translation at the lambda cII gene ribosome-binding site. This construction resulted in the induction of a 45-kilodalton protein at a level of approximately 15% of total cell protein. The polypeptide produced was recognized by antisera raised against human alpha 1-antitrypsin protein and displayed normal biological activity in an in vitro antielastase assay.

Enzymatic properties of purified Escherichia coli uvrABC proteins

The cloned uvrA and uvrB genes of Escherichia coli K-12 were amplified by linkage to the PL promoter of plasmid pKC30. The uvrC gene was amplified in the high-copy-number plasmid pRLM 24. The three gene products (purified in each case to greater than 95% purity) and ATP are required to effectively incise UV-damaged DNAs. The uvrABC proteins bind tightly to damaged sites in DNA, requiring the initial attachment of the uvrA protein in the presence of ATP before productive binding of the uvrB and uvrC proteins. Using a cloned tandem double insert of the lac p-o region as a damaged DNA substrate for the uvrABC complex and analyzing the incision both 5' and 3' to each pyrimidine dimer, we found that one break occurs 7 nucleotides 5' to a pyrimidine dimer and a second break is made 3-4 nucleotides 3' from the same pair of pyrimidines in the dimer. No such breaks are found in the strand complementary to the dimer. The size of the incised fragment in the DNA suggests that incision may be coordinated with excision reactions in repair processes.