Effect of glycerol on plasmid transfer in genetically competent Haemophilus influenzae

Summary The small plasmid pAT4 transformed at characteristically low frequencies those competent Haemophilus influenzae Rd strains that had no DNA homology with this plasmid. Transformation was increased up to 100 times, however, when the recipient cells were exposed to 30% glycerol before plating for transformants. Expression of plasmid resistance markers was then immediate. Ultraviolet irradiation experiments indicated that this large increase was due to release by the glycerol of double-stranded plasmid molecules, presumably from transformasomes. Several other plasmids exhibited the same phenomenon. Dimethylsulfoxide also stimulated plasmid transformation but lysolecithin and high concentrations of NaCl or glucose were ineffective. Glycerol did not increase the efficiency of transformation by either chromosomal DNA or linearized plasmid DNA.     

Acid-Soluble Breakdown of Homologous Deoxyribonucleic Acid Adsorbed by Haemophilus influenzae: Its Biological Significance

Competent bacteria of Haemophilus influenzae strain Rd were exposed to various kinds of radioactive deoxyribonucleic acid (DNA) for short periods of time and at relatively low temperature. The fate of phage HP1 DNA was studied most extensively. Adsorbed DNA was partially acid solubilized by lysogens and by nonlysogens with very similar kinetics. The biological activity of the DNA decreased extensively in both lysogenic and nonlysogenic recipients. 2,4-Dinitrophenol had no effect on the acid solubilization but largely abolished the biological inactivation. Inactivation kinetics for three different markers and for the triple combination were roughly the same. The presence of 2,4-dinitrophenol in the medium, or the HP1 prophage in the chromosome, did not alter this observation. This suggests that acid solubilization involves the destruction of whole DNA molecules. In view of the absence of DNA homology between phage and host, it is concluded that acid-soluble breakdown of adsorbed transforming DNA is not an integral part of the donor DNA integration process. Behavior of mutant bacteria indicates that neither exonuclease III nor exonuclease V is involved.     

Restriction enzymes do not play a significant role in Haemophilus homospecific or heterospecific transformation.

Competent Haemophilus influenzae Rd recipients, either as phage HP1 restricting (r+) or nonrestricting (r-) nonlysogens or defective lysogens, were exposed to deoxyribonucleic acids from various wild-type phage HP1 lysogenic H. influenzae serotype strains (non-encapsulated derivatives of serotypes a,b, c, d, and e), to DNA from lysogenic Haemophilus parahaemolyticus, and to DNA from modified and nonmodified phage HP1. Transformation of antibiotic resistance markers and of prophage markers in homospecific crosses was observed to be unaffected by the recipient restriction phenotype, whereas the transfection response was much reduced in r+ recipients. Heterospecific transformation of prophage markers was reduced by only 80 to 90%, whereas antibiotic resistance marker transformation was 1,000 to 10,000 times lower. Heterspecific transfection was at least 100 times lower than homospecific transfection in both r+ and r- recipients. The general conclusion is that neither class I nor class II restriction enzymes affect significantly the transformation efficiency in homospecific and heterospecific crosses. The efficiency of heterospecific transformation may depend mainly on the deoxyribonucleic acid homology in the genetic marker region.     

ReplicationDomain: a visualization tool and comparative database for genome-wide replication timing data

Background  

Eukaryotic DNA replication is regulated at the level of large chromosomal domains (0.5–5 megabases in mammals) within which replicons are activated relatively synchronously. These domains replicate in a specific temporal order during S-phase and our genome-wide analyses of replication timing have demonstrated that this temporal order of domain replication is a stable property of specific cell types.     

Influence of Transformability on the Formation of Superinfection Double Lysogens in Haemophilus influenzae

Superinfection of growing (nontransformable) cells of defectively lysogenic strains of Haemophilus influenzae with wild-type or with mutant phage HP1 resulted in a number of double lysogens and a small number of monolysogens with altered prophage. The double lysogens were identified by analysis of their monolysogenic segregants and by examining their deoxyribonucleic acid in certain test crosses. The results indicate that the majority had been formed by insertion of the infecting phage genome within the resident prophage. Superinfection of transformable bacteria gave rise to cells with altered prophages (presumably transformants) and to double lysogens which had gained or lost wild-type prophage loci.     

Origin and Direction of Haemophilus Bacteriophage HP1 DNA Replication

Rapidly growing Haemophilus influenzae strain Rd bacteria were infected with bacteriophage HP1 and DNA extracts prepared at various times thereafter. A number of phage genes scattered along the entire phage genome were quantitatively assayed by transformation. The kinetics of activity increases of these genes suggests that phage HP1 DNA replication begins at a fixed origin about one-quarter from the right end and that it proceeds to the left.     

Cloning and characterization of the Haemophilus influenzae mutB gene.

The Haemophilus influenzae mutB+ gene complements Escherichia coli uvrD mutants. The E. coli uvrD+ gene complements H. influenzae mutB1 mutants.     

Repair of methyl methane sulfonate-damaged phage by Haemophilus influenzae

Seven mutants of Haemophilus influenzae strain Rd (mmsA-) have been isolated that are more sensitive to methyl methane sulfonate (mms) than recombination-deficient (recA-) mutants. The mutations cotransformed about 25% with the strA locus while the five studied clustered tightly; they are all probably allelic. The mutants are not sensitive to ultraviolet radiation, X-rays, or nitrous acid. Mms-damaged phage HP1 plated very inefficiently on these mutants, indicating that they lack the first step in the excision repair of the lesion N3-methyladenine (m3A). Incubation of damaged phage at 30 degrees C in the absence of mms resulted in a steady decline of viability when the phage were plated on the wild mmsA+ host but an initial steep rise was seen when it was plated on an mmsA- mutant. The rise is explained by the assumption that m3A lesions hydrolyzed off the DNA giving rise to repairable apurinic sites by both the mmsA+ and mmsA- hosts. No decline in viability was observed when hydroxylamine was present in the medium. This compound is known to prevent or slow down beta-elimination. The delayed decline in viability is therefore explained by assuming that apurinic sites give rise to beta-elimination-induced single strand breaks in the phage DNA that cannot be repaired by either host. Marker rescue experiments indicated that these breaks did not interrupt injection of phage DNA.     

Cloning and characterization of the Haemophilus influenzae Rd rec-1+ gene.

The Haemophilus influenzae Rd rec-1+ gene was cloned from a partial chromosomal digest into a plasmid vector as a 20-kilobase-pair (kbp) BstEII fragment and then subcloned. The smallest subclone with rec-1+ activity carried a 3.1-kbp EcoRI fragment. The identity of the rec-I gene in these clones was confirmed by transforming an Rd strain carrying a leaky rec-1 mutation (recA4) to resistance to methyl methanesulfonate (MMS) by using whole or digested plasmids. It was demonstrated that the Rec+ phenotype of the MMSr transformants was linked to the strA, novAB, and mmsA loci, as expected if the recA4 allele had been replaced by rec-1+. In growing cultures (rec-1 or rec+), all rec-1+-carrying plasmids induced near-maximal levels of transformability when their hosts reached stationary phase; these levels are 100 to 1,000 times higher than the values seen with strains not carrying a Rec plasmid. Transfer of the 3.1-kbp subclone was greatly reduced compared with transfer of similarly sized vector plasmids, and the resulting transformants grew slowly; this suggests an explanation of my failure to directly clone this fragment from chromosomal DNA digests. Transfer of a rec-1+ plasmid to a very poorly genetically transformable H. influenzae Rb strain resulted in greatly increased transformability. Transfer of such plasmids to a noncompetent H. influenzae Rc strain did not render this strain competent. It is suggested that transformability of Rd and Rb strains is limited by rec-1 expression but that the noncompetence of Rc has some other basis.