Bacterial mutants in which the gene N function of bacteriophage lambda is blocked have an altered RNA polymerase.

Bacterial mutants have been isolated, called groN, that block phage development by interference with the action of the product of the phage N gene. lambdatrp phages, which depend on the N product for the synthesis of tryptophan enzymes, do not make these enzymes in groN bacteria. Two type of phage mutants have been isolated that can overcome the groN block. One type makes an altered N product, the other contains an N-bypass mutation. The groN mutation is closely linked to the rifamycin-resistance locus in Escherichia coli. Purified RNA polymerase from the groN mutant is less activated by salt and more sensitive to rifamycin than is the polymerase from gro(+). This suggests that the groN mutation produces a structural change in the bacterial RNA polymerase such that it can no longer interact properly with the phage N product.

Suppressor system in Bacillus subtilis 168.

Multiple auxotrophic strains of Bacillus subtilis 168 were tested for joint one-step reversion of two or more auxotrophic markers to the wild-type phenotype. Mu8u5u5, a strain requiring leucine, methionine, and threonine, yielded revertants that grew without added methionine or threonine and proved to have a suppressor gene. When transferred by transformation with deoxyribonucleic acid, this suppressor gene also suppressed the adenine mutation in another strain, Mu8u5u6. The one-step double revertants fell into two distinct classes: strains of class su(+) (I) grow well in broth; strains of class su(+) (II) grow poorly. Strains su(+) (II) tend to revert frequently to the su(+) (I) or su(-) state. Conditional lethal mutants of phage phie were isolated which can grow on the su(+) and not on the su(-) strains.

A new bacterial gene (groPC) which affects lambda DNA replication.

A bacterial mutation affecting lambda DNA replication, called groPC756, has been mapped between the thr and leu bacterial loci. Most of the parental lambda DNA does not undergo even one round of replication in this host. Lambda mutants, call pi, which map in the lambda P gene are able to overcome the inhibitory effect of the groPC756 mutation. It is shown that the mutation at the groPC locus also interferes with bacterial growth at 42 degree C. A lambda-transducing phage,carrying the groPC+ allele, was isolated as a plaque-former on groPC756 bacteria. Upon lysogenization, it restores both the gro+ and temperature resistant phenotypes.

Identification of a host protein necessary for bacteriophage morphogenesis (the groE gene product).

Mutations in the groE gene of Escherichia coli, which block the correct assembly of the phage lambda head, have been previously described. Many groE mutations exert pleiotropic effects, such as inability to propagate phages T4 and T5 and inability to form colonies at 43 degrees. With the help of the EcoRI and HindIII restrictionenzymes and the appropriate phage vectors, we have constructed two lambda transducing phages, called W3 and H18, that carry the groE+ bacterial gene. Upon lysogenization by phage H18 the groE bacterial mutants recover their gro+ phenotype for both phage growth and the ability to form colonies at 43 degrees. We have identified the groE+ bacterial gene product as a protein of 65,000 molecular weight. Mutants of the W3 transducing phage that were selected on the basis of their ability to propagate on some groE mutant hosts induce the synthesis of a groE protein with altered electrophoretic mobility.

Induction of the heat shock response of E. coli through stabilization of sigma 32 by the phage lambda cIII protein.

The cIII protein of phage lambda favors the lysogenic response to infection by inhibiting the degradation of the lambda cII protein, which exerts the primary control on the developmental decision for lysis or lysogeny. To study the mechanism and scope of cIII-mediated regulation, we have used plasmid systems to examine the specific effect of cIII overproduction on the growth of Escherichia coli and the synthesis of bacterial proteins. We have found that maximal production of cIII prolongs the heat-induced synthesis of E. coli heat shock proteins and provokes elevated production of heat shock proteins even at low temperature. The overproduction of heat shock proteins is correlated with a rapid inhibition of cell growth, as judged by measurements of optical density. We suggest that an overactive heat shock response inhibits bacterial growth, either because excessive production of one or more of the proteins is highly deleterious or because only heat shock promoters are transcribed efficiently. To examine the effect of cIII on sigma 32, the specificity factor for the heat shock response, we have studied the stability of sigma 32 in cells carrying both cIII- and sigma 32-producing plasmids; the half-life of sigma 32 is increased fourfold in the presence of cIII. We conclude that overproduction of cIII provokes the heat shock response by increasing the steady-state level of active sigma 32. These studies also support the concept that the rate of expression of heat shock proteins is directly correlated with the amount of active sigma 32 and that regulation of the stability of sigma 32 may be an important factor for control of the heat shock response.

Identification of the E. coli dnaJ gene product.

We have previously shown that a mutation (groPC259) in the E. coli dnaJ gene renders the cell inviable at high temperatures and arrests bacteriophage lambda DNA replication at all temperatures (Sunshine et al., 1977). We have isolated lambda dnaJ+ transducing phages both by in vitro cloning and by abnormal excision of a lambda dnaK transducing phage integrated near the dnaJ locus. The dnaJ gene product has been identified on SDS polyacrylamide gels after infection of UV-irradiated E. coli cells by lambda dnaJ+ derivative phages. It is a polypeptide chain with an apparent molecular weight of 37,000-daltons. This has been verified by the fact that a transducing phage carrying an amber mutation in the dnaJ gene fails to induce the synthesis of the 37,000-dalton polypeptide chain upon infection of sup+ bacteria, but does so upon infection of supF or supD bacteria.

Studies on the E. coli groNB (nusB) gene which affects bacteriophage lambda N gene function.

Escherichia coli mutants, called groNB, which block the growth of bacteriophage lambda at the level of action of the gene N product, have been isolated as survivors at 42 degrees C of bacteria carrying a) the defective prophage lambda bio11 i lambda cI857 delta H1 or b) the pcR1 plasmid containing the EcoRI immunity fragment of phage lambda cI857. In addition, groNB bacterial mutants have been isolated at 37 degrees C, as large colony formers in the presence of lambda i lambda cI h434, lambda i lambda cI h lambda, and lambda i lambda cI h80 phage. The groNB locus is located at 9 minute of the E. coli genetic map with the order of the neighboring loci being proC tsx groNB purE. Most groNB mutations isolated at 42 degrees C were found to interfere in addition with bacterial growth at low temperatures, since (a) the GroNB phenotypes of lambda growth inhibition and bacterial cold sensitivity cannot be separated by P1 transduction, and (b) some cold resistant revertants simultaneously become Gro+ for lambda growth. Lambda transducing phages carrying the groNB+ bacterial gene have been isolated. GroNB mutant bacteria lysogenized by the transducing phage acquire the Gro+ phenotype and simultaneously the cold resistant phenotype, suggesting that the groNB mutations are recessive to the wild-type gene.

Genetic analysis of two genes, dnaJ and dnaK, necessary for Escherichia coli and bacteriophage lambda DNA replication.

We show that a collection of 93 E. coli mutations which map between thr and leu and which block phage lambda DNA replication define two closely linked cistrons. Work published in the accompanying paper shows that these mutations also affect host DNA replication, so we designate them dnaJ and dnaK; the gene order is thr--dnaK--dnaJ--leu. Demonstration of two cistrons was possible with the isolation of lambda transducing phages carrying one or the other or both of the dna genes. These phages were employed in phage vs bacterial complementation studies which unambiguously show that dnaK and dnaJ are different cistrons.

Novel bacteriophage lambda mutation affecting lambda head assembly.

A novel phage lambda mutation, called dc10, which interferes with proper lambda head assembly has been isolated and characterized. Phage lambda carrying this mutation is (i) unable to form plaques at 30 or 37 degrees C but does so at 42 degrees C and (ii) unable to form plaques at 42 degrees C on pN-constitutive hosts. Both properties are due to dc10 since all phage revertants for one phenotype simultaneously lose the other phenotype and vice versa. The dc10 mutation has been mapped in the B gene and has been shown to be dominant over the corresponding wild-type product. At 30 degrees C the dc10 mutation results in the formation of abnormal petit lambda heads made up of pE, pB, pC, and pNu3. Under pN-constitutive conditions, the dc10 mutation results in the formation of abnormal petit lambda heads made of pE, X1, and X2 only. A model to explain the data is presented.

Surface changes in differentiating Friend erythroleukemic cells in culture.

The sensitivity to agglutination by several plant lectins has been studied during the induced erythroid differentiation of Friend erythroleukemic cells in culture. In addition, the number of lectin receptors on the cell has been measured. It is shown that early during the differentiation, there is an increase in agglutinability while the receptor density remains constant. In the later phase of the differentiation process, the cells lose their sensitivity to agglutination while the receptor number and density increases. These changes were not observed on nonerythroid mastocytoma culture cells. Two nondifferentiating variants of the FL cells were shown to have altered sensitivities to agglutination by ConA.

Identification of the C. coli dnaK (groPC756) gene product.

The E. coli dnaK (groPC756) gene product is essential for bacteriophage lambda DNA replication. Bacterial DNA segments carrying this gene have been cloned onto a bacteriophage lambda vector. The product of the dnaK gene has been identified on SDS polyacrylamide gels after infection of UV-irradiated E. coli cells. The dnaK gene codes for a polypeptide with an apparent molecular weight of 93,000-Mr. Transducing phages carrying amber mutations in the dnaK gene fail to induce the synthesis of the 93,000-Mr polypeptide chain upon infection of sup+ bacteria, but do so upon infection of supF bacteria. E coli carrying the dnaK756 mutation are, in addition, temperature sensitive for growth at 43 degrees C. It is shown that the dnaK756 mutation results in an overproduction of the dnaK gene product at that temperature.

Homologous plant and bacterial proteins chaperone oligomeric protein assembly.

An abundant chloroplast protein is implicated in the assembly of the oligomeric enzyme ribulose bisphosphate carboxylase-oxygenase, which catalyses photosynthetic CO2-fixation in higher plants. The product of the Escherichia coli groEL gene is essential for cell viability and is required for the assembly of bacteriophage capsids. Sequencing of the groEL gene and the complementary cDNA encoding the chloroplast protein has revealed that these proteins are evolutionary homologues which we term 'chaperonins'. Chaperonins comprise a class of molecular chaperones that are found in chloroplasts, mitochondria and prokaryotes. Assisted post-translational assembly of oligomeric protein structures is emerging as a general cellular phenomenon.