Genetic Factors Affecting Recovery of Nonpoint Mutations in the Region of a Gene Coding for Ornithine Transcarbamylase: Involvement of Both the F Factor in Its Chromosomal State and the recA Gene

Mutants of E. coli K12 that overproduce ornithine transcarbamylase can be identified in Car^- strains because they permit utilization of citrulline as a carbamyl phosphate source, due to reversal of the normal OTCase reaction; they are called Cut mutants (citrulline utilizers). Hfr strains that carry the F factor adjacent to argF (one of two duplicate genes that code for ornithine transcarbamylase in E. coli K12) yield more Cut mutants than do F⁺ or F^- strains, or Hfr strains in which the F factor is not adjacent to argF. When Hfr strains in which the F factor is integrated adjacent to argF are made recA, they yield few Cut mutants. Many of the Cut mutants recovered from one of the Hfr strains used in the investigation (Hfr P4X) are unstable; the properties of these unstable mutations suggest that they carry aberrations in the region of the argF gene. Thus, the increased yields of Cut mutants probably result from aberrations that occur when the F factor is integrated adjacent to argF. The nature of these aberrations is not yet known. The unstable Cut mutants are to a large extent stabilized by recA; such stabilization is one of the properties of duplications. Other data indicate that the aberrations may be more complex than simple gene duplications; in particular properties of segregants and some recombinants derived from unstable Cut mutants are most easily interpreted by assuming that segregation from, and possibly formation of, the unstable mutants occurs in several stages.     

Pasteurella Bacteriophage Sex Specific in Escherichia coli

Phage H, thought to be specific for Pasteurella pestis, was shown to plate efficiently on F⁻ strains of Escherichia coli but not on F⁺, F′, or Hfr strains. The phage was adsorbed rapidly to F⁻ strains but was not adsorbed to strains carrying F. Comparison with seven other reported female-specific phages showed that, although phage H was similar to the other phages in some characteristics, the exceptionally low efficiency of plating (<10⁻⁹) on F-containing cells makes phage H a particularly useful female-specific phage.     

Gross Map Distances and Hfr Transfer Times in Escherichia coli K-12

Hfr strains B4 and B8 transfer the Escherichia coli chromosome in opposite directions, each transferring lac⁺ as the last known marker. They were mated in concurrent crosses with the proA leu metE lys trp purE lac strain χ462. Analysis of the time of entry values for these markers showed that Hfr strain B8 transfers the whole chromosome more rapidly than does Hfr strain B4. In both crosses, the rate of transfer observed decelerates. If deceleration occurs as a function of the amount of chromosome transferred, the data are consistent with the markers examined being very accurately placed on the Taylor-Trotter map of the E. coli K-12 genome.     

Isolation of High-Frequency Recombining Strains from Escherichia coli Containing the V Colicinogenic Factor

The isolation and characterization of high-frequency recombining strains from different Escherichia coli host cells containing either the F factor or the Col V factor are described. The strains (with one exception) formed from three of the V⁺ parents showed the same origin and polarity of transfer (xyl-arg-pro-trp-his-mal). The Hfr strains formed from the one remaining V⁺ and the F⁺ host cells showed a greater variety in their points of origin. In addition, several Hfr strains isolated from V⁺ parents lost the ability to produce colicin V. F_v⁺ segregants of these were isolated, and the F_v factors appeared to retain their preferential site for Hfr formation, but they lacked other propertes controlled by the Col V factor. Chromosomal integration of episomes and its relation to the fertility of F⁺ and V⁺ strains are discussed. Production of colicin V appeared to be uninfluenced by the state of the Col V factor within the cell.     

Coupling site-directed mutagenesis with high-level expression: large scale production of mutant porins from E. coli

Combination of an origin repair mutagenesis system with a new mutS host strain increased the efficiency of mutagenesis from 46% to 75% mutant clones. Overexpression with the T7 expression system afforded large quantities of proteins from mutant strains. A series of E. coli B^E host strains devoid of major outer membrane proteins was constructed, facilitating the purification of mutant porins to homogeneity. This allowed preparation of 149 porin mutants in E. coli used in detailed explorations of the structure and function of this membrane protein to high resolution.     

Localization of the structural gene for ribosomal protein L19 (rplS) in Escherichia coli

Summary A temperature-sensitive mutant derived from an E. coli K12 strain, PA3092, was found to have an alteration in the ribosomal protein L19 (Isono et al., 1977). This mutant is a double mutant with a temperature-sensitivity mutation and a mutation leading to the structural alteration of L19 protein. Crosses with various Hfr strains and transductions with P1kc have revealed that the latter mutation maps at 56.4 min, between pheA and alaS. From the fact that two other mutations causing different types of alterations in L19 protein also map at this locus, the gene affected by these mutations was concluded to be the structural gene for the ribosomal protein L19 (rplS).     

Genetic tools for selective labeling of proteins with α-15N-amino acids

Summary A collection of genetic tools that can be used to manipulate amino acid metabolism in Escherichia coli is described. The set comprises 21 strains of bacteria, each containing a different genetic defect that is closely linked to a selectable transposon marker. These tools can be used to construct strains of E. coli with ideal genotypes for residue-specific, selective labeling of proteins with nearly any ¹⁵N-amino acid. By using strains which have been modified to contain the appropriate genetic lesions to control amino acid biosynthesis, dilution of the isotope by endogenous amino acid biosynthesis and scrambling of the label to other types of residues can be avoided.Abbreviations ¹⁵N-amino acid -¹⁵N-amino acid - Cam^R chloramphenicol-resistant - DPA diaminopimelic acid - Hfr high-frequency recombinant - LB Luria broth - Kan^R kanamycin resistant - P1 bacteriophage P1 - pfu plaque-forming units - Str^R streptomycin-resistant - Tet^R tetracycline-resistant     

Mapping of the Locus for Escherichia coli Transfer Ribonucleic Acid Nucleotidyltransferase

cca Mutants of Escherichia coli K12 have altered levels of tRNA nucleotidyl-transferase activity. The cca locus has been located at minute 59.4 of the E. coli linkage map. It is cotransduced with tolC but not with argG, and is the earliest known marker transferred by Hfr strain KL14. The proximity of the tolC locus to the integrated sex factor in Hfr strain KL14 may be useful for mapping sex factor mutations by transduction.     

Some Genetic Consequences of Changes in the Level of recA Gene Function in ESCHERICHIA COLI K-12

Genetic recombination was studied in E. coli mutants that carry lesions in the recA gene but retain some capacity for generating recombinant progeny. We observed that recombination was detectable only at a very low level during the incubation of leaky RecA^- merozygotes in broth. However, recombination appeared to occur at much higher frequencies when recombinant progeny were assayed by selection on minimal agar. Analysis of the recombinants obtained with Hfr donors revealed a deficiency of multiple exchanges per unit length of DNA in leaky RecA ^- strains. In many of these crosses recombinants that inherited donor alleles close to the transfer origin were much reduced in frequency, except when the recipient was also RecB^-.     

Temperature-sensitive mutations affecting the replication of F-prime factors in Escherichia coli K 12

Summary More temperature-sensitive mutants affecting the replication of the F-gal⁺ episome of Escherichia coli K12 have been isolated. Eight of the mutations were located on F itself and three were located on the chromosome.The temperature sensitive F-gal⁺'s have been integrated into the chromosome to produce Hfr strains. These Hfr strains have transfer origins similar to Hfr Cavalli, and all show aberrant excision and transfer of elongated segments of the chromosome including the integrated F-gal to generate long merodiploids.The chromosomal mutations that govern the replication of F have been termed seg (for segregation). Wild-type F-gal⁺ can be integrated into seg cells at 42° C to give Hfrs, in a process analogous to integrative suppression in the formation of Hfrs from cells carrying mutations that are temperature-sensitive for chromosomal DNA replication (dnaA). A curious feature of an Hfr derived from a seg strain is that it also shows F-genote enlargement as well as normal transfer of chromosomal genetic marker. Preliminary transductional mapping data show that the mutation seg-2 is linked to the threonine locus (minute 0).     

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).     

Marker rescue of the adsorption properties of bacteriophage T 4 by bacteriophage T 2

Rescue of adsorption properties from UV-irradiated T4 by T2 as a helper phage, revealed progeny phage with intermediate properties. Fourteen independent progeny phages, plating onE. coli B/2, were plated on several indicator strains and their adsorption properties were also studied with specific T4 antibodies. Two of these, plating onE. coli KS/4, were not inactivated by the T4 antiserum, and were T2h without apparent T4 properties. The other 12 progeny phages did not plate on KS/4, and were inactivated, but at a slower rate than the parental T4. Their mean efficiency of plating onE. coli B/2 (0.83) was significantly lower than that of the parental T4. The efficiency of plating was positively correlated with the velocity of inactivation by T4 antiserum. The observations were explained by assuming that the progeny phages were recombinants of T4 and T2 loci for adsorption sites. Plating of these 12 progeny phages on several indicator strains showed that they were allrII mutants and all, except one, wererI mutants too. In addition, two weretu andh ⁴, respectively. The condition for the appearance of multiple mutants might be a complementation by T2 of UV-damaged functions, which otherwise fail to induce the completion of the lytic cycle in monocomplexes of extracellularly irradiated T4.     

Studies of opal mutations in bacteriophage T4B

Hydroxylamine-induced amber and opal mutants are localized on the map of gene 47 of bacteriophage T4B. The matched map of amber and opal mutations showed the presence of four paired sites which seemed to have arisen in the triplet coding for tryptophan.In growth studies o opal mutants in gene 47 in a series of Su⁺ strains the number of strains bearing a gene-suppressor for amber or ochre mutations also had a weak suppressor activity for some opal mutants. This suppressor acitivity is supposedly due to a second mutation in gene Su_uga.A comparative study of the phage yield with amber and opal mutations located in the same (paired) triplet in gene 47 has shown that the suppressor activity depends on the location of the mutant site along the gene.Experiments dealing with the induction of reversions by nitrous acid in amber and opal mutants with mutational sites located in the same triplet of gene 47 (mutant pairs) have shown the essential influence of the nucleotide sequence in the triplet on the frequency of induced reverse mutations at the given site.     

Effect of recF, recJ, recN, recO and ruv mutations on ultraviolet survival and genetic recombination in a recD strain of Escherichia coli K12

Summary DNA repair and recombination were investigated in a recD mutant of Escherichia coli which lacked the nuclease activity of the RecBCD enzyme. The resistance of this mutant to ultraviolet (UV) light was shown to be a function of recJ. A recD recJ double mutant was found to be more sensitive to UV radiation than a recB mutant, whereas recD and recJ single mutants were resistant. Recombination in conjugational crosses with Hfr donors was also reduced in recD recJ strains, but the effect was modest in comparison with the sensitivity to UV. Within certain limits, mutations in recF, recN, recO, lexA and ruv did not affect sensitivity to UV and recombination in a recD mutant any more than in a recD ⁺ strain. The possibility that recD and recJ provide overlapping activities, either of which can promote DNA repair and recombination in the absence of the other, is discussed.     

Replication of Fpoh+ plasmid in mafA mutants of Escherichia coli defective in plasmid maintenance

Summary A class of F plasmids, designated Fpoh ⁺, was previously shown to be able to replicate extrachromosomally on Hfr strains by virtue of carrying the specific site or region poh ⁺ (permissive on Hfr) of the E. coli chromosome (Hiraga, 1975, 1976a). These plasmids were now found to replicate on E. coli mafA mutants (mafA1 and mafA23) that cannot support vegetative replication of F and some other F-like plasmids. The derivatives of Fpoh ⁺ that have lost the poh ⁺ site, on the other hand, failed to replicate on mafA mutants. These mutants harboring Fpoh ⁺ (but not Poh^- derivatives thereof) exhibit abnormal cell division and form elongated cells, presumably due to competition between Fpoh ⁺ and the host chromosome for some factor(s) essential for the initiation of DNA replication of the both replicons. It is tentatively concluded that the poh ⁺ site is required for F plasmids to replicate on mafA mutants as well as on Hfr strains. In view of the fact that the mechanism of inhibition of autonomous F DNA replication in mafA mutants and in Hfr strains are clearly different, the present data seem to provide strong support to the notion that the poh ⁺ region contains the replication origin of the E. coli chromosome.     

Genetic control of DNA initiation in Escherichia coli

We describe the isolation, and properties of a mutant (CT28) of Escherichia coli with a temperature-sensitive defect in DNA initiation that is reversible. The mutation (dna-28) responsible for this defect is shown to be located in the same region of the map as the dnaC group of DNA initiation mutants.A terminalized culture of CT28 initiates DNA synthesis synchronously immediately upon lowering the temperature, and will do so in the presence of chloram-phenicol.During prolonged incubation at the non-permissive temperature, the cells accumulate a capacity to initiate multiple rounds of replication per chromosome.The variation in the susceptibility of the argH^? and thyA^? alleles to reversion by pulse mutagenesis with nitrosoguanidine during a synchronous round of DNA replication, suggests that this round of replication is bidirectional and commences from an origin in the vicinity of 60 to 65 minutes.CT28 contains two temperature-sensitive mutations. These have been mapped and separated into two derivative strains. One of these, CT28-3b, carries the dna-28 mutation of the C locus, and like the parental double mutant is reversibly temperature-sensitive for an initiation function; but it is more temperature-sensitive than either the double mutant or the other single mutant derivative, CT28-1. The other, CT28-1, is not defective in DNA replication or initiation of replication at the non-permissive temperature.     

Direct plasmid transfer from replica-plated E. coli colonies to competent B. subtilis cells. Identification of an E. coli clone carrying the hisH and tyrA genes of B. subtilis

Summary We have cloned the hisH tyrA wild-type genes of Bacillus subtilis with the aid of the chimeric plasmid pBJ194, which replicates both in B. subtilis and Escherichia coli. Primary cloning was done in E. coli. The original E. coli clone, carrying the recombinant plasmid (pGR1) which complements hisH tyrA mutants of B. subtilis, was selected directly from a mixture of plated E. coli clones by replicaplating these clones onto minimal agar plates without tyrosine spread just before with competent B. subtilis cells. After overnight incubation clusters of small colonies had developed exclusively in the E. coli [pGR1] colony prints.The Tyr⁺ minicolonies were shown to be B. subtilis carrying pGR1 because (i) their appearance depended linearly on the number of B. subtilis cells plated, (ii) they produced extracellular protease and amylase and (iii) plasmids could be reisolated from the minicolonies and used to transform B. subtilis recE4 tyrA1 both to Cm^r and Tyr⁺.Plasmid pGR1 transfer through replica plating was compared with plasmid transfer in liquid. Both systems depended on transformable B. subtilis strains and were sensitive to DNAseI. However, whereas integration of the tyrA ⁺ gene into the chromosome and concomittant loss of plasmids occurred frequently during regular plasmid transformation of Rec⁺ B. subtilis, this was a rare event during plasmid transfer through replica plating.     

Genetic mapping of the X-linked dominant mutations striated (Str) and bare patches (Bpa) to a 600-kb region of the mouse X Chromosome: implications for mapping human disorders in Xq28

Striated (Str) and bare patches (Bpa) are X-irradiation-induced, X-linked dominant mouse mutations that are lethal prenatally in hemizygous males. To map the Str mutation, we generated a backcross involving Mus castaneus. Pedigree analysis of 193 affected female and normal male progeny from the cross places Str extremely close to DXMIT1 and favors a gene order of (Cf-9)-Ids-Gabra3-DXS1104h-(Str, DXMIT1)-F8a-DXPas8-DXBay6-DXMIT6 for the loci studied. This region of the mouse X Chromosome (Chr) is syntenic with proximal human Xq28. Based on the mode of inheritance and clinical phenotype, Str may be a homolog of human familial incontinentia pigmenti (IP2). Further refinement of our genetic mapping of bare patches positions that locus between DXS1104h and DXPas8 in the same region as Str, raising the possibility that Bpa and Str may be allelic or are due to mutations in overlapping contiguous genes.     

Innovative Approach for Improvement of an Antibiotic-Overproducing Industrial Strain of Streptomyces albus

Working with a Streptomyces albus strain that had previously been bred to produce industrial amounts (10 mg/ml) of salinomycin, we demonstrated the efficacy of introducing drug resistance-producing mutations for further strain improvement. Mutants with enhanced salinomycin production were detected at a high incidence (7 to 12%) among spontaneous isolates resistant to streptomycin (Str^r), gentamicin, or rifampin (Rif^r). Finally, we successfully demonstrated improvement of the salinomycin productivity of the industrial strain by 2.3-fold by introducing a triple mutation. The Str^r mutant was shown to have a point mutation within the rpsL gene (encoding ribosomal protein S12). Likewise, the Rif^r mutant possessed a mutation in the rpoB gene (encoding the RNA polymerase β subunit). Increased productivity of salinomycin in the Str^r mutant (containing the K88R mutation in the S12 protein) may be a result of an aberrant protein synthesis mechanism. This aberration may manifest itself as enhanced translation activity in stationary-phase cells, as we have observed with the poly(U)-directed cell-free translation system. The K88R mutant ribosome was characterized by increased 70S complex stability in low Mg²⁺ concentrations. We conclude that this aberrant protein synthesis ability in the Str^r mutant, which is a result of increased stability of the 70S complex, is responsible for the remarkable salinomycin production enhancement obtained.