Origin of Haemophilus influenzae R factors.

The Haemophilus influenzae R plasmids specifying resistance against one, two, or three antibiotics which have emerged in different parts of the world were shown to have closely related but not identical plasmid cores. The gene for ampicillin resistance in the H. influenzae plasmid pKRE5367 is part of a transposon similar to Tn3, which was transposed from pKRE5367 onto RSF1010 in Escherichia coli. An indigenous H. influenzae plasmid (pW266) was isolated. Its properties correspond to those of the H. influenzae R plasmids, except for the presence of a drug resistance transposon. The in vitro-generated H. influenzae R plasmids carrying an ampicillin resistance transposon, a tetracycline resistance transposon, and a transposon for combined tetracycline-chloramphenicol resistance resembled the natural isolates. The findings support the hypothesis that the R plasmids of H. influenzae are of multiclonal evolutionary origin.     

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.     

Circularized copies of amplifiable resistance genes from Haemophilus influenzae plasmids.

Tandem repeat amplification of resistance determinants in Haemophilus influenzae plasmids is associated with the occurrence of separate circular DNA molecules. They were demonstrated to represent mono- and multimeric forms of the amplifiable segments of the plasmids which comprise the respective resistance transposons and an additional region designated as an amplification sequence. The latter region mediates the recombinational events involved in amplification. The DNA circles apparently lack the ability to replicate autonomously but most probably provide an effective means for the translocation of resistance genes from one plasmid to another.     

Mechanism of acquisition of chromosomal markers by plasmids in Haemophilus influenzae.

The hybrid plasmid pNov1 readily acquired genetic information from the chromosome of wild-type, but not rec-2, cells. Most of the recombination had taken place 1 h after entrance of the plasmid into the cell, as judged by transformation of rec-2 by lysates made from wild-type cells exposed to pNov1. Measurement of physical transfer from radioactively labeled cellular DNA to plasmids recombining in wild-type cells failed, since there was little more radioactivity in plasmids from such cells than from labeled rec-2 recipients, in which no recombination took place. EcoRI digestion of pNov1 divided the DNA into a 1.7-kilobase-pair fragment containing the novobiocin resistance marker and a 13-kilobase-pair fragment containing all of the original vector and considerable portions homologous to the chromosome. Transformation by the large fragment alone resulted in a plasmid the size of the original pNov1. Our hypothesis to explain the data is that genetic transfer from chromosome to plasmid took place by a copy choice mechanism.     

Methylase activities from Haemophilus influenzae that protect Haemophilus parainfluenzae transforming deoxyribonucleic acid from inactivation by Haemophilus influenzae endonuclease R.

Specific methylases that have the properties of deoxyribonucleic acid (DNA) modification enzymes have been isolated from Haemophilus influenzae strain Rd. Two activities ((Methylase IIa and methylase III) were found to protect transforming DNA of H. parainfluenzae from the action of H. influenzae restriction enzymes. To determine the specificty of the protection, a procedure based on biological activity was developed for the separation and purification of the restriction endonucleases from H. influenzae strain Rd. Two endonuclease R activities presumably corresponding to Hind II and Hind III (P. H. Roy and H. O. Smith, 1973; H. O. Smith and K. W. Wilcox, 1970) were characterized by differences in their chromatographic properties, ability to attack T7 DNA, and inactivation of the transforming activity of different markers of H. parainfluenzae DNA. One endonuclease R enzyme (Hind II) attacked T7 DNA and was found to inactivate the dalacin resistance marker (smaller than 0.01% activity remaining) with only a slight effect on the streptomycin resistance marker (83% activity remaining). Methylase IIa treatment protected 40% of the dalacin resistance marker of H. parainfluenzae DNA from inactivation by Hind II. The other restriction activity (Hind III) was inert towards T7 DNA and inactivated the streptomycin resistance marker of H. parainfluenzae DNA (smaller than 0.01% activity remaining) without any effect on the dalacin resistance marker. The methylation of H. parainfluenzae DNA accomplished by methylase III protected 60% of the transforming activity of the streptomycin resistance marker of H. parainfluenzae DNA from the action of Hind III.     

Molecular nature of two beta-lactamase-specifying plasmids isolated from Haemophilus influenzae type b.

The molecular nature of two beta-lactamase-specifying plasmids isolated from two separate ampicillin-resistant Haemophilus influenzae type b strains was examined. A 30 X 10(6)-dalton (30-Mdal) plasmid (RSF007) had a copy number of approximately 3 per chromosomal equivalent and a mole fraction guanine plus cytosine content of 0.39. By heteroduplex analysis the 30-Mdal plasmid was found to contain the entire ampicillin translocation DNA segment (TnA) found on R factors of enteric origin. A 3.0-Mdal plasmid (RSF0885) was found as a multicopy pool of approximately 28 copies per chromosomal equivalent, had a mole fraction guanine plus cytosine content of 0.40, and contained only about one-third of the transposable TnA sequence. RSF007 and RSF0885 appeared to be unrelated plasmids in that they share base sequence homology only within the confines of the TnA segment. The 3.0-Mdal Haemophilus plasmid was used to transform E. coli to ampicillin resistance but was found to be unstable in this host in the absence of antibiotic. The possibility that R-plasmids arose in Haemophilus by the translocation of TnA from a donor R-factor onto an indigenous H. influenzae plasmid is discussed.     

New shuttle vectors for Haemophilus influenzae and Escherichia coli: P15A-derived plasmids replicate in H. influenzae Rd

With the aim of identifying new plasmids useful for molecular cloning in Haemophilus influenzae, several P15A-derived plasmids were tested for their ability to transform H. influenzae Rd. The four plasmids tested, pACYC177, pACYC184, pSU2718, and pSU2719 were all able to establish in H. influenzae Rd. The plasmids were stable, could be purified by standard protocols, and were compatible with a plasmid carrying the RSF0885 origin of replication.     

Plasmid-to-plasmid recombination in Haemophilus influenzae.

No recombination between plasmids was observed after conjugal transfer of a plasmid into a cell carrying another plasmid. Two types of such recombination took place after transformation, one type being Rec+ dependent and suggesting a preferred site of recombination. The other much rarer type was at least partially Rec+ independent.     

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.     

Plasmid transformation in Haemophilus influenzae.

Purified 34-megadalton-plasmid deoxyribonucleic acid from antibiotic-resistant strains of Haemophilus influenzae transforms competent strains of H. influenzae more efficiently if the recipient strains contain certain other 30-megadalton plasmids.     

Loss of plasmids containing cloned inserts coding for novobiocin resistance or novobiocin sensitivity in Haemophilus influenzae.

Plasmids pNov1 and pNov1s , coding for resistance and sensitivity to novobiocin, respectively, were readily lost from wild-type Haemophilus influenzae but retained in a strain lacking an inducible defective prophage. The plasmid loss could be partly or wholly eliminated by a low-copy-number mutation in the plasmid or by the presence of certain antibiotic resistance markers in the host chromosome. Release of both phage HP1c1 , measured by plaque assay, and defective phage, measured by electron microscopy, was increased when the plasmids were present. The frequency of recombination between pNov1 and the chromosome, causing the plasmid to be converted to pNov1s , could under some circumstances be decreased from the normal 60 to 70% to below 10% by the presence of a kanamycin resistance marker in the chromosome. This suggested that a gene product coded for by the plasmid, the expression of which was affected by the kanamycin resistance marker, was responsible for the high recombination frequency. Evidence was obtained from in vitro experiments that the gene product was a gyrase.     

Molecular properties of transmissible R factors of Haemophilus influenzae determing tetracycline resistance.

The tetracycline-resistant Haemophilus influenzae strains LU121 and FR16017, recently isolated in West Germany, each harbour a plasmid; that of the former (pLU12U) has a mol. wt of 31.5 X 10(6) and that of the latter (pFR16017) has a mol. wt of 33 X 10(6). Conjugation and DNA-DNA hybridization studies have shown that both plasmids are self-transmissible and carry tetracycline-resistance genes. The purified plasmid DNA of H. influenzae strain LU121 transformed a sensitive Escherichia coli strain to tetracycline resistance. The two R factors are closely related to the H. influenzae plasmid specifying ampicillin resistance (pKRE5367). Electron microscope DNA heteroduplex analysis indicated that pLU121 and pFR15017 probably carry the tetracycline-resistance transposon TnD and that pKRE5367 probably carries the ampicillin-resistance transposon TnA. There is more than one integration site for the insertion which probably represents TnD in pFR15017. All three plasmids have a similar plasmid core and could have a common evolutionary origin.     

Mutations affecting gyrase in Haemophilus influenzae.

Mutants separately resistant to novobiocin, coumermycin, nalidixic acid, and oxolinic acid contained gyrase activity as measured in vitro that was resistant to the antibiotics, indicating that the mutations represented structural alterations of the enzyme. One Novr mutant contained an altered B subunit of the enzyme, as judged by the ability of a plasmid, pNov1, containing the mutation to complement a temperature-sensitive gyrase B mutation in Escherichia coli and to cause novobiocin resistance in that strain. Three other Novr mutations did not confer antibiotic resistance to the gyrase but appeared to increase the amount of active enzyme in the cell. One of these, novB1, could only act in cis, whereas a new mutation, novC, could act in trans. An RNA polymerase mutation partially substituted for the novB1 mutation, suggesting that novB1 may be a mutation in a promoter region for the B subunit gene. Growth responses of strains containing various combinations of mutations on plasmids or on the chromosome indicated that low-level resistance to novobiocin or coumermycin may have resulted from multiple copies of wild-type genes coding for the gyrase B subunit, whereas high-level resistance required a structural change in the gyrase B gene and was also dependent on alteration in a regulatory region. When there was mismatch at the novB locus, with the novB1 mutation either on a plasmid or the chromosome, and the corresponding wild-type gene present in trans, chromosome to plasmid recombination during transformation was much higher than when the genes matched, probably because plasmid to chromosome recombination, eliminating the plasmid, was inhibited by the mismatch.