Characterization of amber and ochre suppressors in Salmonella typhimurium

Genetic analysis of bacteriophage P22 lysozyme structure

The suppression patterns of 11 phage P22 mutants bearing different amber mutations in the gene encoding lysozyme (19) were determined on six different amber suppressor strains. Of the 60 resulting single amino acid substitutions, 18 resulted in defects in lysozyme activity at 30 degrees; an additional seven were defective at 40 degrees. Revertants were isolated on the "missuppressing" hosts following UV mutagenesis; they were screened to distinguish primary- from second-site revertants. It was found that second-site revertants were recovered with greater efficiency if the UV-irradiated phage stocks were passaged through an intermediate host in liquid culture rather than plated directly on the nonpermissive host. Eleven second-site revertants (isolated as suppressors of five deleterious substitutions) were sequenced: four were intragenic, five extragenic; three of the extragenic revertants were found to have alterations near and upstream from gene 19, in gene 13. Lysozyme genes from the intragenic revertant phages were introduced into unmutagenized P22, and found to confer the revertant plating phenotype.

Heme-deficient mutants of Salmonella typhimurium: two genes required for ALA synthesis

The first step in heme biosynthesis is the formation of 5-aminolevulinic acid (ALA). We have isolated, mapped and characterized a large number of Salmonella typhimurium mutants auxotrophic for ALA. These mutants carry defects in either one of two genes, both required for ALA synthesis. The previously identified hemA gene maps at 35 min, and the hemL gene maps at 5 min on the S. typhimurium genetic map. Mutants in hemA and hemL are defective for aerobic and anaerobic respiration, and appear to be oxygen sensitive. The Hem- phenotype of hemL mutants is less severe than that of hemA mutants. Although hemA and hemL mutants are deficient in heme synthesis, genetic tests indicate that they still synthesize two minor products of the heme pathway, siroheme and cobalamin (vitamin B12), under anaerobic conditions. In contrast, hemB, hemC and cysG mutants, blocked after ALA synthesis, make neither siroheme nor vitamin B12. Double mutants defective in both hemA and hemL also make siroheme. We suggest that hemA and hemL are required for one route of ALA synthesis and that a second, minor route of ALA synthesis may operate in S. typhimurium; this second pathway would be independent of the hemA and hemL functions.

The isolation and sequence of missense and nonsense mutations in the cloned bacteriophage P22 tailspike protein gene

Twenty-seven new mutations in the structural gene for the Salmonella typhimurium bacteriophage P22 tailspike protein have been isolated, mapped using a powerful plasmid-based genetic system and their DNA sequence changes determined. The mutations were generated by hydroxylamine treatment of the cloned gene on a plasmid expression vector. Assaying the activity of the tailspike protein produced from this plasmid and screening for plasmid mutants were accomplished by the in situ complementation of P22 capsids imbedded in soft agar to produce infectious phage. Deletion mutations in the cloned gene have been constructed by a two step procedure involving oligonucleotide linker insertion and in vitro deletion by restriction endonuclease digestion. The deletions, whose physical endpoints were determined by DNA sequencing, define 12 genetic and physical intervals into which the new mutations were mapped by marker rescue experiments. These deletions were transferred to phage P22 by recombination and used to map mutations carried on plasmids. Following mapping, the nucleotide change for each of the mutations was determined by DNA sequencing. The majority were absolute missense mutations although both amber and ochre nonsense mutations were also identified in the protein coding portion of the gene. The suppression pattern of the nonsense mutations was determined on several nonsense suppressors. Four of the mutations cause severely depressed levels of tailspike protein expression from both the cloned gene on the plasmid expression vector and from P22 phage carrying these mutations. These mutations were identified as nucleotide changes in what is probably the P22 late operon transcription terminator which immediately follows the tailspike protein coding sequence.

Scaffolding protein regulates the polymerization of P22 coat subunits into icosahedral shells in vitro

Coat and scaffolding subunits derived from P22 procapsids have been purified in forms that co-assemble rapidly and efficiently into icosahedral shells in vitro under native conditions. The half-time for this reaction is approximately five minutes at 21 degrees C. The in vitro reaction exhibits the regulated features observed in vivo. Neither coat nor scaffolding subunits alone self-assemble into large structures. Upon mixing the subunits together they polymerize into procapsid-like shells with the in vivo coat and scaffolding protein composition. The subunits in the purified coat protein preparations are monomeric. The scaffolding subunits appear to be monomeric or dimeric. These results confirm that P22 procapsid formation does not proceed through the assembly of a core of scaffolding, which then organizes the coat, but requires copolymerization of coat and scaffolding. To explore the mechanisms of the control of polymerization, shell assembly was examined as a function of the input ratio of scaffolding to coat subunits. The results indicated that scaffolding protein was required for both initiation of shell assembly and continued polymerization. Though procapsids produced in vivo contain about 300 molecules of scaffolding, shells with fewer subunits could be assembled down to a lower limit of about 140 scaffolding subunits per shell. The overall results of these experiments indicate that coat and scaffolding subunits must interact in both the initiation and the growth phases of shell assembly. However, it remains unclear whether during growth the coat and scaffolding subunits form a mixed oligomer prior to adding to the shell or whether this occurs at the growing edge.

Spontaneous mutagenesis and oxidative damage to DNA in Salmonella typhimurium

Salmonella typhimurium strains containing deletions of oxyR, a positive regulator of defenses against oxidative stress, show 10- to 55-fold higher frequencies of spontaneous mutagenesis compared to otherwise isogenic oxyR+ control strains. The high spontaneous-mutation frequency in oxyR deletion strains is decreased by a factor of 3 when the strains are grown anaerobically. oxyR deletion strains show an increase in small deletion mutations and at least three of the six possible base-substitution mutations (T.A to A.T, C.G to T.A, and C.G to A.T). However, the largest increase in mutation frequency is observed for T.A to A.T transversions (40- to 146-fold), the base-substitution mutation most frequently caused by chemical oxidants. The introduction into oxyR deletion strains of multicopy plasmids carrying the oxyR-regulated genes for catalase (katG) or alkyl hydroperoxide reductase (ahp) results in overexpression of the respective enzyme activities and decreases the number of spontaneous mutants to wild-type levels. The introduction into oxyR deletions of a plasmid carrying the gene for superoxide dismutase (sodA) decreases the mutation frequency by a factor of 5 in some strain backgrounds. Strains that contain a dominant oxyR mutation and overexpress proteins regulated by oxyR show lower spontaneous-mutation frequencies by a factor of 2. These results indicate that oxyR and oxyR-regulated genes play a significant role in defense against spontaneous oxidative DNA damage. The role of oxidative damage to DNA in "spontaneous" mutagenesis is discussed.

Fusions of bacteriophage P22 late genes to the Escherichia coli lacZ gene

The late genes of bacteriophage P22 were fused to lacZ to study their differential expression from the late operon transcript. No instances of posttranscriptional regulation were uncovered, thus supporting the model that the late genes are expressed, by and large, in fixed ratios based on their translational efficiency and message stability.

Identification of sites influencing the folding and subunit assembly of the P22 tailspike polypeptide chain using nonsense mutations

Amber mutations have been isolated and mapped to more than 60 sites in gene 9 of P22 encoding the thermostable phage tailspike protein. Gene 9 is the locus of over 30 sites of temperature sensitive folding (tsf) mutations, which affect intermediates in the chain folding and subunit association pathway. The phenotypes of the amber missense proteins produced on tRNA suppressor hosts inserting serine, glutamine, tryosine and leucine have been determined at different temperatures. Thirty-three of the sites are tolerant, producing functional proteins with any of the four amino acids inserted at the sites, independent of temperature. Tolerant sites are concentrated at the N-terminal end of the protein indicating that this region is not critical for conformation or function. Sixteen of the sites yield temperature sensitive missense proteins on at least one nonsense suppressing host. Most of the sites with ts phenotypes map to the central region of the gene which is also the region where most of the tsf mutations map. Mutations at 15 of the sites have a lethal phenotype on at least one tRNA suppressor host. For nine out of ten sites tested with at least one lethal phenotype, the primary defect was in the folding or subunit association of the missense polypeptide chain. This analysis of the tailspike missense proteins distinguishes three classes of amino acid sites in the polypeptide chain; residues whose side chains contribute little to folding, subunit assembly or function; residues critical for maintaining the folding and subunit assembly pathway at the high end of the temperature range of phage growth; and residues critical over the entire temperature range of growth.

Mutations in an upstream regulatory sequence that increase expression of the bacteriophage T4 lysozyme gene

A P22 hybrid phage bearing the bacteriophage T4 lysozyme gene (e), as well as T4 sequences upstream from the lysozyme gene, was constructed. Amber mutations were introduced into gene e in the hybrid phage, and the resulting mutant phages were tested for the ability to form plaques on amber suppressor strains. Revertant phages that were able to form plaques on amber suppressors that did not suppress the parent amber mutant phages were isolated following UV mutagenesis. Secondary site pseudorevertants were identified among the revertants by a genetic test. Four of the suppressing secondary site mutations were mapped and sequenced. They were found to consist of small sequence alterations immediately upstream from gene e, all of which would tend to destabilize potential base-pairing interactions in the transcript. The mutations were shown to increase lysozyme expression when introduced into an otherwise wild-type hybrid phage, but were found to have little effect on transcription of the lysozyme gene.

Bacteriophage P22 gene 23 product acts preferentially in cis

The expression of the P22 late operon was measured while the activator of the late operon, the product of gene 23, was provided in cis or in trans. It was found that expression of the late operon, assayed from a late-gene-lacZ gene fusion, was reduced by more than twofold when the only functional copy of gene 23 was present in trans.

Initiation of bacteriophage P22 DNA packaging series. Analysis of a mutant that alters the DNA target specificity of the packaging apparatus

Bacteriophage P22 is thought to package its double-stranded DNA chromosome from concatemeric replicating DNA in a "processive" sequential fashion. According to this model, during the initial packaging event in such a series the packaging apparatus recognizes a nucleotide sequence, called pac, on the DNA, and then condenses DNA within the coat protein shell unidirectionally from that point. DNA ends are generated near the pac site before or during the condensation reaction. The opposite end of the mature chromosome is created by a cut made in the DNA after a complete chromosome is condensed within the phage head. Subsequent packaging events on that concatemeric DNA begin at the end generated by the headful cut of the previous event and proceed in the same direction as the previous event. We report here the identification of a consensus nucleotide sequence for the pac site, and present evidence that supports the idea that the gene 3 protein is a central participant in this recognition event. In addition, we tentatively locate the portion of the gene 3 protein that contacts the pac site during the initiation of packaging.

Characterization of suppressible mutations in the viomycin phosphotransferase gene of the Streptomyces enteric plasmid pVE138

The viomycin phosphotransferase gene (vph) is expressed and confers resistance to viomycin in both Streptomyces spp. and members of the family Enterobacteriaceae. We report the isolation of UGA (opal) and UAG (amber) mutations in the vph gene of shuttle plasmid pVE138. We found that the five UGA mutations in vph resulted in a temperature-sensitive phenotype in Salmonella typhimurium. Su- strains are Vior at 28 degrees C and Vios at 37 degrees C, whereas Su+UGA strains are Vior at both 28 and 37 degrees C. The single amber mutation isolated was not temperature sensitive and resulted in the expected Vios phenotype in Su- strains and Vior in Su+UAG strains.

Influence of modification next to the anticodon in tRNA on codon context sensitivity of translational suppression and accuracy

Effects on translation in vivo by modification deficiencies for 2-methylthio-N6-isopentenyladenosine (ms2i6A) (Escherichia coli) or 2-methylthio-N6-(4-hydroxyisopentenyl)adenosine (ms2io6A) (Salmonella typhimurium) in tRNA were studied in mutant strains. These hypermodified nucleosides are present on the 3' side of the anticodon (position 37) in tRNA reading codons starting with uridine. In E. coli, translational error caused by tRNA was strongly reduced in the case of third-position misreading of a tryptophan codon (UGG) in a particular codon context but was not affected in the case of first-position misreading of an arginine codon (CGU) in another codon context. Misreading of UGA nonsense codons at two different positions was codon context dependent. The efficiencies of some tRNA nonsense suppressors were decreased in a tRNA-dependent manner. Suppressor tRNA which lacks ms2i6A-ms2io6A becomes more sensitive to codon context. Our results therefore indicate that, besides improving translational efficiency, ms2i6A37 and ms2io6A37 modifications in tRNA are also involved in decreasing the intrinsic codon reading context sensitivity of tRNA. Possible consequences for regulation of gene expression are discussed.

Classifying mutagens as to their specificity in causing the six possible transitions and transversions: a simple analysis using the Salmonella mutagenicity assay

The standard Salmonella tester strains used to detect base substitution mutations carry the hisG428 ochre mutation (TA102 and TA104) and the hisG46 missense mutation (TA100). These mutations can be reverted by base changes at their mutant his loci or at extragenic suppressor loci. The base changes resulting in each class of revertants of these mutations have been identified, and simple phenotypic screens have been developed to distinguish among them. Revertants at extragenic suppressor loci are distinguished from those at the his loci by their sensitivity to inhibitory histidine analogs. The four ochre suppressor loci of hisG428 are distinguished by their ability to support growth of nonsense mutants of phage P22. These screens are the basis for a rapid and simple system for determining the base substitution specificity of mutagens using hisG428- and hisG46-containing tester strains. Diagnostic mutagens specific for each of the six possible base changes (transitions and transversions) have been identified. Using these diagnostic mutagens, two additional strains, each specifically reverted by a single base substitution mutation, have been developed to provide a minimum of two loci at which to detect each type of base change. The ability of this system to provide detailed information about mutational specificity in a variety of DNA repair backgrounds will allow further elucidation of the mechanisms of mutagenesis and DNA repair.

Bacteriophage L: chromosome physical map and structural proteins

Restriction endonuclease cleavage site mapping was used to locate the regions of highest sequence homology in the chromosomes of Salmonella typhimurium bacteriophages L and P22. These lie in the DNA packaging, tail, early transcription antitermination, and perhaps integration "gene modules." Other regions of the two genomes are substantially less closely related. Phage L, which has no functional immunity I region, lacks approximately 1300 bp of DNA when compared to P22 in this section of the chromosome. At least some of the virion structural proteins are interchangeable between the two phages, which suggests that the two phage structural protein genes are very closely related. In addition, the apparent molecular weights of most P22 and L phage structural proteins are very similar. However, the phage L virion contains about 140 molecules of a 15K capsid protein which apparently has no P22 analog.

Induction of transversion mutations in Escherichia coli by N-methyl-N'-nitro-N-nitrosoguanidine is SOS dependent

Escherichia coli alkA mutants, which are deficient for an inducible DNA glycosylase, 3-methyladenine-DNA glycosylase II, are sensitive to mutagenesis by low doses of the alkylating agent N-methyl-N'-nitro-N-nitrosoguanidine (MNNG). As many as 90% of the alkA-dependent mutations induced by MNNG are also umuC+ dependent and thus are due to DNA lesions that are substrates for the mutagenic functions of the SOS response. A great number of these mutations are base substitutions at A . T sites, particularly A . T transversions. We discuss which DNA lesions may be responsible for these mutations. Our results show that the induction of 3-methyladenine-DNA glycosylase II, which occurs as part of the adaptive response to alkylating agents such as MNNG, significantly reduces the mutagenicity as well as the lethality of alkylation damage.

Bacteriophage P22 tail protein gene expression

We have found that mutations which block bacteriophage P22 head assembly at or before the DNA packaging stage (1-, 2-, 3-, 5-, and 8-) cause up to a 20-fold increase in the amount of tail (gene 9) protein made during infection. This correlation seems strong enough to warrant consideration of a control mechanism in which the failure to package DNA per se causes a large increase in the synthesis of tail protein. Our results indicate that one of the repressors required for maintenance of lysogeny, the mnt gene product, may be partially responsible for this phenomenon.

Assembly-controlled autogenous modulation of bacteriophage P22 scaffolding protein gene expression

In the assembly of bacteriophage P22, precursor particles containing two major proteins, the gene 5 coat protein and the gene 8 scaffolding protein, package the DNA molecule. During the encapsidation reaction all of the scaffolding protein molecules are released intact and subsequently participate in further rounds of DNA encapsidation. We have previously shown that even though it lies in the center of the late region of the genetic map, the scaffolding protein gene is not always expressed coordinately with the remainder of the late proteins and that some feature of the phage assembly process affects its expression. We present here in vivo experiments which show that there is an inverse correlation between the amount of unassembled scaffolding protein and the rate of scaffolding protein synthesis and that long amber fragments of the scaffolding protein can turn down the synthesis of intact scaffolding protein in trans. These results support a model for scaffolding protein regulation in which the feature of the assembly process which modulates the rate of scaffolding protein synthesis is the amount of unassembled scaffolding protein itself.

Autoregulation of the bacteriophage P22 scaffolding protein gene

During the formation of each bacteriophage P22 head, about 250 molecules of the product of gene 8, scaffolding protein, coassemble with and dictate correct assembly of the coat protein into a proper shell structure. At approximately the time that DNA is inserted inside the coat protein shell, all of the scaffolding protein molecules leave the structure. They remain active and participate in several subsequent rounds of shell assembly. Previous work has shown that scaffolding protein gene expression is affected by the head assembly process and has generated the hypothesis that unassembled scaffolding protein negatively modulates the expression of its own gene but that it lacks this activity when complexed with coat protein in proheads. To test this model, a P22 restriction fragment containing the scaffolding and coat protein genes was cloned under control of the lac promoter. These cloned genes were then expressed in an in vitro DNA-dependent transcription-translation reaction. The addition of purified scaffolding protein to this reaction resulted in reduced scaffolding protein synthesis relative to coat and tail protein synthesis to an extent and at a protein concentration that was consistent with the observed reduction in vivo. We conclude that scaffolding protein synthesis is autoregulated and that scaffolding protein is the only phage-coded protein required for this process. In addition, these experiments provide additional evidence that this autoregulation is posttranscriptional.

Fine structure analysis of Salmonella typhimurium glutamate synthase genes

Glutamate synthase activity is required for the growth of Salmonella typhimurium on media containing a growth-rate-limiting nitrogen source. Mutations that alter glutamate synthase activity had been identified in the gltB gene, but it was not known which of the two nonidentical subunits of the enzyme was altered. To examine the gene-protein relationship of the glt region, two nonsense mutations were identified and used to demonstrate that gltB encodes the large subunit of the enzyme. Six strains with independent Mu cts d1 (lac bla) insertions were isolated, from which a collection of deletion mutations was obtained. The deletions were transduced with the nonsense mutations and 38 other glt point mutations to construct a fine-structure genetic map. Chromosome mobilization studies, mediated by Hfr derivatives of Mu cts d1 lysogens, showed that gltB is transcribed in a clockwise direction, as shown in the S. typhimurium linkage map. Studies of the polar effects of three Mu cts d1 insertions indicated that the gene for the small subunit maps clockwise to gltB and that the two genes are cotranscribed to form a glt operon.

Single amino acid substitutions influencing the folding pathway of the phage P22 tail spike endorhamnosidase

Temperature-sensitive mutations in the gene for the thermostable tail spike of phage P22 interyFere with the folding and subunit association pathway at the restrictive temperature but not with the activity or stability of the protein once matured. The local sites of these mutations and the mutant amino acid substitutions have been determined by DNA sequencing. Of 11 temperature-sensitive folding mutations, 3 were replacements of glycine residues by polar residues, and three were replacements of threonine residues by residues unable to form a side-chain H-bond. There were no proline replacements. Two of the temperature-sensitive sites in which threonine residues were replaced by isoleucine residues were homologous. These sequences probably maintain the correct local folding pathway at higher temperatures. The temperature-sensitive amino acid substitutions appear to destabilize a thermolabile intermediate in the wild-type folding pathway or to increase the rate of a competing off-pathway reaction.

Functional interchangeability of DNA replication genes in Salmonella typhimurium and Escherichia coli demonstrated by a general complementation procedure

Twenty-four genes from Salmonella typhimurium that affect DNA replication were isolated from a lambda-Salmonella genomic library by lysogenic complementation of temperature-sensitive mutants of Salmonella or E. coli, using a new plaque complementation assay. The complementing lambda clones, which make red plaques in this assay, and noncomplementing mutant derivatives, which make uncolored plaques, were used to further characterize the temperature-sensitive Salmonella mutants and to establish the functional similarity of E. coli and Salmonella DNA replication genes. For 17 of 18 E. coli mutants representing distinct loci, a Salmonella gene that complemented the mutant was found. This result indicates that single Salmonella replication proteins are able to function in otherwise all E. coli replication complexes and suggests that the detailed properties of Salmonella and E. coli replication proteins are very similar. The other seven Salmonella genes that were cloned were unrelated functionally to any E. coli genes examined. --As an aid to the derivation of chromosomal mutations affecting some of the cloned genes, a general method was developed for placing a transposon in the Salmonella chromosome in a segment corresponding to cloned DNA. Chromosomal mutations were derived in Salmonella affecting a gene (dnaA) that was cloned by complementation of an E. coli mutant by using the transposon-encoded drug resistance as a selectable marker in local mutagenesis.

Facile and gentle method for quantitative lysis of Escherichia coli and Salmonella typhimurium

Garrett et al. (Mol. Gen. Genet. 182:326-331, 1981) constructed strains of Escherichia coli harboring derivatives of plasmid pBR322 that carry the lysis genes (S, R, and Rz) of phage lambda. The plasmid construction placed the genes under control of the lactose operon operator-promotor (and thus of lac repressor). Induction of E. coli strains carrying these plasmids resulted in rapid lysis of the culture unless the S gene was defective, in which case the cells grew normally. A freeze-thaw treatment of induced cells carrying an S- plasmid gave quantitative lysis of either E. coli or Salmonella typhimurium cells under exceptionally gentle conditions. The method was equally effective on exponential phase cells and stationary phase cells and was readily extended to a large number of independent cultures.

Steps in the stabilization of newly packaged DNA during phage P22 morphogenesis

The protein products of three adjacent P22 genes, 4, 10 and 26, are required for the stabilization of DNA newly packaged into P22 phage capsids. We have isolated unstable DNA containing capsids from cells infected with mutants defective in these genes. All three classes could be converted into mature phage in vitro, confirming that they represent intermediates in particle maturation. The first of the three proteins to add to the newly filled capsids is gp4, followed by gp10 and gp26. The active form of gp4 sediments at 3 S, while the active forms of both gp10 and gp26 sediment at 5 S. These soluble subunits appear to polymerize onto the newly filled capsids to form the neck of the mature phage, the channel for DNA injection. Since gp4 is the first protein to act after DNA packaging, the unstable DNA containing capsids from 4- -infected cells must represent the direct product of the packaging of DNA into procapsids. The major fraction of these capsids lost activity with a half-life of 1.1 minutes at 23 degrees C, though they were much more stable at 0 degree C. Electron microscopic observations indicated that the loss of activity was due to the DNA exiting from the incomplete capsids. The marginal stability of the condensed DNA molecules within capsids is consistent with models of ATP-driven condensation and spontaneous DNA ejection. The basis of the stability of these highly condensed molecules remains to be determined.

On the sequential packaging of bacteriophage P22 DNA

Bacteriophage P22 is thought to package daughter chromosomes serially along concatemeric DNA. We present experiments which show that the average DNA packaging series length increases with time after infection, which supports this model. In addition, we have analyzed the effect on average series length of lowering the amount of the various individual proteins involved in DNA packaging. These results support the notion that the protein products of gene 2 and gene 3 are both more stringently required for initiation of sequential DNA packaging series than for their extension, and they are compatible with a model for the control of series length in which that length is determined, at least in part, by a competition between series initiation events and extension events.

Two alanine racemase genes in Salmonella typhimurium that differ in structure and function

Mutations were isolated in a previously undescribed Salmonella typhimurium gene encoding an alanine racemase essential for utilization of L-alanine as a source of carbon, energy, and nitrogen. This new locus, designated dadB, lies within one kilobase of the D-alanine dehydrogenase locus (dadA), which is also required for alanine catabolism. The dadA and dadB genes are coregulated. Mutants (including insertions) lacking the dadB alanine racemase do not require D-alanine for growth unless a mutation is introduced at a second locus, designated dal. Two genes specifying alanine racemase activity were cloned from S. typhimurium. The two cloned DNA sequences do not cross-hybridize with each other; one was shown to contain the dadB gene.

Context effects: translation of UAG codon by suppressor tRNA is affected by the sequence following UAG in the message

The efficiency of various suppressor tRNAs in reading the UAG amber codon has been measured at 42 sites in the lacI gene. Results indicate that: (1) for all suppressors, efficiency is not an a priori value; rather, it is determined at each site by the specific reading context of the suppressed codon; (2) the degree of sensitivity to context effects differs among suppressors. Most affected is amber suppressor supE (su2), whose activity varies over a 20-fold range depending on context; (3) context effects are produced by residues present at the 3' side of the UAG codon. The most important role appears to be played by the base that is immediately adjacent to the codon. When this base is a purine, the amber codon is suppressed more efficiently than when a pyrimidine is in the same position. Superimposed on this initial pattern, the influence of bases further downstream to the UAG triplet can be detected also. The possibility is discussed that context effects are produced by the whole codon following UAG in the message.

Additional restriction endonuclease cleavage sites on the bacteriophage P22 genome

We present complete restriction endonuclease cleavage site maps of the bacteriophage P22 chromosome for 16 enzymes with six base recognition sequences, thereby positioning 116 new sites on the chromosome. Twenty-four such restriction maps for P22 DNA, containing 162 sites, have now been completed, and three enzymes were found that did not cut P22 DNA. Our results are consistent with the ideas that ClaI does not cleave the methylated recognition sequence ATCGA(me)T or A(me)TCGAT and StuI does not cleave the methylated recognition sequence AGGCC(me)T.

Genetic characterization of the sufj frameshift suppressor in Salmonella typhimurium

A new suppressor of +1 frameshift mutations has been isolated in Salmonella typhimurium. This suppressor, sufJ, maps at minute 89 on the Salmonella genetic map between the argH and rpo(rif) loci, closely linked to the gene for the ochre suppressor tyrU(supM). The suppressor mutation is dominant to its wild-type allele, consistent with the suppressor phenotype being caused by an altered tRNA species. The sufJ map position coincides with that of a threonine tRNA(ACC/U) gene; the suppressor has been shown to read the related fourbase codons ACCU, ACCC, ACCA.--The ability of sufJ to correct one particular mutation depends on the presence of a hisT mutation which causes a defect in tRNA modification. This requirement is allele specific, since other frameshift mutations can be corrected by sufJ regardless of the state of the hisT locus.--Strains carrying both a sufJ and a hisT mutation are acutely sensitive to growth inhibition by uracil; the inhibition is reversed by arginine. This behavior is characteristic of strains with mutations affecting the arginine-uracil biosynthetic enzyme carbamyl phosphate synthetase. The combination of two mutations affecting tRNA structure may reduce expression of the structural gene for this enzyme (pyrA).

Isolation of nonsense mutants of lipid-containing bacteriophage PRD1

We isolated nonsense mutants of bacteriophage PRD1, a lipid-containing polyhedral virus capable of infecting many genera of gram-negative bacteria. These mutants were grouped into 19 classes on the basis of genetic complementation and sodium dodecyl sulfate-polyacrylamide gel electrophoretic analysis. PRD1 infection led to the synthesis of at least 25 viral proteins, 17 of which were components of mature virions. The synthesis of proteins fell into the following three classes: very early, middle early, and late. Two of the very early proteins, P1 and P8, had an effect on DNA synthesis, host protein synthesis shutoff, and the turning on of middle and late protein synthesis. Another very early protein, P12, was involved in the shutoff of early protein synthesis. Two genes were identified as affecting lysis of the host. One appeared to be a lysin, whereas the other was an accessory lytic factor.

The influence of codon context on genetic code translation

A class of mutations that increase the deficiency of a suppressor tRNA in translating a particular amber codon has been characterized. The increased efficiency is due to a mutation resulting in a change in the mRNA that affects the nucleotide adjacent to the 3' side of the UAG triplet. Thus the interaction of tRNA with mRNA is influenced by mRNA sequences outside the triplet codon.

Secretion of beta-lactamase requires the carboxy end of the protein

Synthesis and secretion of beta-lactamase were studied in Salmonella typhimurium infected with P22 phage carrying the structural gene for beta-lactamase (the bla gene) in mutant or wild-type form. The wild-type gene was shown to specify two forms of beta-lactamase which differ in molecular weight by about 2500 daltons. This difference is consistent with removal, predicted on other grounds, of 23 amino-terminal residues (the "signal" sequence). All bla- mutants, including chain-terminating mutants lacking as much as 50% or as little as 10% of the protein, were apparently unaffected in this processing step. Pulse-chase experiments showed that more than 85% of the wild-type (as well as mutant) proteins are synthesized as complete overlength precursors before being processed to their mature forms. Virtually all the mature wild-type protein appears in the periplasmic space whereas a large fraction of the precursor appears in the cytoplasm. In contrast, both the precursor and processed forms of beta-lactamase proteins synthesized by chain-terminating mutants (including one which lacks only 10% of its residues from the carboxy end) are not secreted and apparently remain soluble in the cytoplasm. These results show that the carboxy-terminal amino acid sequence (at least) of beta-lactamase is essential to successful transport across the cytoplasmic membrane, and suggest that the presence (and probably also the act of removal) of the signal sequence does not suffice to ensure secretion.

Structure and functions of the bacteriophage P22 tail protein

The product of gene 9 (gp9) of Salmonella typhimurium bacteriophage P22 is a multifunctional structural protein. This protein is both a specific glycosidase which imparts the adsorption characteristics of the phage for its host and a protein which participates in a specific assembly reaction during phage morphogenesis. We have begun a detailed biochemical and genetic analysis of this gene product. A relatively straightforward purification of this protein has been devised, and various physical parameters of the protein have been determined. The protein has an s(20,w) of 9.3S, a D(20,w) of 4.3 x 10(-7) cm(2)/s, and a molecular weight, as determined by sedimentation equilibrium, of 173,000. The purified protein appears as a prolate ellipsoid upon electron microscopic examination, with an axial ratio of 4:1, which is similar to the observed shape when it is attached to the phage particle. The molecular weight is consistent with the tail protein being a dimer of gp9 and each phage containing six of these dimers. An altered form of the tail protein has been purified from supF cells infected with a phage strain carrying an amber mutation in gene 9. Phage "tailed" with this altered form of gp9 adsorb to susceptible cells but form infectious centers with a severely reduced efficiency (ca. 1%). Biochemical analysis of the purified wild-type and genetically altered tail proteins suggests that loss of infectivity correlates with a loss in the glycosidase activity of the protein (2.5% residual activity). From these results we propose that the glycosidic activity of the P22 tail protein is not essential for phage assembly or adsorption of the phage to its host but is required for subsequent steps in the process of infection.

Mapping of the supP (Su6+) amber suppressor gene in Escherichia coli

The supP (Su6(+)) amber suppressor gene has been mapped on the clockwise side of the valS locus near min 95 on the Escherichia coli chromosome.

Model for regulation of the histidine operon of Salmonella

A model is proposed that accounts for regulation of the histidine operon by a mechanism involving alternative configuration of mRNA secondary structure (the alternative stem model). New evidence for the model includes sequence data on three regulatory mutations. The first (hisO1242) is a mutation that deletes sequences needed to form the attenuator mRNA stem and causes constitutive operon expression. The second mutation (hisO9654) is a His- ochre (UAA) mutation in the leader peptide gene; the existence of this mutation constitutes evidence that the leader peptide gene is translated. The third mutation (hisO9663) is remarkable. It neither generates a nonsense codon nor affects a translated sequence; yet, it is suppressible by amber suppressors. We believe this mutation causes a His- phenotype by interfering with mRNA secondary structure. The suppressibility of the mutation is probably due to disruption of the attenuator stem by ribosomes that read through the terminator codon of the leader peptide gene. This explanation is supported by the observation of derepression of a wild-type control region in the presence of an amber suppressor. Evidence is presented that hisT mutants (which lack pseudouridine in the anticodon arm of histidine tRNA) may cause derepression of the his operon by slowing protein synthesis in the leader peptide gene.