Gene/Protein Disease Symptom Drug Enzyme Compound
Pivot Concepts: Gene/Protein Disease Symptom Drug Enzyme Compound   Target Concepts: Gene/Protein Disease Symptom Drug Enzyme Compound

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Query: UMLS:C0348321 (Haemophilus)
15,372 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

Genome-scale metabolic networks can be characterized by a set of systemically independent and unique extreme pathways. These extreme pathways span a convex, high-dimensional space that circumscribes all potential steady-state flux distributions achievable by the defined metabolic network. Genome-scale extreme pathways associated with the production of non-essential amino acids in Haemophilus influenzae were computed. They offer valuable insight into the functioning of its metabolic network. Three key results were obtained. First, there were multiple internal flux maps corresponding to externally indistinguishable states. It was shown that there was an average of 37 internal states per unique exchange flux vector in H. influenzae when the network was used to produce a single amino acid while allowing carbon dioxide and acetate as carbon sinks. With the inclusion of succinate as an additional output, this ratio increased to 52, a 40% increase. Second, an analysis of the carbon fates illustrated that the extreme pathways were non-uniformly distributed across the carbon fate spectrum. In the detailed case study, 45% of the distinct carbon fate values associated with lysine production represented 85% of the extreme pathways. Third, this distribution fell between distinct systemic constraints. For lysine production, the carbon fate values that represented 85% of the pathways described above corresponded to only 2 distinct ratios of 1:1 and 4:1 between carbon dioxide and acetate. The present study analysed single outputs from one organism, and provides a start to genome-scale extreme pathways studies. These emergent system-level characterizations show the significance of metabolic extreme pathway analysis at the genome-scale.
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PMID:The genome-scale metabolic extreme pathway structure in Haemophilus influenzae shows significant network redundancy. 1205 85

l-Aspartate-beta-semialdehyde dehydrogenase (ASA DH) lies at the first branch point in the aspartate metabolic pathway that leads to the formation of the amino acids lysine, isoleucine, methionine, and threonine in most plants, bacteria, and fungi. Since the aspartate pathway is not found in humans, but is necessary for bacterial cell wall biosynthesis, the enzymes in this pathway are potential targets for the development of new antibiotics. The asd gene that encodes for ASA DH has been obtained from several infectious organisms and ligated into a pET expression vector. ASA DHs from Haemophilus influenza, Pseudomonas aeruginosa, and Vibrio cholerae were expressed as soluble proteins in Escherichia coli, while ASA DH from Helicobacter pylori was obtained primarily as inclusion bodies. The V. cholerae genome contains two asd genes. Both enzymes have been expressed and purified, and each displays significant ASA DH activity. The purification of highly active ASA DH from each of these organisms has been achieved for the first time, in greater than 95% purity and high overall yield. Kinetic parameters have been determined for each purified enzyme, and the values have been compared to those of E. coli ASA DH.
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PMID:Expression and purification of aspartate beta-semialdehyde dehydrogenase from infectious microorganisms. 1207 15

Diaminopimelate (DAP) epimerase (DapF) is central to the biosynthesis of both lysine and cell-wall peptidoglycan in many bacteria species. The peptidoglycan layer provides great potential for the development of novel antimicrobials as it is a uniquely prokaryotic feature. Crystals of recombinant Haemophilus influenzae DapF that diffract to beyond 2 A resolution have been obtained which facilitated the solution of the structure by molecular replacement at a resolution approximately 1 A higher than that previously determined. An analysis of the structure (i) in comparison to other PLP-independent racemaces and (ii) in relation to the catalytic mechanism and stereospecificity of DapF is presented.
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PMID:Refinement of Haemophilus influenzae diaminopimelic acid epimerase (DapF) at 1.75 A resolution suggests a mechanism for stereocontrol during catalysis. 1474 37

The reversible dephosphorylation of beta-aspartyl phosphate to L-aspartate-beta-semialdehyde (ASA) in the aspartate biosynthetic pathway is catalyzed by aspartate-beta-semialdehyde dehydrogenase (ASADH). The product of this reaction is a key intermediate in the biosynthesis of diaminopimelic acid, an integral component of bacterial cell walls and a metabolic precursor of lysine and also a precursor in the biosynthesis of threonine, isoleucine and methionine. The structures of selected Haemophilus influenzae ASADH mutants were determined in order to evaluate the residues that are proposed to interact with the substrates ASA or phosphate. The substrate Km values are not altered by replacement of either an active-site arginine (Arg270) with a lysine or a putative phosphate-binding group (Lys246) with an arginine. However, the interaction of phosphate with the enzyme is adversely affected by replacement of Arg103 with lysine and is significantly altered when a neutral leucine is substituted at this position. A conservative Glu243 to aspartate mutant does not alter either ASA or phosphate binding, but instead results in an eightfold increase in the Km for the coenzyme NADP. Each of the mutations is shown to cause specific subtle active-site structural alterations and each of these changes results in decreases in catalytic efficiency ranging from significant (approximately 3% native activity) to substantial (<0.1% native activity).
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PMID:The role of substrate-binding groups in the mechanism of aspartate-beta-semialdehyde dehydrogenase. 1527 61

Aspartate-beta-semialdehyde dehydrogenase (ASADH) catalyzes the reductive dephosphorylation of beta-aspartyl phosphate to L-aspartate-beta-semialdehyde in the aspartate biosynthetic pathway. This pathway is not found in humans or other eukaryotic organisms, yet is required for the production of threonine, isoleucine, methionine and lysine in most microorganisms. The mechanism of this enzyme has been examined through the structures of two active-site mutants of ASADH from Haemophilus influenzae. Replacement of the enzyme active-site cysteine with serine (C136S) leads to a dramatic loss of catalytic activity caused by the expected decrease in nucleophilicity, but also by a change in the orientation of the serine hydroxyl group relative to the cysteine thiolate. In contrast, in the H277N active-site mutant the introduced amide is oriented in virtually the same position as that of the histidine imidazole ring. However, a shift in the position of the bound reaction intermediate to accommodate this shorter asparagine side chain, coupled with the inability of this introduced amide to serve as a proton acceptor, results in a 100-fold decrease in the catalytic efficiency of H277N relative to the native enzyme. These mutant enzymes have the same overall fold and high structural identity to native ASADH. However, small perturbations in the positioning of essential catalytic groups or reactive intermediates have dramatic effects on catalytic efficiency.
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PMID:Critical catalytic functional groups in the mechanism of aspartate-beta-semialdehyde dehydrogenase. 1538 27

To clarify the relationship between mutations commonly found for penicillin-binding protein 3 (PBP 3) of beta-lactamase-nonproducing ampicillin-resistant (BLNAR) Haemophilus influenzae isolates and beta-lactam resistance, single and multiple amino acid mutations at positions 377, 385, 389, 517, and 526 were introduced into PBP 3 of a beta-lactam-susceptible Rd strain by site-directed mutagenesis. Twelve isogenic recombinant strains were challenged with nine beta-lactam antibiotics. Replacement of the asparagine at position 526 with lysine (N526K) increased the resistance to imipenem eightfold and increased the resistance to various cephalosporins two- to eightfold. Substitution of threonine for serine at position 385 (S385T) and/or substitution of phenylalanine for leucine at position 389 (L389F), in addition to the N526K mutation, led to two- to fourfold additional increases in cephalosporin resistance. An isoleucine-to-methionine substitution at position 377 did not change the antibiotic sensitivity of any of the recombinant strains also carrying other PBP 3 mutations tested. Thirty-six clinical isolates carrying a PBP 3 gene (ftsI) with the S385T, L389F, R517H, and/or N526K mutation were chosen from among 279 clinical isolates collected in Japan, and the isolates were grouped into six classes on the basis of the patterns of the four mutations in PBP 3. Rd recombinants were made with each of the ftsI genes. The levels of resistance to beta-lactams varied between recombinants of different classes but were comparable for those of the same class. The levels of resistance to cephalosporins of these recombinants were similar to those of the parent clinical isolates, while those to ampicillin and carbapenems were lower. These results indicate that resistance to beta-lactams, at least to cephalosporins, depends in large part on the PBP 3 mutations R517H, N526K, S385T, and L389F.
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PMID:Genetic approach to study the relationship between penicillin-binding protein 3 mutations and Haemophilus influenzae beta-lactam resistance by using site-directed mutagenesis and gene recombinants. 1598 Mar 57

Transforming growth factor-beta (TGF-beta) family members are multifunctional growth factors involved in regulating diverse biological processes. Despite the critical role for TGF-beta in regulating cell proliferation, differentiation, migration and development, its role in regulating NF-kappaB-dependent inflammatory response still remains unclear. Here, we show that TGF-beta1 induces acetylation of NF-kappaB p65 subunit to synergistically enhance bacterium nontypeable Haemophilus influenzae-induced NF-kappaB activation and inflammatory response in vitro and in vivo. The TGF-beta1-induced acetylation of p65 is mediated via a Smad3/4-PKA-p300-dependent signaling pathway. Acetylation of p65 at lysine 221 by TGF-beta1 is critical for synergistic enhancement of bacteria-induced DNA-binding activity, NF-kappaB activation, NF-kappaB-dependent transcription of TNF-alpha and IL-1beta and interstitial polymorphonuclear neutrophil infiltration in vitro and in vivo. These studies provide new insights into the novel regulation of NF-kappaB by TGF-beta signaling.
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PMID:TGF-beta induces p65 acetylation to enhance bacteria-induced NF-kappaB activation. 1726 54

Diaminopimelate (DAP) epimerase catalyzes the stereoinversion of ll-DAP to meso-DAP, a precursor of l-lysine and an essential component of the bacterial peptidoglycan. This function is vital to bacteria and the enzyme therefore represents an attractive target for the design of novel anti-bacterials. DAP epimerase belongs to the group of PLP-independent amino acid racemases that function through a rather unusual mechanism involving two cysteines acting in concert as a base (thiolate) and an acid (thiol). We have solved the crystal structures of the apo-forms of DAP epimerase mutants (C73S and C217S) from Haemophilus influenzae at 2.3A and 2.2A resolution, respectively. These structures provide a snapshot of the enzyme in the first step of the catalytic cycle. Comparisons with the structures of the inhibitor-bound form reveal that the enzyme adopts an 'open conformation' in the absence of substrates or inhibitors with the two active site cysteines existing as a thiol-thiolate pair. Substrate binding to the C-terminal domain triggers the closure of the N-terminal domain coupled with tight encapsulation of the ligand, stabilization of the conformation of an active site loop containing Cys73 and expulsion of water molecules with concomitant desolvation of the thiolate base. This structural rearrangement is critical for catalysis.
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PMID:Dynamics of catalysis revealed from the crystal structures of mutants of diaminopimelate epimerase. 1788 30

Diaminopimelate (DAP) epimerase is a key enzyme for the biosynthesis of lysine in plants. Lysine is an essential dietary nutrient for mammals. In both plants and bacteria, DAP epimerase catalyzes the interconversion of LL-DAP and DL(meso)-DAP. The absence of a mammalian homolog makes DAP epimerase a promising target for the design of novel herbicides and antibacterials. This enzyme requires no cofactors and it functions through an unusual mechanism involving two cysteine residues acting in concert and alternating as a base (thiolate) and as an acid (thiol). The present study reports the crystal structures of two enzyme-inhibitor complexes of DAP epimerase from Arabidopsis thaliana with different isomers of the irreversible inhibitor and substrate mimic, 2-(4-amino-4-carboxybutyl)-aziridine-2-carboxylate, at 1.95 and 2.3 A resolution. These structures provide the first atomic details of a plant amino acid racemase. Structural analysis reveals that ligand binding to a cleft between the two domains of the enzyme is accompanied by domain closure with two strictly conserved cysteine residues, Cys99 and Cys254, optimally positioned to perform acid/base catalysis via a carbanion stabilization mechanism on the stereogenic alpha-carbon atom of the amino acid. Stereochemical control in catalysis is achieved by means of a highly symmetric catalytic site that can accommodate both the L and D stereogenic centers of DAP at the proximal site, whereas specific interactions at the distal site require only the L configuration. Structural comparisons of the plant enzyme with its bacterial counterpart from Haemophilus influenzae reveal significant conservation of amino acid residues around the active site that extends to their three-dimensional structures and catalytic mechanism.
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PMID:Crystal structure of diaminopimelate epimerase from Arabidopsis thaliana, an amino acid racemase critical for L-lysine biosynthesis. 1901 71

The meso (or D,L) isomer of diaminopimelic acid (DAP), a precursor of L-lysine, is a key component of the pentapeptide linker in bacterial peptidoglycan. While the peptidoglycan incorporated in the highly complex cell wall of the pathogen Mycobacterium tuberculosis structurally resembles that of Escherichia coli, it is unique in that it can contain penicillin-resistant meso-DAP-->meso-DAP linkages. The interconversion of L,L-DAP and meso-DAP is catalysed by the DAP epimerase DapF, a gene product that is essential in M. tuberculosis. Here, the crystal structure of the ligand-free form of M. tuberculosis DapF (MtDapF) refined to a resolution of 2.6 A is reported. MtDapF shows small if distinct deviations in secondary structure from the two-domain alpha/beta-fold of the known structures of Haemophilus influenzae DapF and Bacillus anthracis DapF, which are in line with its low sequence identity (<or=27%) to the former. Modelling the present structure onto that of L,L-aziridino-DAP-bound H. influenzae DapF illustrates that a rigid-body movement of domain II and a rearrangement of the B4-A2 loop (residues 80-90) of domain I are likely to accompany the transition from the present inactive form to a catalytically competent enzyme. Despite a highly conserved active-site architecture, the model indicates that stabilization of the DAP backbone occurs in MtDapF through a tyrosine residue that is specific to mycobacterial DAP epimerases.
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PMID:Structure of the diaminopimelate epimerase DapF from Mycobacterium tuberculosis. 1930 21


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