Your search keyword '"Hakansson, Kristina"' showing total 2 results

1. Polymyxin B resistance in El Tor Vibrio cholerae requires lipid acylation catalyzed by Msb

Author

Matson, Jyl S., Yoo, Hyun Ju, Hakansson, Kristina, and DiRita, Victor J.

Subjects

Polymyxin B -- Physiological aspects, Polymyxin B -- Genetic aspects, Acylation -- Research, Vibrio cholerae -- Physiological aspects, Vibrio cholerae -- Genetic aspects, Drug resistance in microorganisms -- Research, Biological sciences

Abstract

Antimicrobial peptides are critical for innate antibacterial defense. Both Gram-negative and Gram-positive microbes have mechanisms to alter their surfaces and resist killing by antimicrobial peptides. In Vibrio cholerae, two natural epidemic biotypes, classical and El Tor, exhibit distinct phenotypes with respect to sensitivity to the peptide antibiotic polymyxin B: classical strains are sensitive and El Tor strains are relatively resistant. We carried out mutant screens of both biotypes, aiming to identify classical V. cholerae mutants resistant to polymyxin B and El Tor V. cholerae mutants sensitive to polymyxin B. Insertions in a gene annotated msbB (encoding a predicted lipid A secondary acyltransferase) answered both screens, implicating its activity in antimicrobial peptide resistance of V. cholerae. Analysis of a defined mutation in the El Tor biotype demonstrated that msbB is required for resistance to all antimicrobial peptides tested. Mutation of msbB in a classical strain resulted in reduced resistance to several antimicrobial peptides but in no significant change in resistance to polymyxin B. msbB mutants of both biotypes showed decreased colonization of infant mice, with a more pronounced defect observed for the El Tor mutant. Mass spectrometry analysis showed that lipid A of the msbB mutant for both biotypes was underacylated compared to lipid A of the wild-type isolates, confirming that MsbB is a functional acyltransferase in V. cholerae. doi:10.1128/JB.00023-10

Published

2010

2. Biosynthetic analysis of the petrobactin siderophore pathway from Bacillus anthracis

Author

Lee, Jung Yeop, Janes, Brian K., Passalacqua, Karla D., Pfleger, Brian F., Bergman, Nicholas H., Liu, Haichuan, Hakansson, Kristina, Somu, Ravindranadh V., Aldrich, Courtney C., Cendrowski, Stephen, Hanna, Philip C., and Sherman, David H.

Subjects

Biosynthesis -- Research, Bacillus anthracis -- Genetic aspects, Bacillus anthracis -- Research, Gene mutations -- Research, Chromosome deletion -- Research, Biological sciences

Abstract

The asbABCDEF gene cluster from Bacillus anthracis is responsible for biosynthesis of petrobactin, a catecholate siderophore that functions in both iron acquisition and virulence in a murine model of anthrax. We initiated studies to determine the biosynthetic details of petrobactin assembly based on mutational analysis of the ash operon, identification of accumulated intermediates, and addition of exogenous siderophores to asb mutant strains. As a starting point, in-frame deletions of each of the genes in the asb locus (asbABCDEF) were constructed. The individual mutations resulted in complete abrogation of petrobactin biosynthesis when strains were grown on iron-depleted medium. However, in vitro analysis showed that each asb mutant grew to a very limited extent as vegetative cells in iron-depleted medium. In contrast, none of the B. anthracis ash mutant strains were able to outgrow from spores under the same culture conditions. Provision of exogenous petrobactin was able to rescue the growth defect in each asb mutant strain. Taken together, these data provide compelling evidence that AsbA performs the penultimate step in the biosynthesis of petrobactin, involving condensation of 3,4-dihydroxybenzoyl spermidine with citrate to form 3,4-dihydroxybenzoyl spermidinyl citrate. As a final step, the data reveal that AsbB catalyzes condensation of a second molecule of 3,4-dihydroxybenzoyl spermidine with 3,4-dihydroxybenzoyl spermidinyl citrate to form the mature siderophore. This work sets the stage for detailed biochemical studies with this unique acyl carrier protein-dependent, nonribosomal peptide synthetase-independent biosynthetic system.

Published

2007