Antibacterial drugs are one of the most important therapeutic agents of bacterial infections but multidrug resistant Escherichia coli (MDREC) is an increasing problem worldwide. Major resistance mechanism of MDREC is horizontal gene transfer of R plasmids harboring integrons, which the integron integrase (IntI) catalyzes gene cassette insertion and excision through site specific recombination. In this study, resistance profiles of integron harboring E. coli isolated in Korea and the genetic environments of integron gene cassettes were analyzed by PCR and direct sequencing to clarify the mechanisms of spread of integron harboring E. coli. Resistance rates of integron harboring E. coli, including β-lactams, aminoglycosides, and fluoroquinolones and MDR frequencies were significantly higher than that of E. coli without integron (p < 0.01). Majority (80%) of integron harboring E. coli showed resistance transfer by conjugation. Most (80%) of E. coli had dfrA17-aadA5 cassette array and PcH1 hybrid promoter; 16.7% of E. coli had dfrA12-orfF-aadA2 cassette array and PcW promoter. The higher prevalence of weak Pc variants among most (96.7%) of integron harboring MDREC suggests that a flexible cassette array is more important than enhanced expression. All the integrons had LexA binding motif suggests that SOS responses control the expression of these integrons. In conclusion, the genetic bases of integrons were diverse, and the spread and the expression of prevalent gene cassette arrays may be deeply related with strengths of Pc promoters in integrons. These informations will provide important knowledge to control the increase of integron harboring MDREC.
Aminoglycosides ; Bacterial Infections ; Escherichia coli ; Escherichia ; Fluoroquinolones ; Gene Transfer, Horizontal ; Integrases ; Integrons ; Korea ; Polymerase Chain Reaction ; Prevalence ; R Factors ; Recombination, Genetic ; SOS Response (Genetics)

PURPOSE: 7-Bromomethylbenz[alpha]anthracene is a known mutagen and carcinogen. The mutagenic potency of its two major DNA adducts, i.e., N2-(benz[alpha]anthracen-7-ylmethyl)-2'-deoxyguanosine (b[alpha]a2G) and N6-(benz[alpha]anthracen-7-ylmethyl)-2'-deoxyadenosine (b[alpha]a6A), as well as the simpler benzylated analogs, N2-benzyl-2'-deoxyguanosine (bn2G) and N6-benzyl-2'-deoxyadenosine (bn6A), were determined in E. coli. MATERIALS AND METHODS: Double-stranded and gapped plasmid vectors were used to determine the mutagenicity of b[alpha]a2G, b[alpha]a6A, bn2G and bn6A in E. coli. The four, suitably protected, bulky exocyclic amino-substituted adducts were incorporated into 16-base oligodeoxyribonucleotides, in place of normal guanine or adenine residues, which form part of the ATG initiation codon for the lacZ' alpha-complementation gene. The site-specifically modified oligodeoxyribonucleotides were then incorporated into double-stranded plasmids, which contained uracil residues in the complementary strand in the vicinity of the initiation codon. The uracil residues lead to the creation of a gap in the complementary strand due to the actions of E. coli uracil-DNA glycosylase and AP endonuclease. Following the transfection of these plasmid vectors into E. coli strain GP102, a lacZ alpha complementing version of the parent strain AB1157, their propensity to induce mutation was investigated. RESULTS: The percentages of mutant colonies produced by the four modified nucleosides, in both the double-stranded and gapped plasmid vectors, were not significantly different from those produced by the unmodified plasmids. The mutagenicities of the b[alpha]a2G and b[alpha]a6A were extremely low, and a totally unexpected result, whereas, those of the bn2G and bn6A were undetectable. CONCLUSION: In this E. coli site-specific mutagenesis system, these bulky aralkylated adducts exhibited no significant mutagenicities, either with or without SOS induction.
Adenine* ; Codon, Initiator ; Complement System Proteins ; DNA Adducts ; DNA-(Apurinic or Apyrimidinic Site) Lyase ; Escherichia coli* ; Escherichia* ; Guanine* ; Humans ; Mutagenesis ; Mutagenesis, Site-Directed* ; Nucleosides ; Oligodeoxyribonucleotides ; Parents ; Plasmids* ; SOS Response (Genetics) ; Transfection ; Uracil ; Uracil-DNA Glycosidase

The fluoroquinolones are the most widely used broad-spectrum antibiotics, accounting for 18% of global antibacterial market share. They can kill bacteria rapidly with variety of derivatives available. Different quinolones vary significantly in rate and spectrum of killing, oxygen requirement for metabolism and reliance upon protein synthesis. Further understanding the sophisticated mechanisms of action of this important antibiotic family based on the molecular genetic response of bacteria can facilitate the discovery of better quinolone derivatives. Factors such as SOS response, bacterial toxin-antitoxin system, programmed death, chromosome fragmentation and reactive oxygen have been implicated in the action to some extent. "Two steps characteristic" of quinolones killing is also emphasized, which might inspire future better quinolones modification.
Anti-Bacterial Agents ; pharmacology ; Apoptosis ; drug effects ; Bacteria ; drug effects ; enzymology ; genetics ; Chromosomes, Bacterial ; drug effects ; DNA Cleavage ; drug effects ; DNA Gyrase ; drug effects ; DNA Replication ; drug effects ; DNA Topoisomerases ; drug effects ; Fluoroquinolones ; pharmacology ; Quinolones ; pharmacology ; Reactive Oxygen Species ; SOS Response (Genetics) ; drug effects