Protoplast transformation in coryneform bacteria and introduction of an alpha-amylase gene from Bacillus amyloliquefaciens into Brevibacterium lactofermentum

The goal of this study was to investigate the likelihood of developing useful transformation systems for coryneform bacteria. Two species of coryneform bacteria, Brevibacterium lactofermentum and Corynebacterium lilium, were transformed with chimeras constructed from pUB110 and a cryptic coryneform plasmid (pGX1901). C. lilium protoplasts were also efficiently transfected with phage CS1 DNA. High transformation and transfection frequencies were obtained after only 2 min of lysozyme treatment of lysozyme-sensitive mutants. A series of experiments was also conducted to determine whether DNA from other species of important industrial microbes from the genus Bacillus could be expressed in coryneform bacteria. Evidence of restriction of Bacillus subtilis DNA by B. lactofermentum was observed but could be overcome. A Bacillus amyloliquefaciens alpha-amylase gene (amyEBamP) was subcloned onto a plasmid able to replicate in B. lactofermentum. B. lactofermentum transformants for this plasmid expressed amylase activity and produced material cross-reactive to amylase antibody.     

Protoplast transformation in coryneform bacteria and introduction of an alpha-amylase gene from Bacillus amyloliquefaciens into Brevibacterium lactofermentum.

The goal of this study was to investigate the likelihood of developing useful transformation systems for coryneform bacteria. Two species of coryneform bacteria, Brevibacterium lactofermentum and Corynebacterium lilium, were transformed with chimeras constructed from pUB110 and a cryptic coryneform plasmid (pGX1901). C. lilium protoplasts were also efficiently transfected with phage CS1 DNA. High transformation and transfection frequencies were obtained after only 2 min of lysozyme treatment of lysozyme-sensitive mutants. A series of experiments was also conducted to determine whether DNA from other species of important industrial microbes from the genus Bacillus could be expressed in coryneform bacteria. Evidence of restriction of Bacillus subtilis DNA by B. lactofermentum was observed but could be overcome. A Bacillus amyloliquefaciens alpha-amylase gene (amyEBamP) was subcloned onto a plasmid able to replicate in B. lactofermentum. B. lactofermentum transformants for this plasmid expressed amylase activity and produced material cross-reactive to amylase antibody.     

Transfection of Corynebacterium lilium protoplasts

A protoplast transfection system has been developed for a lysine-producing bacterium, Corynebacterium lilium, using the DNA of phage CL31. Phage CL31 is lytic and specific to C. lilium and has a genome of approximately 48 kb. The transfection procedure involves a polyethylene-glycol-mediated introduction of the DNA into lysozyme-treated cells and has a maximum efficiency of 3 X 10(4) transfectants per microgram DNA.     

Salmonella typhimurium SA host specificity system is based on deoxyribonucleic acid-adenine methylation.

We have determined the nature of the deoxyribonucleic acid (DNA) modification governed by the SA host specificity system of Salmonella typhimurium. Two lines of evidence indicate that SA modification is based on methylation of DNA-adenine residues. (i) The SA+ locus of Salmonella was transferred into Escherichia coli B, a strain that does not contain 5-methylcytosine in its DNA; although the hybrid strain was able to confer SA modification, its DNA still did not contain 5-methylcytosine. (ii) the N6-methyladenine content of phage L DNA was measured after growth in various host strains; phage lacking SA modification contained fewer N6-methyladenine residues per DNA. We also investigated the possibility, suggested by others (32), that SA modification protects phage DNA against restriction by the RII host specificity system. Phages lambda, P3, and L were grown in various SA+ and SA- hosts and tested for their relative plating ability on strains containing or lacking RII restriction; the presence or absence of SA modification had no effect on RII restriation. In vitro studies revealed, however, that Salmonella DNA is protected against cleavage by purified RII restriction endonuclease (R-EcoRII). This protection is not dependent on SA modification; rather, it appears to be due to methylation by a DNA-cytosine methylase which has overlapping specificity with the RII modification enzyme, but which is not involved in any other known host specificity system.     

Breakdown and Exclusion of Superinfecting T-Even Bacteriophage in Escherichia coli

In bacterial strains containing the deoxyribonuclease endonuclease I (endonuclease I(+) strains), 70 to 80% of the injected superinfecting T-even phage deoxyribonucleic acid (DNA) is rapidly degraded to oligonucleotides having an average chain length of 8, the same value as that obtained by endonuclease I digestion of purified T-even phage DNA in vitro. In endonuclease I(-) strains, less than 5% of the injected superinfecting T-even phage DNA is degraded to acid-soluble components. The superinfecting phage DNA is, however, fragmented into a large segment having a molecular weight of about 90 x 10(6) and 30 or more small acid-insoluble segments having molecular weights of less than 10(6). In both endonuclease I(+) and endonuclease I(-) strains, over 80% of the DNA from adsorbed primary T2 or T4 phage, but only 50% of the DNA from adsorbed superinfecting T2 or T4 phage, is injected. Superinfecting T4 are genetically excluded as efficiently from endonuclease I(-) strains as they are from endonuclease I(+) strains. The excluded phage cannot complement defects in either early or late gene functions carried by the primary phage. The induction of both superinfection breakdown and superinfection exclusion requires a period of protein synthesis between primary infection and addition of the superinfecting phage. These observations seem best explained by failure of superinfecting DNA to enter the host cell cytoplasm, presumably as a result of changes in the cell envelope induced by the primary phage.     

Restriction alleviation by bacteriophages lambda and lambda reverse.

Deletion analysis indicated that the phage lambda restriction alleviation gene(s) ral resides between the cIII and N genes. The Ral+ phenotype was expressed only when lambda ral+ carried a modification such that it was resistant to restriction by the host specificity system. Under these conditions, Ral function protected superinfecting unmodified phages from restriction by EcoK or EcoB but not from restriction by EcoP1. Ral-protected phage DNA was not concomitantly K and B modified, but rather received only the modification specified by the system of the restricting host. Possible mechanisms for Ral action are discussed. Of the other lambdoid phages tested, the hybrid phage lambda rev had Ral activity, whereas phi 80vir and one lambda-P22 hybrid did not. The restriction alleviation activity of lambda rev called Lar, may be the same as the activity expressed in sbcA- strains of Escherichia coli, but it was functionally separable from exonuclease VIII activity (the product of the recE gene), which is also expressed in sbcA- strains.     

Weakening of bacteriophage lambda EcoK DNA restriction in the presence of plasmid pKM101 ard+. I. General characteristics and genetic localization

The host-controlled K-restriction of unmodified phage lambda is ten to hundred-fold alleviated in the E. coli K12 strain, carring plasmid pKM101 of N-incompatibility group. By restriction mapping Tn5 insertion in pKM101, which reduced pKM101-mediated alleviation of K-restriction, was shown to by located within BglII-B-fragment approximately 9 kb anticlockwise from the EcoRI-site of pKM101. We have termed the gene(s) promoting the alleviation of K-restriction ARD (Alleviation of Restriction of DNA). It was shown that (i) plasmid pKM101-mediated alleviation of K-restriction did not depend on bacterial genes LexA, RecBC, umuC and plasmid gene muc; (ii) ard gene did not mediate EcoK type modification of DNA and did not enhance the modification activity of EcoK system in a way similar to that observed with RAL gene of phage lambda. Action of Ard gene of plasmid pKM101 is highly specific: alleviation of restriction of DNA lambda takes place only in K-strains of E. coli and is practically absent in B-strains and also in E. coli strains which have restricting enzymes of 11 type, EcoRI and EcoRIII.     

Structural characteristics of the Corynebacterium lilium bacteriophage CL31

Bacteriophage CL31 was isolated on a Corynebacterium lilium strain. Out of 30 strains tested, only CL31 was able to form plaques on Corynebacterium glutamicum ATCC 13287, Brevibacterium lactofermentum ATCC 21086, and Arthrobacter sp. strain SI55, but at a very low frequency. This phage belongs to group B of Bradley's classification (D. E. Bradley, Bacteriol. Rev. 31:230-314; 1967). Its head is 53 nm in diameter, and its tail is 396 nm in length. The phage capsid contains three major proteins, of 12.5, 29.0, and 37.0 kilodaltons, and five minor ones (23.9, 26.0, 27.0, 40.0, and 55.4 kilodaltons). CL31 DNA is a linear molecule of 48 kilobases with cohesive ends. Restriction mapping was performed for endonucleases BglII, EcoRI, SalI, and KpnI. The expression of CL31 genes in Escherichia coli was studied by the maxicell technique; 12 different proteins were detected.     

Bacteriophage T4 mutants deficient in alteration and modification of the Escherichia coli RNA polymerase

An extensive screening of coliphage T4 mutants has revealed two distinct classes defective, respectively, in the two sequential phage-induced phosphorylations of the host RNA polymerase, alteration and modification. The existence of these mutants proves that T4-specified functions are involved in both processes. The viabilities of these mutants demonstrate that neither alteration nor modification is essential for growth in Escherichia coli B/r. Physiological studies after infection of E. coli B/r have failed to reveal any abnormalities of phage deficient in alteration or modification. Both mutants normally inhibit host protein and stable RNA synthesis and normally express all classes of T4 genes. Thus, these specific phage-induced structural changes in the host RNA polymerase are not fundamental to the control of gene expression during T4 development. Alteration and modification may be required for growth in some strains of E. coli and hence be selectively advantageous because they extend the normal host range of the phage.Alteration appears to be catalyzed by a T4 function injected with the DNA. A polypeptide of molecular weight 61,000, which is probably cleaved during morphogenesis from a precursor of molecular weight 79,000, is missing in phage particles of alteration-deficient strains and may be the phage activity so injected. The T4 gene involved in alteration is named alt.Modification is controlled by a T4-replicative gene that has been mapped into a region of about 500 base-pairs between genes 39 and 56. These mapping data show that the defect in α modification defines a new T4 gene, named mod.     

Developing live Shigella vaccines using lambda Red recombineering

Live attenuated Shigella vaccines have shown promise in inducing protective immune responses in human clinical trials and as carriers of heterologous antigens from other mucosal pathogens. In the past, construction of Shigella vaccine strains relied on classical allelic exchange systems to genetically engineer the bacterial genome. These systems require extensive in vitro engineering of long homologous sequences to create recombinant replication-defective plasmids or phage. Alternatively, the lambda red recombination system from bacteriophage facilitates recombination with as little as 40 bp of homologous DNA. The process, referred to as recombineering, typically uses an inducible lambda red operon on a temperature-sensitive plasmid and optimal transformation conditions to integrate linear antibiotic resistance cassettes flanked by homologous sequences into a bacterial genome. Recent advances in recombineering have enabled modification of genomic DNA from bacterial pathogens including Salmonella, Yersinia, enteropathogenic Escherichia coli, or enterohemorrhagic E. coli and Shigella. These advances in recombineering have been used to systematically delete virulence-associated genes from Shigella, creating a number of isogenic strains from multiple Shigella serotypes. These strains have been characterized for attenuation using both in vivo and in vitro assays. Based on this data, prototypic Shigella vaccine strains containing multiple deletions in virulence-associated genes have been generated.     

Restriction and modification in Bacillus subtilis: inducibility of a DNA methylating activity in nonmodifying cells.

The nonrestricting/nonmodifying strain Bacillus subtilis 222 (r-m-) can be induced to synthesize a DNA-modifying activity upon treatment with either mitomycin C (MC) or UV light. This is shown by the following facts. (i) Infection of MC-pretreated 222 cells with unmodified SPP1 phage yields about 3% modified phage that are resistant to restriction in B. subtilis R (r+m+). The induced modifying activity causes the production of a small fraction of fully modified phage in a minority class of MC-treated host cells. (ii) The MC-pretreated host cells contain a DNA cytosine methylating activity: both bacterial and phage DNAs have elevated levels of 5-methylcytosine. (iii) The MC-induced methylation of SPP1 DNA takes place at the recognition nucleotide sequences of restriction endonuclease R from B. subtilis R. (iv) Crude extracts of MC-pretreated 222 cells have enhanced DNA methyltransferase activities, with a substrate specificity similar to that found in modification enzymes present in (constitutively) modifying strains.     

Isolation of Plaque-Forming, Galactose-Transducing Strains of Phage Lambda

Plaque-forming, galactose-transducing lambda strains have been isolated from lysogens in which bacterial genes have been removed from between the galactose operon and the prophage by deletion mutation.—A second class has been isolated starting with a lysogenic strain which carries a deletion of the genes to the right of the galactose operon and part of the prophage. This strain was lysogenized with a second lambda phage to yield a lysogen from which galactose-transducing, plaque-forming phages were obtained. These plaque-forming phages were found to be genetically unstable, due to a duplication of part of the lambda chromosome. The genetic instability of these partial diploid strains is due to homologous genetic recombindation between the two identical copies of the phage DNA comprising the duplication. The galactose operon and the duplication of phage DNA carried by these strains is located between the phage lambda P and Q genes.     

Overproduction of the EcoRII endonuclease and methylase by Escherichia coli strains carrying recombinant plasmids constructed in vitro

Recombinant DNA molecules were constructed from the plasmid pIL203 and the EcoRI-fragment of N3 plasmid containing EcoRII endonuclease and methylase genes and also a gene for resistance to sulfanilamide. The pIL203 plasmid, used as a vector, consisted of the Bam HI-EcoRI-fragment of the plasmid pBR322 conferring resistance to ampicillin and the Bam HI-EcoRI-fragment of lambda phage containing promoters, a thermosensitive mutation in the cI gene and a suppressible amber mutation in the cro gene. Ampicillin-sulfanilamide-resistant clones were selected and tested for their restriction and modification phenotype. The recombinant plasmid DNA, isolated from ApRSuR-resistant clones, which restricted and modified phage lambda imm21 with EcoRII specificity, had the EcoRI-fragment with EcoRII genes in a single orientation. The recombinant plasmid pSK323 was transferred into E. coli strains with su-, su1, su2 or su3 phenotypes. The synthesis of products of EcoRII genes by these strains grown at 37 degrees C is increased by 10--50-fold.     

Restriction and Modification of Bacteriophage S2 in Haemophilus influenzae

The major conclusion from these studies is that variants of Haemophilus influenzae Rd which restrict and modify phage S2 are metastable and capable of giving rise to one another with high frequency. Nonrestrictive RdS cells segregate spontaneously to the restricting, modifying phenotype in about 5% of the progeny of a single clone. The restrictive cells derived from RdS revert to the nonrestrictive phenotype in 15 to 25% of the progeny of a single clone. These frequencies are not appreciably affected by treatment with acriflavine or ethidium bromide, compounds which affect plasmid stability, or by nitrosoguanidine, a powerful mutagen. The genetic locus for restriction and modification of bacteriophage S2 is found to have a chromosomal position between the biotin and proline loci. Restriction-modification of phage S2 has been shown to be a function of its deoxyribonucleic acid (DNA) in that transfection with S2 phage DNA or prophage DNA is subject to host restriction and modification. An enzyme preparation, which contains endodeoxyribonuclease but no appreciable exonuclease activity, from mutant H. influenzae com(-10) did not restrict phage S2.RdS DNA or prophage DNA transfecting activity, indicating that this endodeoxyribonuclease is not responsible for phage restriction. A new restriction enzyme isolated from H. influenzae Rd was found to be the major enzyme involved in the restriction of bacteriophage S2. The enzyme inactivated the transfecting activity of unmodified phage DNA but did not attack modified phage DNA. Unlike endodeoxyribonuclease R, this enzyme requires adenosine triphosphate and S-adenosylmethionine.     

Genetic and physiological studies of an Escherichia coli locus that restricts polynucleotide kinase- and RNA ligase-deficient mutants of bacteriophage T4.

The RNA ligase and polynucleotide kinase of bacteriophage T4 are nonessential enzymes in most laboratory Escherichia coli strains. However, T4 mutants which do not induce the enzymes are severely restricted in E. coli CTr5X, a strain derived from a clinical E. coli isolate. We have mapped the restricting locus in E. coli CTr5X and have transduced it into other E. coli strains. The restrictive locus seems to be a gene, or genes, unique to CTr5X or to be an altered form of a nonessential gene, since deleting the locus seems to cause loss of the phenotypes. In addition to restricting RNA ligase- and polynucleotide kinase-deficient T4, the locus also restricts bacteriophages lambda and T4 with cytosine DNA. When lambda or T4 with cytosine DNA infect strains with the prr locus, the phage DNA is injected, but phage genes are not expressed and the host cells survive. These phenotypes are unlike anything yet described for a phage-host interaction.     

Characterization of Deoxyribonucleic Acid of Virulent Bacteriophage and its Infectivity to Host Bacteria, Pseudomonas solanacearum

Virulent bacteriophage PK-101 was isolated from soil infested with strain K-101 of Pseudomonas solanacearum and nucleic acid was prepared from the phages. Some chemical properties of phage nucleic acid and its infectivities to various strains of P. solanacearum were examined in the present study. By digestion with restriction endonucleases, phage nucleic acid was shown to be linear duplex DNA approximately 35 kb long. Restriction fragment length polymorphism was observed when electrophoresis patterns of enzyme-digested PK-101 DNA were compared with those of DNA prepared from different phage isolates. Transfection of host strains by PK-101 DNA was carried out, and it was infectious not only to host strain K-101, but also to other strains which were resistant to phage particles. Transfection efficiency was considerably enhanced by directly introducing phage DNA into bacterial cells by means of an electroporation. The electroporation technique was also effective to transform P. solanacearum with large-size plasmid DNA.     

A Novel P22 Prophage in Salmonella typhimurium

Under several sets of conditions, all of which seem to perturb purine metabolism, Salmonella typhimurium releases a variety of phages which were not known to be present in the strain. These cryptic phages are not induced by UV irradiation. Furthermore, the induction process does not require a functional recA gene product. While phages of several phenotypic classes have been recovered, including both turbid and clear plaque formers, all appear to be variants of P22 because all show DNA restriction patterns indistinguishable from that of P22. The variety of types suggests that the cryptic prophage is mutagenized as a consequence of the induction process. All the temperature phages tested are capable of transducing a variety of chromosomal markers with high efficiency. The phages induced in this novel way are capable of forming plaques on the strains that gave rise to them. Since the strains releasing phage are not immune to P22, the parental lysogens must not express immunity and the phage must be held in a cryptic state by a novel mechanism. The released phage possess an intact P22 immunity system because many can form standard immune lysogens after reinfection of Salmonella. These results raise the possibility that Salmonella typhimurium harbors cryptic phages that are subject to a novel system of global control related to purine metabolism. Preliminary evidence suggests that the regulation system may involve DNA modification.     

Mutants of the N-3 R-Factor Conditionally Defective in hspII Modification and Deoxyribonucleic Acid-Cytosine Methylase Activity

The N-3 drug resistance (R) factor specifies a deoxyribonucleic acid (DNA)-cytosine methylase and a DNA restriction-modification (hspII) system. We have isolated three independent mutants that are conditionally defective in their ability to modify bacteriophage lambda and to methylate DNA-cytosine residues. The ratio of 5-methylcytosine to N(6)-methyladenine in bacterial DNA and in the DNA of phages lambda and fd was determined after labeling with [methyl-(3)H]methionine at various growth temperatures. Although the ability of the wild-type N-3 factor to modify phage lambda and to methylate DNA-cytosine residues was unaffected with increasing temperature, two of the mutants exhibited a parallel loss in modification and cytosine methylation ability. The ability of the third mutant to carry out these functions was dependent on the presence or absence of an amber suppressor mutation in the host genome. These results offer further support for the notion that hspII modification is mediated by a DNA-cytosine methylase. Evidence is also presented that the modification methylase is responsible for the in vivo methylation of phage fd DNA (which is not subject to hspII restriction in vivo).     

Salmonella typhimurium LT2 strains which are r- m+ for all three chromosomally located systems of DNA restriction and modification.

We describe the derivation of two strains of Salmonella typhimurium LT2 which are r- m+ for all three of the known chromosomal genes for the restriction and modification of DNA, hsdLT, hsdSA, and hsdSB; the strains were designated LB5000 and LB5010. LB5000 is a smooth derivative sensitive to phage P22; LB5010 is a galE strain sensitive to phage P1.     

Role of bacteriophages in genomic variability of related coagulase-negative staphylococci

Abstract DNA analysis using pulsed-field gel electrophoresis (PFGE) has emerged as one of the most sensitive epidemiological tools for the characterization of coagulase-negative staphylococci (CNST). The significance of some minor differences observed between the DNA restriction pulsed patterns of two CNST strains are difficult to interpret since they can theoretically be due to minor chromosomal rearrangements or to phage DNA integration. The latter possibility was investigated by comparing DNA restriction patterns of Staphylococcus epidermidis strains with those of their lysogenized derivatives. In vitro lysogenisation was obtained by exposing the strains to phage 118II. The pulsed patterns of the lysogenized strains were compared to those of their parental strains, revealing a shift in size of approximately 50 kb in a single band which was shown by Southern blotting to contain prophage. One strain was lysogenized ten times, revealing a potential preferref attachment site for phage 118II. These results confirm that chromosomal integration of a phage can be responsible for minor stanle variations in DNA restriction patterns.