Conditional lethal mutants of bacteriophage T4 unable to grow on a streptomycin resistant mutant of Escherichia coli.

Sixteen conditional lethal mutants of bacteriophage T4D have been isolated which grow on Escherichia coli CR63 (a su+ streptomycin-sensitive K12 strain) but are restricted by CR/s (a streptomycin-resistant derivative of CR63). These mutants have been given the prefix str. Four of these mutants are amber and 12 appear to be missense. Eleven of the 12 missense mutants appear to be "pseudo-amber" (i.e. they are restricted by a su- E. coli B strain but not by a su- K12 strain); the other missense mutant was not restricted by either B or K12. The str mutations mapped in 12 different genes. Most were clustered in a region of early genes (gene 56 to gene 47). Fifty-eight amber and 10 "pseudo-amber" mutants isolated previously for their inability to grow on E. coli B were tested for restriction by CR/s. All the amber mutants grew normally on CR/s, whereas all 10 "pseudo-amber" mutants were restricted by CR/s. This implies that the phenotype of the "pseudo-amber" mutants is the result of a ribosomal difference between the permissive host CR63 and the restrictive hosts B and CR/s. These str mutants should prove to be useful alternatives to amber mutants for genetic and biochemical studies of bacteriophage T4 and for studies of the E. coli ribosome. It should be possible ot isolate similar mutants in other bacteriophages provided that streptomycin resistant hosts are available.     

Suppression of amber and ochre rII mutants of bacteriophage T4 by streptomycin

Orias, E. (University of California, Santa Barbara), and T. K. Gartner. Suppression of amber and ochre rII mutants of bacteriophage T4 by streptomycin. J. Bacteriol. 91:2210-2215. 1966.-Streptomycin-induced suppression of amber and ochre rII mutants of phage T4 was studied in a streptomycin-sensitive strain of Escherichia coli and four nearly isogenic streptomycin-resistant derivatives of this strain, in the presence and in the absence of an ochre suppressor. Most of the 12 rII mutants tested were suppressed by streptomycin in the streptomycin-sensitive su(-) strain. This streptomycin-induced suppression in the su(-) strain was eliminated by the independent action of at least two of the four nonidentical mutations to streptomycin resistance. In two of the su(+)str-r strains, streptomycin markedly augmented the suppression caused by the ochre suppressor. In those su(-)str-r hosts in which significant streptomycin-induced suppression could be measured, the amber mutants were more suppressible than the ochre mutants.     

Isolation of mutants of bacteriophage T4 unable to induce thymidine kinase activity. II. Location of the structural gene for thymidine kinase.

Amber mutants of bacteriophage T4 have been isolated that induce thymidine kinase activity only after infection of a strain of Escherichia coli carrying a suppressor mutation. The activity induced when one of these mutants infected this suppressor strain is much more heat sensitive than the activity induced by wild-type T4. This indicates that this amber mutation lies within the structural gene for thymidine kinase. This gene is between fI and v on the standard T4 genetic map. A mutant of tt4 that is unable to induce thymidine kinase activity incorporates only about one-eighth as much thymidine into its DNA as phage that do induce thymidine kinase. This contrasts to the findings that the total thymidine kinase activity in extracts prepared from cells infected with phage able to induce thymidine kinase in only twice as great as the activity in cells infected with the mutant unable to induce the enzyme.     

Characterization of new regulatory mutants of bacteriophage T4. II. New class of mutants.

Amber mutants of bacteriophage T4 have been isolated that induce thymidine kinase activity only after infection of a strain of Escherichia coli carrying a suppressor mutation. The activity induced when one of these mutants infected this suppressor strain is much more heat sensitive than the activity induced by wild-type T4. This indicates that this amber mutation lies within the structural gene for thymidine kinase. This gene is between fI and v on the standard T4 genetic map. A mutant of tt4 that is unable to induce thymidine kinase activity incorporates only about one-eighth as much thymidine into its DNA as phage that do induce thymidine kinase. This contrasts to the findings that the total thymidine kinase activity in extracts prepared from cells infected with phage able to induce thymidine kinase in only twice as great as the activity in cells infected with the mutant unable to induce the enzyme.     

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.     

Nonsense suppression in a multiauxotrophic derivative of Escherichia coli 15T-: identification and consequences of an amber triplet in the deoxyribomutase gene

Previously, arginine revertants of Escherichia coli WWU, a derivative of E. coli 15T(-), have been subdivided by two independent methods: (i) the streak morphology on nutrient agar, and (ii) the pattern of phage growth using amber and ochre mutants of bacteriophage T4. In the first assay, revertants were subdivided into two classes according to the appearance of streaks after incubation on nutrient agar, a thick, even line of growth defining normal revertants and a thin, irregular line defining aberrant revertants. In the second assay, revertants were classified by the suppressors they contained. The present work demonstrates that revertants containing an amber suppressor show the aberrant morphology and are also able to catabolize thymidine for energy and carbon. This is in contrast to the parent WWU containing no suppressor, which shows a normal morphology and cannot utilize thymidine as an energy source. Revertants containing no suppressor, isolated specifically for their ability to catabolize thymidine, show an aberrant morphology. Together, these results indicate that the aberrant morphology results from suppression of an amber triplet in a gene of the thymidine catabolic pathway. Enzyme assays show the amber triplet to be in the gene specifying deoxyribomutase. It is suggested that the aberrant arginine revertants are analogous to high thymine-requiring mutants and that, in general, high and low thymine-requiring mutants differ from one another in their ability to catabolize deoxyribose-1-phosphate.     

Isolation of nonsense suppressor mutants in Pseudomonas.

A strain of Escherichia coli harboring the drug resistance plasmid RP1 was treated with the mutagen N-methyl-N-nitro-N-nitro-N-nitrosoguanidine, and mutants were isolated in which ampicillin resistance had been lost due to an amber mutation in the plasmid. One of these mutants was again treated, and a strain was isolated in which tetracycline resistance was also lost due to an amber mutation in the plasmid. The plasmid containing amber mutations in the genes amp and tet was named pLM2. This plasmid could be transferred to strains of Pseudomonas aeruginosa, P. phaseolicola, and P. pseudoalcaligenes. Mutants resistant to ampicillin and tetracycline could not be obtained from P. phaseolicola carrying pLM2. However, strains of E. coli, P. aeruginosa, and P. pseudoalcaligenes carrying the plasmid did produce mutants simultaneously resistant to both antibiotics. All of the mutants of E. coli had developed nonsense suppressors since they became phenotypically lac+, although harboring a lac amber mutation, and formed plaques with amber mutants of phages PRR1 and PRD1 that attack organisms carrying RP1. Approximately 20% of the resistant mutants of P. aeruginosa and P. pseudoalcaligenes were sensitive to the amber mutant of PRD1. These mutants were of variable stability and grew somewhat more slowly than their parent strains. One of the suppressor mutants of P. pseudoalcaligenes, designated ERA(pLM2)S4, was used for the isolation of nonsense mutants of bacteriophage PHA6, a virus having a segmented genome of double-stranded ribonucleic acid and an envelope of lipids and proteins.     

Isolation and partial characterization of three Escherichia coli mutants with altered transfer ribonucleic acid methylases.

Seven transfer ribonucleic acid (tRNA) methylase mutants were isolated from Escherichia coli K-12 by examining the ability of RNA prepared from clones of unselected mutagenized cells to accept methyl groups from S-adenosylmethionine catalyzed by crude enzymes from wild-type cells. Five of the mutants had an altered uracil-tRNA methylase; consequently their tRNA's lacked ribothymidine. One mutant had tRNA deficient in 7-methylguanosine, and one mutant contained tRNA lacking 2-thio-5-methylaminomethyluridine. The genetic loci of the three tRNA methylase mutants were distributed over the E. coli genome. The mutant strain deficient in 7-methylguanosine biosynthesis showed a reduced efficiency in the suppression of amber mutations carried by T4 or lambda phages.     

Isolation of Mutants of Bacteriophage T4 Unable to Induce Thymidine Kinase Activity

New mutants of T4 have been isolated by using a strain of Escherichia coli lacking thymidine kinase activity. These T4 mutants, designated tk, are able to grow on this E. coli strain under light on plates containing 5-bromodeoxyuridine and were all found to be unable to induce thymidine kinase (ATP: thymidine 5'-phosphotransferase, EC 2.7.1.21). All of these tk mutants fall into one complementation group which maps just to the right of rI on the standard T4 genetic map, far from most other genes coding for enzymes involved in pyrimidine metabolism. The tk mutants grow as well as wild-type T4, indicating that thymidine kinase is a non-essential enzyme.     

Transmission of amber mutants of bacteriophage T4. III. Thermostability of the replication of amber mutants in cells of a non-permissive host is typical for the majority of phage tail genes

The article deals with determination of the spreading of the earlier discovered phenomenon of the temperature sensitivity of multiplication of T4 phage amber mutants. On the basis of the study of the dependence of multiplication of 50 amber mutants in 22 genes of T4 phage tail in the cells of non-permissive host on the incubation temperature in the range of 15-41 degrees C, the following conclusion is drawn: temperature sensitivity of multiplication of amber mutants appears to be gene-specific and is widely spread among T4 phage genes, i.e. in the case of amber mutants the burst size decreases, even for 14 tail genes, by several orders with the increase in incubation temperature. Temperature sensitivity of multiplication is typical of amber mutants in the genes whose proteins are either of small number in a phage particle (several molecules) or play the role of catalytic factors. Moreover, genes, amber mutants of which possess temperature sensitivity of multiplication, map in defined clusters.     

Effect of mutations in Escherichia coli genes PolAm RecA, RecB and RecC on the frequency of genetic recombination in amber-mutants involving the early genes of bacteriophage T4]

Effects of mutations in genes PolA, RecA, RecB and RecC of Escherichia coli on the recombination frequencies between rII markers of T4 have been studied in conditions of partial inhibition of some early functions. It was found that the presence of the mutations in genes PolA or RecA decreased significantly the recombination frequency of phage amber mutant in the gene 43 (DNA polymerase), increased it in the case of amber mutation in the gene 46 (exonuclease) and had no effect on the recombination of amber mutants in genes 30, 32, 33, 41, 42, 45, 44, 52. None of the amber mutants studied changed recombination frequencies in the presence of the mutations in genes RecB or RecC. Possible mechanisms of some of the effects observed are discussed.     

Systematic mutation of bacteriophage T4 lysozyme

Amber mutations were introduced into every codon (except the initiating AUG) of the bacteriophage T4 lysozyme gene. The amber alleles were introduced into a bacteriophage P22 hybrid, called P22 e416, in which the normal P22 lysozyme gene is replaced by its T4 homologue, and which consequently depends upon T4 lysozyme for its ability to form a plaque. The resulting amber mutants were tested for plaque formation on amber suppressor strains of Salmonella typhimurium. Experiments with other hybrid phages engineered to produce different amounts of wild-type T4 lysozyme have shown that, to score as deleterious, a mutation must reduce lysozyme activity to less than 3% of that produced by wild-type P22 e416. Plating the collection of amber mutants covering 163 of the 164 codons of T4 lysozyme, on 13 suppressor strains that each insert a different amino acid substitutions at every position in the protein (except the first). Of the resulting 2015 single amino acid substitutions in T4 lysozyme, 328 were found to be sufficiently deleterious to inhibit plaque formation. More than half (55%) of the positions in the protein tolerated all substitutions examined. Among (N-terminal) amber fragments, only those of 161 or more residues are active. The effects of many of the deleterious substitutions are interpretable in light of the known structure of T4 lysozyme. Residues in the molecule that are refractory to replacements generally have solvent-inaccessible side-chains; the catalytic Glu11 and Asp20 residues are notable exceptions. Especially sensitive sites include residues involved in buried salt bridges near the catalytic site (Asp10, Arg145 and Arg148) and a few others that may have critical structural roles (Gly30, Trp138 and Tyr161).     

TRNA2Gln Su+2 mutants that increase amber suppression.

We selected mutants of lambda pSu+2 which had an increased ability to suppress on Escherichia coli trp B9601 amber mutation on translationally stringent rpsL594 streptomycin-resistant ribosomes. tRNA2Gin Su+2 molecules produced from eight independent mutants were purified, and their ribonucleic acid sequences were determined. Two types of mutations were mapped to the tRNA2Gin Su+2(glnV) gene by this method. Both altered the pseudouridine at position 37 of the tRNA anticodon loop. Seven of the isolates were transitions (pseudouridine to cytosine), and one was a transversion (pseudouridine to adenine). These mutations resulted in Su+ transfer ribonucleic acid molecules that exhibited higher transmission coefficients than their parent Su+2 transfer ribonucleic acids. As judged by their suppressor spectra on T4 amber mutants, which were almost identical to that of Su+2, the two mutant Su+ transfer ribonucleic acids inserted glutamine at amber sites.     

Suppression of Amber Mutations of Bacteriophage T4 Gene 43 (DNA Polymerase) by Translational Ambiguity

The growth properties of twelve different amber (am) mutants of bacteriophage T4 gene 43 (DNA polymerase) were examined by using nonpermissive (su(-)) as well as permissive (su(+)) Escherichia coli hosts. It was found that most of these mutants were measurably suppressed in su(-) hosts by translational ambiguity (misreading of codons during protein synthesis). The ability of these mutants to grow in response to this form of weak suppression probably means that the T4 gene 43 DNA polymerase can be effective in supporting productive DNA replication when it is supplied in small amounts. By similar criteria, studies with other phage mutants suggested that the products of T4 genes 62 (uncharacterized), 44 (uncharacterized), 42 (dCMP-hydroxymethylase), and 56 (dCTPase) are also effective in small amounts. Some T4 gene products, such as the product of gene 41 (uncharacterized), seem to be partially dispensable for phage growth since am mutants of such genes do propagate, although weakly, in streptomycin-resistant su(-) hosts which appear to have lost the capacity to suppress am mutations by ambiguity.     

Transmission of bacteriophage T4 amber mutants. I. Temperature sensitivity of gene 26 T4 phage mutant amN131 multiplication in Escherichia coli B cells]

When studying the single cycle of the multiplication of gene 26 mutant amN131 of phage T4, like in temperature shift experiments, the yield of this mutant in non-permissive host depends greatly on the temperature. The burts size of phage in Escherichia coli B is found to be 3.3 phage particles at 25 degrees C, 1.6 at 30 degrees C, 0.051 at 37 degrees C and 0.0007 at 41 degrees C. In the case of permissive host (E. coli CR-63) the burst size per cell decreases from 158 to 49 phage particles at the same temperature interval. The results of the single-burst experiments indicate, that when the incubation temperature increases, the number of E. coli B cells, in which the phage particles maturate, also decreases. It results in the dependence of the transmission coefficient value on the temperature. The transmission coefficient in the conditions favourable for the maturation of the phage is found to be 0.80. It is shown by several methods that the temperature sensitivity of the multiplication of the mutant amN131 in bacterial cells is entirely due to amber mutation in genome of the phage. Therefore the amber mutants having high temperature sensitivity when maturating in non-permissive host cells exist among ordinary amber mutants of phage T4.     

A functional requirement for modification of the wobble nucleotide in the anticodon of a T4 suppressor tRNA

Temperature-sensitive mutants of E. coli have been isolated which restrict the growth of strains of bacteriophage T4 which are dependent upon the function of a T4-coded amber or ochre suppressor transfer RNA. One such mutant restricts the growth of certain ochre but not amber suppressor-requiring phage. Analysis of the T4 tRNAs synthesized in this host revealed that many nucleotide modifications are significantly reduced. The modifications most strongly affected are located in the anticodon regions of the tRNAs. The T4 ochre suppressor tRNAs normally contain a modified U residue in the wobble position of the anticodon; it has been possible to correlate the absence of this specific modification in the mutant host with the restriction of suppressor activity. Furthermore, the extent of this restriction varies dramatically with the site of the nonsense codon, indicating that the modification requirement is strongly influenced by the local context of the mRNA. An analysis of spontaneous revertants of the E. coli ts mutant indicates that temperature sensitivity, restriction of phage suppressor function, and undermodification of tRNA are the consequences of a single genetic lesion. The isolation of a class of partial revertants to temperature insensitivity which have simultaneously become sensitive to streptomycin suggests that the translational requirement for the anticodon modification can be partially overcome by a change in the structure of the ribosome.     

Nucleotide sequence of the bacteriophage T4 gene 57 and a deduced amino acid sequence.

A 693 basepair cloned fragment of bacteriophage T4 DNA, which supports specifically growth of T4 amber mutants in gene 57, has been sequenced. A polypeptide can be deduced from this sequence, that is either 54 or 60 amino acids long depending which of two AUG codons, 18 nucleotides apart, are used for initiation. The size of this deduced polypeptide is compatible with the size of a single polypeptide (based on polyacrylamide gel electrophoresis) synthesized in vivo in E. coli under the direction of the cloned T4 DNA fragment.     

Physical mapping and complete nucleotide sequence of the denV gene of bacteriophage T4.

Phage T4 deletion mutants that are folate analog resistant (far) and contain deletions in the region of the T4 genome near denV have been isolated previously. We showed that one of these mutants (T4farP12) expressed normal denV gene activity, whereas another mutant (T4farP13) was defective in the denV gene. The rII-distal (right) physical endpoints of these deletions defined the limits of the interval in which the rII-proximal (left) endpoint of the denV gene should be located. The deletion endpoints were identified by restriction and Southern hybridization analyses of phage derivatives containing deoxycytidine instead of hydroxymethyldeoxycytidine in their DNAs. The results of these analyses localized the rII-proximal (left) end of the denV gene to a region between 62.4 and 64.3 kilobases on the T4 physical map. denV+ phage resulted from marker rescue with two of five denV- alleles tested, using plasmids containing a 1.8-kilobase fragment from this region or a 179-base-pair terminal fragment derived from it. Sequencing of the 179-base-pair fragment from wild-type DNA showed a 130-base-pair open reading frame with its termination codon at the rII-proximal end. Confirmation that this open reading frame is part of the denV coding sequence was obtained by identifying a TAG amber codon in the homologous DNA derived from a denV amber mutant strain. This mutant strain rescued the denV+ allele from plasmids containing the wild-type sequence. An adjacent overlapping restriction fragment was also cloned, permitting determination of the remaining denV gene sequence. Based on these results, the 3' end of the coding region of the denV locus was mapped to kilobase position 64.07 on the T4 physical map, and the 5' end was mapped to position 64.48.