Effect of glycerol on Haemophilus influenzae transfection.

Competent Haemophilus influenzae bacteria were exposed to purified phage HP1 DNA and then plated for transfectants (PFU). When 32% (final concentration) glycerol was added before plating, between 10- and 100-fold more transfectants were observed. Glycerol had no significant effect on transfection with DNA from single or tandem double lysogens. It also had little effect on transformation with chromosomal DNA or on transformation of defective HP1 lysogens with phage HP1 DNA. It was concluded that glycerol induced the release of adsorbed linear double-stranded DNA into the interior of the cells.     

Isolation and characterization of a UV-sensitive mutator (mutB1) mutant of Haemophilus influenzae.

The mutB1 mutant of Haemophilus influenzae is very sensitive to UV radiation but only slightly sensitive to methylmethane sulfonate or N-methyl-N'-nitro-N-nitrosoguanidine. Cultures of mutB1 cells contain high numbers of spontaneous mutants and show hypermutability after exposure to the latter mutagen. Normally high-efficiency transforming markers, as well as low-efficiency ones, transform mutB1 recipients at similarly low efficiencies. Significant host cell reactivation was observed when mutB1 cells were exposed to UV-damaged phage; however, these mutants showed a decrease in phage recombination. This mutant did not degrade its DNA following exposure to UV. It is speculated that the mutB1 mutation is similar to the Escherichia coli uvrD mutation.     

Plasmid transfer in Haemophilus influenzae.

Twenty-nine strains of Haemophilus influenzae highly resistant to ampicillin, chloramphenicol, or tetracycline were examined for the presence of plasmids. Agarose gel electrophoresis of ethanol-precipitated cell extracts revealed large plasmids in 11 strains, of which 7 were conjugative. Plasmid transfer by conjugation between isogenic strains was quite efficient, but transfer between different serotypes was nearly always much more inefficient. Type I or II restriction enzymes do not appear to be barriers to this transfer. Encapsulated cells can be both efficient donors and recipients. Small plasmids were seen in three strains, but only two of the three are resistance factors (RSF0885, pUB703). Thus, in 17 isolates antibiotic resistance genes are believed to be located in the bacterial chromosome. Most of these resistances could be transferred by genetic transformation into the widely used Rd strain. In some cases transfer of chromosomal resistance into conjugative plasmids was observed in both rec+ and rec host cells. Since transfer by conjugation seems to be the more efficient process, it is puzzling that in the majority of the 29 isolates studied resistance genes appeared to be in the chromosome.     

Fate of transforming bacteriophage HP1 deoxyribonucleic acid in Haemophilus influenzae lysogens.

The biological fate of temperate phage HP1 deoxyribonucleic acid (DNA) was followed after uptake by defectively lysogenic competent Haemophilus influenzae cultures. The similar inactivation kinetics of three single phage genetic markers and of their triple combination indicated a complete rather than partial destruction of about half of the adsorbed DNA molecules. Intracellular DNA breakdown products were tentatively identified by hydroxyapatite column chromatography as short single strands and extensively damaged short double strands. Integrated donor DNA (after single-strand insertion?) was still highly efficient for triple-marker co-transformation. This suggests that whole or nearly whole donor DNA molecules were integrated. Some donor DNA was never integrated but remained largely unaltered. This DNA fraction did not contain significant amounts of recipient prophage marker activity. It is concluded that it had not participated in some kind of reciprocal recombination event involving the recipient chromosome. Since very similar phage DNA marker inactivation rates were observed after adsorption by competent nonlysogenic recipients (transfection), the relationship between biological inactivation of adsorbed donor phage DNA and its integration in lysogenic recipients is not clear.     

Chromosomally integrated conjugative plasmids are common in antibiotic-resistant Haemophilus influenzae.

Twenty-three highly antibiotic-resistant strains of Haemophilus influenzae and two of Haemophilus parainfluenzae without detectable large plasmids were examined for conjugative transfer of their resistance to H. influenzae strain Rd or to other strains. Very inefficient transfer was observed for 18 H. influenzae strains and 1 H. parainfluenzae strain. All H. influenzae transcipients carried a large plasmid, and they were in turn efficient donors of their resistances in standard conjugation crosses with isogenic recipients. This was not seen for the H. parainfluenzae transcipients. It is concluded that most of the original antibiotic-resistant cultures carried an integrated conjugative R plasmid which had been excised in a few cells in each population. It was these cells which transferred resistance in the primary crosses.     

Mechanism of additive genetic transformation in Haemophilus influenzae.

Transforming deoxyribonucleic acid (DNA) preparations from Haemophilus influenzae Rd strains carrying a chromosomally integrated, conjugative, antibiotic resistance transfer (R) plasmid were exposed to ultraviolet radiation and then assayed for antibiotic resistance transfer on sensitive wild-type Rd competent suspensions and on similar suspensions of a uvr-1 mutant unable to excise pyrimidine dimers. No host cell reactivation of resistance transfer (DNA repair) was observed. Parallel experiments with ethanol-precipitated, heated, free R plasmid DNA preparations gave much higher survival when assayed on the wild-type strain compared to the survival on the uvr-1 strain. These observations indicate that additive genetic transformation (in this case, the addition of the integrated R plasmid to the recipient genome) involves single-strand insertion.