Genetical analysis of rifampicin resistant mutants of E. coli K 12

Summary E. coli rifampicin-resistant (rif-r) mutants were divided into two conventional groups: A, resistant to 50–100g/ml of rifampicin both on complete and minimal medium and B, sensitive to these concentrations of rifampicin on minimal, but resistant on complete medium. RNA polymerase from rif-r-A mutants is resistant to high concentrations of rifampicin in vitro while the enzyme from rif-r-B mutants but slightly if at all differs from the wild-type enzyme in its response to the drug.All rif-r-A and rif-r-B mutants are closely linked and map between argH and thi on E. coli K 12 chromosome. We failed to isolate any rifampicin-resistant mutants which would map outside this region.     

Effect of R Factors on Rifampicm Resistance in <Emphasis Type="Italic">E. coli</Emphasis>

THE bactericidal effect of rifampicin, a semi-synthetic rifamycin, is due to its action on DNA-dependent RNA polymerase¹ and all rifampicin-resistant mutants of Escherichia coli contain an altered RNA polymerase with an increased resistance to rifampicin in vitro^2–4. While studying a possible curing effect of rifampicin on E. coli R factors, we observed that R⁺ recombinants of some rif-r mutants are more sensitive to rifampicin (Table 1). Of the cells harbouring certain R factors, less than 1% are able to form colonies on rifampicin-supplemented agar, while with certain others there is no detectable effect.     

Escherichia coli merodiploids with altered ratios of episomal to chromosomal RNA polymerase activity

Summary Starting with an E. coli merodiploid strain (rpoB ⁺ (rifS)/rpoB^- (rifR)) containing equal amounts of rifampicin-sensitive and resistant RNA polymerase activities, mutants were isolated that had a disproportionately high ratio of the rifampicin-resistant enzyme activity. With one strain it is shown that the mutation responsible for this phenotype is closely linked to the rifR (rpoB^-) allele.     

Symbiotic Properties of Antibiotic-Resistant and Auxotrophic Mutants of Rhizobium leguminosarum

A number of auxotrophic and antibiotic-resistant mutants of Rhizobium leguminosarum were isolated and their symbiotic properties examined. Among the auxotrophic mutants tested, only those with an adenine requirement were found to be symbiotically defective and these were all non-infective. Of the antibiotic-resistant mutants isolated, only a minority of the rifampicin-resistant mutants had a modified symbiotic phenotype and this was ineffective. Preliminary evidence suggests that the basis for the resistance in these mutants is a modified DNA-dependent RNA polymerase.     

Rhizobium japonicum mutants defective in symbiotic nitrogen fixation.

Rhizobium japonicum strains 3I1b110 and 61A76 were mutagenized to obtain 25 independently derived mutants that produced soybean nodules defective in nitrogen fixation, as assayed by acetylene reduction. The proteins of both the bacterial and the plant portions of the nodules were analyzed by two-dimensional polyacrylamide gel electrophoresis. All of the mutants had lower-than-normal levels of the nitrogenase components, and all but four contained a prominent bacteroid protein not observed in wild-type bacteroids. Experiments with bacteria grown ex planta suggested that this protein was derepressed by the absence of ammonia. Nitrogenase component II of one mutant was altered in isoelectric point. The soluble plant fraction of the nodules of seven mutants had very low levels of heme, yet the nodules of five of these seven mutants contained the polypeptide of leghemoglobin. Thus, the synthesis of the globin may not be coupled to the content of available heme in soybean nodules. The nodules of the other two of these seven mutants lacked not only leghemoglobin but most of the other normal plant and bacteroid proteins. Ultrastructural examination of nodules formed by these two mutants indicated normal ramification of infection threads but suggested a problem in subsequent survival of the bacteria and their release from the infection threads.     

Bradyrhizobium japonicum isocitrate dehydrogenase exhibits calcium-dependent hysteresis

Bradyrhizobium japonicum NADP(+)-dependent isocitrate dehydrogenase was purified both from cultured cells and from the symbiotic form of the bacteria and was found to be identical in terms of N-terminal amino acid sequence, kinetics, and physicochemical properties. Magnesium and glycerol were absolute requirements for maintaining enzyme activity. The N-terminal amino acid sequence of the enzyme was more similar to the sequences from soybean and yeast than to other bacterial sequences. There was no immunological cross-reaction of antibodies from B. japonicum isocitrate dehydrogenase to extracts of soybean, pea, or Escherichia coli, but there was detectable, although weak, cross-reaction of antibodies from E. coli with the B. japonicum enzyme. B. japonicum isocitrate dehydrogenase displayed strong inhibition by NADH, indicating that during symbiotic nitrogen fixation the enzyme activity would be markedly reduced in planta. The enzyme displayed a calcium-dependent hysteresis, with a pronounced lag lasting as long as 2 min. Hysteresis was evident at concentrations of magnesium less than 0.5 mM and calcium greater than 1 microM. The hysteresis could be alleviated by excess magnesium or by 1,2-bis(2-aminophenoxy)ethane-N,N,N',N'-tetraacetic acid. The results suggest two roles for magnesium during catalysis; one magnesium may be needed to convert the enzyme into the steady-state form and the second needed for chelation of isocitrate for catalysis. The calcium-dependent hysteretic behavior of B. japonicum NADP(+)-isocitrate dehydrogenase suggested that this metal could serve as an intracellular regulator during symbiosis.     

Transposon Tn5-induced mutagenesis of Rhizobium japonicum yielding a wide variety of mutants

When the "suicide" vector pSUP1011, which carries transposon Tn5 (Kmr), was introduced into Rhizobium japonicum USDA 110, kanamycin-resistant (Kmr) colonies were detected at a frequency (4.2 X 10-6) ca. 30 times greater than the spontaneous kanamycin resistance frequency (1.4 X 10-7). Ten thousand Kmr mutants were isolated and tested for nutritional auxotrophy. Auxotrophs were detected at a frequency of 0.5%. The following classes of auxotrophs were identified: adenine- (three), histidine- (three), glutamate- (five), adenine plus thiamine- (nine), uracil- (three), pantothenic acid- (one), tryptophan- (three), and methionine- (three). Mutants blocked in symbiotic nitrogen fixation (Fix-) were also identified at a frequency of 3%. The glutamate auxotrophs were studied in more detail, and all five showed an altered expression of nitrogenase activity in free-living cultures.     

Isocitrate dehydrogenase of Bradyrhizobium japonicum is not required for symbiotic nitrogen fixation with soybean

A mutant strain of Bradyrhizobium japonicum USDA110 lacking isocitrate dehydrogenase activity was created to determine whether this enzyme was required for symbiotic nitrogen fixation with soybean (Glycine max cv. Williams 82). The isocitrate dehydrogenase mutant, strain 5051, was constructed by insertion of a streptomycin resistance gene cassette. The mutant was devoid of isocitrate dehydrogenase activity and of immunologically detectable protein, indicating there is only one copy in the genome. Strain 5051 grew well on a variety of carbon sources, including arabinose, pyruvate, succinate, and malate, but, unlike many microorganisms, was a glutamate auxotroph. Although the formation of nodules was slightly delayed, the mutant was able to form nodules on soybean and reduce atmospheric dinitrogen as well as the wild type, indicating that the plant was able to supply sufficient glutamate to permit infection. Combined with the results of other citric acid cycle mutants, these results suggest a role for the citric acid cycle in the infection and colonization stage of nodule development but not in the actual fixation of atmospheric dinitrogen.     

Isolation and characteristics of rifampicin-resistant mutants of Streptomyces erythraeus strain

Erythromycin-producing strains of S. erythraeus were characterized with respect to formation of spontaneous and induced rifampicin-resistant mutants. It was shown that the frequency of spontaneous rifampicin-resistant mutants formed by various strains amounted to 0.9.10(-8) = 9.1.10(-7). In some events the exposure to nitrosoguanidine increased the frequency of such mutants by 2 orders of magnitude. The rifampicin-resistant mutants differed in antibiotic resistance. It was found that a significant part of the rifampicin-resistant mutants became sensitive to heating (19.1 per cent) and lost the ability to form aeromycelium (21.8 per cent).     

Reiteration of genes involved in symbiotic nitrogen fixation by fast-growing Rhizobium japonicum.

By using cloned Rhizobium meliloti nodulation (nod) genes and nitrogen fixation (nif) genes, we found that the genes for both nodulation and nitrogen fixation were on a plasmid present in fast-growing Rhizobium japonicum strains. Two EcoRI restriction fragments from a plasmid of fast-growing R. japonicum hybridized with nif structural genes of R. meliloti, and three EcoRI restriction fragments hybridized with the nod clone of R. meliloti. Cross-hybridization between the hybridizing fragments revealed a reiteration of nod and nif DNA sequences in fast-growing R. japonicum. Both nif structural genes D and H were present on 4.2- and 4.9-kilobase EcoRI fragments, whereas nifK was present only on the 4.2-kilobase EcoR2 fragment. These results suggest that the nif gene organizations in fast-growing and in slow-growing R. japonicum strains are different.     

Overexpression and purification of a biologically active rifampicin-resistant beta subunit of Escherichia coli RNA polymerase

The gene rpoB (rifD 18), which encodes rifampicin-resistant beta subunit of Escherichia coli RNA polymerase, has been placed on an overexpression plasmid under the control of bacteriophage T7 promoter. Induction of the T7 RNA polymerase gene in the host cells resulted in extensive overproduction of the beta polypeptide. Most of the overproduced material was recovered from cell lysates in insoluble form and was solubilized by extraction with 6 M urea. Purified overproduced beta subunit was added, in molar excess, to urea-denatured rifampicin-sensitive RNA polymerase. Upon removal of urea by dialysis, the reconstituted enzyme became rifampicin-resistant, indicating that overproduced beta subunit can be efficiently assembled into functional holoenzyme.     

Bradyrhizobium japonicum delta-aminolevulinic acid dehydratase is essential for symbiosis with soybean and contains a novel metal-binding domain.

The Bradyrhizobium japonicum hemA gene product delta-aminolevulinic acid (ALA) synthase is not required for symbiosis of that bacterium with soybean. Hence, the essentiality of the subsequent heme synthesis enzyme, ALA dehydratase, was examined. The B. japonicum ALA dehydratase gene, termed hemB, was isolated and identified on the basis of its ability to confer hemin prototrophy and enzyme activity on an Escherichia coli hemB mutant, and it encoded a protein that was highly homologous to ALA dehydratases from diverse organisms. A novel metal-binding domain in the B. japonicum ALA dehydratase was identified that is a structural composite of the Mg(2+)-binding domain found in plant ALA dehydratases and the Zn(2+)-binding region of nonplant ALA dehydratases. Enzyme activity in dialyzed extracts of cells that overexpressed the hemB gene was reconstituted by the addition of Mg2+ but not by addition of Zn2+, indicating that the B. japonicum ALA dehydratase is similar to the plant enzymes with respect to its metal requirement. Unlike the B. japonicum hemA mutant, the hemB mutant strain KP32 elicited undeveloped nodules on soybean, indicated by the lack of nitrogen fixation activity and plant hemoglobin. We conclude that the hemB gene is required for nodule development and propose that B. japonicum ALA dehydratase is the first essential bacterial enzyme for B. japonicum heme synthesis in soybean root nodules. In addition, we postulate that ALA is the only heme intermediate that can be translocated from the plant to the endosymbiont to support bacterial heme synthesis in nodules.     

MSX-resistant mutants of Anabaena 7120 with derepressed heterocyst development and nitrogen fixation

To investigate the role of ammonium-assimilating enzyme in heterocyst differentiation, pattern formation and nitrogen fixation, MSX-resistant and GS-impaired mutants of Anabaena 7120 were isolated using transposon (Tn5-1063) mutagenesis. Mutant Gs1 and Gs2 (impaired in GS activity) exhibited a similar rate of nitrogenase activity compared to that of the wild type under dinitrogen aerobic conditions in the presence and absence of MSX. Filaments of Gs1 and Gs2 produced heterocysts with an evenly spaced pattern in N₂-grown conditions, while addition of MSX altered the interheterocyst spacing pattern in wild type as well as in mutant strains. The wild type showed complete repression of heterocyst development and nitrogen fixation in the presence of NO₃ ^– or NH₄ ⁺, whereas the mutants Gs1 and Gs2 formed heterocysts and fixed nitrogen in the presence of NO₃ ^– and NH₄ ⁺. Addition of MSX caused complete inhibition of glutamine synthetase activity in wild type but Gs1 and Gs2 remained unaffected. These results suggest that glutamine but not ammonium is directly involved in regulation of heterocyst differentiation, interheterocyst spacing pattern and nitrogen fixation in Anabaena.     

Induced plasmid-genome rearrangements in Rhizobium japonicum.

The P group resistance plasmids RP1 and RP4 were introduced into Rhizobium japonicum by polyethylene-glycol-induced transformation of spheroplasts. After cell wall regeneration, transformants were recovered by selecting for plasmid determinants. Plant nodulation, nitrogen fixation, serological, and bacterial genetics studies revealed that the transformants were derived from the parental strains and possessed the introduced plasmid genetic markers. Agarose gel electrophoresis, restriction enzyme analysis, and DNA hybridization studies showed that many of the transformant strains had undergone genome rearrangements. In the RP1 transformants, chromosomal DNA was found to have transposed into a large indigenous plasmid of R. japonicum, producing an even larger plasmid, and the introduced R plasmid DNA was found to be chromosomally integrated rather than replicating autonomously or integrated into the endogenous plasmid. Seemingly, a similar section of chromosomal DNA was involved in all the genomic rearrangements observed in the R. japonicum RP1 and RP4 transformant strains.     

The Formation of Nitrogen-Fixing Bacteroids Is Delayed but Not Abolished in Soybean Infected by an [alpha]-Ketoglutarate Dehydrogenase-Deficient Mutant of Bradyrhizobium japonicum

A mutant strain of Bradyrhizobium japonicum USDA 110 devoid of [alpha]-ketoglutarate dehydrogenase activity (LSG184) was used to test whether this tricarboxylic acid cycle enzyme is necessary to support nitrogen fixation during symbiosis with soybean (Glycine max). LSG184 formed nodules about 5 d later than the wild-type strain, and the nodules, although otherwise normal in structure, contained many fewer infected host cells than is typical. At 19 d after inoculation cells infected with the mutant strain were only partially filled with bacteroids and showed large accumulations of starch, but by 32 d after inoculation the host cells infected with the mutant appeared normal. The onset of nitrogen fixation was delayed about 15 d for plants inoculated with LSG184, and the rate, on a per nodule fresh weight basis, reached only about 20% of normal. However, because nodules formed by LSG184 contained only about 20% of the normal number of bacteroids, it could be inferred that the mutant, on an individual bacteroid basis, was fixing nitrogen at near wild-type rates. Therefore, the loss of [alpha]-ketoglutarate dehydrogenase in B. japonicum does not prevent the formation or the functioning of nitrogen-fixing bacteroids in soybean.     

Mechanism of action of rifamazine, a member of a new class of (dimeric) rifamycins.

1. Rifamazine (AF/RP) a dimeric rifamycin, is active against bacterial DNA-dependent RNA polymerase and against viral RNA-dependent DNA polymerase. 2. Rifamazine is active also against DNA-dependent RNA polymerase extracted from rifampicin-resistant mutants of Escherichia coli. It does not interfere with enzyme-template interaction or with RNA elongation. It blocks initiation. 3. A comparison is made between the mechanism of action of rifamazine and that of rifampicin, and of AF/013 (octyloxime of 3-formylrifamycin SV), a C-class rifamycin. Our results show that the mechanism of action of rifamazine is more similar to that of rifampicin than to that of the octyloxime derivative. 4. Activity of rifamazine against RNA polymerase from rifampicin-resistant mutants is thought to be due to binding of the dimer to both the rifamycin-specific binding site and to a second weak site.