Regulation of H2 oxidation activity and hydrogenase protein levels by H2, O2, and carbon substrates in Alcaligenes latus

Why does the Aβ peptide of Alzheimer share structural similarity with antimicrobial peptides?

The Aβ peptides causally associated with Alzheimer disease have been seen as seemingly purposeless species produced by intramembrane cleavage under both physiological and pathological conditions. However, it has been increasingly suggested that they could instead constitute an ancient, highly conserved effector component of our innate immune system, dedicated to protecting the brain against microbial attacks. In this antimicrobial protection hypothesis, Aβ aggregation would switch from an abnormal stochastic event to a dysregulated innate immune response. In this perspective, we approach the problem from a different and complementary perspective by comparing the structure and sequence of Aβ(1-42) with those of bona fide antimicrobial peptides. We demonstrate that Aβ(1-42) bears convincing structural similarities with both viral fusion domains and antimicrobial peptides, as well as sequence similarities with a specific family of bacterial bacteriocins. We suggest a model of the mechanism by which Aβ peptides could elicit the immune response against microbes.

Pastore et al. provide independent evidence that the Alzheimer Aβ peptides could function as antimicrobial peptides based on convincing structural and sequence similarities with viral fusion domains and established antimicrobial peptides. Aβ could dispatch an antimicrobial function through a mechanism that involves membrane pore formation.

The synthesis of Rhodobacter capsulatus HupSL hydrogenase is regulated by the two-component HupT/HupR system

The synthesis of the membrane-bound [NiFe]hydrogenase of Rhodobacter capsulatus (HupSL) is regulated negatively by the protein histidine kinase, HupT, and positively by the response regulator, HupR. It is demonstrated in this work that HupT and HupR are partners in a two-component signal transduction system. The binding of HupR protein to the hupS promoter regulatory region (phupS ) was studied using gel retardation and footprinting assays. HupR protected a 50 bp region localized upstream from the binding site of the histone-like integration host factor (IHF) regulator. HupR, which belongs to the NtrC subfamily, binds to an enhancer site (TTG-N5-CAA) localized at -162/-152 nt. However, the enhancer-binding HupR protein does not require the RpoN sigma factor for transcriptional activation, as is the case for NtrC from enteric bacteria, but functions with sigma70-RNA polymerase, as is the case for R. capsulatus NtrC. Besides, unlike NtrC from Escherichia coli, HupR activates transcription in the unphosphorylated form and becomes inactive by phosphorylation. This was demonstrated by replacing the putative phosphorylation site (D54) of the HupR protein with various amino acids or by deleting it using site-directed mutagenesis. Strains expressing mutated hupR genes showed high hydrogenase activities even in the absence of H2, indicating that hupSL transcription is activated by the binding of unphosphorylated HupR protein. Strains producing mutated HupRD54 proteins were derepressed for hupSL expression as were HupT- mutants. It is shown that the phosphorylated form of HupT was able to transfer phosphate to wild-type HupR protein but not to mutated D54 HupR proteins. Thus, it is concluded that HupT and HupR are the partners of a two-component regulatory system that regulates hupSL gene transcription.

Effects of ammonia on the de novo synthesis of polypeptides in cells of Nitrosomonas europaea denied ammonia as an energy source

The effects of ammonium on the de novo synthesis of polypeptides in the soil-nitrifying bacterium Nitrosomonas europaea have been investigated. Cells were incubated in the presence of both acetylene and NH4+. Under these conditions, the cells were unable to utilize NH4+ as an energy source. Energy to support protein synthesis was supplied by the oxidation of hydroxylamine or other alternative substrates for hydroxylamine oxidoreductase. De novo protein synthesis was detected by 14C incorporation from 14CO2 into polypeptides by sodium dodecyl sulfate-polyacrylamide gel electrophoresis and fluorography. In the presence of NH4+, acetylene-treated cells synthesized the 27-kDa polypeptide of ammonia monoxygenase (AMO) and two other major polypeptides (with sizes of 55 and 65 kDa). The synthesis of these polypeptides was completely inhibited by chloramphenicol and attenuated by rifampin. The optimal concentration of hydroxylamine for the in vivo 14C-labeling reaction was found to be 2 mM. The effect of NH4+ concentration was also examined. It was shown to cause a saturable response with a Ks of approximately 2.0 mM NH4+. Labeling studies conducted at different pH values suggest cells respond to NH3 rather than NH4+. No other compounds tested were able to influence the synthesis of the 27-kDa component of AMO, although we have also demonstrated that this polypeptide can be synthesized under anaerobic conditions in cells utilizing pyruvate- or hydrazine-dependent nitrite reduction as an energy source. We conclude that ammonia has a regulatory effect on the synthesis of a subunit of AMO in addition to providing nitrogen for protein synthesis.

Two open reading frames (ORFs) identified near the hydrogenase structural genes in Azotobacter vinelandii, the first ORF may encode for a polypeptide similar to rubredoxins

Sequencing of 744 base pairs (bp) of a cloned section of DNA from Azotobacter vinelandii reveals two complete, closely-spaced open reading frames (ORF1 and ORF2). Both ORFs are transcribed from the same DNA strand as that of the structural genes for hydrogenase (hoxK and hoxG, Menon, A.L. et al. (1990) Gene 96, 67-74), and are located downstream from the latter genes. The distance between the end of hoxG and the beginning of ORF1 is approx. 3.0 kilobases (kb). Most of the deduced amino acid sequence of ORF1 shares high homology with rubredoxin sequences. Some of the deduced amino acid sequence of ORF2 shares homology with that of a reported partial ORF from Rhodobacter capsulatus, ORF located within a region of DNA required for dihydrogen oxidation in that organism. Implications of these findings with respect to dihydrogen metabolism are discussed.

Cyclic AMP in prokaryotes

Cyclic AMP (cAMP) is found in a variety of prokaryotes including both eubacteria and archaebacteria. cAMP plays a role in regulating gene expression, not only for the classic inducible catabolic operons, but also for other categories. In the enteric coliforms, the effects of cAMP on gene expression are mediated through its interaction with and allosteric modification of a cAMP-binding protein (CRP). The CRP-cAMP complex subsequently binds specific DNA sequences and either activates or inhibits transcription depending upon the positioning of the complex relative to the promoter. Enteric coliforms have provided a model to explore the mechanisms involved in controlling adenylate cyclase activity, in regulating adenylate cyclase synthesis, and in performing detailed examinations of CRP-cAMP complex-regulated gene expression. This review summarizes recent work focused on elucidating the molecular mechanisms of CRP-cAMP complex-mediated processes. For other bacteria, less detail is known. cAMP has been implicated in regulating antibiotic production, phototrophic growth, and pathogenesis. A role for cAMP has been suggested in nitrogen fixation. Often the only data that support cAMP involvement in these processes includes cAMP measurement, detection of the enzymes involved in cAMP metabolism, or observed effects of high concentrations of the nucleotide on cell growth.

Cyclic AMP in prokaryotes

Cyclic AMP (cAMP) is found in a variety of prokaryotes including both eubacteria and archaebacteria. cAMP plays a role in regulating gene expression, not only for the classic inducible catabolic operons, but also for other categories. In the enteric coliforms, the effects of cAMP on gene expression are mediated through its interaction with and allosteric modification of a cAMP-binding protein (CRP). The CRP-cAMP complex subsequently binds specific DNA sequences and either activates or inhibits transcription depending upon the positioning of the complex relative to the promoter. Enteric coliforms have provided a model to explore the mechanisms involved in controlling adenylate cyclase activity, in regulating adenylate cyclase synthesis, and in performing detailed examinations of CRP-cAMP complex-regulated gene expression. This review summarizes recent work focused on elucidating the molecular mechanisms of CRP-cAMP complex-mediated processes. For other bacteria, less detail is known. cAMP has been implicated in regulating antibiotic production, phototrophic growth, and pathogenesis. A role for cAMP has been suggested in nitrogen fixation. Often the only data that support cAMP involvement in these processes includes cAMP measurement, detection of the enzymes involved in cAMP metabolism, or observed effects of high concentrations of the nucleotide on cell growth.

Kinetic analysis of the interaction of nitric oxide with the membrane-associated, nickel and iron-sulfur-containing hydrogenase from Azotobacter vinelandii

The effects of nitric oxide (NO) on the membrane-associated form of the nickel and iron-sulfur-containing hydrogenase from Azotobacter vinelandii have been investigated. In the presence of H2 and an electron acceptor (turnover conditions), NO acts as a noncompetitive inhibitor vs. methylene blue (Ki = 12 microM). There is no element of competition between NO and H2, implying that the site of NO action is not the H2-activating site of the hydrogenase. When the membrane-associated hydrogenase is incubated under non-turnover conditions, the enzyme is irreversibly inactivated by NO in a time-dependent process. The inactivation is a non-saturable, pseudo-first-order process which is consistent with a direct chemical reaction between NO and the hydrogenase. Kinetic evidence is presented which is compatible with an interaction between NO and a redox-active component other than the H2-activating site on the enzyme. The complex inhibition pattern of NO has been interpreted in terms of two distinct interactions of NO with iron-sulfur centers of the hydrogenase.

Cloning, sequencing and characterization of the [NiFe]hydrogenase-encoding structural genes (hoxK and hoxG) from Azotobacter vinelandii

The Azotobacter vinelandii [NiFe]hydrogenase-encoding structural genes were isolated from an A. vinelandii genomic cosmid library. Nucleotide (nt) sequence analysis showed that the two genes, hoxK and hoxG, which encode the small and large subunits of the enzyme, respectively, form part of an operon that contains at least one other gene. The hoxK gene encodes a polypeptide of 358 amino acids (aa) (39,209 Da). The deduced aa sequence encodes a possible 45-aa N-terminus extension, not present in the purified A. vinelandii hydrogenase small subunit, which could be a cellular targeting sequence. The hoxG gene is downstream form, and overlaps hoxK by 4 nt and encodes a 602-aa polypeptide of 66,803 Da. The hoxK and hoxG gene products display homology to aa sequences of hydrogenase small and large subunits, respectively, from other organisms. The hoxG gene lies 16 nt upstream from a third open reading frame which could encode a 27,729-Da (240-aa) hydrophobic polypeptide containing 53% nonpolar and 11% aromatic aa. The significance of this possible third gene is not known at present.

Identification of distinct NAD-linked hydrogenase protein species in mutants and nickel-deficient wild-type cells of Alcaligenes eutrophus H16

By crossed immunoelectrophoresis with antibodies against the NAD-linked hydrogenase the presence of three hydrogenase protein species was demonstrated in crude extracts of Alcaligenes eutrophus H16. Protein 1 (antigen 1) exhibited NAD-reducing activity and was shown to be identical with the native heterotetrameric enzyme. Protein 2 (antigen 2) was catalytically inactive in the antibody-precipitated form and corresponded to the beta subunit (56 kDa) of the holoenzyme. Protein 3 (antigen 3) was serologically distinct from antigen 2 and catalyzed NADH-oxidizing (diaphorase) activity, suggesting that it either consists of the alpha peptide or of the alpha and gamma subunits of the diaphorase dimer. Tandem immunoelectrophoresis revealed that antigen 2 was the predominant protein species in cells cultivated under nickel deficiency. Low concentrations of the diaphorase-active antigen 3 were also detected under these conditions. Extracts from mutants defective in the catalytic activity of NAD-reducing hydrogenase still contained the four polypeptides. This was shown by immunodiffusion and immunoblotting with antibodies raised against the individual subunits. However, as observed with nickel-deficient cells, no complete tetrameric protein could be identified, and the dominant subunit species (70-80%) was the beta peptide.

Activities, occurrence, and localization of hydrogenase in free-living and symbiotic frankia

Symbiotic and free-living Frankia were investigated for correlation between hydrogenase activities (in vivo/in vitro assays) and for occurrence and localization of hydrogenase protein by Western blots and immuno-gold localization, respectively. Freshly prepared nodule homogenates from the symbiosis between Alnus incana and a local source of Frankia did not show any detectable in vivo or in vitro hydrogenase uptake activity, as also has been shown earlier. However, a free-living Frankia strain originally isolated from these nodules clearly showed both in vivo and in vitro hydrogenase activity, with the latter being approximately four times higher. Frankia strain Cpl1 showed hydrogen uptake activity both in symbiosis with Alnus incana and in a free-living state. Western blots on the different combinations of host plants and Frankia strains used in the present study revealed that all the Frankia sources contained a hydrogenase protein, even the local source where no in vivo or in vitro activity could be measured. The 72 kilodalton protein found in the symbiotic Frankia as well as in the free-living Frankia strains were immunologically related to the large subunit of a dimeric hydrogenase purified from Alcaligenes latus. Recognitions to polypeptides with molecular masses of about 41 and 19.5 kilodaltons were also observed in Frankia strain UGL011101 and in the local source of Frankia, respectively. Immunogold localization of the protein demonstrated that in both the symbiotic state and the free-living nitrogen-fixing Frankia, the protein is located in vesicles and in hyphae. The inability to measure any uptake hydrogenase activity is therefore not due to the absence of hydrogenase enzyme. However, the possibility of an inactive hydrogenase enzyme cannot be ruled out.

Nickel affects expression of the nickel-containing hydrogenase of Alcaligenes latus

The effects of nickel on the expression of hydrogenase in the hydrogen-oxidizing bacterium Alcaligenes latus were studied. In the absence of added nickel, both hydrogenase activity, measured as O2-dependent H2 uptake, and hydrogenase protein, measured in a Western immunoblot, were very low compared with the levels in cells induced for hydrogenase in the presence of nickel. Hydrogenase activity and protein levels were dependent on the added nickel concentration and were saturated at 30 nM added Ni2+. The amount of hydrogenase protein in a culture at a given nickel concentration was calculated from the H2 uptake activity of the culture at that Ni2+ concentration. Between 0 and 30 nM added Ni2+, the amount of hydrogenase protein (in nanomoles) was stoichiometric with the amount of added Ni2+. Thus, all of the added Ni2+ could be accounted for in hydrogenase. Between 0 and 50 nM added Ni2+, all the Ni present in the cultures was associated with the cells after 12 h; above 50 nM added Ni2+, some Ni remained in the medium. No other divalent metal cations tested were able to substitute for Ni2+ in the formation of active hydrogenase. We suggest two possible mechanisms for the regulation of hydrogenase activity and protein levels by nickel.

Hydrogen-mediated enhancement of hydrogenase expression in Azotobacter vinelandii

Azotobacter vinelandii cultures express more H2 uptake hydrogenase activity when fixing N2 than when provided with fixed N. Hydrogen, a product of the nitrogenase reaction, is at least partly responsible for this increase. The addition of H2 to NH4+-grown wild-type cultures caused increased whole-cell H2 uptake activity, methylene blue-dependent H2 uptake activity of membranes, and accumulation of hydrogenase protein (large subunit as detected immunologically) in membranes. Both rifampin and chloramphenicol inhibited the H2-mediated enhancement of hydrogenase synthesis. Nif- A. vinelandii mutants with deletions or insertions in the nif genes responded to added H2 by increasing the amount of both whole-cell and membrane-bound hydrogenase activities. Nif- mutant strain CA11 contained fourfold more hydrogenase protein when incubated in N-free medium with H2 than when incubated in the same medium containing Ar. N2-fixing wild-type cultures that produce H2 did not increase hydrogenase protein levels in response to added H2.