Cloning and expression of the gene(s) for chromosome-mediated beta-lactamase production of Proteus vulgaris in Escherichia coli

The gene(s) for chromosome-mediated beta-lactamase production of Proteus vulgaris GN7919 was cloned into a unique EcoRI site of pACYC184 as an insert of a 14.2-kb fragment, which was further digested into two fragments with EcoRI, 4.9 and 9.3 kb. The restriction enzyme digestion pattern of the recombinant plasmid, designated pMS182, had no similarity to those of other chromosomal beta-lactamase genes cloned from gram-negative bacteria. Plasmid pMS182 enabled host Escherichia coli ML4953 to inducibly produce beta-lactamase which was identical to that of the parent P. vulgaris in substrate profile, molecular weight, and reactivity to antiserum raised against P. vulgaris GN7919 beta-lactamase. The pMS182-harboring E. coli were highly resistant to beta-lactam antibiotics, possibly based on inducible production of beta-lactamase.     

The rtn gene of Proteus vulgaris is actually from Escherichia coli.

The rtn gene, identified as coming from Proteus vulgaris ATCC 13315, is present in Escherichia coli K-12, and over a 440-bp region of rtn is identical to the published Proteus sequence, with the exception of a single G insertion. It was not possible to verify the presence of rtn in P. vulgaris.     

Isolation and analysis of the C-terminal signal directing export of Escherichia coli hemolysin protein across both bacterial membranes.

We have studied the C-terminal signal which directs the complete export of the 1024-amino-acid hemolysin protein (HlyA) of Escherichia coli across both bacterial membranes into the surrounding medium. Isolation and sequencing of homologous hlyA genes from the related bacteria Proteus vulgaris and Morganella morganii revealed high primary sequence divergence in the three HlyA C-termini and highlighted within the extreme terminal 53 amino acids the conservation of three contiguous sequences, a potential 18-amino-acid amphiphilic alpha-helix, a cluster of charged residues, and a weakly hydrophobic terminal sequence rich in hydroxylated residues. Fusion of the C-terminal 53 amino acid sequence to non-exported truncated Hly A directed wild-type export but export was radically reduced following independent disruption or progressive truncation of the three C-terminal features by in-frame deletion and the introduction of translation stop codons within the 3' hlyA sequence. The data indicate that the HlyA C-terminal export signal comprises multiple components and suggest possible analogies with the mitochondrial import signal. Hemolysis assays and immunoblotting confirmed the intracellular accumulation of non-exported HlyA proteins and supported the view that export proceeds without a periplasmic intermediate. Comparison of cytoplasmic and extracellular forms of an independently exported extreme C-terminal 194 residue peptide showed that the signal was not removed during export.     

Cloning and the expression of the hemolysin gene of Leptospira pomona pomona in Escherichia coli

The library of Leptospira pomona genes was obtained on phage vector AL 47.1. From this library a recombinant phage carrying the hemolysin gene was selected. The DNA fragment (7.7 kb) of this phage containing the hemolysin gene was subcloned on plasmid pUC19. E. coli clones with hybrid plasmid pDR7 were shown to be hemolytic, but the secretion of hemolysin by E. coli into the culture medium was not observed.     

Investigation of the instability of plasmids directing the expression of Met-prochymosin in Escherichia coli

The causes of the instability of a multicopy plasmid, pCT70, which directs the expression of calf prochymosin in Escherichia coli, were investigated. Plasmid pAT153 and its derivative, pCT54, were stable for more than 90 generations in continuous culture with glucose limitation. The multicopy plasmid pCT66, which expressed very low levels of prochymosin due to poor translational efficiency, and low copy number plasmids which efficiently expressed the prochymosin gene, were also stable. These results indicated that high level translation of the recombinant gene was the cause of the instability of pCT70. The maximum specific growth rate of E. coli(pCT70) was reduced by 30% compared with E. coli(pCT66). To fulfil the requirements of a production system, a dual origin plasmid with controllable copy number was developed. Both this plasmid (pMG165) and a derivative which contained the prochymosin gene (pMG168) were stable when maintained at low copy number. When the copy number of plasmid pMG168 was increased by putting replication under the control of the lambda PR promoter and the cI857 temperature sensitive repressor, expression of prochymosin was achieved. This strategy enables large-scale production of prochymosin without the need for antibiotic selection or other methods of preventing plasmid loss.     

Transport of hemolysin by Escherichia coli

The hemolytic phenotype in Escherichia coli is determined by four genes. Two (hlyC and hlyA) determine the synthesis of a hemolytically active protein which is transported across the cytoplasmic membrane. The other two genes (hlyBa and hlyBb) encode two proteins which are located in the outer membrane and seem to form a specific transport system for hemolysin across the outer membrane. The primary product of gene hlyA is a protein (protein A) of 106,000 daltons which is nonhemolytic and which is not transported. No signal peptide can be recognized at its N-terminus. In the presence of the hlyC gene product (protein C), the 106,000-dalton protein is processed to the major proteolytic product of 58,000 daltons, which is hemolytically active and is transported across the cytoplasmic membrane. Several other proteolytic fragments of the 106,000-dalton protein are also generated. During the transport of the 58,000-dalton fragment (and possible other proteolytic fragments of hlyA gene product), the C protein remains in the cytoplasm. In the absence of hlyBa and hlyBb the entire hemolytic activity (mainly associated with the 58,000-dalton protein) is located in the periplasm: Studies on the location of hemolysin in hlyBa and hlyBb mutants suggest that the gene product of hlyBa (protein Ba) binds hemolysin and leads it through the outer membrane whereas the gene product of hlyBb (protein Bb) releases hemolysin from the outer membrane. This transport system is specific for E coli hemolysin. Other periplasmic enzymes of E coli and heterologous hemolysin (cereolysin) are not transported.     

Inhibitory action of selenite on Escherichia coli, Proteus vulgaris, and Salmonella thompson

Weiss, K. F. (Iowa State University, Ames), J. C. Ayres, and A. A. Kraft. Inhibitory action of selenite on Escherichia coli, Proteus vulgaris, and Salmonella thompson. J. Bacteriol. 90:857-862. 1965.-The resistance of three microorganisms, Escherichia coli (ISU-41), Proteus vulgaris (ISU-37c), and Salmonella thompson (ISU-86-2), to increasing concentrations of selenite was determined. E. coli was completely inhibited by 1.25% sodium hydrogen selenite, and 0.25% sodium hydrogen selenite caused a pronounced lag. P. vulgaris survived selenite concentrations of over 3%. S. thompson was inhibited completely by 3% selenite but not by 2.5%, although there was a considerable lag and a decrease in total growth. The relationship of growth, uptake, and reduction of selenite was determined. The susceptible E. coli incorporated up to twice as much selenium as did the other two organisms during the early stages of incubation. Radioautographs of seleno analogues of sulfur-containing amino acids revealed the presence of seleno-cystine in all three organisms, and seleno-methionine in E. coli. Compounds having R(F) values corresponding to possible oxidation products of seleno-methionine were present in the hydrolysates of P. vulgaris and S. thompson. Kinetic aspects of selenite uptake, rather than the ultimate localization of selenite in the cell protein, appear to be the factors that determine the degree of resistance or of susceptibility to selenite.     

Analysis of the in vivo activation of hemolysin (HlyA) from Escherichia coli.

Hemolysin (HlyA) from Escherichia coli containing the hlyCABD operon separated from the nonhemolytic pro-HlyA upon two-dimensional (2-D) polyacrylamide gel electrophoresis. The migration distance indicated a net loss of two positive charges in HlyA as a result of the HlyC-mediated activation (modification). HlyA activated in vitro in the presence of [U-14C]palmitoyl-acyl carrier protein comigrated with in vivo-activated hemolysin on 2-D gels and was specifically labelled, in agreement with the assumption that the activation is accomplished in vitro and in vivo by covalent fatty acid acylation. The in vivo-modified amino acid residues were identified by peptide mapping and 2-D polyacrylamide gel electrophoresis of mutant and truncated HlyA derivatives, synthesized in E. coli in the presence and absence of HlyC. These analyses indicated that the internal residues Lys-564 and Lys-690 of HlyA, which have recently been shown by others to be fatty acid acylated by HlyC in vitro, are also the only modification sites in vivo. HlyA activated in E. coli was quantitatively fatty acid acylated at both sites, and the double modification was required for wild-type hemolytic activity. Single modifications in mutant and truncated HlyA derivatives suggested that both lysine residues are independently fatty acid acylated by a mechanism requiring additional sequences or structures flanking the corresponding acylation site. The intact repeat domain of HlyA was not required for the activation. The pore-forming activities of pro-HlyA and singly modified HlyA mutants in planar lipid bilayer membranes suggested that the activation is not essential for transmembrane pore formation but rather required for efficient binding of the toxin to target membranes.     

Identification of the Serratia marcescens hemolysin determinant by cloning into Escherichia coli.

A cosmid bank of Serratia marcescens was established from which DNA fragments were cloned into the plasmid pBR322, which conferred the chromosomally encoded hemolytic activity to Escherichia coli K-12. By transposon mutagenesis with Tn1000 and Tn5 IS50L::phoA (TnphoA), the coding region was assigned to a DNA fragment, designated hly, comprising approximately 7 kilobases. Two proteins with molecular weights of 61,000 (61K protein) and 160,000 (160K protein) were expressed by the pBR322 derivatives and by a plasmid which contained the hly genes under the control of a phage T7 promoter and the T7 RNA polymerase. When strongly overexpressed the 160K protein was released by E. coli cells into the extracellular medium concomitant with hemolytic activity. The genes encoding the 61K and the 160K proteins were transcribed in the same direction. Mutants expressing a 160K protein truncated at the carboxy-terminal end were partially hemolytic. Hemolysis was progressively inhibited by saccharides with increasing molecular weights from maltotriose (Mr 504) to maltoheptaose (Mr 1,152) and was totally abolished by dextran 4 (Mr 4,000). This result and the observed influx of [14C]sucrose into erythrocytes in the presence of hemolytic E. coli transformants under osmotically protective conditions suggest the formation of defined transmembrane channels by the hemolysin.     

DNA sequence analysis of the recA genes from Proteus vulgaris, Erwinia carotovora, Shigella flexneri and Escherichia coli B/r

Summary The complete nucleotide sequences of therecA genes fromEscherichia coli B/r,Shigella flexneri, Erwinia carotovora andProteus vulgaris were determined. The DNA sequence of the coding region of theE. coli B/r gene contained a single nucleotide change compared with theE. coli K12 gene sequence whereas theS. flexneri gene differed at 7 residues. In both cases, the predicted proteins were identical in primary structure to theE. coli K12 RecA protein. The DNA sequences of the recA genes fromE. carotovora andP. vulgaris were 80% and 74% homologous, respectively, to theE. coli K12 gene. The predicted amino acid sequences of theE. carotovora andP. vulgaris RecA proteins were 91% and 85% identical respectively, to that ofE. coli K12. The RecA proteins from bothP. vulgaris andE. carotovora diverged significantly in sequence in the last 50 residues whereas they showed striking conservation throughout the first 300 amino acids which include an ATP-binding region and a subunit interaction domain. A putative LexA repressor binding site was localized upstream of each of the heterologous genes.     

Cloning and characterization of recA genes froM Proteus vulgaris, Erwinia carotovora, Shigella flexneri, and Escherichia coli B/r

The recA genes of Proteus vulgaris, Erwinia carotovora, Shigella flexneri and Escherichia coli B/r have been isolated and introduced into Escherichia coli K-12. All the heterologous genes restore resistance to killing by UV irradiation and the mutagen 4-nitroquinoline-1-oxide in RecA- E. coli K-12 hosts. Recombination proficiency is also restored as measured by formation of Lac+ recombinants from duplicated mutant lacZ genes and the ability to propagate phage lambda derivatives requiring host recombination functions for growth (Fec-). The cloned heterologous genes increase the spontaneous induction of lambda prophage in lysogens of a recA strain. Addition of mitomycin C stimulates phage production in cells carrying the E. coli B/r and S. flexneri recA genes, but little or no stimulation is seen in cells carrying the E. carotovora and P. vulgaris recA genes. After treatment with nalidixic acid, the heterologous RecA proteins are synthesized at elevated levels, a result consistent with their regulation by the E. coli K-12 LexA repressor. Southern hybridization and preliminary restriction analysis indicate divergence among the coding sequences, but antibodies prepared against the E. coli K-12 RecA protein cross-react with the heterologous enzymes, indicating structural conservation among these proteins.