Effect of bacteriophage lambda infection on synthesis of groE protein and other Escherichia coli proteins.

We used two-dimensional gel electrophoresis to quantitate the changes in rates of synthesis that follow phage lambda infection for 21 Escherichia coli proteins, including groE and dnaK proteins. Although total protein synthesis and the rates of synthesis of most individual E. coli proteins decreased after infection, some proteins, including groE protein, dnaK protein, and stringent starvation protein, showed increases to rates substantially above their preinfection rates. Infection by lambda Q- affected host synthesis in the same way as infection by gamma+, whereas infection by lambda N- showed no detectable effect on host synthesis. Deletion of the early genes between att and N abolished the effect, and shorter deletions in this region gave intermediate effects. By this sort of deletion mapping, we show that a large part, though not all, of the effect of lambda infection on host protein synthesis can be ascribed to the early region that contains phage genes Ea10 and ral. We compared the changes in protein synthesis after infection with the changes that occur in uninfected cells upon heat shock or amino acid starvation. The spectrum of changes that occurred on infection was very different from that seen after heat shock but quite similar to that seen during amino acid starvation. Despite this similarity of the effects of lambda infection and starvation, we did not detect any increase in the level of guanosine tetraphosphate during infection. We show that the groE protein is the same protein as B56.5 of Lemaux et al. (Cell 13:427-434, 1978) and A protein of Subramanian et al. (Eur. J. Biochem. 67:591-601, 1976).     

Rec-Mediated Recombinational Hot Spot Activity in Bacteriophage Lambda. I. Hot Spot Activity Associated with Spi- Deletions and bio Substitutions

In order to survey the distribution along the bacteriophage lambda chromosome of Rec-mediated recombination events, crosses are performed using conditions which block essentially all DNA synthesis. One parent is density-labeled and carries a genetic marker in the left terminal lambda gene (A), while the other parent is unlabeled and carries a genetic marker in the right terminal lambda gene (R). Both parents are deleted for the lambda recombination genes int and red, together with other recombination-associated genes, by virtue of either (1) a pure deletion or (2) a bio insertion-deletion. The distribution in a cesium density gradient of the resulting A+R+ recombinant phage reflects the chromosomal distribution of the recombination events which gave rise to those phage.Crosses employing either of two different pure deletion phage strains exhibit recombinational hot spot activity located near the right end of the lambda chromosome, between the cI and R genes. This hot spot activity persists when unlimited DNA synthesis is allowed. Crosses employing bio1-substituted phage strains exhibit recombinational hot spot activity located to the right of the middle of the chromosome and to the left of the cI gene. Crosses employing either bio1 or bio69-substituted phage strains indicate that the bio-associated hot spot activity occurs in the presence of DNA synthesis, but is dependent on a functional host recB gene.     

Isolation of Lambda Transducing Phage with the bio Genes Inserted between Lambda Genes P and Q

Plaque-forming, biotin-transducing phages were constructed with the bio genes inserted between lambda genes P and Q. These phages were isolated for the eventual aim of fusing the lambda Q gene to the bio operon. The following steps were used to construct these phages: A defective temperature-sensitive lysogen was constructed with the bio genes adjacent to and to the left of lambda genes beta NcI857OPQSRA. Heat-resistant survivors were screened for deletions with endpoints in the bio operon and to the right of lambda P and to the left of lambda A. Five of approximately 1,600 heat-resistant survivors had these properties. Two had the gene order bioAB .... lambda QSRA. When these two strains were lysogenized with lambda cI857b221 and heat induced, the desired transducing phages were obtained. We characterized these phages and studied one in detail. Two-thirds of the plaque-forming transducing phages isolated carried the entire bioB gene and only part of the bioA gene, and one-third carried the entire bioA and bioB genes. The phages isolated lost the bio genes upon propagation, indicating that they contain a partial duplication of phage genes. The duplication was shown not to involve the entire lambda Q gene in one of these phages, lambda bioq1b221. A recombinant of this phage, lambda Nam7am53c17b221, failed to form plaques under biotin-derepression conditions. We conclude that if the lambda Q gene was fused to the bio operon in this phage, not enough lambda Q gene product was made to allow phage propagation.     

Multicopy suppression of cold-sensitive sec mutations in Escherichia coli.

Mutations in the secretory (sec) genes in Escherichia coli compromise protein translocation across the inner membrane and often confer conditional-lethal phenotypes. We have found that overproduction of the chaperonins GroES and GroEL from a multicopy plasmid suppresses a wide array of cold-sensitive sec mutations in E. coli. Suppression is accompanied by a stimulation of precursor protein translocation. This multicopy suppression does not bypass the Sec pathway because a deletion of secE is not suppressed under these conditions. Surprisingly, progressive deletion of the groE operon does not completely abolish the ability to suppress, indicating that the multicopy suppression of cold-sensitive sec mutations is not dependent on a functional groE operon. Indeed, overproduction of proteins unrelated to the process of protein export suppresses the secE501 cold-sensitive mutation, suggesting that protein overproduction, in and of itself, can confer mutations which compromise protein synthesis and the observation that low levels of protein synthesis inhibitors can suppress as well. In all cases, the mechanism of suppression is unrelated to the process of protein export. We suggest that the multicopy plasmids also suppress the sec mutations by compromising protein synthesis.     

Phylogenetical relationship based on groE genes among phenotypically related Enterobacter,Pantoea, Klebsiella,Serratia and Erwinia species

In an attempt to define the phylogenetical relationship among 17 phenotypically related species of genera Enterobacter, Pantoea, Serratia, Klebsiella and Erwinia, we determined almost all of their groE operon sequences using the polymerase chain reaction direct sequencing method. The number of nucleotide substitutions per site was 0.12+/-0.030. The value was 3.6-fold higher than that of 16S rDNA. As a result, we were successful in constructing molecular phylogenetic trees which had a finer resolution than that based on the 16S rDNA sequences. The phylogenetic trees based on the nucleotide sequences and deduced amino acid sequences of groE operons indicated that the members of genera Enterobacter, Pantoea and Klebsiella were closely related to each other, while Serratia and Erwinia species except Erwinia carotovora, made distinct clades. The close relationship between Enterobacter aerogenes and Klebsiella pneumoniae, that had been suggested by biochemical tests and DNA hybridization, was also supported by our molecular phylogenetic trees.     

Thermoresistant revertants of an Escherichia coli strain carrying tif-1 and ruv mutations: non-suppressibility of ruv by sfi.

Spontaneous thermoresistant revertants were isolated from Tif1 Ruv- and Tif1 Ruv+ strains of Escherichia coli K-12. They were divided into five groups; backmutants to tif+ and recA structural gene mutants accounted for at least two of these groups. Mutations with an unconditional RecA- phenyotype were detected at a higher frequency in the Tif1 Ruv- strains (65%) than in the Tif1 Ruv+ strains (25%). A third group consisted of revertants exhibiting a RecA- phenotype at low temperature. Revertants with normal recombination ability and UV resistance, but with a thermosensitive defect in propagating lambda bio11 phage, were also isolated (group 4). The alleles responsible for this property were cotransducible with the srl gene, suggesting that they are located at the recA locus. Other revertants, which might carry lex, LEXB, or zab mutations, were UV sensitive and were able to propagate lambda bio11 phage (group 5). The sfi mutation, which suppresses filamentation in the Tif1 and UV-sensitive Lon- strains, does not restore UV resistance of the Ruv- mutant.     

Purification and properties of the groES morphogenetic protein of Escherichia coli

The morphogenesis of lambda proheads is governed by the products of at least four bacteriophage-coded genes (B, C, E and Nu3) and two host-coded genes (groES (mopB) and groEL (mopA)). Earlier genetic experiments indicated that the phenotypes of some of the groES- mutations could be suppressed by mutations in the groEL gene, suggesting an interaction between the two groE proteins in vivo (Tilly, K., and Georgopoulos, C. P. (1982) J. Bacteriol. 149, 1082-1088). The Mr 15,000 groES protein was overproduced and purified to homogeneity by monitoring its presence after polyacrylamide gel electrophoresis. Both gel filtration on an AcA34 sizing column and glycerol gradient centrifugation indicate that the groES protein possesses an oligomeric structure of Mr 80,000. In agreement, electron microscopic pictures of the purified groES protein show that it possesses a symmetrical ring-like structure. The sequence of the first five amino acids and the overall composition of the purified protein match those predicted by the nucleotide sequence of the groES gene. The following results implicate a physical association between the groES and groEL proteins in vitro. The groES protein inhibits the weak ATPase activity of the groEL protein, with a maximal effect seen at a 1:1 molar ratio; the two proteins cosediment during glycerol gradient centrifugation in the presence of ATP and Mg2+; and the groES protein binds specifically to a groEL-affinity column. These results help explain why mutations in either of the groE genes exhibit similar phenotypes with respect to both lambda and bacterial growth.     

A physical map of the bioAB region in the lambda bio transducing phage

The center of the pBopA promoter-operator region for the bioABFCD operon is located 1.71 kb clockwise from the att lambda site on the Escherichia coli genome, as determined by the position of the p131 (IS1) insertion. The order of several bio endpoints to the right of p131 is lambda bio267, 122, 169, 74, 1, and 69. The endpoints of the two bio deletions, delta 61 in bioA and delta 3h in bioB, were also determined.     

The groES and groEL heat shock gene products of Escherichia coli are essential for bacterial growth at all temperatures.

The products of the groES and groEL genes of Escherichia coli, constituting the groE operon, are known to be required for growth at high temperature (42 degrees C) and are members of the heat shock regulon. Using a genetic approach, we examined the requirement for these gene products for bacterial growth at low temperature (17 to 30 degrees C). To do this, we constructed various groES groEL heterodiploid derivative strains. By inactivating one of the groE operons by a polar insertion, it was shown by bacteriophage P1 transduction that at least one of the groE genes was essential for growth at low temperature. Further P1 transduction experiments with strains that were heterodiploid for only one of the groE genes demonstrated that both groE gene products were required for growth at low temperature, which suggested a fundamental role for the groE proteins in E. coli growth and physiology.     

Stimulation of mutations suppressing the loss of replication control by small alcohols

Transient exposure of lysogenic Escherichia coli cells to small alcohols stimulated the frequency of mutations suppressing the lethal loss of replication control from a prophage fragment of bacteriophage lambda. The stimulation in mutation frequency paralleled the effect of mutagenic agents, and in this sense the alcohols behaved as mutagens. 10-min treatments above distinct threshold concentrations at 23%, 18%, 10% and 4% (v/v) were required in order for methanol, ethanol, isopropanol and propanol to evoke mutagenic effects. The selected mutant cells were, in general, equally or more sensitive to ethanol than the starting cells. The mutagenicity of methanol and ethanol was detected only with E. coli strains with lambda fragments that included the site-specific and general recombination genes found within the phage int-kil gene interval; whereas, stimulation of the frequency of phenotypically identical mutations by nitrosoguanidine or ionizing radiation did not require that the lambda fragment encode these genes. Treatments of lysogenic cells with mutagenic concentrations of ethanol did not trigger prophage induction and were concluded not to induce a cellular SOS response nor to denature the prophage repressor, or to disrupt repressor-operator binding. The toxicity of ethanol was pH-dependent. Cellular sensitivity to ethanol toxicity was unaffected by the integrated lambda fragment(s) or by an intact lambda prophage; but, it was increased by deletions of the E. coli chromosome extending rightward from bio into uvrB, and rightward from chlA.     

Cloning and location of a gene governing lysine epsilon-aminotransferase, an enzyme initiating beta-lactam biosynthesis in Streptomyces spp.

In actinomycetes that produce beta-lactam antibiotics of the cephem type, lysine epsilon-aminotransferase is the initial enzyme in the conversion of lysine to alpha-aminoadipic acid. We used a two-stage process ("chromosome walking") to screen a lambda library of Streptomyces clavuligerus genomic DNA for fragments that expressed lysine epsilon-aminotransferase activity in S. lividans. Restriction analysis of the cloned DNA confirmed the location of the putative lat gene within the cluster of beta-lactam biosynthesis genes, roughly midway between pcbC, the structural gene for isopenicillin N synthetase, and the putative cefE gene encoding deacetoxycephalosporin C synthetase.     

Interaction of the heat shock protein GroEL of Escherichia coli with single-stranded DNA-binding protein: suppression of ssb-113 by groEL46.

Previous studies from our laboratory have shown that an allele of the heat shock protein GroEL (groEL411) is able to specifically suppress some of the physiological defects of the single-stranded DNA-binding protein mutation ssb-1. A search for additional alleles of the groE genes which may act as suppressors for ssb mutations has led to the identification of groEL46 as a specific suppressor of ssb-113. It has very little or no effect on ssb-1 or ssb-3. All of the physiological defects of ssb-113, including temperature-sensitive growth, temperature-sensitive DNA synthesis, sensitivity to UV irradiation, methyl methanesulfonate, and bleomycin, and reduced recombinational capacity, are restored to wild-type levels. The ssb-113 allele, however, is unable to restore sensitivity of groEL46 cells to phage lambda. The mechanism of suppression of ssb-113 by groEL46 appears to differ from that of ssb-1 by groEL411. The data suggest that GroEL may interact with single-stranded DNA-binding protein in more than one domain.     

DNA polymerase lambda can elongate on DNA substrates mimicking non-homologous end joining and interact with XRCC4-ligase IV complex

Non-homologous end joining (NHEJ) is one of two pathways responsible for the repair of double-strand breaks in eukaryotic cells. The mechanism involves the alignment of broken DNA ends with minimal homology, fill in of short gaps by DNA polymerase(s), and ligation by XRCC4-DNA ligase IV complex. The gap-filling polymerase has not yet been positively identified, but recent biochemical studies have implicated DNA polymerase lambda (pol lambda), a novel DNA polymerase that has been assigned to the pol X family, in this process. Here we demonstrate that purified pol lambda can efficiently catalyze gap-filling synthesis on DNA substrates mimicking NHEJ. By designing two truncated forms of pol lambda, we also show that the unique proline-rich region in pol lambda plays a role in limiting strand displacement synthesis, a feature that may help its participation in in vivo NHEJ. Moreover, pol lambda interacts with XRCC4-DNA ligase IV via its N-terminal BRCT domain and the interaction stimulates the DNA synthesis activity of pol lambda. Taken together, these data strongly support that pol lambda functions in DNA polymerization events during NHEJ.     

Stability of coliphage lambda DNA replication initiator, the lambda O protein.

The initiator of coliphage lambda DNA replication, lambda O protein, may be detected among other 35S-labeled phage and bacterial proteins by a method based on immunoprecipitation. This method makes it possible to study lambda O proteolytic degradation in lambda plasmid-harboring or lambda phage-infected cells; it avoids ultraviolet (u.v.)-irradiation of bacteria, used for depression of host protein synthesis, prior to lambda phage infection. We confirm the rapid decay of lambda O protein (half-time of 80 s), but we demonstrate the existence of a stable lambda O fraction. In the standard five minute pulse-chase experiments, 20% of synthesized lambda O is stable. The extension of the [35S]methionine pulse, possible in lambda plasmid-harboring cells, leads to a linear increase of this fraction, as if a part of the synthesized lambda O was constantly made resistant to proteolysis. Less than 5% of lambda O protein synthesized during one minute is transformed into a stable form. We presume that the stable lambda O is identical with lambda O present in the normal replication complex and thus protected from proteases. We cannot find any stable lambda O in Escherichia coli recA+ cells that were irradiated with u.v. light prior to lambda phage infection, but their recA- counterparts behave normally, suggesting that recA function interferes in the assembly of a normal replication complex in u.v.-irradiated bacteria. The stable lambda O found in lambda plasmid-harboring, amino acid-starved relA cells is responsible for the lambda O-dependent lambda plasmid replication that occurs in this system in the absence of lambda O synthesis. The existence of stable lambda O raises doubt concerning its role as the limiting initiator protein in the control of replication. Another significance of lambda O rapid degradation is proposed.