Properties and structure of a gene 24-controlled T4 giant phage

Giant T4 bacteriophage were found by Doermann et al. (1973a) with point mutants in gene 23 and by Cummings et al. (1973) after l-canavanine induction followed by an arginine chase. We now find T4 giant phage with 14 out of 15 tested temperature-sensitive mutants in gene 24 grown at intermediate temperatures between 33 °C and 37 °C.For one of these mutants, T4,24(tsB86), we found that (a) the optimum temperature for giant phage production is 34.8 °C, (b) the head-length distribution peaks sharply between 10 and 12 normal T4 phage head lengths, (c) about 75% of our giant phage have two tails, (d) the buoyant density in CsCl is greater than that of normal phage, (e) they are infectious and show an increased u.v. resistance, (f) their sodium dodecyl sulphate gel electrophoresis pattern is qualitatively similar to that of normal T4 phage, although the relative intensities of some of the bands are different, showing for example, a decreased $\text{P24}{}^1\text{P23}{}^1$² ratio, (g) optical diffraction and filtering of the flattened cylindrical part of the giant heads show a p6 surface net with a lattice constant of approximately 130 Å, a unique $\text{u}\text{v}$ ratio of $\text{15}\text{5}$ and a capsomer morphology of the type 1 + 6 + 6.Mixed infections with T4 wild type and T4.24(amN65) also yield giant phage. These are produced in highest amounts with a multiplicity of infection ratio of 5:5; no giants are observed at ratios of 1:9 or 9:1, suggesting that their formation may be caused by a dosage effect of P24.     

Distinct nuclear genes for yeast mitochondrial and cytoplasmic methionyl-tRNA synthetases.

Total methionine-tRNA synthetases from wild type $\text{Saccharomyces}\text{cerevisiae}$ can be fractionated on hydroxylapatite into two peaks: Peak I is the mitochondrial, peak II the cytoplasmic isoenzyme. The specificity towards various tRNAs and the antigenic determinants are not identical. A mutant strain, known for its altered cytoplasmic enzyme, contains a mitochondrial species with the same properties as the wild type mitochondrial enzyme, as well as a cytoplasmic isoenzyme with a K_M for methionine about 300 times higher than the corresponding wild type enzyme. Another strain, obtained by back-crossing the mutant with a wild type strain, retains the enzyme pattern found in the mutant. The results are in favor of two distinct nuclear genes for yeast mitochondrial and cytoplasmic methionyl-tRNA synthetases.     

Interaction of wild-type and poky mitochondrial DNA in heterokaryons of Neurospora.

The mitochondrial phenotype of $\text{poky}$ and other extra-nuclear $\text{Neurospora}$ mutants is known to predominate over that of wild type in heteroplasms. This phenomenon was investigated in heterokaryons using normally occurring strain differences in restriction enzyme patterns to distinguish wild-type and $\text{poky}$ mitochondrial DNAs. Each of ten independent heterokaryons eventually showed the $\text{poky}$ phenotype as judged by slow growth rate and deficiency of 19 S RNA. Six heterokaryons contained mitochondrial DNAs with restriction enzyme patterns of the $\text{poky}$ parent whereas four contained DNAs which lacked restriction enzyme fragments characteristic of the $\text{poky}$ parent. The latter may be recombinants of wild-type and $\text{poky}$ mitochondrial DNA.     

Immunological properties of membrane fractions from wild type and dnaA mutants of Escherichia coli

Membrane vesicles from Escherichia coli wild type and an otherwise isogenic $\text{dna}\text{A}$ mutant were used to immunize rabbits. In addition, a membrane protein fraction, containing the material found deficient in $\text{dna}$A mutants, was purified by preparative polyacrylamide gel electrophoresis in sodium dodecylsulfate, and used for immunization. The antisera produced were analyzed by immunoelectrophoresis and immunofluorescence microscopy. The antisera obtained by immunization with membrane vesicles from either wild type or $\text{dna}\text{A}$ mutant membrane preparations were qualitatively similar in the precipitin bands seen after immunoelectrophoresis. The antisera obtained by immunization with the purified protein fraction contained a subset of the antibodies seen when whole vesicles were used for immunization. In a semiquantitative precipitin assay, the antisera prepared against whole membrane vesicles or the isolated protein fraction both caused the precipitation of more protein from sodium dodecylsulfate-solubilized membranes of wild type than of $\text{dna}\text{A}$ mutants. No difference was seen by immunoelectrophoresis between the protein composition of wild type or $\text{dna}\text{A}$ membrane preparations. Thus, the $\text{dna}\text{A}$ mutant appears to differ from the wild type in the quantitative composition of its membrane proteins, whereas no qualitative differences were detected.Fluorescein-conjugated antiserum preparations were employed to assess the reactivity of intact cells, spheroplasts and membrane vesicles with the antisera studied above. Wild type cells of E. coli have a barrier to reaction with the antisera; this barrier is removed when the cells are converted to spheroplasts or to membrane vesicle. Similarly, a highly permeable mutant of E. coli permits reaction of the antisera with unaltered cells. Antisera to both whole membrane vesicles and to the isolated protein fraction react identically with the cellular and subcellular preparations. Thus, antisera prepared from membrane proteins isolated after sodium dodecylsulfate-polyacrylamide gel electrophoresis can still recognize some antigens present in membrane vesicle preparations.     

Bacteriophage P22 development is temperature sensitive in thiolutin resistant mutants of Salmonella typhimurium.

Thiolutin resistant mutants of $\text{Salmonella}\text{typhimurium}$ can not support the development of phage P22 at high temperature (40°C). Although normal amounts of phage DNA and lysozyme are synthesised, very few infectious particles are formed at higher temperature. The results indicate the involvement of host function in phage development.     

Identification of an Escherichia coli inner membrane polypeptide specified by a lambda-tonB transducing.

Analysis by polyacrylamide gel electrophoresis of the proteins coded by a λ$\text{ton}$B transducing phage, after infection of UV-irradiated bacteria, revealed the presence of at least 7 new polypeptides. Three of these were identified as proteins of the $\text{trp}$ operon whilst three others were deleted by a spontaneous mutation in the $\text{ton}$B region carried by the phage. A single polypeptide, molecular weight 40,000 was absent from a phage carrying a proflavine induced mutation in $\text{ton}$B. We conclude that this protein, which was localised in the inner membrane by sarkosyl fractionation of the envelope, is the $\text{tonB}$ product.     

The separation of phage promoter from bacterial lac promoter for beta-galactosidase expression in transducing phage lambda plac5.

The replication defective transducing phage λp$\text{lac}\text{5}\text{O}\text{29}\text{P}$3 carries a portion of the $\text{E.}\text{coli}\text{lac}$ operon in the $\text{b}$2 region of the lambda phage. This $\text{lac}$ operon segment contains the $\text{lac}$ promoter, the $\text{lac}$ operator, and the β-galactosidase $\text{z}$ gene, but does not contain the $\text{lac}$ repressor $\text{i}$ gene. The $\text{z}$ gene can be expressed from both the inserted $\text{lac}$ promoter and the phage promoter. When $\text{E.}\text{coli}$ strain 594 ($\text{z}$^?, $\text{i}$⁺) or JC6256 (Δ$\text{lac}$) is infected by λp$\text{lac}\text{5}\text{O}\text{29}\text{P}$3 in the absence of additional cyclic AMP, β-galactosidase synthesis is shown to be expressed from the phage promoter. When 594 (λ⁺) or JC6256 (λ⁺) is infected by λp$\text{lac}\text{5}\text{O}\text{29}\text{P}$3 in the presence of additional cyclic AMP and IPTG, β-galactosidase synthesis is shown to be expressed from the inserted $\text{lac}$ promoter.The ability to separate the phage promoter from the inserted $\text{lac}$ promoter for β-galactosidase expression will simplify the interpretation whenever λp$\text{lac}$5 is used.     

Skunks have gene sequences in their cellular DNA related to squirrel monkey retrovirus: transmission between species of a new world primate endogenous type D retrovirus.

The squirrel monkey ($\text{Saimiri}$,$\text{sciureus}$), a New World primate, contains multiple copies of endogenous type D retroviral gene sequences in the cellular DNA of all its tissues. Gene sequences partially homologous to these type D virus genes are also found in the cellular DNA of normal tissues of the New World carnivore, the skunk ($\text{Mephitis}$,$\text{mephitis}$ and $\text{Spilogale}$,$\text{putorius}$). We there-fore conclude that this class of viruses has, under natural conditions, been transmitted between the germ lines of these evolutionarily distant species. The example of interspecies transmission described here is the first that has been described among New World species and also the first that has been demonstrated for retroviruses other than type C viruses.     

Isolation of a new division altered mutant of Escherichia coli 15T

A Mutant of $\text{Escherichia coli}$ 15T^? (555-7) has been isolated which grows at a rate equal to that of the wild type at division times of 40 min or less, but grows faster than normal at division times greater than 40 min. At division times greater than 40 min the division time of the mutant is identical to the chromosome synthesis time of the wild type in the same medium. In one slow-growth medium (M9-aspartic acid) chromosome synthesis and gap times of the mutant were measured and the time required for synthesis of a chromosome was approximately the same as that of the wild type, but the gap in DNA synthesis observed in the mutant was only about 12% of that observed in wild type.     

Purification of a unique bisulfite-reducing enzyme from Desulfovibrio vulgaris

An enzyme which catalyzes the reduction of bisulfite to sulfide and thiosulfate was purified from extracts of the sulfate-reducing bacterium, $\text{Desulfovibrio vulgaris}$. Trithionate was not a product of this reaction nor was it or thiosulfate reduced by the enzyme. High substrate concentrations inhibited sulfide but not thiosulfate formation. The enzyme was named bisulfite reductase II to distinguish it from bisulfite reductase which reduces bisulfite to trithionate.     

Relationship of metabolite inhibition of growth to flow-of-carbon patterns in nature

Various genetic diseases arise from biochemical imbalances that are relatively subtle in the sense that the original mutations are not lethal, that the organism is most vulnerable to damage during certain phases of rapid development, and that in well-managed cases it may be possible to avoid damaging effects through the use of appropriate nutritional manipulations. Analogous imbalances occur in lower organisms. Data obtained with $\text{Pseudomonas}$$\text{putida}$ illustrate that susceptibility to metabolic imbalance is conditionally dependent upon the nutritional regimen.Stereoisomers of leucine, isoleucine and valine, except for L-allo-isoleucine, are metabolized as sole sources of carbon and energy by $\text{P.}$$\text{putida}$. Although the cell yields calculated following utilization of $\text{D}$-leucine and $\text{L}$-leucine were similar, the rate of growth on D-leucine was seven-fold faster than on $\text{L}$-leucine. Slower growth on the $\text{L}$-isomer is not explained as 2-ketoisocaproate limitation since 2-ketoisocaproate production from $\text{L}$-leucine appears to occur more readily than from $\text{D}$-leucine. Spontaneous mutants were obtained which grew 2–10 times more rapidly than wild type on $\text{L}$-leucine, $\text{L}$-isoleucine, or $\text{L}$-valine. It is concluded that the true growth potential (rate) of wild type on any of the branched-chain amino acids is masked by a partial, sustained inhibitory effect produced by the corresponding keto acids or their derivative metabolites. Inhibition of growth rate was only found during utilization of branched-chain amino acids as the sole source of carbon and energy, indicating that the metabolite vulnerability is unique to particular flow-of-carbon patterns during growth. The partial and sustained depression of growth rate by branched-chain amino acids in the absence of other carbon sources cannot be attributed to mis-regulation events localized within the biosynthetic pathway. It is concluded that the catabolism of branched-chain amino acids produces a generalized state of metabolic imbalance owing to the existence of abnormally high levels of degradative metabolites such as keto acids of Coenzyme-A derivatives. Such compounds could (1) interfere with keto acid (e.g. pyruvate) metabolism, (ii) cause feed-forward inhibition of rate-limiting steps in the pathways of branched-chain amino acid catabolism, (iii) perturb fatty acid composition or disrupt the biochemical integrity of membrane material, or (iv) react with substrate-ambiguous enzymes, either slowing essential biochemical reactions to rates that are growth-limiting or producing erroneous products having antimetabolite properties.These effects of branched-chain amino acids in $\text{P.}$$\text{putida}$ may be quite relevant to the molecular events that characterize maple syrup urine disease in man. Metabolite inhibition is probably more common in nature than is generally appreciated, and an appreciation of the molecular basis for anomalous inhibitions of growth in prokaryotic systems should help supply insight into various molecular diseases in man, many of them yet to be described.     

A membrane potential threshold for phage T4 DNA injection

DNA penetration from T4 phage adsorbed to $\text{Escherichia coli}$ was measured at different membrane potentials. There was a precipitous reduction in DNA penetration between 110 mV and 60 mV. This threshold of membrane potential for DNA penetration is independent of ΔpH and rather insensitive to external pH between 6 and 8.     

Excision repair of uracil during replication of phiX174 DNA in vitro.

Each of the stages in the replication of ØX174 DNA $\text{in vitro}$, e. g., conversion of circular single stranded parental DNA to the duplex replicative form (SS → RF), replication of the closed circular duplex form (RF → RF), and synthesis of circular single stranded progeny DNA (RF →SS), may be affected by a reduced level of dUTPase. Thus, in enzyme preparations from mutant strains defective in dUTPase ($\text{dut}$^?), the complementary strand synthesized in the SS → RF reaction is abnormally short (7–8S vs. 14S), and the extent of RF replication is decreased 10-fold. Preferential removal of dUTPase during fractionation of enzyme preparations from wild type ($\text{dut}$⁺) cells may produce comparable effects. In particular, the single stranded circular DNA synthesized in the RF → SS reaction by a set of highly purified enzymes is rapidly degraded upon incubation with the less pure enzymes required for its conversion to RF. All of these effects are plausibly accounted for by the incorporation into DNA of uracil from dUTP, possibly present as a contaminant in one or more components of the reaction, followed by excision of the uracil and phosphodiester bond cleavage at the resulting apyrimidinic site.     

Transfection of Vibrio cholerae by bacteriophage phi 149 DNA

DNA isolated from Choleraphage ø149 of Group IV was infectious when mixed with competent $\text{V.}\text{cholerae}$ cells. The cells were competent during mid-log phase of growth. The infectivity of phage DNA was destroyed by deoxyribonuclease but not by ribonuclease or pronase. About 5 min is required for the establishment of the DNase resistant state. The dose response curve for transfection suggested that 2 to 3 molecules of DNA are required to produce one infections center. An infectivity of 5 × 10⁴ infectious center per μg of DNA was obtained.     

An analysis of repressor overproduction by the lambda cIIIs mutant.

Efficient lysogenization of Escherichia coli K12 by bacteriophage λ requires the high level of synthesis of the phage repressor shortly after infection. This high level of synthesis of repressor requires the action of the λ eII and cIII proteins. Certain mutants of λ (λcIIIs) appear to have excess $\text{c}\text{II}\text{c}\text{III}$ activity and can lysogenize more efficiently than λ⁺. The basis for the enhanced lysogenization is that, while two or more infecting phage are necessary for λ⁺ to lysogenize, a single infecting λcIIIs particle is sufficient for lysogenization. Also, repressor levels in cells infected with λcIIIs are higher than in those infected with λ⁺. I report here that repressor overproduction by λcIIIs (1) is due to a much higher rate of repressor synthesis than that of λ⁺; (2) is most marked at low multiplicities of infection, possibly because λcIIIs produces repressor much more efficiently than λ⁺ as a singly infecting phage.     

Preferential synthesis of yeast mitochondrial DNA in alpha factor-arrested cells

α factor is a diffusible substance produced by $\text{S. cerevisiae}$ cells of the $\text{α}$ mating type which inhibits cell division (1) and the initiation of nuclear DNA synthesis (2) in cells of the $\text{a}$ mating type. In this report, it is shown that mitochondrial DNA synthesis continues at a normal rate in $\text{a}$ cells for at least 6 hours in the presence of α factor, resulting in a 5-fold increase in the amount of mitochondrial DNA per cell. The continued synthesis of mitochondrial DNA in the absence of nuclear DNA synthesis allows specific labeling of yeast mitochondrial DNA.     

A mutant of Escherichia coli with altered inducer specificity for the fad regulon

A novel regulatory mutant of the fatty acid degradation ($\text{fad}$) regulon of $\text{Escherichia coli}$ was isolated. This mutant, D-2, was induced to synthesize the fatty acid β-oxidation enzymes during growth on decanoate and laurate whereas the wild type strain was induced only when fatty acids with a chain length greater than 12 carbon atoms were present in the growth medium. The fatty acid specificity of the acyl CoA synthetase was also changed in strain D-2. The data are consistant with the hypothesis that acyl CoA's themselves are the inducers of the $\text{fad}$ regulon and suggest that strain D-2 may synthesize an altered $\text{fad}$ regulatory protein. The results also suggest that the acyl CoA synthetase may possess regulatory as well as enzymatic activity.