Structure and mobilization of an ampicillin and gentamicin resistance determinant

IS26 and the IS26 family: versatile resistance gene movers and genome reorganizers

SUMMARYIn Gram-negative bacteria, the insertion sequence IS26 is highly active in disseminating antibiotic resistance genes. IS26 can recruit a gene or group of genes into the mobile gene pool and support their continued dissemination to new locations by creating pseudo-compound transposons (PCTs) that can be further mobilized by the insertion sequence (IS). IS26 can also enhance expression of adjacent potential resistance genes. IS26 encodes a DDE transposase but has unique properties. It forms cointegrates between two separate DNA molecules using two mechanisms. The well-known copy-in (replicative) route generates an additional IS copy and duplicates the target site. The recently discovered and more efficient and targeted conservative mechanism requires an IS in both participating molecules and does not generate any new sequence. The unit of movement for PCTs, known as a translocatable unit or TU, includes only one IS26. TU formed by homologous recombination between the bounding IS26s can be reincorporated via either cointegration route. However, the targeted conservative reaction is key to generation of arrays of overlapping PCTs seen in resistant pathogens. Using the copy-in route, IS26 can also act on a site in the same DNA molecule, either inverting adjacent DNA or generating an adjacent deletion plus a circular molecule carrying the DNA segment lost and an IS copy. If reincorporated, these circular molecules create a new PCT. IS26 is the best characterized IS in the IS26 family, which includes IS257/IS431, ISSau10, IS1216, IS1006, and IS1008 that are also implicated in spreading resistance genes in Gram-positive and Gram-negative pathogens.

On-Farm Anaerobic Digestion of Dairy Manure Reduces the Abundance of Antibiotic Resistance-Associated Gene Targets and the Potential for Plasmid Transfer

The present study investigated the impact of on-farm anaerobic digestion on the abundance of enteric bacteria, antibiotic resistance-associated gene targets, and the horizontal transfer potential of extended-spectrum β-lactamase (ESBL) genes. Samples of raw and digested manure were obtained from six commercial dairy farms in Ontario, Canada. Digestion significantly abated populations of viable coliforms in all six farms. Conjugative transfer of plasmids carrying β-lactamase genes from manure bacteria enriched overnight with buffered peptone containing 4 mg/liter cefotaxime into a β-lactam-sensitive green fluorescent protein (GFP)-labeled Escherichia coli recipient strain was evaluated in patch matings. Digestion significantly decreased the frequency of the horizontal transfer of ESBL genes. Twenty-five transconjugants were sequenced, revealing six distinct plasmids, ranging in size from 40 to 180 kb. A variety of ESBL genes were identified: bla_CTX-M-1, bla_CTX-M-14, bla_CTX-M-15, bla_CTX-M-27, bla_CTX-M-55, and bla_PER-1. bla_CTX-M-15 was the most prevalent ESBL gene detected on plasmids harbored by transconjugants. Various mobile genetic elements were found located proximal to resistance genes. Ten gene targets, including sul1, str(A), str(B), erm(B), erm(F), intI1, aadA, incW, bla_PSE, and bla_OXA-20, were quantified by quantitative PCR on a subset of 18 raw and 18 digested samples. Most targets were significantly more abundant in raw manure; however, erm(B) and erm(F) targets were more abundant in digested samples. Overall, on-farm digestion of dairy manure abated coliform bacteria, a number of antibiotic resistance-associated gene targets, and the potential for in vitro conjugation of plasmids conferring resistance to extended-spectrum β-lactams and other classes of antibiotics into E. coli CV601. IMPORTANCE Using livestock manure for fertilization can entrain antibiotic-resistant bacteria into soil. Manure on some dairy farms is anaerobically digested before being land applied. Recommending the widespread implementation of the practice should be founded on understanding the impact of this treatment on various endpoints of human health concern. Although lab-scale anaerobic treatments have shown potential for reducing the abundance of antibiotic resistance genes, there are very few data from commercial farms. Anaerobic digestion of manure on six dairy farms efficiently abated coliform bacteria, E. coli, and a majority of antibiotic resistance-associated gene targets. In addition, the conjugation potential of plasmids carrying ESBL genes into introduced E. coli strain CV601 was reduced. Overall, anaerobic digestion abated coliform bacteria, the genes that they carry, and the potential for ESBL-carrying plasmid transfer.

The IS6 family, a clinically important group of insertion sequences including IS26

The IS6 family of bacterial and archaeal insertion sequences, first identified in the early 1980s, has proved to be instrumental in the rearrangement and spread of multiple antibiotic resistance. Two IS, IS26 (found in many enterobacterial clinical isolates as components of both chromosome and plasmids) and IS257 (identified in the plasmids and chromosomes of gram-positive bacteria), have received particular attention for their clinical impact. Although few biochemical data are available concerning the transposition mechanism of these elements, genetic studies have provided some interesting observations suggesting that members of the family might transpose using an unexpected mechanism. In this review, we present an overview of the family, the distribution and phylogenetic relationships of its members, their impact on their host genomes and analyse available data concerning the particular transposition pathways they may use. We also provide a mechanistic model that explains the recent observations on one of the IS6 family transposition pathways: targeted cointegrate formation between replicons.

Bacterial genome instability

Bacterial genomes are remarkably stable from one generation to the next but are plastic on an evolutionary time scale, substantially shaped by horizontal gene transfer, genome rearrangement, and the activities of mobile DNA elements. This implies the existence of a delicate balance between the maintenance of genome stability and the tolerance of genome instability. In this review, we describe the specialized genetic elements and the endogenous processes that contribute to genome instability. We then discuss the consequences of genome instability at the physiological level, where cells have harnessed instability to mediate phase and antigenic variation, and at the evolutionary level, where horizontal gene transfer has played an important role. Indeed, this ability to share DNA sequences has played a major part in the evolution of life on Earth. The evolutionary plasticity of bacterial genomes, coupled with the vast numbers of bacteria on the planet, substantially limits our ability to control disease.

Characterization of the highly variable region surrounding the blaCTX-M-9 gene in non-related Escherichia coli from Barcelona

OBJECTIVES

The dispersion of a clone, a plasmid or a mobile element carrying the bla(CTX-M-9) gene was evaluated in 30 Escherichia coli strains isolated in Barcelona between 1996 and 1999. The presence of the previously described orf513-bearing class 1 integron, In60, carrying the bla(CTX-M-9) gene, was also studied.

METHODS

The clonality was analysed by pulsed-field gel electrophoresis. Plasmid analysis was performed by S1 digestion and hybridization with the CTX-M-9 probe. PCR mapping using specific designed primers was used to study the presence of In60 and In60-like structures.

RESULTS

The clonality between the 30 strains was minor. The size of bla(CTX-M-9) carrying plasmids ranged between approximately 80 and 430 kb. One strain produced only a chromosome-encoded CTX-M-9 beta-lactamase. Thirty-six per cent of the strains showed differences with respect to the In60 structure due to an insertion or deletion events.

CONCLUSIONS

These findings suggest that the bla(CTX-M-9) gene may be carried by a mobile element that disperses it between plasmids. The fast dispersion of the CTX-M-9 enzyme could therefore be due to both diffusion of plasmids and mobile elements.

Cloning and sequence analysis of blaBIL-1, a plasmid-mediated class C beta-lactamase gene in Escherichia coli BS

The extended-spectrum, plasmid-borne beta-lactamase gene blaBIL-1, which was discovered in Escherichia coli, has been cloned. Unusually for a plasmid-borne beta-lactamase, blaBIL-1 encodes a novel class C enzyme and appears to have originated from the chromosomal ampC gene of Citrobacter freundii.

Molecular epidemiology of two genes encoding 3-N-aminoglycoside acetyltransferases AAC(3)I and AAC(3)II among gram-negative bacteria from a Spanish hospital

The molecular epidemiology of the aacC1 and aacC2 genes, encoding 3-N-aminoglycoside acetyltransferases AAC(3)I and AAC(3)II, respectively, was studied by DNA-DNA hybridization. The sample included 315 gentamicin-resistant Gram-negative bacilli collected over a six-month period from patients attending a Spanish Hospital. The aminoglycoside resistance phenotype of these strains was also determined. The aacC1 probe hybridized with 39 strains, the aacC2 probe with 146 strains and both probes hybridized with 26 strains. The aacC1 gene was most frequently detected in Pseudomonas aeruginosa whereas the aacC2 gene was most frequently detected in enterobacteria and Acinetobacter spp. Strains harbouring aacC genes were isolated from both in- and outpatients with different infectious diseases, mainly urinary tract infections. As inferred from the results of Southern hybridization, both genes showed a wide horizontal dispersion among plasmids and bacteria.

Molecular cloning and nucleotide sequencing of a novel aminoglycoside 6'-N-acetyltransferase gene from an R-plasmid of Salmonella typhimurium S24 isolated in Taiwan

A conjugative aminoglycoside resistance plasmid pST2 has been isolated from Escherichia coli K-12 14R525, which was mated with a clinical isolate of Salmonella typhimurium S24. A novel resistance gene of aminoglycoside 6'-N-acetyltransferase[AAC(6')] was cloned from plasmid pST2 on a 1,393 kilobase (kb) of SphI-SalI fragment into vector pACYC184 and pUC18. This novel AAC(6') gene in plasmid pST2 acetylated kanamycin, amikacin, dibekacin, tobramycin, gentamicin, netilmicin, and sisomicin. The complete nucleotide sequence of the novel AAC(6') gene and its neighboring sequences were also determined. Minicell experiments detected only one protein of 24.7 kilodaltons (kDa) translated from an open reading frame of the 618 base pairs (bp) gene.

Direct involvement of IS26 in an antibiotic resistance operon

The plasmid pBWH77, originally found in an isolate of Klebsiella pneumoniae, harbors a new antibiotic resistance operon containing two resistance genes transcribed from an IS26-hybrid promoter, as shown by nucleotide sequencing, mRNA mapping, and the effect of inserting a transcription terminator within the promoter-proximal gene. The nucleotide sequence of this region revealed that the operon (IAB) is made up of three sections that are closely related to previously described genetic elements. The -35 region of the promoter, together with the adjacent sequence, is identical to sequences of the IS26 element. One of the resistance genes, aphA7, which is located next to the hybrid promoter, confers assistance to neomycin and structurally related aminoglycosides. This aphA7 gene is highly homologous to aphA1 of Tn903, with five nucleotide differences. The second gene, blaS2A, encodes an evolved SHV-type beta-lactamase with a pI of 7.6 that confers resistance to the broad-spectrum cephalosporins cefotaxime and ceftizoxime. The deduced amino acid sequence of SHV-2A shows that amino acid 238 is a serine, a residue reported to confer resistance to cefotaxime. We discuss how the operon may have evolved by a combination of insertion sequence-mediated genetic rearrangements and acquisitive evolution. Using phylogenetic parsimony, we show that aphA7 in the IAB operon evolved from an ancestral form similar to aphA1 in Tn903 and that blaS2A evolved from an ancestral form similar to blaS1.

Nucleotide sequence of the aacC2 gene, a gentamicin resistance determinant involved in a hospital epidemic of multiply resistant members of the family Enterobacteriaceae

A gentamicin resistance determinant of a conjugative plasmid from Enterobacter cloacae was cloned on a 3.2-kilobase fragment in the PstI site of pBR322. Substrate profiles for eight aminoglycosides at three concentrations showed that the resistance was due to aminoglycoside-(3)-N-acetyltransferase isoenzyme II. Insertion mapping by the gamma-delta transposon revealed that the size of the gene was approximately 1 kilobase. Nucleotide sequencing of the aacC2 gene identified an open reading frame of 858 base pairs, preceded by a promoter and a ribosome-binding site. From these data the molecular mass of the protein was calculated to be 30.6 kilodaltons. A comparison of the nucleotide sequence of the aacC2 gene with those published for the aacC3 and aacC4 genes showed complete homology of the aacC2 gene and the presumed aacC3 gene. An internal restriction fragment of the gene used as a probe in colony hybridization demonstrated the presence of the aacC2 gene in 86% of 86 multiply resistant isolates of the family Enterobacteriaceae obtained during an 18-month hospital epidemic. This corroborates our earlier data on the enzyme identification by the susceptibility profiling method.

Plasmid-mediated beta-lactamases among aminoglycoside resistant gram-negative bacilli

Plasmid-mediated beta-lactamases were characterized by DNA hybridization in 371 aminoglycoside resistant gram-negative bacilli with known aminoglycoside resistance mechanism. Positive hybridization was detected in 50% to a TEM-1 probe, in 2% to a SHV-1 probe, and in 3% to both probes simultaneously. No hybridization was obtained to OXA-1, OXA-2, PSE-1/PSE-4/CARB-3 or PSE-2 beta-lactamase probes. TEM-1 beta-lactamase occurred simultaneously in 82% of strains showing the AAC(3)-V type of aminoglycoside resistance mechanism. Using isoelectric focusing as a control method, we found potentially plasmid-encoded beta-lactamases, other than TEM-1 and SHV-1, at various pIs in 13% of 288 randomly selected strains. The pIs of these strains or strains showing positive hybridizations did not fit to pIs of recently characterized plasmid-mediated enzymes against third-generation cephalosporins (e.g. CTX-1). In addition, the strains did not show resistance to cefotaxime or ceftazidime. According to the in vitro susceptibility data ceftazidime and cefotaxime were active against most of the aminoglycoside resistant strains studied. In contrast, the activity of piperacillin was much lower than that of the cephalosporins tested.

Construction of a probe for the aminoglycoside 3-V-acetyltransferase gene and detection of the gene among endemic clinical isolates

A recent surveillance study at Vanderbilt University Medical Center indicated that 8.5% of the gram-negative bacilli isolated were resistant to gentamicin. To determine what proportion of current gentamicin-resistant isolates elaborated aminoglycoside 3-V-acetyltransferase [AAC(3)-V], a probe for this gene was constructed from a 975-base-pair PstI-SalI fragment of the nonconjugative R plasmid pCER954b. This plasmid was first isolated at Vanderbilt University Medical Center from epidemic strains of Serratia marcescens. Nineteen isolates determined to produce AAC(3)-V by MIC profile all reacted with the probe. The probe did not hybridize with DNA from organisms producing 10 other aminoglycoside-modifying enzyme types. With this probe, 30 (36%) of 84 gentamicin-resistant, gram-negative bacilli elaborated AAC(3)-V. Of these 30 isolates, 25 contained a conjugative plasmid that transferred gentamicin resistance. In contrast to other medical centers, at Vanderbilt a sizable number of gentamicin-resistant, gram-negative bacilli produced AAC(3)-V. This resistance determinant, initially identified in an epidemic Serratia strain, has persisted and become incorporated into currently isolated endemic strains of gram-negative bacilli.