Suppression of the lexC (ssbA) mutation of Escherichia coli by a mutant of bacteriophage P1

Summary A new mutant of bacteriophage P1 designated lxc that suppresses the phenotype of lexC and ssbA mutants of Escherichia coli was isolated and characterized. The properties of lexC mutants suppressed by the lxc mutation include temperature sensitive growth at 42° C, sensitivity to ultraviolet light and alkylating agents, and a nonmutagenic response following exposure to ultraviolet irradiation. A bac mutant of bacteriophage P1 that suppresses the temperature sensitivity of dnaB mutants does not affect the phenotype of lexC or ssbA mutants. Neither the lxc or bac mutations affect the ultraviolet light sensitivity of strains with the mutations uvrA155, lexA102, or recA56.     

ThegrpD55 locus ofEscherichia coli appears to be an allele ofdnaB

Attempts to characterize thegrpD55 mutation ofEscherichia coli have led us to conclude that the gene had been assigned an incorrect map position. The mutation was found to cotransduce withmalF3089:: Tn10 (at 91.5 min) and adnaB-expressing plasmid was able to complement fully thegrpD55 defect in replication. These studies strongly suggest thatgrpD55 is an allele ofdnaB and is localized near 92 min on theE. coli linkage map.     

Initiation of DNA replication in Escherichia coli: RNase H-deficient mutants do not require the dnaA function

Summary A series of temperature-resistant revertants were isolated from strains of Escherichia coli K12 carrying a temperature-sensitive mutation in the dnaA gene. Four independent revertants were found which still carry the original ts mutation. The ability of these strains to grow at high temperature is due to a suppressor mutation, called sin. All four sin mutations are located between the genes metD and proA on the genetic map of E. coli, which suggests that they all affect the same gene. The sin suppressors, which were isolated for their ability to suppress one dnaA mutation, are also able to suppress three other temperature-sensitive dnaA mutations, but they are not able to suppress mutations in either of the two genes dnaB or dnaC. The sin suppressors alone do not confer any particular phenotype on bacteria, but they are deficient in the enzyme RNase H. On the basis of these findings we propose that the function of the dnaA protein is to protect a DNA-RNA hybrid at the origin of replication against RNase H.     

A dnaB analog function specified by bacteriophage P7 and its comparison to the similar function specified by bacteriophage P1

Summary Evidence is presented that bacteriophage P7 specifies an analog of the E. coli DNA replication protein, dnaB. As in the related bacteriophage P1 (D'Ari et al., 1975; Ogawa, 1975), in lysogens of P7, the production of the analog protein is repressed and constitutive mutants could be isolated. Such constitutive of several dnaB(ts) mutations and also rescue a strain carrying a dnaB amber mutation. While neither P7 nor the mutant P1bacban (defective in the structural gene ban) could suppress dnaB(ts) mutations efficiently, recombinants between these two phages could do so, indicating the presence of a functional dnaB analog gene (called sdb) on P7. In a dnaB amber strain suppressed by the presence of the constitutive mutant P7csb, bacteriophage failed to replicate which is a further similarity between P7 and P1. P7csb mutants or P7-P1bacban recombinants were found to be less thermoresistant than P1bac1 suggesting that the P7-specified dnaB analog protein or its production is relatively less tolerant of temperatures above 37°C.     

Localization of the structural gene for ribosomal protein L19 (rplS) in Escherichia coli

Summary A temperature-sensitive mutant derived from an E. coli K12 strain, PA3092, was found to have an alteration in the ribosomal protein L19 (Isono et al., 1977). This mutant is a double mutant with a temperature-sensitivity mutation and a mutation leading to the structural alteration of L19 protein. Crosses with various Hfr strains and transductions with P1kc have revealed that the latter mutation maps at 56.4 min, between pheA and alaS. From the fact that two other mutations causing different types of alterations in L19 protein also map at this locus, the gene affected by these mutations was concluded to be the structural gene for the ribosomal protein L19 (rplS).     

Genetic analysis of the dnaB region of Escherichia coli K-12: The identification of a recombinational hot spot

Summary The insertion of an F into the malB-dnaB-ampA region of Escherichia coli K-12 was examined. It was found that insertion occurred preferentially at a site within the dnaB gene. The presence of mutations in this gene did not seem to alter the site of F insertion but in some cases did affect the frequency at which this recombinational event took place. The map position of various dnaB alleles relative to this site was determined and compared with the allele order obtained by P1 transduction. Models to explain the nonrandom pattern of insertion are discussed.     

Escherichia coli mutants temperature-sensitive for DNA synthesis

Summary A series of mutants of E. coli temperature-sensitive for DNA synthesis has been studied. The temperature-sensitive DNA mutations map in seven distinct genetic loci most of which have not been previously reported. Mutations in dnaA and in dnaC affect the initiation of DNA replication; those at the remaining loci affect chain elongation. A temperature-sensitive Flac is shown to suppress a group A mutant with somewhat less efficiency than other F factors previously reported by others. The gene products rendered temperaturesensitive by the mutations have not been identified for any of the loci.     

Increased spontaneous mutation rates in mutants of E. coli with altered DNA polymerase III

Summary Two temperature-sensitive mutants in dnaE, the structural gene for DNA polymerase III of Escherichia coli, show increased spontaneous mutation rates at permissive temperatures. Studies of the reversion of well-characterized trpA mutations in dnaE strains show that the mutagenic effect of altered DNA polymerase III applies to several different base substitution events, but not to frameshifts. The results suggest that DNA polymerase III is involved in base-selection during DNA replication.MRC Molecular Genetics Unit     

A dnaB analog specified by bacteriophage P1

Bacteriophage P1 is shown to determine a product that can substitute in DNA replication for the protein specified by cistron dnaB of Escherichia coli. The viral dnaB analog (ban) is repressed in the wild-type P1 prophage and expressed constitutively in plaque-forming mutants, P1bac, described here. A particular P1bac prophage allows lysogens of dnaBts bacteria to survive as colony-formers at temperatures that arrest DNA synthesis in the non-lysogens. The P1bac prophage furthermore permits construction of an otherwise inviable strain bearing the unsuppressed amber mutation dnaB266.P1bac prophages also suppress the groP character which is associated with certain dnaB mutations. The subclass of dnaB mutations called groP are those which prevent the growth of bacteriophage λ⁺ at temperatures permissive for bacterial DNA synthesis, but allow the growth of certain λ mutants (λπ); π mutations have been mapped in gene P. Thus, λ⁺ is enabled to grow in groP hosts by the presence of P1bac-1 prophage. When dnaB protein is absent, however, as in the case of the unsuppressed amber mutant, the ban protein furnished by the P1bac prophage does not support λ growth. Therefore, in the groP(P1bac-1) lysogens both the dnaB and ban products are needed for λ growth, suggesting interactions between these E. coli and P1 proteins or their subunits.Mutations (termed ban) that prevent the expression of the dnaB analog determined by P1 have been obtained. P1bac-1ban-1, unlike P1bac-1, fails to replicate in dnaBts hosts at temperatures non-permissive for bacterial DNA synthesis. Thus, the dnaB protein and its P1-determined analog can interchangeably fulfill an essential role in the replication of both the E. coli and P1 replicons. At permissive temperatures the lysogenization of certain dnaBts strains by P1bac-1ban-1 is very inefficient, probably as a result of negative complementation.Mutations bac-1 and ban-1 are closely linked on the P1 chromosome and their order relative to several amber mutations has been determined. Dominance studies of the alleles in transient diploids show that the ban-1 mutation is recessive to ban⁺. The bac-1 mutation, on the other hand, behaves in dominance tests as a DNA site mutation that permits constitutive expression in cis of the operon to which the ban gene belongs.     

TFS1: A suppressor of cdc25 mutations in Saccharomyces cerevisiae

Summary The TFS1 gene of Saccharomyces cerevisiae is a dosage-dependent suppressor of cdc25 mutations. Overexpression of TFS1 does not alleviate defects of temperature-sensitive adenylyl cyclase (cdc35) or ras2 disruption mutations. The ability of TFS1 to suppress cdc25 is allele specific: the temperature-sensitive cdc25-1 mutation is suppressed efficiently but the cdc25-5 mutation and two disruption mutations are only partially suppressed. TFS1 maps to a previously undefined locus on chromosome XII between RDN1 and CDC42. The DNA sequence of TFS1 contains a single long open reading frame encoding a 219 amino acid polypeptide that is similar in sequence to two mammalian brain proteins. Insertion and deletion mutations in TFS1 are haploviable, indicating that TFS1 is not essential for growth.     

ore2, a mutation affecting proline biosynthesis in the yeast Saccharomyces cerevisiae, leads to a cdc phenotype

Summary We report here the isolation of temperature-sensitive mutants of the yeast Saccharomyces cerevisiae which exhibit cdc phenotypes. The recessive mutations defined four complementation groups, named ore1, ore2, ore3 and ore4. At the non-permissive temperature, strains bearing these mutations arrested in the G1 phase of the cell cycle. The wild-type allele of the gene altered in ore2 mutants was cloned. The nucleotide sequence of a fragment which can complement the mutation showed the presence of an open reading frame capable of encoding a protein with 286 amino acid residues. The deduced amino acid sequence showed 25% identity with that of the Escherichia coli 1-pyrroline-5-carboxylate reductase, an enzyme of the pathway for the biosynthesis of proline. The ore2 mutants, correspondingly, were found to be capable of growing at the non-permissive temperature on a synthetic medium supplemented with proline. In addition, the chromosomal location of the gene and its restriction map were compatible with those previously reported for the PRO3 gene which encodes the S. cerevisiae ¹-pyrroline-5-carboxylate reductase.     

Insertional disruption of the nusB (ssyB) gene leads to cold-sensitive growth of Escherichia coli and suppression of the secY24 mutation

Summary The Escherichia coli gene ssyB was cloned and sequenced. The ssyB63 (Cs) mutation is an insertion mutation in nusB, while the nusB5 (Cs) mutation suppresses secY24, indicating that inactivation of nusB causes cold-sensitive cell growth as well as phenotypic suppression of secY24. The correct map position of nusB is 9.5 min rather than I I min as previously assigned. It is located at the distal end of an operon that contains a gene showing significant homology with a Bacillus subtilis gene involved in riboflavin biosynthesis.     

A dnaB analog ban, specified by bacteriophage P1: genetic and physiological evidence for functional analogy and interactions between the two products.

Summary Bacteriophage P1 has been shown previously to determine a product ban than can substitute in DNA replication for the protein specified by cistron dnaB of Escherichia coli. However, ban product furnished by P1 bac prophage (ban constitutive) substitutes only poorly for DNA replication in the absence of dnaB product in a strain bearing an unsuppressed amber mutation, dnaB266, as shown by the cryosensitivity of the dnaB266 (P1 bac) lysogen and its unability to support growth. An additional mutation (termed crr) in the P1 bac prophage has been obtained which confers cryoresistance to the sup ⁺ dnaB266 (P1 bac crr) lysogen and restores its ability to support growth. ban product produced in P1 bac crr lysogen fulfills all dnaB roles in vivo, especially in the various instances in which ban product expressed in P1 bac lysogens does not. The ban product is expressed constitutively in P1 crr prophage. The crr-1 mutation is tightly linked to the bac-1 and ban-1 mutations and is dominant over crr ⁺. The nature of the crr mutation is discussed: two hypotheses are considered, that of a mutation in the ban gene rendering the ban product more active or that of a site mutation in the ban operon increasing the level of ban expression. Expression of ban product (wild type or altered) leads to interactions with the variously altered dnaB product. Both positive and negative interactions are described. Genetic results presented here suggest that ban and dnaB subunits interact to form hybrid dnaB-like molecules; the average composition of which depends on the relative quantities of ban and dnaB subunits in the cell.     

Cloning of the excC and excD genes involved in the release of periplasmic proteins by Escherichia coli K12

Summary Strains of Escherichia coli K12 carrying a tolA, tolB, lky or exc mutation located at min 16.5 on the genetic map released periplasmic proteins into the extracellular medium. Wild-type genes defined by these mutations have been cloned from E. coli genomic bank made with plasmid pBR328. Subcloning experiments and complementation studies showed that lky and exc mutations were located either in the previously described tolA and tolB genes or in the newly characterized excC and excD genes. Using minicells, excC and excD gene products were identified as proteins with a molecular mass of 19 and 21 kDa, respectively.     

Isolation and characterization of a temperature-sensitive amber suppressor mutant of Escherichia coli K12

Summary By mutagenizing an E. coli strain carrying an amber suppressor supD ^- (or su _I ⁺), we isolated a mutant whose amber suppressor activity was now temperature-sensitive. The mutant suppressor gene was named sup-126, which was found to be cotransduced with the his gene by phage P1vir at the frequency of ca. 20%. At 30° C it suppresses many amber mutations of E. coli, phage T4, and phage . At 42° C, however, it can suppress none of over 30 amber mutations tested so far. The sup-126 mutation is unambiguous and stable enough to be useful for making production of an amber protein temperature-sensitive.     

Analysis of the dnaB function of Escherichia coli K12 and the dnaB-like function of P1 prophage

The dnaB function of Escherichia coli K12 was studied with a series of isogenic strains differing from each other only by a mutation in the dnaB gene. The strains showed different phenotypes depending on the particular dnaB mutation they carry. A clear example is provided by a strain carrying dnaB266 mutation which turned out to be an amber mutation. When the mutation was suppressed by different suppressors, the strains showed different phenotypes. Thus, dnaB proteins which differ from each other by only one amino acid at the mutation site give different phenotypes. Mutation dnaB266 is lethal to the host when not suppressed. Hence the dnaB protein is essential for bacterial growth.Three P1 mutants, P1mcb-4, P1mcb-5 and P1mcb-8, were isolated which converted the temperature-sensitive bacterial growth of dnaB266-supE to resistant growth. Lysogenization with P1mcb allowed growth of dnaB266su⁻ strain which was absolutely defective in the bacterial dnaB function, indicating that the dnaB-like function of P1 prophage can substitute for the bacterial dnaB function. However, lysogenization by P1mcb did not support the growth of λ and λπ phages on dnaB 266su⁻. While P1mcb-4 and P1mcb-5 prophages altered the phenotypes of other dnaB strains to permit the growth of bacterial and λ phage at 32 °C and 42 °C, P1mcb-8 prophage supports the growth of λ phages and bacteria at 42 °C but not λ phage growth on groP-bacteria at 32 °C. The alteration of phenotypes of the P1mcb lysogens varied depending on the dnaB mutations they carried. Mutual interaction between the bacterial dnaB protein and the phage dnaB-like protein which results in different phenotypes of lysogens is suggested.     

Inactivation of SSM4, a new Saccharomyces cerevisiae gene, suppresses mRNA instability due to rna14 mutations

Decay rates of mRNAs depend on many elements and among these, the role of the poly(A) tail is now well established. In the yeast Saccharomyces cerevisiae, thermosensitive mutations in two genes, RNA14 and RNA15, result in mRNAs having shorter poly(A) tails and reduced half-life. To identify other components interacting in the same process, we have used a genetic approach to isolate mutations that suppress the thermosensitivity of an rna14 mutant strain. Mutations in a single locus, named SSM4, not only suppress the cell growth phenotype but also the mRNA instability and extend the short mRNA poly(A) tails. The frequency of appearance and the recessive nature of these mutations suggested that the suppressor effect was probably due to a loss of function. We failed to clone the SSM4 gene directly by complementation, owing to its absence from gene banks; it later emerged that the gene is toxic to Escherichia coli, but we have nevertheless been able to clone the SSM4 sequence by Ty element transposition tagging. Disruption of the SSM4 gene does not affect cell viability and suppresses the rna14 mutant phenotypes. The protein encoded by the SSM4 gene has a calculated molecular mass of 151 kDa and does not contain any known motif or show homology with known proteins. The toxicity of the SSM4 gene in E. coli suggests that a direct biochemical activity is associated with the corresponding protein.     

Bacteriophage P1 Ban protein is a hexameric DNA helicase that interacts with and substitutes for Escherichia coli DnaB

Since the ban gene of bacteriophage P1 suppresses a number of conditionally lethal dnaB mutations in Escherichia coli, it was assumed that Ban protein is a DNA helicase (DnaB analogue) that can substitute for DnaB in the host replication machinery. We isolated and sequenced the ban gene, purified the product, and analysed the function of Ban protein in vitro and in vivo. Ban hydrolyses ATP, unwinds DNA and forms hexamers in the presence of ATP and magnesium ions. Since all existing conditionally lethal dnaB strains bear DnaB proteins that may interfere with the protein under study, we constructed a dnaB null strain by using a genetic set-up designed to provoke the conditional loss of the entire dnaB gene from E.coli cells. This novel tool was used to show that Ban restores the viability of cells that completely lack DnaB at 30°C, but not at 42°C. Surprisingly, growth was restored by the dnaB252 mutation at a temperature that is restrictive for ban and dnaB252 taken separately. This indicates that Ban and DnaB are able to interact in vivo. Complementary to these results, we demonstrate the formation of DnaB–Ban hetero-oligomers in vitro by ion exchange chromatography. We discuss the interaction of bacterial proteins and their phage-encoded analogues to fulfil functions that are essential to phage and host growth.     

An amber mutation in the gene rpsA for ribosomal protein S1 in Escherichia coli

Summary An amber mutation has been induced in the gene rpsA (which codes fo ribosomal protein S1) of Escherichia coli K-12 strain in the presence of an amber suppressor (supD) and mutations sueA, sueB and sueC that additively enhance the efficiency of suppression. That the amber mutation has occurred in the gene rpsA was confirmed by complementation with a plasmid which carried the wild-type allele of rpsA. The mutation is lethal in the absence of an amber suppressor, indicating that ribosomal protein S1 is indispensable to E. coli.     

Synthesis of tryptophanase in Escherichia coli: Isolation and characterization of a structural-gene mutant and two regulatory mutants

Summary A mutant of E. coli has been isolated that is temperature-sensitive in respect of tryptophanase. When incubated at 60°C, cell-free extracts of the mutant suffer inactivation of enzyme activity much more rapidly than similar extracts of the wild type. After lysogeny with a specialized transducing phage carrying the wild-type tryptophanase gene, the mutant is able to synthesize tryptophanase that is wild-type in its response to treatment at 60°C. It is concluded that the mutation lies in the structural gene for the enzyme.Two further mutants have been isolated that synthesize tryptophanase constitutively. One mutation renders synthesis of the enzyme indifferent to the presence of inducer; the other mutation allows synthesis of the enzyme in the absence of inducer at about 35% of the fully induced wild-type rate. Neither mutation alleviates catabolite repression. Genetic mapping shows that the constitutive mutations lie very close to the structural-gene mutation, on the side of the structural gene distant from bglR.