Academics and managers are confronted with reconciling the social and economic aspects of business-to-business exchanges. In a service context, the authors investigate the relative importance of contractual and relational governance on exchange performance and the influence of the boundary spanner on the implementation of these governance mechanisms and on exchange performance. They test a model of the governance of commercial banking exchanges using interview data with both parties to the exchange (the account manager as the bank's boundary spanner and the business client). Relational governance is the predominant governance mechanism associated with exchange performance. Contractual governance is also positively associated to exchange performance, but to a much lesser extent. The closeness of the account manager to the client company in terms of information gathering is also positively associated to exchange performance. However, this is mediated through both contractual and relational governance mechanisms with relational governance being the stronger mechanism.
A genetic polymorphism at the NAT2 gene locus, encoding for polymorphic N-acetyltransferase (NAT2), segregates individuals into rapid, intermediate or slow acetylator phenotypes. Both rapid and slow acetylator phenotypes have been associated with increased incidence of cancer in certain target organs related to arylamine exposure, suggesting a role for acetylation in both the activation and deactivation of arylamine carcinogens. A second gene (NAT1) encodes for a different acetyltransferase isozyme (NAT1) that is not subject to the classical acetylation polymorphism. In order to assess the relative ability of NAT1 and NAT2 to activate and deactivate arylamine carcinogens, we tested the capacity of recombinant human NAT1 and NAT2, expressed in Escherichia coli XA90 strains DMG100 and DMG200 respectively, to catalyze the N-acetylation (deactivation) and O-acetylation (activation) of a variety of carbocyclic and heterocyclic arylamine carcinogens. Both NAT1 and NAT2 catalyzed the N-acetylation of each of the 17 arylamines tested. Rates of N-acetylation by NAT1 and NAT2 were considerably lower for heterocyclic arylamines such as 2-amino-3-methyl-imidazo[4,5-f]quinoline (IQ), particularly those (e.g. IQ) with steric hindrance to the exocyclic amino group. For carbocyclic arylamines such as 4-aminobiphenyl and beta-naphthylamine, the apparent affinity was significantly (P < 0.05) higher for NAT2 than NAT1. NAT1/NAT2 activity ratios and clearance calculations suggest a significant role for the polymorphic NAT2 in the N-acetylation of carbocyclic arylamine carcinogens. Both NAT1 and NAT2 catalyzed acetyl coenzyme A-dependent O-acetylation of N-hydroxy-2-aminofluorene and N-hydroxy-4-aminobiphenyl to yield DNA adducts. NAT1 catalyzed paraoxon-resistant, intramolecular N,O-acetyltransferase-mediated activation of N-hydroxy-2-acetylaminofluorene and N-hydroxy-4-acetylaminobiphenyl at low rates; catalysis by NAT2 was not readily detectable in the presence of paraoxon. In summary these studies strongly suggest that the human acetylation polymorphism influences both the metabolic activation (O-acetylation) and deactivation (N-acetylation) of arylamine carcinogens via polymorphic expression of NAT2. These findings lend mechanistic support for human epidemiological studies suggesting associations between both rapid and slow acetylator phenotype and cancers related to arylamine exposure.
Human polymorphic N-acetyltransferase (NAT2) catalyzes the N-acetylation of arylamine drugs and carcinogens. Human acetylator phenotype is regulated at the NAT2 locus and has been associated with differential risk to certain drug toxicities or cancer. We examined arylamine substrate and acetyl coenzyme A cofactor affinities, and the N-acetyltransferase catalytic activities of the wild-type and 14 different mutant or chimeric human NAT2 alleles expressed in an Escherichia coli JM105 expression system. NAT2 alleles contained nucleic acid substitutions at positions 191(G-->A; Arg64-->Gln), 282(C-->T; silent), 341(T-->C; Ile114-->Thr), 481(C-->T; silent), 590(G-->A; Arg197-->Gln), 803(A-->G; Lys268-->Arg), 857(G-->A; Gly286-->Glu) and various combinations (282/590; 282/803; 282/857; 341/481; 341/803; 341/481/803; 481/803) of the 870 base pair NAT2 coding region. Expression of all 15 NAT2 alleles produced immunoreactive NAT2 protein with N-acetylation activity. NAT2 proteins encoded by alleles with nucleic acid substitutions at positions 191, 341, 590, 282/590, 341/481, 341/803, and 341/481/803 exhibited arylamine N-acetyltransferase maximum velocities significantly (P < 0.001) lower than the wildtype NAT2. Thus, nucleic acid substitutions at positions 191, 341, and 590 either alone or in combination with other silent or conservative amino acid substitutions were sufficient to result in NAT2 proteins with significant reductions in N-acetylation activities. The recombinant NAT2 proteins also showed relative differences in intrinsic stability following incubation at 37 degrees C and 50 degrees C. NAT2 encoded by alleles with nucleotide substitutions at positions 191 and 857 were particularly unstable relative to the wild type.(ABSTRACT TRUNCATED AT 250 WORDS)
The pH-inducible acid tolerance response (ATR) is believed to play a major role in acid adaptation and virulence of Streptococcus mutans. To study this phenomenon in S. mutans JH1005, differential display PCR was used to identify and clone 13 cDNA products that had increased expression in response to pH 5.0 compared to that of pH 7.5-grown cells. One of these products, confirmed to be pH inducible by RNA dot blot and reverse transcription-PCR analyses, had 67% identity to a uvrA-UV repair excinuclease gene in Bacillus subtilis. Further sequence analysis of the uvrA homologue using the S. mutans genome database revealed that the complete gene was encoded in an open reading frame (ORF) of 2,829 bp (944 amino acids; 104.67 kDa). Immediately 3 of uvrA was an ORF encoding a putative aminopeptidase gene (pepP). uvrA knockouts were constructed in S. mutans strains JH1005, NG8, and UA159 using allelic-exchange mutagenesis, replacing the entire gene with an erythromycin resistance cassette. As with uvrA mutants in other bacteria, the S. mutans uvrA mutants were extremely sensitive to UV irradiation. The uvrA mutant of S. mutans JH1005 was also more sensitive than the wild type to growth at pH 5.0, showing a 15% reduction in growth rate and a 14% reduction in final resting culture density. Acid-adapted S. mutans JH1005 uvrA mutants were shown to be more resistant to UV irradiation than was the parent but were unable to survive exposure to a killing pH of 3.0. Moreover, agarose gel electrophoretic analysis of chromosomal DNA isolated from uvrA-deficient cells exposed to low pH demonstrated more DNA damage than that for the wild-type strain. Here we suggest that uvrA and the nucleotide excision repair pathway are involved in the repair of acid-induced DNA damage and are associated with successful adaptation of S. mutans to low pH.The oral bacterium Streptococcus mutans is able to gain a selective advantage over other oral microbes by withstanding extreme fluctuations in plaque pH. In the plaque environment, resident bacteria metabolize dietary carbohydrate, which results in the production of organic acids and a decrease in plaque pH. Telemetric measurements of plaque pH indicate that the pH can drop from 7.0 to values ranging from 4.0 to 3.0 (23). The ability to adapt to moderate pH promotes the survival of S. mutans under lower-pH conditions that would otherwise be lethal (37). This adaptive response in S. mutans is called the acid tolerance response (ATR) (37, 42), and similar mechanisms have been identified in some enteric bacteria (11,12). Acid adaptation in S. mutans requires de novo protein synthesis (37) of up to 36 acid-regulated proteins (19) presumably encoded by acid-inducible genes.Aside from the general features of the cellular response to acid pH, relatively little is known about the function of the numerous proteins encoded by the pH-inducible genes that constitute the S. mutans ATR. The genes for the protein repair chaperone, DnaK (22), and the 54-kDa subunit homologue of the eukaryotic signal recognition pa...
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