Bacteriophage T4 transfer RNA. I. Isolation and characterization of two-phage-coded nonsense suppressors

Two phage-coded nonsense suppressors, psuf_a⁺ and psu_b⁺, have been isolated and characterized. Both were isolated as pseudo-wild type revertants of phage strains which carry multiple amber mutations. psu_a⁺ is an amber suppressor which occurs at a frequency of 10⁻¹¹ to 10⁻¹² and is indistinguishable from wild type phage in its growth on both B and K strains of Escherichia coli bacteria. psu_b⁺ may be either an amber or an ochre suppressor, which occurs at a frequency of 10⁻⁷ to 10⁻¹⁰ and makes small plaques on B strains, but grows very poorly or not at all on K strains. Phage with the characteristics of psu_a⁺ occur in populations of psu_b⁺ phage at a frequency of 10⁻⁴. Both suppressors insert serine in response to the amber codon at an efficiency of about 45%.     

The transfer RNA processing defect in Escherichia coli strains BN and CAN is not due to a mutation in RNAase D or RNAase II

Escherichia coli strains BN and CAN are unable to support the growth of bacteriophage T4 psu₁⁺-amber double mutants. For strain BN, this phenotype has been attributed to a defect in 3′ processing of the precursor to psu₁⁺ tRNA^Ser. Since RNAase D and RNAase II are the only well-characterized 3′ exoribonucleases to be implicated in tRNA processing, the status of these activities and their genes in the mutant strains was investigated. Although extracts of strains BN and CAN were defective for hydrolysis of the artificial tRNA precursor, tRNA-C-U, these strains contained normal levels of RNAase D and RNAase II, and purified RNAase D or RNAase II could only partially complement the mutant extracts. Introduction of the wild-type RNAase D gene into strains BN and CAN did not correct the mutant phenotype. Likewise, strains defective in RNAase D and/or RNAase II plated T4psu₁⁺-amber phage normally. These results indicate that the tRNA processing defect in strains BN and CAN is not due to a mutation in either RNAase U or RNAase II. The possibility that the mutation in these strains affects another exoribonuclease or a factor influencing the activity and specificity of RNAase D or RNAase II is discussed.     

Mutants of satellite bacteriophage P4 that are defective in the suppression of transcriptional polarity

The satellite bacteriophage P4 relies on a helper such as P2 to supply the gene products necessary for virion assembly and cell lysis (Six, 1975). P4 has the unique capacity to activate the late genes of P2 by a mechanism that differs from the one normally used by P2 itself. This process has been termed transactivation (Calendar et al., 1977). In addition, P4 is able to suppress the strong polarity associated with certain P2 amber mutations. The isolation of P4 mutants solely defective in polarity suppression (psu^?) demonstrates that the ability of P4 to suppress polarity is non-essential for P4 growth. In particular, polarity suppression plays no essential role in either transactivation or head size determination. The product of the P4 psu gene has been identified as a 19,900 M_r P4 late protein.     

The psu1+ amber suppressor gene of bacteriophage T4: identification of its amino acid and transfer RNA

Previous work identified the psu⁺₁ amber suppressor gene of bacteriophage T4. Analysis of protein arising from suppression now shows that psu⁺₁ specifies the insertion of serine in response to the amber triplet. The efficiency of suppression is 70%.The psu₁⁺ gene affects a serine transfer RNA coded by bacteriophage T4. Comparative ribonuclease T₁ fingerprint analysis of the serine transfer RNAs made by wild type T4 and psu⁺₁ strains shows a specific alteration in the patterns, presumably reflecting a mutational alteration in the anticodon of the transfer RNA. Mutations which result in the loss of suppressor activity define two genes: one is apparently the structural gene for the serine transfer RNA; the function of the second gene, M1, is less clear. Mutational inactivation of either gene prevents the appearance of the serine transfer RNA and a second transfer RNA, which has not yet been associated with its cognate amino acid. M1 mutants are also deficient in the production of several additional transfer RNA species, as well as several larger RNAs. The significance of these results in relation to transfer RNA biosynthesis is discussed.     

Suppression of temperature sensitive mutants of bacteriophage T4 by bacterial opal suppressors

Summary Some of the partial revertants from opal (UGA) mutants of bacteriophage T4 are temperature sensitive in su ^– host cells but are still temperature resistant in su ⁺ cells. Hence these revertants are missense mutants suppressible by bacterial opal suppressors. Such a suppression may be explained in terms of codon-anticodon interactions by the wobble hypothesis.     

Identification of the E. coli groNB(nusB) gene product

Summary The E. coli groNB(nusB) gene product has been previously shown to be necessary for bacteriophage N protein function. The product of the groNB gene has been identified on SDS polyacrylamide gels after infection of UV-irradiated E. coli cells with various groNB ⁺ transducing phage derivatives. It is a polypeptide with an apparent molecular weight of 14,000 daltons. Transducing phage carrying either a deletion or an amber mutation in the groNB gene fail to synthesize the 14,000-M_r polypeptide chain upon infection of a sup ⁺ host. However, am ⁺ revertants of the groNBam phage do induce the synthesis of the polypeptide.     

Characterization of an amber suppressor in Pneumococcus.

Summary Partial revertant has been isolated, with resistance to aminopretin intermediate between wild type and mutant. This phenotype is the result of a mutation at a gene unlinked to the amiA locus. This suppressor mutation (su⁺) has no phenotypic characteristics by itself except a slow growth. 9 amiA mutants (belonging to 6 sites) are affected by su⁺ out of the 30 investigated mutants (i.e. 22 sites). The efficiency of suppression is site dependent. Two sites out of 14 mutants belonging to the thymidilate synthetase gene are suppressible. Thymidilate synthetase activity is partially restored by su⁺. Optochin mutants can also be suppressed. Thus su⁺ is not gene specific but site specific. Moreover when the str-41 allele conferring resistance to streptomycine is introduced by transformation, the suppression effect is restricted. All these properties are characteristic of an informational suppressor.The t-RNA extracted from the suppressor strain su⁺ but not the wild type restored the synthesis of coat protein coded by RNA from an amber mutant of bacteriophage f2. Attempts to detect ochre suppression activity gave negative results. It is suggested that the su⁺ gene is amber specific.Thus su⁺ can provide insight into the nature of suppressible mutations which should be point mutations. Both low efficiency and high efficiency mutants are affected by su⁺; this is additional evidence that both categories contain point mutations.     

DNA sequence analysis of point mutations in traA, the F pilin gene, reveal two domains involved in F-specific bacteriophage attachment

Summary Six missense point mutations in traA (WPFL43,44,45,46,47 and 51), the gene encoding F pilin in the transfer region of the F plasmid, have been characterized for their effect on the transfer ability, bacteriophage (R17, QB and fl) sensitivity and levels of piliation expressed by the plasmid. The sequence analysis of the first five of these mutations revealed two domains in the F pilin subunit exposed on the surface of the F pilus which mediate phage attachment. These two domains include residues 14–17 (approximately) and the last few residues at the carboxy-terminus of the pilin protein. One of these mutants had a pleiotropic affect on pilus function and was thought to have affected pilus assembly. The sixthe point mutant (WPFL51), previously thought to be in traA, was complemented by chimeric plasmids carrying the traG gene of the F transfer region, which may be involved in the acetylation of the pilin subunit. A traA nonsense mutant (JCFL1) carried an amber mutation near the amino-terminus which is well suppressed in SuI⁺ (supD) and SuIII⁺ (supF) strains. Neither the antigenicity of the pilin nor the efficiency of plating of F-specific bacteriophages were affected when this plasmid was harbored by either suppressor strain. A second amber mutant (JCFL25) which is not suppressible, carried its mutation in the codon for the single tryptophan in F pilin, suggesting that this residue is important in subunit interactions during pilus assembly. Two other point mutants (JCFL32 and 44) carried missense mutations in the leader sequence (positions 9 and 13) which affected the number of pili per cell presumably by altering the processing of propilin to pilin.     

Isolation and characterization of a temperature-sensitive amber suppressor mutant of Escherichia coli K12

Summary By mutagenizing an E. coli strain carrying an amber suppressor supD ^- (or su _I ⁺), we isolated a mutant whose amber suppressor activity was now temperature-sensitive. The mutant suppressor gene was named sup-126, which was found to be cotransduced with the his gene by phage P1vir at the frequency of ca. 20%. At 30° C it suppresses many amber mutations of E. coli, phage T4, and phage . At 42° C, however, it can suppress none of over 30 amber mutations tested so far. The sup-126 mutation is unambiguous and stable enough to be useful for making production of an amber protein temperature-sensitive.     

Identification of the C. coli dnaK (groPC756) gene product.

Summary The E. coli dnaK (groPC756) gene product is essential for bacteriophage DNA replication. Bacterial DNA segments carrying this gene have been cloned onto a bacteriophage vector. The product of the dnaK gene has been identified on SDS polyacrylamide gels after infection of UV-irradiated E. coli cells. The dnaK gene codes for a polypeptide with an apparent molecular weight of 93,000-Mr. Transducing phages carrying amber mutations in the dnaK gene fail to induce the synthesis of the 93,000-Mr polypeptide chain upon infection of sup ⁺ bacteria, but do so upon infection of supF bacteria. E. coli carrying the dnaK756 mutation are, in addition, temperature sensitive for growth at 43° C. It is shown that the dnaK756 mutation results in an overproduction of the dnaK gene product at that temperature.     

Synchronous division induced in Escherichia coli K12 by gemts mutants of phage Mu

Summary Infection with the bacteriophage mutant Mu c ⁺ gemts2 at 42° C induces synchrony in cell division in cultures of Escherichia coli K12. This synchrony may last for several cycles and is not only due to selection since synchronization is observed even when bacterial survival to the infection is over 80% as in lysogens for Mu c ⁺ gemts2. The mechanism by which sycnhrony is induced is not known, but since the product of Mu gene gem (previously called lig) has been shown to interact with the enzymatic system in the bacteria controlling the degree of DNA supercoiling, the phenomenon could be a consequence of this interaction.     

A T7 amber mutant defective in DNA-Binding protein

Summary A T7 amber mutant, UP-2, in the gene for T7 DNA-binding protein was isolated from mutants that could not grow on sup ⁺ ssb-1 bacteria but could grow on glnU ssb-1 and sup ⁺ ssb ⁺bacteria. The mutant phage synthesized a smaller amber polypeptide (28,000 daltons) than T7 wild-type DNA-dinding protein (32,000 daltons). DNA synthesis of the UP-2 mutant in sup ⁺ ssb-1 cells was severely inhibited and the first round of replication was found to be repressed. The abilities for genetic recombination and DNA repair were also low even in permissive hosts compared with those of wild-type phage. Moreover, recombination intermediate T7 DNA molecules were not formed in UP-2 infected nonpermissive cells. The gene that codes for DNA-binding protein is referred to as gene 2.5 since the mutation was mapped between gene 2 and gene 3.     

Vegetative recombination of bacteriophage Mu-1 in Escherichia coli

Summary Twenty-two amber mutants of the thermoinducible mutator phage Mu-c4ts were isolated. These mutants fall into 11 complementation groups. The data obtained by crossing these amber mutants suggest that bacteriophage Mu-1 has a linear vegetative linkage map. In a recombination deficient host of the RecA type the recombination frequencies are extremely low, indicating that Mu-1, in contrast to many other E. coli phages, is dependent on the recombination system of its host. With as a helper phage, recombination between Mu phages in a RecA host is restored to about 1/3 of the frequency in a Rec⁺ host. Although Mu-1 is able to integrate efficiently into the chromosome of a RecA strain, it seems that its integration system does not contribute to vegetative recombination.The survival of UV-irradiated Mu-1 was measured on different radiation sensitive mutants of E. coli. The survival on a UvrB strain was very low as compared to the wild-type; the survival on a RecA strain was almost the same as on the wild-type.Research Fellow from the Laboratory of Genetics, State University, Leiden, The Netherlands.     

The isolation and characterization of bacterial strains (Tab32) that restrict bacteriophage T4 gene 32 mutants

Summary Gene 32 of bacteriophage T4 codes for a single-stranded DNA binding protein. We have isolated mutants of Escherichia coli (called Tab32) that specifically restrict the growth of gene 32 missense mutants and allow normal growth of T4⁺. During infections of Tab32 with 32^tsL171, large amounts of DNA are synthesized and late proteins are made, but very few progeny phage are produced. At least two bacterial mutations are necessary for the restrictive phenotype; these mutations have been mapped to about min 41 and min 64.     

Mutagenesis in Escherichia coli. V. Attempted interconversion of ochre and amber suppressors and mutational instability due to an ochre suppressor

Summary A possible quantitative system for the interconversion of ochre and amber suppressors was studied in Escherichia coli WU36-10, a strain in which a leucine requirement is suppressed by amber suppressors and a tyrosine requirement is suppressed by ochre suppressors. The conversion of am Sup-2⁺ to oc Sup-2⁺ occurred at rates similar to those for the de novo induction of such suppressors, both spontaneously and after ultraviolet or gamma irradiation. Both induction and conversion of suppressors showed the phenomenon of mutation frequency decline after ultraviolet light. Conversions in the opposite direction from oc Sup-2⁺ to am Sup-2⁺ were, however, not detected in unmutagenised populations of oc Sup-2⁺ strains derived either by conversion from an am Sup-2⁺ strain or de novo from the parental WU36-10, nor were they detected after treatment with ultraviolet light, gamma radiation or 2-aminopurine. If the conversion of oc Sup-2⁺ to am Sup-2⁺ occurs at all, it is at a rate very considerably lower than that for the conversion of am Sup-2⁺ to oc Sup-2⁺. Some Tyr⁺ oc Sup-2⁺ mutants demonstrated mutation rates c. 100 times greater than those of WU36-10 for mutation to Leu⁺ spontaneously and after ultraviolet or gamma radiation. Possible explanations of this are discussed.     

Nanovariant RNAs: nucleotide sequence and interaction with bacteriophage Qbeta replicase

Gene 2 amber mutants of bacteriophage T4 grown on su^? hosts produce whole particles of which less than 0.5% are infective on su⁺ hosts. Although the DNA of such particles is full-sized and un-nicked, it is degraded to acid-soluble fragments after infection of exo V⁺ hosts. This breakdown does not occur on exo V^? deficient hosts, and such hosts are fully permissive for gene 2-defective particles. We have now determined that giant-headed, gene 2-defective particles containing several genome lengths of DNA per head are fully infective on exo V⁺ hosts even though part of the parental DNA is degraded to acid-soluble fragments early after infection. Restriction of gene 2-defective particles must therefore be due to exonucleolytic degradation of the incoming DNA. If the parental DNA is of sufficient length to enable a complete genome to survive this degradation before production of anti-exoV, such particles are now infective.     

Reversion of bacteriophage T4rIImutants by high levels of pyrimidine deoxyribonucleosides

Summary High levels of pyrimidine deoxyribonucleosides, but not purine deoxyribonucleosides, increase the reversion rate of bacteriophage T4rII mutants to r ⁺. This increased reversion rate is not observed when a thymidine kinase mutation is introduced into the bacteriophage, but the high reversion rate persists when the host, E. coli, harbors a thymidine kinase mutation.     

Genetic analysis of bacteriophage P4 using P4-plasmid ColE1 hybrids

Summary A set of plasmids that contain fragments of the bacteriophage P4 genome has been constructed by deleting portions of a P4-ColE1 hybrid. A P4 genetic map has been established and related to the physical map by examining the ability of these plasmids to rescue various P4 mutations. The P4 vir1 mutation and P4 genes involved in DNA replication (), activation of P2 helper genes ( and ), polarity suppression (psu) and head size determination (sid) have been mapped, as has the region responsible for synthesis of a nonessential P4 protein.One of the deleted plasmids contains only 5900 base pairs (52%) of P4 but will form plaques if additional DNA is added to increase its total size to near that of P4. This plasmid is also unique in that it will not form stable associations with P2 lysogens of E. coli which are recA ⁺. P4 mutants can be suppressed as a result of replication under control of the ColE1 part of the hybrid.     

Identification of transfer RNA suppressors in Escherichia coli. II. Duplicate genes for tRNA2Gln.

The number of gene copies for tRNA₂^Gln in λpsu⁺2 was determined by genetic and biochemical studies. The transducing phage stimulates the production of the su⁺2 (amber suppressor) and su°2 glutamine tRNAs and methionine tRNA_m. When the su⁺2 amber suppressor was converted to an ochre suppressor by single-base mutation, the phage stimulated ochre-suppressing tRNA₂^Gln, instead of the amber-suppressing tRNA₂^Gln. From the transducing phage carrying the ochre-suppressing allele, strains carrying both ochre and amber suppressors were readily obtainable. These phages stimulated both ochre-suppressing and amber-suppressing tRNA₂^Gln, but not the non-suppressing form. We conclude that the original transducing phage carries two tRNA₂^Gln genes, one su⁺2 and one su°2. The transducing phage carrying two suppressors, ochre and amber, segregates one-gene derivatives that encode only one or the other type of suppressor tRNA. These derivatives apparently arise by unequal recombination involving the two glutamine tRNA genes in the parental phage. This segregation is not accompanied by the loss of the tRNA_m^Met gene. Based on these results, it is suggested that Escherichia coli normally carries in tandem two identical genes specifying tRNA₂^Gln at 15 minutes on the bacterial chromosome. su⁺2 mutants may arise by single-base mutations in the anticodon region of either of these two, leaving the other intact. By double mutations, tRNA₂^Gln genes could also become ochre suppressors. A tRNA_m^Met gene is located near, but not between, these two tRNA₂^Gln genes.     

A nonsense mutation in bacteriophage P1 eliminates the synthesis of a protein required for normal plasmid maintenance

A mutant of bacteriophage P1 that is defective in plasmid maintenance was isolated. P1 seg-101 carries an amber mutation in a region previously implicated in the control of plasmid maintenance. By use of a host bearing a temperature-sensitive suppressor, the dependence of P1 maintenance on the seg-101⁺ protein product was established. The rates of segregation of cured cells under various conditions suggest a role for the seg-101⁺ product in the partition of plasmids to daughter cells rather than in the replication of the plasmid. This hypothesis is supported by the observation that P1 seg-101 can drive host chromosomal DNA replication when integrated into the chromosome of a dnaA host under conditions that are nonpermissive for both the seg-101 and dnaA alleles.