Biochemical and immunological properties of two forms of pertactin, the 69,000-molecular-weight outer membrane protein of Bordetella pertussis.

Two apparent isoforms of the virulence-associated 69,000-molecular-weight protein pertactin were purified from Bordetella pertussis. Mass spectrometry showed a difference of 2,060 Da, which may result from differential C-terminal cleavage of a larger precursor. Both forms were protective in a mouse model, eliciting bactericidal antibodies and reducing respiratory tract colonization.

Preliminary X-ray crystallographic analysis of holotoxin from Bordetella pertussis.

Pertussis (whooping cough) is a serious infectious disease caused by the bacterium Bordetella pertussis. One of the major virulence factors is a protein known as pertussis toxin, which is composed of six subunits, with a total molecular weight of 106,000. Enzymatic transfer of ADP-ribose from NAD to a family of GTP-binding proteins is effected by the largest subunit (S1 or the A monomer), while binding of host cells and entry of S1 to the interior is a function of the other subunits (the B oligomer). The holotoxin crystallizes in the orthorhombic space group P2(1)2(1)2(1), with unit cell dimensions a = 98.4 A, b = 164.2 A and c = 195.2 A. The crystals are suitable for high-resolution X-ray diffraction analysis.

Regulation of nitrogen fixation in Rhodospirillum rubrum grown under dark, fermentative conditions.

Rhodospirillum rubrum was shown to grow fermentatively on fructose with N2 as a nitrogen source. The nitrogenase activity of these cells was regulated by the NH4+ switch-off/switch-on mechanism in a manner identical to that for photosynthetically grown cells. In vitro, the inactive nitrogenase Fe protein from fermenting cells was reactivated by an endogenous membrane-bound, Mn2+-dependent activating enzyme that was interchangeable with the activating enzyme isolated from photosynthetic membranes.

Regulation of nitrogenase activity by covalent modification in Chromatium vinosum.

Nitrogenase in Chromatium vinosum was rapidly, but reversibly inhibited by NH4+. Activity of the Fe protein component of nitrogenase required both Mn2+ and activating enzyme. Activating enzyme from Rhodospirillum rubrum could replace Chromatium chromatophores in activating the Chromatium Fe protein, and conversely, a protein fraction prepared from Chromatium chromatophores was effective in activating R. rubrum Fe protein. Inactive Chromatium Fe protein contained a peptide covalently modified by a phosphate-containing molecule, which migrated the same in SDS-polyacrylamide gels as the modified subunit of R. rubrum Fe protein. In sum, these observations suggest that Chromatium nitrogenase activity is regulated by a covalent modification of the Fe protein in a manner similar to that of R. rubrum.

Purification and Mn2+ activation of Rhodospirillum rubrum nitrogenase activating enzyme.

The Fe protein activating enzyme for Rhodospirillum rubrum nitrogenase was purified to approximately 90% homogeneity, using DE52-cellulose chromatography and sucrose density gradient centrifugation. Activating enzyme consists of a single polypeptide of molecular weight approximately 24,000. ATP was required for catalytic activity, but was relatively ineffective in the absence of Mg2+. When the concentration of MgATP2- was held in excess, there was an additional requirement for a free divalent metal ion (Mn2+) for enzyme activity. Kinetic experiments showed that the presence of Mg2+ influenced the apparent binding of Mn2+ by the enzyme, resulting in a lowering of the concentration of Mn2+ required to give half-maximum activity (K alpha) as the free Mg2+ concentration was increased. A low concentration of Mn2+ had a sparing effect on the requirement for free Mg2+. There is apparently a single metal-binding site on activating enzyme which preferentially binds Mn2+ as a positive effector, and free Mg2+ can compete for this site.

Effect of light intensity and inhibitors of nitrogen assimilation on NH4+ inhibition of nitrogenase activity in Rhodospirillum rubrum and Anabaena sp.

Nitrogenase activity in Rhodospirillum rubrum was inhibited by NH4+ more rapidly in low light than in high light. Furthermore, the nitrogenase of cells exposed to phosphorylation uncouplers was inhibited by NH4+ more rapidly than was the nitrogenase of controls without an uncoupler. These observations suggest that high levels of photosynthate inhibit the nitrogenase inactivation system. L-Methionine-DL-sulfoximine, a glutamine synthetase inhibitor, prevented NH4+ from inhibiting nitrogenase activity, which suggests that NH4+ must be processed at least to glutamine for inhibition to occur. An inhibitor of glutamate synthase activity, 6-diazo-5-oxo-L-norleucine, inhibited nitrogenase activity in the absence of NH4+, but only in cells exposed to low light. The mechanism of 6-diazo-5-oxo-L-norleucine inhibition appeared to be the same as that induced by NH4+, because nitrogenase activity could be restored in vitro by activating enzyme and Mn2+. The inhibitor data suggest that the glutamine pool or a molecule that responds to it activates the Fe protein-modifying (or protein-inactivating) system and that the accumulation of this (unidentified) molecule is retarded when the cells are exposed to high light. It was confirmed here that Anabaena nitrogenase is also inhibited by NH4+, but only when the cells are incubated under low light. This inhibition, however, unlike that in R. rubrum, could be completely reversed in high light, suggesting that the mechanisms of nitrogenase inhibition by NH4+ in these two phototrophs are different.

Novel mutant of Anabaena sp. strain CA which growns on N2 but not on combined nitrogen.

A mutant has been isolated from Anabaena sp. strain CA by treatment with N-methyl-N'-nitro-N-nitrosoguanidine, which has the unusual phenotypic characteristic of growth only under N2-fixing conditions. Growth of the mutant was completely inhibited by NO3- or NH4+ at concentrations routinely used for growth of the wild type, and sensitivity to NH4+ was especially pronounced. The inhibitory effect of NH4+ could not be overcome by glutamine, glutamate, or casein hydrolysate. Ammonia had no immediate inhibitory effect on protein synthesis, CO2 fixation, or O2 evolution, and the gradual inhibition of C2H2 reduction activity by NH4+ resembled a repression phenomenon. The glutamine synthetase activity of N2-fixing cultures appeared normal, yet the mutant was incapable of utilizing exogenous NH4+ for growth. Preliminary evidence suggests a possible alteration of glutamine synthetase, which could result in sensitivity to exogenous NH4+ by progressive inactivation of the enzyme or repression of its synthesis.

Mutants of Anabaena strain CA altered in their ability to grow under nitrogen-fixing conditions.

Mutants of Anabaena strain CA impaired in nitrogenase activity and growth on N2 were isolated and characterized. One mutant was selected for resistance to L-methionine-DL-sulfoximine, and others were selected for resistance to DL-7-azatryptophan or for requirements for combined nitrogen. The mutants varied in sensitivity of growth and nitrogenase activity to atmospheric 02. Several of the mutants whose growth on N2 was impaired under aerobic conditions could grow and reduce acetylene at rates comparable to the wild type when grown microaerobically under N2-CO2 (99:1). The acetylene reduction activity of some of the strains grown under N2-CO2 was immediately and completely lost upon exposure to atmospheric O2, but in at least one strain this loss was reversed when the O2 concentration was lowered, even after 10 h of exposure to air. The characteristics of the O2-sensitive mutants suggest that there may be several sites sensitive to O2 and that the protective mechanism involves several different phenomena.

N(2) Fixation Associated with Decaying Leaves of the Red Mangrove (Rhizophora mangle).

N(2) (C(2)H(2)) fixation was associated with decaying leaves of Rhizophora mangle. The process was predominantly anaerobic, with about two-thirds of the nitrogenase activity being light dependent. Average N(2) fixation rates in the light were 11 mug of N per g (dry weight) per h for leaves that had decayed for 2 to 3 weeks. This nitrogen input is probably significant in the estuarine, detrital food chains linked to R. mangle.