Broderick Dychinco scite author profile

The ability of bacteria to acquire and disseminate heterologous genes has been a major factor in the development of multiple drug resistance. A gene, intI4, was identified that encodes a previously unknown integrase that is associated with a "gene-VCR" organization (VCRs are Vibrio cholerae repeated sequences), similar to that of the well-characterized antibiotic resistance integrons. The similarity was confirmed by IntI1-mediated recombination of a gene-VCR cassette into a class 1 integron. VCR cassettes are found in a number of Vibrio species including a strain of V. metschnikovii isolated in 1888, suggesting that this mechanism of heterologous gene acquisition predated the antibiotic era.

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The evolutionary history of chromosomal super-integrons provides an ancestry for multiresistant integrons

Rowe‐Magnus

Guérout

Ploncard

et al. 2001

Proc. Natl. Acad. Sci. U.S.A.

218

185

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Integrons are genetic elements that acquire and exchange exogenous DNA, known as gene cassettes, by a site-specific recombination mechanism. Characterized gene cassettes consist of a target recombination sequence (attC site) usually associated with a single open reading frame coding for an antibiotic resistance determinant. The affiliation of multiresistant integrons (MRIs), which contain various combinations of antibiotic resistance gene cassettes, with transferable elements underlies the rapid evolution of multidrug resistance among diverse Gram-negative bacteria. Yet the origin of MRIs remains unknown. Recently, a chromosomal super-integron (SI) harboring hundreds of cassettes was identified in the Vibrio cholerae genome. Here, we demonstrate that the activity of its associated integrase is identical to that of the MRI integrase, IntI1. We have also identified equivalent integron superstructures in nine distinct genera throughout the ␥-proteobacterial radiation. Phylogenetic analysis revealed that the evolutionary history of the system paralleled that of the radiation, indicating that integrons are ancient structures. The attC sites of the 63 antibiotic-resistance gene cassettes identified thus far in MRIs are highly variable. Strikingly, one-fifth of these were virtually identical to the highly related yet species-specific attC sites of the SIs described here. Furthermore, antimicrobial resistance homologues were identified among the thousands of genes entrapped by these SIs. Because the gene cassettes of SIs are substrates for MRIs, these data identify SIs as the source of contemporary MRIs and their cassettes. However, our demonstration of the metabolic functions, beyond antibiotic resistance and virulence, of three distinct SI gene cassettes indicates that integrons function as a general genecapture system for bacterial innovation. T he impact of lateral gene transfer on bacterial evolution is underscored by the realization that foreign DNA can represent up to one-fifth of a given bacterial genome (1). Perhaps the most striking embodiment of its affect on microbial adaptation has been the rapid and widespread emergence of similar antibiotic-resistance profiles among phylogenetically diverse Gram-negative clinical and environmental isolates over the last half-century (2). The localization of antibiotic-resistance determinants to mobile entities such as plasmids and transposons readily explained this phenomenon (3-6). Closer examination revealed that in many cases a new type of genetic element, termed an integron, harbored the resistance determinants. Integrons are natural cloning and expression systems that incorporate open reading frames and convert them to functional genes (for review see refs. 7 and 8). The integron platform codes for an integrase (intI) that mediates recombination between a proximal primary recombination site (attI) and a secondary target called an attC site [or 59-base element (59be)]. The attC site is normally found associated with a single open reading frame (ORF), and the attC-ORF ...

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Antibiotic Resistance in the ECOR Collection: Integrons and Identification of a Novel aad Gene

Mazel

Dychinco

Webb

et al. 2000

Antimicrob Agents Chemother

305

173

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The 72 Escherichia coli strains of the ECOR collection were examined for resistance to 10 different antimicrobial agents including ampicillin, tetracycline, mercury, trimethoprim, and sulfonamides. Eighteen strains were resistant to at least one of the antibiotics tested, and nearly 20% (14 of 72) were resistant to two or more. Several of the resistance determinants were shown to be carried on conjugative elements. The collection was screened for the presence of the three classes of integrons and for the sul1 gene, which is generally associated with class 1 integrons. The four strains found to carry a class 1 integron also had Tn21-encoded mercury resistance. One of the integrons encoded a novel streptomycin resistance gene, aadA7, with an attC site (or 59-base element) nearly identical to the attC site associated with the qacF gene cassette found in In40 (M. -

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