High-efficiency, temperature-sensitive suppression of amber mutations in Escherichia coli.

We have constructed a high-copy-number plasmid carrying an allele of the supD gene (supD43,74). The plasmid conferred temperature-sensitive suppression of amber mutations. Strains carrying the plasmid exhibited 50 to 60% suppression at 30 degrees C but little or no suppression at 42 degrees C. After a temperature shift from 30 to 42 degrees C the efficiency of suppression decreased gradually over a 60- to 90-min period before reaching the 42 degrees C steady-state level of suppression.     

Suppressors of a UGG missense mutation in Escherichia coli

As part of our investigation of tRNA structure-function relationships, we isolated and preliminarily characterized translational suppressors of the tryptophan codon UGG in a trpA missense mutant of Escherichia coli. the parent strain also contained two other mutant alleles relevant to the suppressor search; these were supD, which codes for a serine-inserting amber suppressor tRNA, and gly V55, the gene for a GGA/G-reading mutationally altered glycine tRNA. On the basis of map location, reversed-phase (RPC-5) column chromatography of glycyl-tRNA, and codon response, several classes have been distinguished so far. The number of suppressors in each class, their codon responses, and their apparent genic identities, respectively, are as follows: class 1--4 suppressors, UGG, supD; class 2--12 suppressors, UGG, glyU; class 3--9 suppressors, UGA and UGG, glyT; class 4--2 suppressors, UGG, glyT; class 5--7 suppressors, UGG, gly V55. Besides these, one suppressor retains supD activity, but so far its map location has not been distinguished from that of supD. Another suppressor clearly does not map near supD or any of the glycine tRNA genes mentioned. These last two suppressors may represent novel missense suppressors such as misacylated tRNA's or mutationally altered aminoacyl-tRNA synthetases, tRNA modification enzymes, or ribosomes. Finally, three other suppressors were obtained from a strain containing glyT56, the gene for an AGA/G-reading form of glyT tRNA. All three occurred at the expense of glyT56 activity and exhibited the the transductional linkage to argH that is characteristic of glyT.     

Location of the Escherichia coli K-12 ruv gene affecting septum formation after inhibition of deoxyribonucleic acid synthesis.

Escherichia coli ruv gene was located at 36.1 min on the chromosome by P1 transduction experiments and the gene order his - supD - uvrC, dar4 - ruv - eda - fadD - pps was proposed. Complementation analysis by an F' factor carrying genes in the his region indicated that ultraviolet light sensitivity genes, ruv and uvrC, consist of different cistrons and wild-type alleles of these genes are dominant over the mutant alleles.     

Escherichia coli supH suppressor: temperature-sensitive missense suppression caused by an anticodon change in tRNASer2.

We describe the cloning and the DNA sequence of the Escherichia coli supH missense suppressor and of the supD60(Am) suppressor genes. supH is a mutant form of serU which codes for tRNASer2. The supH coding sequence differs from the wild-type sequence by a single nucleotide change which corresponds to the middle position of the anticodon. The CGA anticodon of wild-type tRNA and CUA anticodon of supD tRNA is changed to CAA in supH tRNA, which is expected to recognize the UUG leucine codon. We propose that the supH suppressor causes the insertion of serine in response to this codon. The temperature sensitivity caused by supH may be due to a conformation of the CAA anticodon in the supH tRNASer that is slightly different than that in the corresponding tRNALeu species.     

Genetic Mapping and Dominance of the Amber Suppressor, Su1 (supD), in Escherichia coli K-12

In this report Su1 (supD), which is known to suppress "amber" mutations by means of a specific transfer ribonucleic acid, has been mapped relative to his and uvrC and has been found to be located at about 37.5 min on the Taylor and Trotter genetic map of the Escherichia coli K-12 chromosome. In addition, Su1(+) has been shown to be dominant over Su1(-), which supports the idea that Su1 is the structural gene for the suppressing transfer ribonucleic acid.     

On the molecular basis of the thermal sensitivity of an Escherichia coli topA mutant.

Studies of two temperature-sensitive Escherichia coli topA strains AS17 and BR83, both of which were supposed to carry a topA amber mutation and a temperature-sensitive supD43,74 amber-suppressor, led to conflicting results regarding the essentiality of DNA topoisomerase I in cells grown in media of low osmolarity. We have therefore reexamined the molecular basis of the temperature sensitivity of strain AS17. We find that the supD allele in this strain had lost its temperature sensitivity. The temperature sensitivity of the strain, in media of all osmolarity, results from the synthesis of a mutant DNA topoisomerase I that is itself temperature-sensitive. Nucleotide sequencing of the AS17 topA allele and studies of its expected cellular product show that the mutant enzyme is not as active as its wild-type parent even at 30 degrees C, a permissive temperature for the strain, and its activity relative to the wild-type enzyme is further reduced at 42 degrees C, a nonpermissive temperature. Our results thus implicate an indispensable role of DNA topoisomerase I in E. coli cells grown in media of any osmolarity.     

Genetic Analysis of Mutations Indirectly Suppressing recB and recC Mutations

Mutations in sbcB inactivate exonuclease I and suppress the UV-sensitive, mitomycin-sensitive, recombination-deficient phenotypes associated with recB and recC mutations. Mapping experiments have located sbcB about 0.4 minutes from the his operon at 38.0 on the standard map of E. coli. This places sbcB between supD and his. A four-point cross shows that sbcB lies between P2 attH and his. P2 eduction deleting the his operon beginning with P2 attH also deletes sbcB and produces the expected exonuclease I deficiency and suppression of recB(-). The occurrence of chemical-mutagen-induced and spontaneous mutations indirectly suppressing recB(-) and recC(-) is examined. Three lines of strains produce only sbcA mutations while only sbcB mutations occur in a fourth line. Explanations for this behavior are proposed in light of the ability of the first three lines to express sbcB mutations which they inherit by transduction.     

Regulation of tyrosine and phenylalanine biosynthesis in Escherichia coli K-12: properties of the tyrR gene product

A spontaneous amber tyrR mutant has been isolated in which constitutive synthesis of 3-deoxy-d-arabinoheptulosonic acid 7-phosphate (DAHP) synthetase (tyr) and DAHP synthetase (phe) is suppressible by supC(-), supD(-), supF(-) and supU(-). This finding suggests the tyrR gene product is a protein. Derepression of DAHP synthetase (phe) in this and in seven other spontaneous tyrR mutants and in four Mu-1-induced tyrR mutants provides further evidence for the involvement of the tyrR gene product in phenylalanine biosynthesis. Evidence that the tyrR product is a component of repressor, rather than an enzyme involved in its synthesis or modification, comes from a study of a temperature-sensitive tyrR mutant. This mutant is of the thermolabile type, since derepression occurs rapidly and in the presence and absence of growth.     

A nucleotide change in the anticodon of an Escherichia coli serine transfer RNA results in supD-amber suppression.

The tRNAs specified by the wild type and amber suppressor alleles of the Escherichia coli supD gene have been identified, and their primary structures determined. The sequences differ by a single nucleotide in the middle of the anticodon. A CUA anticodon allows the suppressor tRNA to read the UAG stop codon; the CGA anticodon in the minor serine tRNA species from which the suppressor is derived is specific for the serine codon UCG.     

Lambdoid Coliphage HK139 Integrates Between his and supD

Phage HK139 is UV inducible and lambda homoimmune and has the host range of phi80. It can recombine with lambda as well as with phi80, and in the prophage form it is found integrated between the loci his and supD.     

An amber mutation in the gene encoding the beta'' subunit of Escherichia coli RNA polymerase.

An Escherichia coli strain carrying an amber mutation (UAG) in rpoC, the gene encoding the beta prime subunit of RNA polymerase, was isolated after mutagenesis with nitrosoguanidine. The mutation was moved into an unmutagenized strain carrying the supD43,74 allele, which encodes a temperature-sensitive su1 amber suppressor, and sue alleles, which enhance the efficiency of the suppressor. In this background, beta prime is not synthesized at high temperature. Suppression of the mutation by the non-temperature-sensitive amber suppressor su1+ yields a protein which is functional at all temperatures examined (30, 37, and 42 degrees C).     

Nonsense and insertion mutants in the relA gene of E. coli: cloning relA.

We have made use of lysogens of a specialized transducing bacteriophage, lambdapyrG+ relA+, to select nonsense (relAnon) and insertion (relAins) mutations in the relA gene. Three independent relAnon mutants were isolated on the phage. In all three, the relaxed phenotype was suppressed by supD, supE, supF or sup6. Three independent relAins mutants were isolated, all containing an insertion element (probably IS2) in an apparently identical location in the relA gene. Polyacrylamide gel electrophoretic analysis of peptides synthesized by the phages in ultraviolet lightkilled host cells revealed that no stringent factor was coded for by either the relAins or relAnon phages (the latter in a sup+ cell); stringent factor was detected when the relAnon phages were used in a similar experiment with supD or supE host cells. The relAnon and relAins mutations could be crossed in haploid form in the E. coli chromosome. These recombinants grew with a normal doubling time, had a ppGpp pool which was between 70 and 100% compared with the classical relA strain, and underwent a normal carbon source shift-down. A restriction endonuclease map of the pyrG relA region of the specialized transducing phage is presented in which the position of the insertion element (recognized by a novel Hind III-cut site) defines the position of the relA gene. This position was verified by an analysis of the structure of five plasmids formed by cloning portions of the region in the pBR322 cloning vehicle. Our results indicate that the relA gene is not an essential cellular function, that there might be a second mechanism for the synthesis of basal level ppGpp in the cell and that the sole function of the relA gene is apparently the high level ppGpp synthesis triggered in response to deacylated tRNA.     

Conditionally transposition-defective derivative of Mu d1(Amp Lac).

A Mu d1 derivative is described which is useful for genetic manipulation of Mu-lac fusion insertions. A double mutant of the specialized transducing phage Mu d1(Amp Lac c62ts) was isolated which is conditionally defective in transposition ability. The Mu d1 derivative, designated Mu d1-8(Tpn[Am] Amp Lac c62ts), carries mutations which virtually eliminate transposition in strains lacking an amber suppressor. In such strains, the Mu d1-8 prophage behaves like a standard transposon. It can be moved from one strain of Salmonella typhimurium to another by the general transducing phage P22 with almost 100% inheritance of the donor insertion mutation. When introduced into a recipient carrying supD, supE, or supF, 89 to 94% of the Ampr transductants were transpositions of the donor Mu d1-8, from the transduced fragment into new sites. The stability of Mu d1-8 in a wild-type, suppressor-free background was sufficient to permit use of the fusion to select constitutive mutations without prior isolation of deletions to stabilize the fusion. Fusion strains could be grown at elevated temperature without induction of the Mu d prophage. The transposition defect of Mu d1-8 was corrected by a plasmid carrying the Mu A and B genes.     

The construction in vitro of transducing derivatives of phage lambda

Summary Methods are described for the construction of plaque-forming, transducing derivatives of phage lambda, using appropriate receptor genomes and fragments of DNA generated by the restriction enzymes endo R.EcoRI and endo R.HindIII. The general properties of the transducing derivatives are described and discussed. Plaque-forming phages carrying the E. coli trp, his, cysB, thyA, supD, supE, supF, hsd, tna and lig genes have been isolated.     

Isolation and characterization of D-serine deaminase constitutive mutants by utilization of D-serine as sole carbon or nitrogen source.

Mutants constitutive for D-serine deaminase (Dsdase) synthesis were isolated by utilizing D-serine as sole nitrogen or carbon source in the chemostat. This method generated only regulatory constitutive (dsdC) mutants. The altered dsdC gene product in these strains is apparently able to bind D-serine more efficiently than the wild-type dsdC+ gene product--a selective advantage. Constitutive synthesis of Dsdase in all of these dsdC mutants is extremely sensitive to catabolite repression, and catabolite repression is reversed by the addition of D-serine. Of the 15 mutants generated by this method, none are suppressible by supD, supE, or supF. Mutations to a low level of constitutivity (maximal specific activity of 9) occur much more frequently than mutations to a high level (maximal specific activity of 79). High level constitutive synthesis of Dsdase results from the synthesis of an altered dsdC gene product--not from loss of ability to form the dsdC product. Dsdase synthesis is not regulated by the nitrogen supply in the medium, as nitrogen starvation does not result in the derepression of Dsdase synthesis.     

鼠伤寒沙门氏菌嘌呤生物合成的调控研究X.purR琥珀突变体(am)的分离和氨基酸取代的初步研究

以超阻遏突变体３—１８为出发株,采用以乳糖为唯一碳源的ＮＣＥ平板的方法分离到４３９ 株调节突变体。通过转导引入ｔＲＮＡ抑制基因从中检测到 １１株 ｐｕｒＲ（ａｍ）候选株。共转导分 析证明,这些突变株的琥珀浪突变均发生在ｐｕｒＲ上。用 ｓｕｐＤ． ｓｕｐＥ和 ｓｕｐＦ分别对上述各ａｍｂｅｒ 突变体作了氨基酸取代实验,初步结果表明：同一氨基酸对ｐｕｒＲ不同位点（ａｍ）的氨基酸取 代,对ＰｕｒＲ调节功能有不同程度的影响。不同氨基酸（３种）对ｐｕｒＲ同一位点（ａｍ）的氨基酸取 代,对其调节功能的影响也存在差异。     

High expression of the second lysine decarboxylase gene, ldc, in Escherichia coli WC196 due to the recognition of the stop codon (TAG), at a position which corresponds to the 33th amino acid residue of sigma38, as a serine residue by the amber suppressor, supD

Escherichia coli WC196, which was obtained from the strain W3110 by nitrosoguanidine mutagenesis as an overproducer of lysine, produced approximately twenty times more cadaverine than did W3110, and had a twenty fold higher level of rpoS gene product, sigma38, than in W3110. Both WC196 and W3110 had a stop codon (TAG) in rpoS at position which corresponds to the 33th residue of sigma38 protein. In addition, WC196 but not W3110 had a mutation in the gene encoding Ser-tRNA (SerU), called, supD. Analysis of the amino acid sequence of a sigma38 preparation from WC196 showed that the 33th residue of sigma38 is a serine residue. The deltarpoS deltacadA mutant of E. coli W3110 harboring the plasmid containing rpoS, in which the TAG codon was converted to a TCG codon for serine-33 residue of sigma38, expressed a significant amount of Ldc and accumulated a large amount of sigma38. However, the deltarpoS deltacadA mutant of W3110 with the plasmid containing the intact rpoS from W3110 could synthesize neither sigma38 nor Ldc significantly.     

F'-plasmid transfer from Escherichia coli to Pseudomonas fluorescens.

Various F' plasmids of Escherichia coli K-12 could be transferred into mutants of the soil strain 6.2, classified herein as a Pseudomonas fluorescens biotype IV. This strain was previously found to receive Flac plasmid (N. Datta and R.W. Hedges, J. Gen Microbiol. 70:453-460, 1972). ilv, leu, met, arg, and his auxotrophs were complemented by plasmids carrying isofunctional genes; trp mutants were not complemented or were very poorly complemented. The frequency of transfer was 10(-5). Subsequent transfer into other P. fluorescens recipients was of the same order of magnitude. Some transconjugants were unable to act as donors, and these did not lose the received information if subcultured on nonselective media. Use of F' plasmids helped to discriminate metabolic blocks in P. fluorescens. In particular, metA, metB, and argH mutants were so distinguished. In addition, F131 plasmid carrying the his operon and a supD mutation could partially relieve the auxotrophy of thr, ilv, and metA13 mutants, suggesting functional expression of E. coli tRNA in P. fluorescens. In P. fluorescens metA Rifr mutants carrying the F110 plasmid, which carried the E. coli metA gene and the E. coli rifs allele, sensitivity to rifampin was found to be dominant at least temporarily over resistance. This suggests interaction of E. coli and P. fluorescens subunits of RNA polymerase. his mutations were also complemented by composite P plasmids containing the his-nif region of Klebsiella pneumoniae (plasmids FN68 and RP41). nif expression could be detected by acetylene reduction in some his+ transconjugants. The frequency of transfer of these P plasmids was 5 X 10(-4).     

Suppressibility of recA, recB, and recC mutations by nonsense suppressors.

Mutations in the recA, recB, and recC genes of Escherichia coli K-12 were surveyed to ascertain whether or not they are suppressed by nonsense suppressors. Several mutations which map in or near the recA gene, but have not been called recA mutations, were also surveyed. An amber recB mutation, recB156, and an amber recC mutation, recC155, were isolated. One recB mutation, recB95, and four recC mutations, recC22, recC38, recC82, and recC83, were found to be suppressed by a UGA suppressor. In addition to the previously isolated amber recA mutation recA99, two other recA mutations, recA52 and recA123, were found to be suppressed by amber suppressor supD32 but not by supE44.