Complementation experiments between conditional lethal mutants of bacteriophage ?X174

Summary Complementation experiments with temperature sensitive (ts) and suppressor sensitive (sus) mutants of bacteriophage X174 unambiguously revealed five cistrons on the basis of a clear bipartition of burst sizes.A new group of sus mutants (emeralds) was found, defective in a function essential for growth in Shigella sonnei V64.The complementation between ts and sus mutants was in general asymmetric in that the yield of ts particles was lower than that of the sus particles. The mutants of one cistron (defective in RF-replication) showed a completely asymmetric complementation behaviour both of ts and sus mutants. The ts mutants of this group, which show to be early, appear to be defective in two functions.The possibility is discussed that in each cell only one phage genome is replicated. This would explain both kinds of asymmetric complementation and the low burst sizes that were obtained when mutants of particular genes were complemented.     

Short nascent DNA pieces, accumulating in Saccharomyces cerevisiae after inhibition of DNA chain elongation, hybridize to specific chromosomal sites

Summary In temperature-sensitive DNA chain elongation mutants (cdc8 ^ts) of Saccharomyces cerevisiae even at the restrictive temperature a small portion of DNA is synthesized, which can be labeled by radioactivity. Under denaturing conditions this product sediments in alkaline sucrose gradients with about 4S. It is probable that these short nascent DNA pieces are derived predominantly from newly activated origins of replication. An alternative and more direct method of limiting the elongation of DNA chains uses araCMP as an inhibitor in nucleoside monophosphate-incorporating yeast strains. As with the cdc8 ^ts mutants the only radioactive products in labeling experiments with [³²P]dTMP are 4S pieces. Potential sites of their formation are small replication bubbles and terminal doublestranded loops observed in electron micrographs of the DNA from araCMP-inhibited cells. The pieces hybridize specifically with the replication origin of the 2 m-plasmid, the chromosome telomeres and a group of chromosomal genes. Other genes and the centromere of chromosome 11 (CEN11) do not react. The 4S pieces hybridize with only three of nine cloned autonomously replicating sequences (ARS). It is concluded that ARS sequences, at least in the presence of araCMP, are not always used as replication origins within their normal environment on the chromosome.     

Genetic mapping of the G101 bacteriophage (Pseudomonas aeuruginosa by temperature-sensitive mutations

Temperature-sensitive (ts) mutations of the G101 phage were isolated after mutagenesis with hydroxylamine. A complementation analysis of 61ts mutants showed that these mutants may be divided into at least 12 complementation groups. Twots mutants probably originated in genes which control lytic functions of the G101 phage. It was shown by three factor crosses that all of the 12ts mutations tested are localized on that side of the “c” region where the probablecI repressor gene is positioned. Sevents mutations is closely linked to thecI ₂₆ clear marker, three exhibit a closer linkage and two do not exhibit any linkage withcI. All mutations isolated until now can be arrange linearly. According to the present knowledge the preliminary genetic map of the G101 phage is linear.     

Localization of his genes on the Rhizobium trifolii RS800 linkage map

Summary We have studied N-methyl-N-nitro-N-nitrosoguanidine (NTG)- and Tn5-induced histidine auxotrophic mutants in Rhizobium trifolii. HisGE, hisD and hisH mutants have been characterized. Using the Kemper's equation we have located them on the R. trifolii linkage map. The hisGE and hisD genes are clustered in the same region and are closely linked to the spectinomycin marker. The hisH gene is located in another region equidistant from the streptomycin and rifampicin markers. The two regions carrying his genes are separated by a distance approximately one-third of the length of the chromosome.     

Repressor and rex product of coliphage lambda: lack of collaboration and joint controls

Summary Exposure to 41° C for 10 to 100 minutes rapidly inactivates repressor bearing several ts mutations in the A or B region of gene cI, but does not result in simultaneous rapid loss of the rex function, which restricts phage T4 rII. One may conclude that the rex product does not directly collaborate with the repressor protein. Immediate loss of the rex activity at 47.5° C, observed with most of the cIts mutants and even cI⁺, appears to be unrelated to the repressor inactivation. In tof ⁺ lysogens carrying nonlethal cIts prophage mutants, the prolongation of induction at 41° C ultimately results in irreversible loss of the rex function, but only after about six cell generations. In similar experiments with tof deficient lysogens, loss of the rex activity requires about eleven cell generations and the rex function is regained in less than 30 minutes after return of the lysogen to 30° C. Two methods of rex assay, the more sensitive phage yield method and the infective center method, were employed.     

Isolation and complementation analysis of temperature-sensitive mutants of the PS8 bacteriophage ofAgrobacterium tumefaciens

The isolation, method of complementation analysis and classification of temperature-sensitive (ts) mutants of phage PS8 (Agrobacterium tumefaciens) are described.     

Partial exclusion of genes of bacteriophage T2 with T4-glucosylated DNA in crosses with bacteriophage T4

A recombinant strain (D41) between phage T2 and T4 was isolated which possessed the T2 region of the genome between genes 32 and 39 and both the T4 genesgt ⁺ andgt ⁺ for glucosyltransferase. D41 was crossed with T4amber mutants in the genes for early functions and in some genes for late funcitions. The progeny of the crosses was examined for the frequency of theam ⁺ markers from D41. Genes 32, 60 and 39 in the T2 region of the recombinant strain were as sensitive to exclusion as those in standard-type T2. The T4 glucosylation of the DNA of these T2 genes did not protect them against partial exclusion by T4. However, genes in the region from gene 56 to 55 in the recombinant were resistent to exclusion. In standard-type T2 this region of the genome is sensitive to partial exclusion by T4. There are at least four exclusion sensitive sites in T2: one near gene 32, one near gene 60, one linked to gene 56 and one between genes 42 and 55.This investigation was carried out partially within the frame of the Association between Euratom and the University of Leiden, contract nr. 052-64-1-BIAN.     

The nature of ompA mutants of Escherichia coli K12 exhibiting temperature-sensitive bacteriophage resistance

Summary A class of ompA mutants of Escherichia coli, exhibiting temperature-sensitive resistance towards phages using the OmpA protein as receptor, was analysed. The mutants produce detectable levels of the protein at 42°C but not at 30°C (Manning and Reeves 1976). They were found to have a deletion (one isolate) or insertions (three isolates) upstream of the coding part of the ompA gene. Several previously characterized mutants possessing insertions or a deletion in the non-translated 5 area of the gene also exhibited a similar temperature-sensitive phage resistance. This cold-sensitive phenotype is explained in terms of the recent discovery that the stability of ompA mRNA is regulated by the rate of cell growth (Nilsson et al. 1984).     

Isolation and Primary Identification of Methylotrophic Yeast Hansenula polymorpha Mutants for Peroxisome Biogenesis

After exposure of cells of the methylotrophic yeast Hansenula polymorphaHF246leu1-1 to N-nitro-N-nitrosoguanidine, a collection of 227 mutants unable to grow on methanol at elevated temperature (45°C) was obtained. Ninety four ts mutants (35% of the total number of mutants), which were unable to grow on methanol only at 45°C but could grow at optimal temperature (37°C), were isolated. Complementation analysis of mutants using 12 deletion mutants for genes of peroxisome biogenesis (PEX) (available in this yeast species by the beginning of our work) allowed to assign 51 mutants (including 16 ts) to the separate group of mutants unable to complement deletion mutants with defects in eight PEX genes. These mutants were classified into three groups: group 1 contained 10pex10 mutants (4ts mutants among them); group 2 included 19 mutants that failed to complement otherpex testers: 1 pex1; 2 pex4(1ts); 6 pex5(5ts); 3 pex8; 1 pex13; 6 (3ts) pex19; group 3 contained 22 multiple mutants. In mutants of group 3, hybrids with several testers do not grow on methanol. All mutants (51) carried recessive mutations, except for mutant 108, in which the mutation was dominant only at 30°C, which suggests that it is ts-dominant. Recombination analysis of mutants belonging to group 2 revealed that only five mutants (two pex5 and three pex8) carried mutations for the corresponding PEX genes. Analysis of the spore population from the hybrids of remaining 14 mutants with the pex tester demonstrated the presence of methanol-utilizing segregants, which indicates mutation localization in other genes. In 19 mutants, random analysis of ascospores from hybrids obtained upon crossing mutants of group 3 with a strain lacking peroxisomal disorders (ade11) revealed a single mutation causing the appearance of a multiple phenotype. A more detailed study of two mutants from this group allowed us to localize this mutation in the only PEX gene (PEX1 or PEX2). The revealed disorder of complementation interactions between nonallelic genes is under debate.     

The glucose kinase gene of Streptomyces coelicolor and its use in selecting spontaneous deletions for desired regions of the genome

Summary A number of deletions in the glucose kinase (glk) region of the Streptomyces coelicolor chromosome were found among spontaneous glk mutants. The deletions were identified by probing Southern blots of chromosomal DNA from glk mutants with cloned glk DNA. The deletions ranged in size from 0.3 kb to greater than 2.9 kb. When cloned glk DNA was introduced on a C31 phage vector into a glk mutant that contained a deletion of the entire homolgous chromosomal glk region, glucose kinase activity was detected in extracts of these cells. The entire coding information for at least a subunit of glucose kinase is there-fore present on the cloned glk DNA. The 0.3 kb glk chromosomal deletion was used to demonstrate that transfer of chromosomal glk mutations on the the C31::glk phage could occur by recombination in vivo. Since glk mutations frequently arise from deletion events, a method was devised for inserting the cloned glk DNA at sites in the chromosome for which cloned DNA is available, and thus facilitating the isolation of deletions in those DNA regions. C31::glk vectors containing a deletion of the phage att site cannot lysogenize S. coelicolor recipients containing a deletion of the glk chromosomal gene unless these phages contain S. coelicolor chromosomal DNA. In such lysogens, the glk gene becomes integrated into the chromosome by homologous recombination directed by the chromosomal insert on the phage DNA. In appropriate selective conditions, mutants which contain deletions of the glk gene that extend into the adjacent host DNA can be easily isolated. This method was used to insert glk into the methylenomycin biosynthetic genes, and isolate derivatives with deletions of host DNA from within the prophage into the adjacent host DNA. Phenotypic and Southern blot analysis of the deletions showed that there are no genes essential for methylenomycin biosynthesis for at least 13 kb to the left of a region concerned with negative regulation of methylenomycin biosynthesis. Many of the deletions also removed part of the C31 prophage.     

Host mutant (tabD)-induced inhibition of bacteriophage T4 late transcription: II. Genetic characterization of mutants

In this paper we show that the tabD mutants, selected with ts553 or tsCB53, and described in the accompanying paper (Coppo et al., 1975): (a) are recessive to tab⁺; (b) fail to complement each other, and thus map in the same cistron; (c) by their linkage to rif and their dominance relationships with well characterized amber mutations in the Escherichia coli RNA polymerase operon, probably all map in the gene controlling the synthesis of the β′ subunit of the enzyme. We also describe the isolation of a ts⁺, k^D mutant in phage T4 gene 55, used in the selection of a new tabD mutant (tabD^k292). This tab mutant: (a) generates a defective phenotype which differs somewhat from that of the other tabD mutants; (b) complements the other tabD mutants; (c) by its dominance relationship to amber mutants in the RNA polymerase operon, can be assigned to the structural gene coding for the β subunit of the enzyme.A new type of interaction between T4 genes 55 and 45 is also described. The k^D properties of ts553 (gene 55) are suppressed at 30 °C, by a temperature-sensitive mutation in gene 45. This type of interaction between missense mutations in genes 45 and 55 apparently occurs even in tab⁺ strains, since temperature-sensitive mutations in gene 45 accumulate in lysates of two gene 55 mutants (ts553 and tsA81).     

Host genes involved in the replication of single-stranded DNA phage ?K

Summary Using various replication mutants of E. coli, the host genes that participate in the replication of some K12-specific single-stranded DNA phages have been determined. Functional products of dnaE,-F,-G and -Z genes are required for the multiplication of K, whereas dnaA,-B,-C(D), H,-I and -P are dispensable for viral replication. In contrast with polB, recA, B, C, or xth functions, host rep activity is essential for K. At the restrictive temperature, the yield of K was markedly reduced in the ligts7 mutant and partially decreased in a polA ^ts strain. The phage K is thus less dependent on the host cells than X174 and A which require additionally the dnaB,-C(D) and -H functions. Replication of phage St-1 depends on dnaG and -Z gene products, but not on dnaP function. Although not much affected in polA ^ts host, growth of St-1 was significantly diminished in dnaF or ligts7 mutants.     

Head length determination in bacteriophage T4: The role of the core protein P22

We have found that two different temperature-sensitive mutations in gene 22, tsA74 and ts22-2, produce high frequencies (up to 85%) of petite phage particles when grown at a permissive or intermediate temperature. Moreover, the ratio of petite to normal particles in a lysate depends upon the temperature at which the phage are grown. These petite phage particles appear to have approximately isometric heads when viewed in the electron microscope, and can be distinguished from normal particles by their sedimentation coefficient and by their buoyant density in CsCl. They are biologically active as detected by their ability to complement a co-infecting amber helper phage. Lysates of both mutants grown at a permissive temperature reveal not only a significant number of petite phage particles in the electron microscope, but also sizeable classes of wider-than-normal particles, particles having abnormally attached tails, and others having more than one tail.Striking protein differences exist between the purified phage particles of tsA74 or ts22-2 and wild-type T4. B1¹, a 61,000 molecular weight head protein, is completely absent from the phage particles of both mutants, and the internal protein IPIII¹ is present in reduced amounts as compared to wild type. The precursor to B1¹ is present in the lysates, but these mutations appear to prevent its incorporation into heads, so it does not become cleaved.The product of gene 22 (P22) is known to be the major protein of the morphogenetic core of the T4 head. Besides the mutations reported here, several mutations which affect head length have been found in gene 23, which codes for the major capsid protein (Doermann et al., 1973b). We suggest a model in which head length is determined by an interaction between the core (P22 and IPIII) and the outer shell (P23).     

Temperature-Sensitive Lethal Mutations on Yeast Chromosome I Appear to Define Only a Small Number of Genes

A method was developed for isolating large numbers of mutations on chromosome I of the yeast Saccharomyces cerevisiae. A strain monosomic for chromosome I (i.e., haploid for chromosome I and diploid for all other chromosomes) was mutagenized with either ethyl methanesulfonate or N-methyl-N'-nitro-N -nitrosoguanidine and screened for temperature-sensitive (Ts^- ) mutants capable of growth on rich, glucose-containing medium at 25° but not at 37°. Recessive mutations induced on chromosome I are expressed, whereas those on the diploid chromosomes are usually not expressed because of the presence of wild-type alleles on the homologous chromosomes. Dominant ts mutations on all chromosomes should also be expressed, but these appeared rarely. — Of the 41 ts mutations analyzed, 32 mapped on chromosome I. These 32 mutations fell into only three complementation groups, which proved to be the previously described genes CDC15, CDC24 and PYK1 (or CDC19). We recovered 16 or 17 independent mutations in CDC15, 12 independent mutations in CDC24 and three independent mutations in PYK1. A fourth gene on chromosome I, MAK16, is known to be capable of giving rise to a ts-lethal allele, but we recovered no mutations in this gene. The remaining nine mutations isolated using the monosomic strain appeared not to map on chromosome I and were apparently expressed in the original mutants because they had become homozygous or hemizygous by mitotic recombination or chromosome loss. — The available information about the size of chromosome I suggests that it should contain approximately 60–100 genes. However, our isolation in the monosomic strain of multiple, independent alleles of just three genes suggests that only a small proportion of the genes on chromosome I is easily mutable to give a Ts^--lethal phenotype. — During these studies, we located CDC24 on chromosome I and determined that it is centromere distal to PYK1 on the left arm of the chromosome.     

Characterization of two temperature-sensitive mutants of Sigma virus (authors transl)

Summary Temperature-sensitive mutants have been isolated from Drosophila Sigma virus, a Rhabdovirus inducing CO₂ sensitivity in Drosophila melanogaster. We have studied the decay of infectious centers at non permissive temperature. The proportion of destroyed infectious centers is the same for the wild type, ts⁺, and for ts9. On the opposite, it is more important for ts 4. Temperature-sensitive function of ts 4 appears necessary to the viral genome replication. With the three clones, ts⁺, ts 4 and ts 9, we have obtained stabilized Drosophila females able to transmit Sigma virus to their whole progeny. We have tried to see in each case, if stabilized flies could transmit the virus to their progeny at non permissive temperature. Flies stabilized with ts⁺ and ts 9 can, flies stabilized with ts 4 cannot. Therefore two categories of mutants are defined: those that are transmitted hereditarily. at non permissive temperature, and not blocked in genome replication. Those that are blocked in genome replication and not transmitted. When the virus cannot replicate, the divisions in the germ line cells dilute the viral genomes. The consequence will be a real healing of germ line cells, and then a break in hereditary transmission by stabilized flies. All the results with temperature-sensitive mutants are coherent with this hypothesis.

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Étude de mutants thermosensibles du virus Sigma

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Mémoire présenté par F. Gros     

Further physical characterization of deletion and substitution mutants affecting the control of lysogeny in bacteriophage P2

Summary A deletion of phage P2, del6 (L.E. Bertani, 1980), thought to remove the structural gene int, and a deletion/substitution, vir94, thought to remove genes int, C and cox, were mapped by electron microscopy, using the heteroduplex technique.Four independent deletion/substitution mutations, all affecting the regulatory region of P2, were compared in all possible combinations with the same technique: two showed sequence homology in their substitution DNA. The results confirm the model proposed for the origin of these mutants, analogous to that for the origin of transducing variants in phage , but suggest in first approximation that the exchange between the P2 DNA and the chromosome of the host bacterium may occur at several different bacterial sites.A map of the regulatory region of P2, based on all data available from the study of deletions and insertions, is presented.     

Molecular cloning of menaquinone biosynthetic genes of Escherichia coli K12

Summary A tranducing phage carrying some of the genes (men) defining the early stages of menaquinone biosynthesis was isolated from a pool of recombinant lambda phages that had been constructed from R.HindIII digests of E. coli DNA and the corresponding insertion vector. The lesions of menB and menC mutants were complemented by the phage but menD mutants were transduced either at low frequencies or not at all. This indicates that the transducing phage contains functional menB and menC genes but that only part of the menD gene had been cloned. The phage (G68) was accordingly disignated menCB(D). Studies with the transducing phage enabled earlier mapping data (Guest 1979) to be reinterpreted in favour of the gene order nalA.... menC..menB..menD.... purF. Restriction analyses established the presence of a bacterial DNA fragment (11.5 kb) linked by a R.HindIII target to the right arm of the genome but fused to the left arm of the vector. Hybridization studies confirmed that the cloned DNA was derived from a larger R.HindIII fragment (21 kb). A physical map of the men region was constructed and some flanking and overlapping fragments were identified.     

Heterozygosis of phage 2-3 of Rhizobium meliloti: Moderate level of mismatch repair or gene conversion

Summary Analysis of clear/turbid mottled (heterozygotic plaques) of Rhizobium meliloti temperate phage 16-3 indicates that the efficiency of repair at three sites (ti3, ti4, and ti5) in the C cistron is 2 to 20-fold less than that observed in E. coli phage . In agreement with this conclusion, heterozygotic plaques were observed at similar frequency in crosses where point and small delection mutants were combined, suggesting that in Rhizobium, DNA molecules with short single-stranded loops can escape from repair as efficiently as the simple mismatches.