Resistance to trimethoprim and sulfonamides

Sulfonamides and trimethoprim have been used for many decades as efficient and inexpensive antibacterial agents for animals and man. Resistance to both has, however, spread extensively and rapidly. This is mainly due to the horizontal spread of resistance genes, expressing drug-insensitive variants...

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Veröffentlicht in:	Veterinary research (Paris) 2001-05, Vol.32 (3-4), p.261-273
1. Verfasser:	Sk ld, Ola
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Sprache:	eng
Schlagworte:	Animal biology Animal genetics Animals Biochemistry, Molecular Biology Cell Behavior Cellular Biology Chromosomes dfr9 gene Drug Resistance, Microbial - genetics Erwinia amylovora Escherichia coli Gene Transfer, Horizontal Genetics Humans Immunology Life Sciences Microbiology and Parasitology Models, Chemical Molecular biology Neurons and Cognition Plasmids Restriction Mapping Santé publique et épidémiologie sul1 gene sul2 gene Sulfonamides - therapeutic use Trimethoprim - therapeutic use Trimethoprim Resistance - genetics
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description	Sulfonamides and trimethoprim have been used for many decades as efficient and inexpensive antibacterial agents for animals and man. Resistance to both has, however, spread extensively and rapidly. This is mainly due to the horizontal spread of resistance genes, expressing drug-insensitive variants of the target enzymes dihydropteroate synthase and dihydrofolate reductase, for sulfonamide and trimethoprim, respectively. Two genes, sul1 and sul2, mediated by transposons and plasmids, and expressing dihydropteroate synthases highly resistant to sulfonamide, have been found. For trimethoprim, almost twenty phylogenetically different resistance genes, expressing druginsensitive dihydrofolate reductases have been characterized. They are efficiently spread as cassettes in integrons, and on transposons and plasmids. One particular gene, dfr9, seems to have originally been selected in the intestine of swine, where it was found in Escherichia coli, on large plasmids in a disabled transposon, Tn5393, originally found in the plant pathogen Erwinia amylovora. There are also many examples of chromosomal resistance to sulfonamides and trimethoprim, with different degrees of complexity, from simple base changes in the target genes to transformational and recombinational exchanges of whole genes or parts of genes, forming mosaic gene patterns. Furthermore, the trade-off, seen in laboratory experiments selecting resistance mutants, showing drug-resistant but also less efficient (increased Kms) target enzymes, seems to be adjusted for by compensatory mutations in clinically isolated drug-resistant pathogens. This means that susceptibility will not return after suspending the use of sulfonamide and trimethoprim.
doi_str_mv	10.1051/vetres:2001123
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There are also many examples of chromosomal resistance to sulfonamides and trimethoprim, with different degrees of complexity, from simple base changes in the target genes to transformational and recombinational exchanges of whole genes or parts of genes, forming mosaic gene patterns. Furthermore, the trade-off, seen in laboratory experiments selecting resistance mutants, showing drug-resistant but also less efficient (increased Kms) target enzymes, seems to be adjusted for by compensatory mutations in clinically isolated drug-resistant pathogens. 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Resistance to both has, however, spread extensively and rapidly. This is mainly due to the horizontal spread of resistance genes, expressing drug-insensitive variants of the target enzymes dihydropteroate synthase and dihydrofolate reductase, for sulfonamide and trimethoprim, respectively. Two genes, sul1 and sul2, mediated by transposons and plasmids, and expressing dihydropteroate synthases highly resistant to sulfonamide, have been found. For trimethoprim, almost twenty phylogenetically different resistance genes, expressing druginsensitive dihydrofolate reductases have been characterized. They are efficiently spread as cassettes in integrons, and on transposons and plasmids. One particular gene, dfr9, seems to have originally been selected in the intestine of swine, where it was found in Escherichia coli, on large plasmids in a disabled transposon, Tn5393, originally found in the plant pathogen Erwinia amylovora. There are also many examples of chromosomal resistance to sulfonamides and trimethoprim, with different degrees of complexity, from simple base changes in the target genes to transformational and recombinational exchanges of whole genes or parts of genes, forming mosaic gene patterns. Furthermore, the trade-off, seen in laboratory experiments selecting resistance mutants, showing drug-resistant but also less efficient (increased Kms) target enzymes, seems to be adjusted for by compensatory mutations in clinically isolated drug-resistant pathogens. 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genetics</topic><topic>Erwinia amylovora</topic><topic>Escherichia coli</topic><topic>Gene Transfer, Horizontal</topic><topic>Genetics</topic><topic>Humans</topic><topic>Immunology</topic><topic>Life Sciences</topic><topic>Microbiology and Parasitology</topic><topic>Models, Chemical</topic><topic>Molecular biology</topic><topic>Neurons and Cognition</topic><topic>Plasmids</topic><topic>Restriction Mapping</topic><topic>Santé publique et épidémiologie</topic><topic>sul1 gene</topic><topic>sul2 gene</topic><topic>Sulfonamides - therapeutic use</topic><topic>Trimethoprim - therapeutic use</topic><topic>Trimethoprim Resistance - genetics</topic><toplevel>peer_reviewed</toplevel><toplevel>online_resources</toplevel><creatorcontrib>Sk ld, Ola</creatorcontrib><collection>Medline</collection><collection>MEDLINE</collection><collection>MEDLINE (Ovid)</collection><collection>MEDLINE</collection><collection>MEDLINE</collection><collection>PubMed</collection><collection>CrossRef</collection><collection>Bacteriology Abstracts (Microbiology B)</collection><collection>Industrial and Applied Microbiology Abstracts (Microbiology A)</collection><collection>Technology Research Database</collection><collection>Environmental Sciences and Pollution Management</collection><collection>Engineering Research Database</collection><collection>Biotechnology and BioEngineering Abstracts</collection><collection>MEDLINE - 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Resistance to both has, however, spread extensively and rapidly. This is mainly due to the horizontal spread of resistance genes, expressing drug-insensitive variants of the target enzymes dihydropteroate synthase and dihydrofolate reductase, for sulfonamide and trimethoprim, respectively. Two genes, sul1 and sul2, mediated by transposons and plasmids, and expressing dihydropteroate synthases highly resistant to sulfonamide, have been found. For trimethoprim, almost twenty phylogenetically different resistance genes, expressing druginsensitive dihydrofolate reductases have been characterized. They are efficiently spread as cassettes in integrons, and on transposons and plasmids. One particular gene, dfr9, seems to have originally been selected in the intestine of swine, where it was found in Escherichia coli, on large plasmids in a disabled transposon, Tn5393, originally found in the plant pathogen Erwinia amylovora. 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subjects	Animal biology Animal genetics Animals Biochemistry, Molecular Biology Cell Behavior Cellular Biology Chromosomes dfr9 gene Drug Resistance, Microbial - genetics Erwinia amylovora Escherichia coli Gene Transfer, Horizontal Genetics Humans Immunology Life Sciences Microbiology and Parasitology Models, Chemical Molecular biology Neurons and Cognition Plasmids Restriction Mapping Santé publique et épidémiologie sul1 gene sul2 gene Sulfonamides - therapeutic use Trimethoprim - therapeutic use Trimethoprim Resistance - genetics
title	Resistance to trimethoprim and sulfonamides
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