A mutation which modifies the activity of a translational suppressor in Aspergillus nidulans

A third type of translational fidelity mutation has been induced in Aspergillus nidulans. The new mutation enhances growth, in suppressing conditions, of a strain containing suppressor suaC109 and antisuppressor asuD14 and is called aloB8 for its allosuppressor activity. Compared with the progenitor strain (asuD14, suaC109), ribosomes from the new mutant (aloB8, asuD14, suaC109) increase misincorporation of leucine in a poly(U)-dependent homologous cell-free assay. The misreading level is maintained by ribosomes after washing with 500 mM KCl and suggests an alteration in a ribosomal component or a tightly bound factor. Ribosomes from an aloB8, asu+, sua+ strain also misread to a higher level than those of the control strain despite the fact that, in vivo, this mutation alone has no known suppressor activity. Mg2+ ions have been used in vivo for the first time to classify translation mutants.     

Antisuppressor mutations and sulfur-carrying nucleosides in transfer RNAs of Schizosaccharomyces pombe

Antisuppressor mutations reduce the efficiency of nonsense suppressors. A mutation in the gene sin4 of Schizosaccharomyces pombe leads to loss of 5-(methoxycarbonylmethyl) thiouridine (mcm5s2U) from the first anticodon position of tRNAs. This resembles the phenotype of sin3 (Heyer, W. D., Thuriaux, P., Kohli, J., Ebert, P., Kersten, H., Gehrke, C., Kuo, K. C., and Agris, P. F. (1984) J. Biol. Chem. 259, 2856-2862), but the mutations reside in different genes. In vivo 35S-labeled tRNA from the parental suppressor strain sup3, the antisuppressor strains sin3 and sin4, and the double mutant sin3 sin4 has been digested to nucleosides and analyzed with high performance liquid chromatography methods. The major sulfur-carrying nucleoside in wild-type S. pombe tRNA is mcm5s2U. It is reduced in the mutant strains. Two other thiolated nucleosides are also present: 2-thiouridine and a nucleoside of unknown structure. Neither was affected by the antisuppressor mutations. Thiocytidine has not been found. Independent from their effect on suppressors, the two mutations sin3 and sin4 reduce the growth rate of cells, and sin3 also increases cell length. In vivo decoding of the serine codon UCG by the UCA reading serine tRNA is not promoted by the two antisuppressor mutations.     

An antisuppressor mutation of Schizosaccharomyces pombe affects the post-transcriptional modification of the "wobble" base in the anticodon of tRNAs

The screening of antisuppressor mutants of the yeast Schizosaccharomyces pombe has been successfully accomplished with high resolution liquid chromatographic methods for the analysis of tRNA nucleosides. Antisuppressor mutations reduce or abolish the function of nonsense suppressor-tRNAs or other informational suppressors. Nonradioactive or 35S-labeled unfractionated tRNA from various strains was digested to nucleosides and analyzed by high performance liquid chromatography. The mutant sin3 has lost the nucleoside 5-(methoxycarbonylmethyl)-2-thiouridine from its tRNA in comparison to parental strains. In eukaryotes this nucleoside is found at the first position of the anticodon (wobble position) in several isoacceptor tRNAs that preferentially recognize codons ending with adenosine. The sin3 mutation reduces the efficiency of UGA and UAA suppressor tRNASer and suppressor tRNALeu. The genetic cosegregation of modification loss, antisuppressor phenotype, and a change in cell size is demonstrated. This indicates that a single mutation in the structural gene for a tRNA modification enzyme causes the three different phenotypes.     

High-level accumulation of a recombinant antibody fragment in the periplasm of Escherichia coli requires a triple-mutant (degP prc spr) host strain

During production of a humanized antibody fragment secreted into the periplasm of Escherichia coli, proteolytic degradation of the light chain was observed. In order to determine which protease(s) were responsible for this degradation, we compared expression of the F(ab')(2) antibody fragment in several E. coli strains carrying mutations in genes encoding periplasmic proteases. Analysis of strains cultured in high cell density fermentations showed that the combination of mutations in degP prc spr was necessary for the cells to produce high levels of the desired recombinant antibody fragment. In order to eliminate the possible effects of mutations in other genes, we constructed E. coli strains with protease mutations in isogenic backgrounds and repeated the studies in high cell density fermentations. Extensive light chain proteolysis persisted in degP strains. However, light chain proteolysis was substantially decreased in prc and prc spr strains, and was further decreased with the introduction of a degP mutation in prc and prc spr mutant strains. These results show that the periplasmic protease Prc (Tsp) is primarily responsible for proteolytic degradation of the light chain during expression of a recombinant antibody fragment in E. coli, and that DegP (HtrA) makes a minor contribution to this degradation as well. The results also show that spr, a suppressor of growth defects in prc strains, is required for a prc mutant to survive throughout high cell density fermentations.     

Transfer RNA modifications that alter +1 frameshifting in general fail to affect -1 frameshifting

Using mutants (tgt, mnmA(asuE, trmU), mnmE(trmE), miaA, miaB, miaE, truA(hisT), truB) of either Escherichia coli or Salmonella enterica serovar Typhimurium and the trm5 mutant of Saccharomyces cerevisiae, we have analyzed the influence by the modified nucleosides Q34, mnm(5)s(2)U34, ms(2)io(6)A37, Psi39, Psi55, m(1)G37, and yW37 on -1 frameshifts errors at various heptameric sequences, at which at least one codon is decoded by tRNAs having these modified nucleosides. The frequency of -1 frameshifting was the same in congenic strains only differing in the allelic state of the various tRNA modification genes. In fact, in one case (deficiency of mnm(5)s(2)U34), we observed a reduced ability of the undermodified tRNA to make a -1 frameshift error. These results are in sharp contrast to earlier observations that tRNA modification prevents +1 frameshifting suggesting that the mechanisms by which -1 and +1 frameshift errors occur are different. Possible mechanisms explaining these results are discussed.     

Host-controlled Restriction of T-even Bacteriophages: Relation of Endonuclease I and T-even-induced Nucleases to Restriction

Restriction of nonglucosylated T2 phage (T(*)2) as a function of bacterial growth state was the same for endonuclease I-containing and endonuclease I-deficient strains of Escherichia coli B. Furthermore, E. coli strains with various levels of restriction for T2 had comparable endonuclease I activities. It was also found that a T4 mutant temperature-sensitive for gene 46 and 47 functions was fully restricted at 42 C. It therefore appears that neither endonuclease I nor the phage-induced nucleases whose activities are blocked by mutations in genes 46 and 47 catalyze the initial event in restriction of nonglucosylated T-even phages.     

Restoration of hydrogenase activity in hydrogenase-negative strains of Escherichia coli by cloned DNA fragments from Chromatium vinosum and Proteus vulgaris

DNA fragments from Proteus vulgaris and Chromatium vinosum were isolated which restored hydrogenase activities in both hydA and hydB mutant strains of Escherichia coli. The hydA and hydB genes, which map near minute 59 of the genome map, 17 kb distant from each other, are not structural hydrogenase genes, but mutation in either of these genes leads to failure to synthesize any of the hydrogenase isoenzymes. The smallest DNA fragments which restored hydrogenase activity to both E. coli mutant strains were 4.7 kb from C. vinosum and 2.3 kb from P. vulgaris. These fragments were cleaved into smaller fragments which did not complement either of the E. coli mutations. The cloned heterologous genes also restored formate hydrogenlyase activity but they did not restore activity in hydE, hupA or hupB mutant strains of E. coli. The cloned genes, on plasmids, did not lead to the synthesis of proteins of sufficient size to be the hydrogenase catalytic subunit. The hydrogenase proteins synthesized by hydA and hydB mutant strains of E. coli transformed by cloned genes from P. vulgaris and C. vinosum were shown by isoelectric and immunological methods to be E. coli hydrogenase. Thus, these genes are not hydrogenase structural genes.     

Escherichia coli mutants lacking NADH dehydrogenase I have a competitive disadvantage in stationary phase.

We have previously characterized mutant strains of Escherichia coli that are able to take over stationary-phase cultures. Here we describe two insertion mutations that prevent such strains from expressing this phenotype. Both insertions were mapped to min 51, and sequence analysis revealed that both mutated genes encode proteins homologous to subunits of mitochondrial NADH dehydrogenase I. Crude extracts prepared from both mutant strains were able to oxidize NADH but lacked the enzymatic activity needed to oxidize deamino-NADH, a substrate specific for NADH dehydrogenase I. This is the first identification of genes encoding subunits of NADH dehydrogenase I in E. coli. The significance of the inability of these mutant strains to compete in stationary-phase cultures is discussed.     

Genetic analysis of mutations that compensate for loss of Escherichia coli DNA topoisomerase I

A transposon Tn10 insertion in topA, the structural gene of Escherichia coli DNA topoisomerase I, behaves as an excluded marker in genetic crosses with many strains of E. coli. However, derivative strains that accept this mutant topA allele are readily selected. We show that many of these topA mutant strains contain additional mutations that compensate for the loss of DNA topoisomerase I. Genetic methods for mapping and manipulating such compensatory mutations are described. These methods include a plate-mating test for the ability of strains to accept a topA::Tn10 allele and a powerful indirect selection for transferring compensatory mutations from male strains into non-compensatory female strains. One collection of spontaneous compensatory mutants is analyzed in detail and is shown to include compensatory mutations at three distinct loci: gyrA and gyrB, the genes that encode the subunits of DNA gyrase, and a previously unidentified locus near tolC. Mutations at this third locus, referred to as toc (topoisomerase one compensatory) mutations, do not behave as point mutations in transductional crosses and do not result in lowered DNA gyrase activity. These results show that wild-type strains of E. coli require DNA topoisomerase I, and at least one class of compensatory mutations can relieve this requirement by a mechanism other than reduction of DNA gyrase activity.     

Genetic analysis of Escherichia coli K-12 chromosomal mutants defective in expression of F-plasmid functions: identification of genes cpxA and cpxB.

Two temperature-sensitive, chromosomal mutants of Escherichia coli were selected for their inability to express deoxyribonucleic acid donor activity and other activities associated with the conjugative plasmid F. These mutants were also auxotrophic for isoleucine and valine at 41 degrees C. Each mutant strain contained two altered genes: cpxA, located at 88 min on the E. coli K-12 genetic map, and cpxB, located at 41 min. Mutations in both genes were required for maximal expression of mutant phenotypes. The parent strain of mutants KN401 and KN312 already contained the cpxB mutation that is present in both mutants (cpxB1). This mutation by itself was cryptic. The cpxA mutations represent different mutant alleles since they are of independent origin. A cpxA mutation by itself significantly affected the expression of plasmid functions and growth at 41 degrees C in the absence of isoleucine and valine, but strains containing both a cpxA and cpxB mutation were more severely affected. Along with the observation that both cpxA mutations were revertable, the temperature sensitivity of cpxA cpxB+ cells suggests that both cpxA alleles contain point mutations that do not completely destroy the activity of the cpxA gene product.     

Phenotypic manifestation of epigenetic determinant [ISP+] in Saccharomyces serevisiae depends on combination of mutations in SUP35 and SUP45 genes

It is known that translation fidelity in Saccharomyces yeast is determined by factors of genetic and epigenetic (prion) nature. The work represents results of further analysis of strains containing non-chromosomal determinant [ISP+], described earlier. This determinant is involved in the control of translation fidelity and some of its properties indicate that it is a prion. [ISP+] manifests phenotypically as antisuppressor of two sup35 mutations and can be cured by guanidine hydrochloride (GuHCl). Here we have shown that sup35 mutants containing [ISP+] contain also additional sup45 mutations. These mutations cause amino acid replacements in different regions of eRF1 translation termination factor, encoded by SUP45 gene. Strains bearing sup35-25 mutation contain sup45 mutation, which causes amino acid replacement at position 400 of eRF1; strains bearing sup35-10 contain mutation causing replacement, which alters eRF1 at position 75. Thus, antisuppressor phenotype of [ISP+] strains depends on interaction of sup35 and sup45 mutations, as well as on the GuHCl-curable epigenetic determinant.     

Genetic and physiological tests of three phosphate-specific transport mutants of Escherichia coli.

Phosphate-specific transport system mutations phoT35, pst-2, and phoS25-(Am) were mapped between bgl and glmS, at about 83 min on the Escherichia coli chromosome. All three mutations were recessive to wild-type genes on transducing bacteriophage lambda asn. The phoS25 (Am) and pst-2 mutations were also recessive to transducing phage lambda dglm; however, the phoT35 mutation was not. This suggests that phoT35 lies in a different complementation group from phoS25 (Am) or pst-2. Isogenic series of strains carrying these mutations were constructed in two genetic backgrounds, pit+ (wild type) and pit (relying entirely on the phosphate-specific transport system for phosphate uptake). The pst-2 pit double mutant was incapable of Pi utilization, but the phoT35 pit double mutant exhibited no such deficiency.     

Missense mutations in the lacZ gene that result in degradation of beta-galactosidase structural protein.

Thirty-two missenese mutations were found among more than 200 independently induced mutations in the lacZ gene of Escherichia coli. Twenty of these missense mutations were induced by nitrosguandine, and 12 were induced by aminopurine. The lacZ structural protein was endogenously degradable in seven of the mutant strains; the mutations in these strains were found to lie at only three sites in the lacZ gene. Five of the seven independent mutations were at a single site, and some heterogeneity in the degradation of the lacZ protein was observed within these mutant strains.     

Genetic analysis of conjugational recombination in Escherichia coli K12 strains deficient in RecBCD enzyme

Conjugational recombination in Escherichia coli was investigated by comparing the effects of recN, recO, ruv and lexA mutations on the formation of recombinants in crosses with strains lacking RecBCD enzyme. The results presented reveal that recN and ruv mutations do not abolish residual recombination in a recB mutant, and have only a rather modest effect on recombination in recBC sbcA strains; in these respects they are quite different from recF, recJ and recO mutations. The differences between these two groups of genes are discussed in relation to the molecular exchanges needed to produce viable recombinants.     

Dominant lethal mutations in the dnaB helicase gene of Salmonella typhimurium

A class of dominant lethal mutations in the dnaB (replicative helicase) gene of Salmonella typhimurium is described. The mutated genes, when present on multicopy plasmids, interfered with colony formation by Escherichia coli host strains with a functional chromosomal dnaB gene. The lethal phenotype was expressed specifically in supE (glutamine-inserting) host strains and not in Sup+ strains, because the mutant genes, by design, also possessed an amber mutation derived from a glutamine codon. Mutations located at 11 sites by deletion mapping and DNA sequence analysis varied in the temperature dependence and severity of their lethal effects. None of the mutations complemented a dnaB(Ts) host strain at high temperature (42 degrees C). Therefore, these nonfunctional DnaB proteins must engage some component(s) of the DNA replication machinery and inhibit replication. These mutations are predicted to confer limited, specific defects in either the catalytic activity of DnaB or the ability of DnaB to interact with one of its ligands such as DNA, nucleotide, or another replication protein. The variety of mutant sites and detailed phenotypes represented in this group of mutations may indicate the operation of more than one specific mechanism of lethality.     

Base excision repair enzyme endonuclease III suppresses mutagenesis caused by 8-hydroxy-dGTP

To examine whether base excision repair suppresses mutations induced by oxidized deoxyribonucleotide 5'-triphosphates in the nucleotide pool, 8-hydroxy-dGTP (8-OH-dGTP) and 2-hydroxy-dATP were introduced into Escherichia coli strains deficient in endonucleases III (Nth) and VIII (Nei) and MutY, and mutations in the chromosomal rpoB gene were analyzed. The spontaneous rpoB mutant frequency was also examined in mutT/nth and mutT/nei strains, to assess the influence on the mutations induced by the endogenous 8-OH-dGTP accumulated in the mutT mutant. The mutations induced by exogenous 2-hydroxy-dATP were similar in all of the strains tested. Exogenous 8-OH-dGTP increased the rpoB mutant frequency more efficiently in the nth strain than that in the wild-type strain. The spontaneous mutant frequency in the mutT/nth strain was 2-fold higher than that in the mutT strain. These results suggest that E. coli endonuclease III also acts as a defense against the mutations caused by 8-OH-dGTP in the nucleotide pool.     

Participation of the Escherichia coli heat shock proteins DnaJ, DnaK, and GrpE in autorepression of the P1 plasmid repA promoter

The replicon of the low copy number plasmid P1 uses the three Escherichia coli heat shock proteins DnaJ, DnaK, and GrpE for the efficient initiation of its DNA replication. The only P1-encoded protein required for plasmid replication is the initiator, RepA. Binding of RepA to the origin also represses the promoter for the repA gene, which is located within the origin. We found that repression is incomplete in E. coli strains with mutations in the dnaJ, dnaK, or grpE genes. Since there is no decrease in RepA concentration in the mutant strains, the mutations are likely to affect the protein-DNA or protein-protein reactions required for repression, thereby decreasing RepA binding at its promoter. We also showed that the deficit in repression can be overcome by providing excess RepA, implying that the mechanism of repression is not altered in the mutant strains. Since repression requires RepA binding to the origin, a binding deficit might account for the replication defect in the heat shock mutants.     

Polyproline binding is an essential function of human profilin in yeast.

Structural analysis of human profilin has revealed two tryptophan residues, W3 and W31, which interact with polyproline. The codons for these residues were mutated to encode phenylalanine and the mutant proteins overexpressed in Eschericia coli. The isolated proteins were diminished in their ability to bind polyproline, whereas phosphatidylinositol 4,5-bisphosphate (PIP2) binding remained unchanged. In many strains of Saccharomyces cerevisiae, disruption of the gene encoding profilin, PFY1, is lethal. It was found that expression of the gene for human profilin is capable of suppressing this lethality. The polyproline-binding mutant alleles of the human gene were cloned into various yeast expression vectors. Each of the mutant genes resulted in suppression of the lethality of pfy1Delta. It was observed that the mutant protein expression levels paralleled the growth rates of the strains. The severity of various morphological abnormalities of the strains was also attenuated with increased protein levels, suggesting that profilin polyproline-binding mutations are deleterious to cell growth unless overexpressed. Both tryptophan mutations were combined to give a third mutant allele that was found both unable to bind polyproline and to suppress the lethality of a pfy1 deletion. Immunoprecipitation experiments suggested that the mutants were unaltered in their affinity for actin and PIP2. These data strongly suggest that polyproline binding is an essential function of profilin.     

New mutations fts-36, lts-33, and ftsW clustered in the mra region of the Escherichia coli chromosome induce thermosensitive cell growth and division.

Three new mutants of Escherichia coli showing thermosensitive cell growth and division were isolated, and the mutations were mapped to the mra region at 2 min on the E. coli chromosome map distal to leuA. Two mutations were mapped closely upstream of ftsI (also called pbpB), in a region of 600 bases; the fts-36 mutant showed thermosensitive growth and formed filamentous cells at 42 degrees C, whereas the lts-33 mutant lysed at 42 degrees C without forming filamentous cells. The mutation in the third new thermosensitive, filament-forming mutant, named ftsW, was mapped between murF and murG. By isolation of these three mutants, about 90% of the 17-kilobase region from fts-36-lts-33 to envA could be filled with genes for cell division and growth, and the genes could be aligned.