Multiple Interactions of a DNA-Binding Protein IN VIVO. III. Phage T4 Gene-32 Mutations Differentially Affect Insertion-Type Recombination and Membrane Properties

We have investigated the in vivo roles of T4 gene- 32 protein in recombination. We have studied the effects of gene- 32 mutations under conditions that allow normal DNA replication and are permissive for progeny production. Under these conditions, certain gene- 32 mutations specifically reduce insertion-type (short-interval) recombination but none affect crossover-type (long-interval) recombination (see Figure 5). Heterozygote frequencies in all gene-32 mutants are similar to or higher than in a gene-32⁺ background and are not correlated with recombination deficiencies. "Recombination-deficient" alleles are dominant or codominant over the "recombination-proficient" gene-32 mutation tsL171. This explains apparent discrepancies between a gene-32 map deduced from two-factor crosses and the map derived from three-factor crosses.

We have also found that the "recombination proficient" mutation tsL171 and its homoalleles suppress the characteristic plaque morphology of rII mutants. Under restrictive conditions, tsL171 is partially suppressed by rII mutations, which allow the use of host ligase in recombination.

Our present and previous results are discussed in terms of current recombination models. We conclude that gene-32 protein functions in recombination by forming a complex with DNA, with recombination enzymes and with membrane components. Since gene-32 protein interacts with many components of this recombination complex, gene-32 mutations may differentially affect various recombination steps.

     

A class of gyrase mutants of Salmonella typhimurium show quinolone-like lethality and require Rec functions for viability

We have identified a new class of DNA gyrase mutants of Salmonella typhimurium that show chronic derepression of the SOS regulon. Thus, these mutants mimic the response of wild-type cells to gyrase inhibitors of the quinolone family. SOS induction by conditional lethal mutations gyrA208 or gyrB652, like that mediated by quinolones, is completely dependent on the function of the recB gene product. Introduction of recA or recB null mutations into these strains exacerbates their temperature-sensitive phenotype and prevents growth at the otherwise permissive temperature of 37°C. Selection of suppressors that concomitantly restore growth at 37°C and SOS induction in a recB^? background yielded mutations that relieve the RecB requirement for homologous recombination; namely, sbcB mutations as well as mutations at a new locus that was named sbcE. Such mutations also restore SOS induction in quinolone-treated gyr⁺recB^? strains. These findings indicate that Rec functions are needed for growth of the gyrase mutants at 37°C and suggest that recombinational repair intermediates constitute the SOS-inducing signal in the mutants as well as in quinolone-treated wild-type bacteria. Unlike quinolones, however, the gyr mutations described in this study do not cause detectable accumulation of ‘cleavable’ gyrase–DNA complexes in plasmid or chromosomal DNA. Yet gyrA208 (the only allele tested) was found to trigger RecB-mediated reckless degradation of chromosomal DNA in recA^? cells at restrictive temperatures. Indirect evidence suggests that double-stranded DNA ends, entry sites for the RecBCD enzyme, are generated in the gyr mutants by the breakage of DNA-replication forks. We discuss how this could occur and how recombinational rescue of collapsed replication forks could account for cell survival (and SOS induction) in the gyr mutants as well as in quinolone-treated bacteria.     

On the role of the single-stranded DNA binding protein of bacteriophage T4 in DNA metabolism. I. Isolation and genetic characterization of new mutations in gene 32 of bacteriophage T4

Summary The product of gene 32 of bacteriophage T4 is a single-stranded DNA binding protein involved in T4 DNA replication, recombination and repair. Functionally differentiated regions of the gene 32 protein have been described by protein chemistry. As a preliminary step in a genetic dissection of these functional domains, we have isolated a large number of missense mutants of gene 32. Mutant isolation was facilitated by directed mutagenesis and a mutant bacterial host which is unusually restrictive for missense mutations in gene 32. We have isolated over 100 mutants and identified 22 mutational sites. A physical map of these sites has been constructed and has shown that mutations are clustered within gene 32. The possible functional significance of this clustering is considered.     

Gene 32 protein of bacteriophage T4 moderates the activities of the T4 gene 46/47-controlled nuclease and of the Escherichia coli RecBC nuclease in vivo.

Genes 46 and 47 of phage T4 control a nuclease that is required for genetic recombination and may act similarly to the Escherichia coli RecBC nuclease. In vivo, the nucleolytic activities of both of these nucleases must be moderated so that recombining DNA intermediates are not destroyed. We conclude from our present experiments that the phage T4 gene 32 protein, specifically its C-terminal domain, participates in such moderation. We have investigated DNA degradation in different gene 32 and gene 32/46 mutants under conditions that are completely restrictive for progeny production in all the mutants. Under these conditions, DNA of those gene 32 mutants in which the C-terminal domain of the protein is not synthesized or is modified is degraded to acid-soluble material. T4 gene 46 or E. coli recB mutations reduce such degradation; together they abolish it completely. By contrast, single gene 32 mutants which produce an unaltered C-terminal domain show little or no degradation of their DNA. Residual protection against nucleases is unrelated to residual primary DNA replication or to overproduction of the mutant peptides in the different gene 32 mutants.     

Escherichia coli mutants with temperature-sensitive synthesis of DNA

Summary Seven mutants of E. coli with temperature-sensitive synthesis of DNA have been isolated. Synthesis of RNA, protein and DNA precursors does not appear to be directly affected. The mutants can be divided into at least two groups on the basis of their pattern of DNA synthesis, their ability to support phage growth at 41° and their genetic mapping.Mutants of the first group are heterogeneous in their pattern of DNA synthesis at 40°. Some mutants cease DNA synthesis abruptly upon transfer to 40° and any residual DNA synthesis is barely detectable. In others there is substantial residual synthesis at 40°. All these Group 1 mutants are alike, however, in that they support the growth of phage T4 but not Lambda at 41°. Two mutants with barely detectable residual DNA synthesis carry DNA mutations which have been mapped by P1 transduction and show about 72% linkage to the malB locus. It has not yet proved possible to map accurately the mutants showing substantial residual synthesis, and the possibility that these mutations are in a different gene(s) has not been excluded.A single mutant has been placed in a second group. Like some Group 1 mutants it synthesizes substantial amounts of DNA at 40° before synthesis stops. However, unlike them it supports the growth of T4 and Lambda at 41°. The DNA mutation maps near the leu locus. Certain properties of this mutant are consistent with the idea that initiation of DNA synthesis is temperature-sensitive in this strain.Adapted from a dissertation presented in partial fulfillment of the degree of Doctor of Philosophy. This investigation was supported in part by U.S. Public Health Services Grant 5-TO1-GM00829 from the National Institute of General Medical Sciences and in part by U.S.P.H.S. research grant GM12524.     

Mutations in the N-terminal cooperativity domain of gene 32 protein alter properties of the T4 DNA replication and recombination systems

The gene 32 protein (gp32) of bacteriophage T4 is the essential single-stranded DNA (ssDNA)-binding protein required for phage DNA replication and recombination. gp32 binds ssDNA with high affinity and cooperativity, forming contiguous clusters that optimally configure the ssDNA for recognition by DNA polymerase or recombination enzymes. The precise roles of gp32 affinity and cooperativity in promoting replication and recombination have yet to be defined, however. Previous work established that the N-terminal "B-domain" of gp32 is essential for cooperativity and that point mutations at Arg(4) and Lys(3) positions have varying and dramatic effects on gp32-ssDNA interactions. Therefore, we examined the effects of six different gp32 B-domain mutants on T4 in vitro systems for DNA synthesis and homologous pairing. We find that the B-domain is essential for gp32's stimulation of these reactions. The stimulatory efficacy of gp32 B-domain mutants generally correlates with the hierarchy of relative ssDNA binding affinities, i.e. wild-type gp32 approximately R4K > K3A approximately R4Q > R4T > R4G gp32-B. However, the functional defect of a particular mutant is often greater than can be explained simply by its ability to saturate the ssDNA at equilibrium, suggesting additional defects in the proper assembly and activity of DNA polymerase and recombinase complexes on ssDNA, which may derive from a decreased lifetime of gp32-ssDNA clusters.     

32P-base analysis of DNA

A ³²P-labeling method for the base composition analysis of nonradioactive DNA was developed consisting of the digestion of DNA to deoxynucleoside 3′-monophosphates by incubation with a mixture of micrococcal nuclease and spleen phosphodiesterase, transfer of ³²P-label from [γ-³²P]ATP to the 5′-hydroxyl groups of the mononucleotides by T4 polynucleotide kinase, two-dimensional anion-exchange thin-layer chromatography on PEI-cellulose of the resultant [5′-³²P]deoxynucleoside 3′,5′-bisphosphates, autoradiography, and scintillation counting. The method was standardized to afford quantitative digestion of DNA to mononucleotides as well as to give quantitative incorporation of ³²P-label into the nucleotides in the DNA hydrolysate so as to make the method an accurate means for determining the base composition of eucaryotic DNA containing adenine, guanine, thymine, cytosine, and 5-methylcytosine.     

Essential functions of the 32 kDa subunit of yeast replication protein A

Replication protein A (RPA) is a heterotrimeric (70, 32 and 14 kDa subunits), single-stranded DNA-binding protein required for cellular DNA metabolism. All subunits of RPA are essential for life, but the specific functions of the 32 and 14 kDa subunits remains unknown. The 32 kDa subunit (RPA2) has multiple domains, but only the central DNA-binding domain (called DBD D) is essential for life in Saccharomyces cerevisiae. To define the essential function(s) of RPA2 in S. cerevisiae, a series of site-directed mutant forms of DBD D were generated. These mutant constructs were then characterized in vitro and in vivo. The mutations had minimal effects on the overall structure and activity of the RPA complex. However, several mutants were shown to disrupt crosslinking of RPA2 to DNA and to dramatically lower the DNA-binding affinity of a RPA2-containing subcomplex. When introduced into S. cerevisiae, all DBD D mutants were viable and supported normal growth rates and DNA replication. These findings indicate that RPA2–DNA interactions are not essential for viability and growth in S. cerevisiae. We conclude that DNA-binding activity of RPA2 is dispensable in yeast and that the essential function of DBD D is intra- and/or inter-protein interactions.     

A T4 DNA fragment containing genes for the baseplate central plug: Endonuclease restriction, gene expression and cell wall changes

Summary A fragment of Escherichia coli bacteriophage T4D DNA, containing 6.1 Kbp which included the six genes (genes 25, 26, 51, 27, 28 and 29) coding for the tail baseplate central plug has been partially characterized. This DNA fragment was obtained originally by Wilson et al. (1977) by the action of the restriction enzyme EcoRI on a modified form of T4 DNA and was inserted in the pBR322 plasmid and then incorporated into an E. coli K12 strain called RRI. This plasmid containing the phage DNA fragment has now been reisolated and screened for cleavage sites for various restriction endonucleases. Restriction enzymes Bgl 11 and Xbal each attacked one restriction site and the enzyme Hpa 1 attacked two restriction sites on this fragment. The combined digestion of the hybrid plasmid containing the T4 EcoRI DNA fragment conjugated to the pBR322 plasmid with one of these enzymes plus Bam H1 restriction enzyme resulted in the localization of the restriction site for Bgl 11, Xba 1 and Hpa 1. Escherichia coli strain B cells were transformed with this hybrid plasmid and found to have some unexpected properties. E. coli B cells, which are normally restrictive for T4 amber mutants and for T4 temperature sensitive mutants (at 44°) after transformation, were permissive for 25am, 26am and 26^Ts, 51am, and 51^Ts, 27^Ts, and 28^Ts T4 mutants. Extracts from the transformed E. coli cells were found in complementation experiments to contain the gene 29 product, as well as the gene 26 product, the gene 51 product, and the gene 27 product. The complementation experiments and the permissiveness of the transformed E. coli B cells to the various conditional lethal mutants clearly showed that the six T4 genes were producing all six gene products in these transformed cells. However, these cells were not permissive for T4 amber mutants in genes 27, 28, and 29. The transformed E. coli B cells, as compared to untransformed cells, were found to have altered outer cell walls which made them highly labile to osmotic shock and to an increased rate of killing by wild type T4 and all T4 amber mutants except for T4 am29. The change in cell walls of the transformed cells has been found to be due to the T4 baseplate genes on the hybrid plasmid, since E. coli B transformed by the pBR322 plasmid alone does not show the increase in osmotic sensitivity.     

Mutations that increase the mitotic stability of minichromosomes in yeast: characterization of RAR1

Summary In an attempt to identify proteins involved in the initiation of DNA replication, we have isolated a series of Saccharomyces cerevisiae mutants in which the function of putative replication origins is affected. The phenotype of these Rar^- (regulation of autonomous replication) mutants is to increase the mitotic stability of plasmids whose replication is dependent on weak ARS elements. These mutations are generally recessive and complementation analysis shows that mutations in several genes may improve the ability of weak ARS elements to function. One mutation (rar1-1) also confers temperature-sensitive growth, and thus an essential gene is affected. We have determined the DNA sequence of the RAR1 gene, which reveals an open reading frame for a 48.5 kDa protein. The RAR1 gene is linked to rna1 on chromosome XIII.     

A coupled in vitro system for the formation and packaging of concatemeric phage T1 DNA

Summary Extracts derived from E. coli cells infected non-permissively with phage T1 amber mutants were used in an in vitro system to investigate the packaging of T1 DNA into phage heads. The standard extract used infections with amber mutants in genes 1 and 2 (g1^-g2^-) which are defective in T1 DNA synthesis but can synthesis the proteins required for particle morphogenesis. g1^-g2^- extracts packaged T1⁺ virion DNA molecules with an efficiency of 3×10⁵ pfu/g DNA. Extracts from cells infected with phage also defective in DNA synthesis but carrying additional mutations in genes 3.5 or 4 which are required for concatemer formation in vivo (g1^-g3.5^- and g1^-g4^- extracts) package T1 virion DNA at substantially lower efficiencies.Analysis of the DNA products from these in vitro reaction showed that concatemeric DNA is formed very efficiently by g1^-g2^- extracts but not by g1^-g3.5^- or g1^-g4^- extracts. These results are interpreted as evidence that the T1 in vitro DNA packaging system primarily operates in a similar manner to the in vivo headful mechanism. This is achieved in vitro by the highly efficient conversion of T1 virion DNA into concatemers which are then packaged with a much lower efficiency into heads to form infectious particles. A secondary pathway for packaging T1 DNA into heads and unrelated to the headful mechanism may also exist.     

Loss of Pol32 in Drosophila melanogaster Causes Chromosome Instability and Suppresses Variegation

Pol32 is an accessory subunit of the replicative DNA Polymerase δ and of the translesion Polymerase ζ. Pol32 is involved in DNA replication, recombination and repair. Pol32’s participation in high- and low-fidelity processes, together with the phenotypes arising from its disruption, imply multiple roles for this subunit within eukaryotic cells, not all of which have been fully elucidated. Using pol32 null mutants and two partial loss-of-function alleles pol32^rd1 and pol32^rds in Drosophila melanogaster, we show that Pol32 plays an essential role in promoting genome stability. Pol32 is essential to ensure DNA replication in early embryogenesis and it participates in the repair of mitotic chromosome breakage. In addition we found that pol32 mutantssuppress position effect variegation, suggesting a role for Pol32 in chromatin architecture.     

Replication of the mini-R1 plasmid Rsc11 and Rsc11 hybrid plasmids

Summary The DNA polymerase induced by bacteriophage T7 is composed of a phage-specified subunit, the gene 5 protein, and a host-specified subunit, the 12,000 dalton thioredoxin of Escherichia coli. tsnC mutants of E. coli B (Chamberlin, 1974) have no detectable thioredoxin, and thus cannot support the growth of phage T7, although they are killed by phage infection. A mutant of E. coli K12 affecting thioredoxin has been isolated by a modification of the procedure used by Chamberlin (1974) to isolate tsnC mutants of E. coli B. The gene affecting thioredoxin has been designated trxA. This mutant, E. coli JM109, shows the TsnC phenotype in that it is killed by, but cannot support the growth of, bacteriophage T7. T7 DNA replication does not occur in mutantinfected cells. These phenotypic expressions of the tsnC mutation have enabled us to screen recombinants for the trxA allele in HfrxF^- crosses and F-ductants in episome transfer experiments. Extracts of transductants in generalized transduction by P1 phage were screened for their ability to complement partially purified phage T7 gene 5 protein to form T7 DNA polymerase. The trxA gene is located at 84 min on the E. coli linkage map, between uvrE and metE; trxA is 34% co-transducible with metE.     

Spectrum of 32P-induced mutants of Caenorbabditis elegans

Mutants of the free living nematode C. elegans were isolated by using ³²P as a mutagen. It is shown that most of these mutants arise from ³²P suicide. A comparison of EMS-induced and ³²P-induced autosomal recesive mutations shows that there are no large regions of C. elegans genome which are protected from chemical mutagenic action of EMS.     

Bacteriophage T4 Gene 32 Participates in Excision Repair as Well as Recombinational Repair of Uv Damages

Gene 32 of phage T4 has been shown previously to be involved in recombinational repair of UV damages but, based on a mutant study, was thought not to be required for excision repair. However, a comparison of UV-inactivation curves of several gene 32 mutants grown under conditions permissive for progeny production in wild-type or polA- hosts demonstrates that gene 32 participates in both kinds of repair. Different gene 32 mutations differentially inactivate these repair functions. Under conditions permissive for DNA replication and progeny production, all gene 32 mutants investigated here are partially defective in recombinational repair, whereas only two of them, P7 and P401, are also defective in excision repair. P401 is the only mutant whose final slope of the inactivation curve is significantly steeper than that of wild-type T4. These results are discussed in terms of interactions of gp32, a single-stranded DNA-binding protein, with DNA and with other proteins.     

Viscosity study of DNA. II. The effect of simple salt concentration on the viscosity of high molecular weight DNA and application of viscometry to the study of DNA isolated from T4 and T5 bacteriophage mutants

Polyelectrolyte expansion effects on high molecular weight bacteriophage DNA have been studied by examining the influence of simple salt concentration upon the intrinsic viscosity, [η]. The viscosity–molecular weight exponent a in the expression [η] = KM^a diminishes from 0.8 in 0.005M simple salt to a limiting value of 0.6 for salt concentrations greater than 0.6M at 25°C. The ε parameter of the N^1+ε hydrodynamic representation thus varies from approximately 0.2–0.07 over this range of salt concentration. The intrinsic, viscosity of DNA decreases slightly with increasing temperature at low and moderate salt concentrations but becomes independent of temperature at high salt concentrations. The expansion of the DNA molecular domain is linear in the reciprocal square root of the simple salt concentration. Viscosity differences among DNA's isolated from several bacteriophage T5 mutants reflect small differences in molecular weight which are in agreement, with sine determination by other techniques. The DNA's isolated from various rII mutants of T4 bacteriophage including some very large deletion mutations were found to be identically the same size in accord with current genetic ideas. Details of the representation and extrapolation of viscosity data are discussed and the sensitivity of the technique is evaluated.     

RNase H-defective mutants of Escherichia coli: a possible discriminatory role of RNase H in initiation of DNA replication

Summary Mutants of Escherichia coli completely deficient in RNase H activity were isolated by inserting transposon Tn3 into the structural gene for RNase H, rnh, and its promoter. These rnh ^- mutants exhibited the following phenotypes; (1) the mutants grew fairly normally, (2) rnh ^- cells could be transformed with ColE1 derivative plasmids, pBR322 and pML21, though the plasmids were relatively unstable, under non selective conditions, (3) rnh ^- mutations partially suppressed the temperature-sensitive phenotype of plasmid pSC301, a DNA replication initiation mutant derived from pSC101, (4) rnh ^- mutations suppressed the temperature-sensitive growth character of dnaA ^ts mutant, (5) rnh ^- cells showed continued DNA synthesis in the presence of chloramphenicol (stable DNA replication). Based on these findings we propose a model for a role of RNase H in the initiation of chromosomal DNA replication. We suggest that two types of RNA primers for initiation of DNA replication are synthesized in a dnaA/oriC-dependent and-independent manner and that only the dnaA/oriC-dependent primer is involved in the normal DNA replication since the dnaA/oriC independent primer is selectively degraded by RNase H.Abbreviations AP^r ampicillin-resistant - kb kilobase pair(s) - NEM N-ethyl maleimide - Ts temperature-sensitive     

New Escherichia coli gyrA and gyrB mutations which have a graded effect on DNA supercoiling

Summary We isolated new gyrA and gyrB mutations in Escherichia coli which have a graded effect on DNA supercoiling. The mutants, selected respectively for resistance to nalidixic acid and coumermycin, were sorted by means of a rapid in vivo assay of DNA gyrase activity (Aleixandre and Blanco 1987). Cells carrying a gyrB (Cou^r) mutation usually showed a decrease in DNA supercoiling, which would indicate a reduction in gyrase activity. In contrast, most of the gyrA (Nal^r) mutations had no significant effect on DNA supercoiling. Moreover, they conferred a high level of resistance to nalidixic acid and other quinolones, thus being similar to the gyrA(Nal^r) mutants currently used. We also detected rare gyrA mutants showing a reduction in DNA gyrase activity. These mutants were, in addition, resistant to only low concentrations of quinolones, which allowed us to use the phenotype of partial quinolone resistance as an indicator to score gyrA mutations affecting DNA supercoiling. When gyrB mutations were introduced into the gyrA mutants, these became more sensitive to quinolones and a decrease in supercoiling was observed. Moreover, the topA10 mutation sensitized gyrA(Nal^r) cells to quinolones. We conclude therefore that the GyrA-dependent quinolone resistance is diminished as a consequence of the reduction either in topoisomerase I or gyrase activities.     

Genetic analysis of two bacterial RNA polymerase mutants that inhibit the growth of bacteriophage T7

Summary The Escherichia coli mutants 7009 and BR3 are defective in the growth of bacteriophage T7. We have previously shown that both of these mutant hosts produce an altered RNA polymerase which is resistant to inhibition by the T7 gene 2 protein (De Wyngaert and Hinkle 1979). In both strains, the mutation which prevents T7 growth is closely linked to rifA (rpoB). Both mutants are complemented by transformation with a multicopy plasmid carrying rpoB and rpoC but not by a plasmid carrying only rpoB. This indicates that the mutations reside in rpoC, the structural gene for the subunit of RNA polymerase. When a single copy of the wildtype rpoC allele is introduced into the mutant using the transducing phage drif ^d18, the mutant allele is dominant over wildtype. The drif ^d18 transductant also remains unable to support the growth of T7 in the presence of rifampin. This supports our conclusion that the mutation is in rpoC. We have measured the growth of T7 phage, the kinetics of phage DNA synthesis, and the structure of replicative DNA intermediates in several transductants, and compared these results with those obtained in the original mutant strains.     

The isolation and characterization of TabR bacteria: Hosts that restrict bacteriophage T4 rII mutants

Summary We have isolated mutants of Escherichia coli B (called TabR) that restrict the growth of bacteriophage T4 rII mutants at high temperature. TabR strains lysed very rapidly after infection with rII mutants, and no progeny phage were produced. T4⁺-infected TabR cells also lysed quickly, but the cells remained intact long enough to give a small burst. We have selected pseudorevertants of rII deletion mutants that grow on TabR at high temperature; tk (thymidine kinase) is a component of one class of these pseudorevertants.T4 strains harboring mutations in genes 12, 16, 25, 34, 36, 45 and 63 were also specifically restricted on TabR strains at high temperature. Bacteriophages T2, T4, T5, T6, and T7 grew normally on TabR, while , 80, and P1 failed to grow at any temperature. The most restrictive TabR strains were auxotrophic for methionine at high temperature, and most spontaneous Met⁺ revertants had also lost the ability to restrict rII mutants, suggesting that the TabR phenotype and methionine auxotrophy result from the same mutation.Although the mechanism by which TabR strains exert their restriction has not been determined, one model is described. The potential uses of these and similar strains is discussed.