Cloning and expression in Enterobacteriaceae of the extended-spectrum β-lactamase gene from a Pseudomonas aeruginosa plasmid

Abstract An extended-spectrum β-lactamase, the gene for which is located on plasmid pMS350 in Pseudomonas aeruginosa strains, hydrolyzes carbapenems and other extended-spectrum β-lactam antibiotics. We cloned the pMS350 β-lactamase gene in an Escherichia coli K-12 strain using the vector plasmid pHSG398, and subcloned it into pMS360, a plasmid with a wide host-range. This resulted in the formation of the recombinant plasmid, pMS363, containing a 4.1-kb DNA insert that includes the extended-spectrum β-lactamase gene. Plasmid pMS363 was introduced into the P. aeruginosa PAO strain or into six species of Enterobacteriaceae, and the specific activities of the β-lactamase and MICs of various β-lactam antibiotics were estimated. The cloned gene was capable of expression in these strains and caused resistance to carbapenem, penem and other β-lactam antibiotics, with the exception of aztreonam.     

The acquisition of clinically relevant amoxicillin resistance in Streptococcus pneumoniae requires ordered horizontal gene transfer of four loci

Understanding how antimicrobial resistance spreads is critical for optimal application of new treatments. In the naturally competent human pathogen Streptococcus pneumoniae, resistance to β-lactam antibiotics is mediated by recombination events in genes encoding the target proteins, resulting in reduced drug binding affinity. However, for the front-line antibiotic amoxicillin, the exact mechanism of resistance still needs to be elucidated. Through successive rounds of transformation with genomic DNA from a clinically resistant isolate, we followed amoxicillin resistance development. Using whole genome sequencing, we showed that multiple recombination events occurred at different loci during one round of transformation. We found examples of non-contiguous recombination, and demonstrated that this could occur either through multiple D-loop formation from one donor DNA molecule, or by the integration of multiple DNA fragments. We also show that the final minimum inhibitory concentration (MIC) differs depending on recipient genome, explained by differences in the extent of recombination at key loci. Finally, through back transformations of mutant alleles and fluorescently labelled penicillin (bocillin-FL) binding assays, we confirm that pbp1a, pbp2b, pbp2x, and murM are the main resistance determinants for amoxicillin resistance, and that the order of allele uptake is important for successful resistance evolution. We conclude that recombination events are complex, and that this complexity contributes to the highly diverse genotypes of amoxicillin-resistant pneumococcal isolates.     

A microtitre plate-based assay for the screening of β-lactams

A.R. QUESADA, A. CAÑEDO, M.A. MORENO AND J.L. FERNÁNDEZ-PUENTES. 1996. A simple, rapid, sensitive and automatizable method for the detection and quantification of bacterial cell wall inhibitors has been developed. The procedure is characterized by the use of a micro-organism hypersensitive to β-lactam antibiotics that contains an inducible cytosolic β-galactosidase; this enzyme is released when the micro-organism cell wall is disrupted by the antibiotic action, and then measured by the use of a chromogenic substrate. The present method allows the detection of β-lactam traces in other non-β-lactam antibiotics, and has been successfully applied in the detection of small amounts of β-lactams in biological fluids such as milk and Actinomycetes fermentation broths. The easy automatization of this method makes it specially suitable for the screening of new antibiotics of natural origin.     

Preparation and application of microarrays for the detection of antibiotic resistance genes in samples isolated from Changchun,China

The emergence of antibiotic-resistant bacteria, especially tetracycline- and β-lactam-resistant bacteria, poses a great threat to human health. The purpose of this study was to develop and apply a suitable gene microarray for the detection of antibiotic resistance genes. We isolated 463 strains of bacteria from a hospital, a veterinary station, an animal nursery, and living environment of Changchun, China. After screening, it was found that 93.9% of these bacteria were resistant to tetracycline, 74.9% to ampicillin, 55.6% to deoxycycline, and 41.7% to ciprofloxacin. For amplification of antibiotic genes, we designed 28 pairs of primers. In addition, 28 hybridization probes for these genes were developed. The DNA microarray analysis was performed at 42°C for 5 h. We were successful in detecting 12 resistance genes by microarray analysis. After detection, we also evaluated the sensitivity of the microarray analysis. The LDL (Lowest Detection Level) of the microarray was 1 × 10⁶ copies/ml of template DNA. It is believed that such microarray-based determination of tetracycline and β-lactam resistance genes can have a potential application in clinical studies in the future.     

The β-lactam-sensitive d,d-carboxypeptidase activity of Pbp4 controls the l,d and d,d transpeptidation pathways in Corynebacterium jeikeium

Corynebacterium jeikeium is an emerging nosocomial pathogen responsible for vascular catheters infections, prosthetic endocarditis and septicemia. The treatment of C. jeikeium infections is complicated by the multiresistance of clinical isolates to antibiotics, in particular to β-lactams, the most broadly used class of antibiotics. To gain insight into the mechanism of β-lactam resistance, we have determined the structure of the peptidoglycan and shown that C. jeikeium has the dual capacity to catalyse formation of cross-links generated by transpeptidases of the d , d and l , d specificities. Two ampicillin-insensitive cross-linking enzymes were identified, Ldt_Cjk1, a member of the active site cysteine l , d -transpeptidase family, and Pbp2c, a low-affinity class B penicillin-binding protein (PBP). In the absence of β-lactam, the PBPs and the l , d -transpeptidase contributed to the formation of 62% and 38% of the cross-links respectively. Although Ldt_Cjk1 and Pbp2C were not inhibited by ampicillin, the participation of the l , d -transpeptidase to peptidoglycan cross-linking decreased in the presence of the drug. The specificity of Ldt_Cjk1 for acyl donors containing a tetrapeptide stem accounts for this effect of ampicillin since the essential substrate of Ldt_Cjk1 was produced by an ampicillin-sensitive d , d -carboxypeptidase (Pbp4_Cjk). Acquisition and mutational alterations of pbp2C accounted for high-level β-lactam resistance in C. jeikeium .     

The biosynthetic genes for clavulanic acid and cephamycin production occur as a 'super-cluster' in three Streptomyces

Abstract The cosmid cloning vector pHC79 has been used to clone fragments of chromosomal DNA from the Streptomyces: S. clavuligerus, S. jumonjinensis and S. katsurahamanus . These strains all produce both the β-lactam antibiotic, cephamycin and the β-lactamase inhibitor, clavulanic acid. Although structurally related these two β-lactams are known to be derived from different biosynthetic precursors. Hybridisation studies and restriction mapping have shown that the gene clusters encoding the two biosynthetic pathways are chromosomally adjacent in these strains, thus creating a 'super-cluster' of genes involved in both the production and enhancement of activity of a β-lactam antibiotic.     

A two-component signal-transducing system is involved in competence and penicillin susceptibility in laboratory mutants of Streptococcus pneumoniae

Penicillin resistance in Streptococcus pneumoniae has been attributed so far to the production of penicillin-binding protein (PBP) variants with decreased affinities for β-lactam antibiotics. Cefotaxime-resistant laboratory mutants, selected after several steps on increasing concentrations of this β-lactam, become deficient in transformation as well. A DNA fragment conferring both cefotaxime resistance and transformation deficiency was isolated and cloned from the mutant C306. The cefotaxime resistance associated with this resistance determinant was not accompanied with apparent changes in PBP properties, and it mapped on the chromosome distinct from the known resistance determinants, genes encoding PBP2x, PBP1a or PBP2b. Determination of a 2265 bp DNA sequence of the resistance determinant revealed two open reading frames, claR and claH, whose deduced amino acid sequence identified the corresponding proteins as the response regulator and histidine kinase receptor, respectively (members of the two families of bacterial signal-transducing proteins). Two hydrophobic peptide regions divided the histidine kinase ClaH into two putative domains: an N-terminal extracelluiar sensor part, and an intracelluiar C-terminal domain with the conserved His-226 residue, the presumed phosphorylation site. The single point mutations responsible for cefotaxime-resistance and transformation deficiency of C306 and of another two independently isolated cefotaxime-resistant mutants were each located in the C-terminal half of ClaH. A small extracellular protein, the competence factor, is required for induction of competence. Neither C306 nor the transformants obtained with the mutated claH gene produced competence factor, and exogenous competence factor could not complement the transformation deficiency, indicating that the signal-transducing system cia is involved in early steps of competence regulation.     

Cloning of a beta-lactam resistance determinant of Enterobacter cloacae affecting outer membrane proteins of Enterobacteriaceae

Abstract In this paper we describe the cloning of a restriction fragment of Enterobacter cloacae chromosomal DNA that causes β-lactam resistance in both Escherichia coli HB101 and the parental strain E. cloacae 2249-1.
The increase in minimum inhibitory concentration (MIC) of the β-lactam antibiotics studied was not the result of enhanced β-lactamase production, but of a decrease in the concentration of the pore proteins OmpF and OmpC in E. coli and of a 37-kDa membrane protein in E. cloacae . The results obtained thus far indicate that we have cloned a gene encoding a 20 kDa polypeptide that is involved in the regulation of outer membrane protein synthesis.     

Cloning, sequencing and expression in Escherichia coli of the low-affinity penicillin binding protein of Enterococcus faecalis

Abstract Low-affinity penicillin binding proteins are particular membrane proteins, in several Gram-positive bacteria, which are involved in β-lactam antibiotic resistance. The structural gene for the low-affinity penicillin binding protein 5 (PBP5) of Enterococcus faecalis was cloned and sequenced. From the sequence of the 3378 bp, a 2040 bp coding region was identified. From biochemical analysis it emerges that E. faecalis PBP5 is a type II membrane protein with an uncleaved N-terminal and is composed of 679 amino acids with a molecular weight of 74055. This protein showed 48 and 33% of identity with Enterococcus hirae PBP5 and Staphylococcus aureus PBP2a, both low-affinity PBPs involved in β-lactam resistance. Anti-PBP5 antibodies cross-reacted with a membrane protein present in other species of enterococci, but the entire gene fragment cloned hybridized only with DNAs of E. faecalis strains, thus suggesting that genes coding for low-affinity PBPs of enterococci are not stictly homologous. In this experiment digoxigenin-labelled E. faecalis DNA was used.     

Intraspecies and Interspecies Transformation Reactions in Pneumococcus and Streptococcus

The efficiency of transformation of pneumococcus and a strain of viridans streptococcus (strain D) to streptomycin resistance is influenced by the species in which the mutation to resistance occurred, as well as by the species in which the mutated gene has been replicated. Pneumococcus and streptococcus strain D transform in higher frequency with DNA that has been replicated in bacteria of the same species than with DNA from the heterologous species. However, the difference between the frequencies of interspecific and intraspecific transformation is much greater with pneumococcus as receptor than with streptococcus. In addition pneumococcus transforms in higher frequency with wholly homologous (pneumococcal) DNA than with DNA from pneumococci that have replicated the streptococcal Sm^r gene. Pneumococcus is transformed in lower frequency by wholly heterologous (streptococcal) DNA than by DNA from streptococci that have replicated the pneumococcal Sm^r gene. Streptococcus behaves similarly in that wholly homologous (streptococcal) DNA transforms it more efficiently than when the transforming fragment contains a pneumococcal moiety. Streptococcus is transformed in the same or lower frequency by wholly heterologous (pneumococcal) DNA than by DNA from pneumococci that have replicated the streptococcal Sm^r gene. When erythromycin resistance was used as genetic marker instead of streptomycin resistance, similar results were found.     

Studies on genetic transformation of Theobroma cacao L.: evaluation of different polyamines and antibiotics on somatic embryogenesis and the efficiency of uidA gene transfer by Agrobacterium tumefaciens

In order to develop a more efficient genetic transformation system for cacao somatic embryos, the effects of polyamines and β-lactam antibiotics on somatic embryogenesis, hygromycin as selective agent, and different factors affecting uidA gene transfer have been evaluated. The polyamines putrescine, spermidine, and spermine significantly improved secondary somatic embryogenesis in cacao. Spermine at 1,000 μM provided the best responses, increasing 6.7× the percentage of embryogenic callus and 2.5× the average number of embryos per embryogenic callus. The β-lactam antibiotics timentin and meropenem, used for Agrobacterium tumefaciens counter-selection, had a non-detrimental effect on secondary somatic embryogenesis, depending on their concentration, whereas the commonly used β-lactam cefotaxime inhibited it, irrespective of the tested concentration. Hygromycin showed a strong inhibitory effect on secondary somatic embryogenesis of cacao, impairing completely the embryo production at 20 mg l⁻¹. Following the criterion of GUS activity, the best conditions for T-DNA transfer into cotyledon explants from primary somatic embryos of cacao were a sonication of the explants for 100 s, a 20-min incubation period in Agrobacterium solution, an Agrobacterium concentration of 1.0 (OD₆₀₀), and cocultivation of the explants on tobacco feeder layers. These findings will have important implications for studies on functional genomics of cacao.     

Transformation of the entomopathogenic fungus, Metarhizium flavoviride strain CG423 to benomyl resistance

Metarhizium flavoviride strain CG423 is being developed as a mycoinsecticide against grasshoppers. This strain has been transformed to resistance to the fungicide benomyl by a polyethylene glycol (PEG)-mediated procedure using a mutant tubulin gene from Neurospora crassa . Transformation frequencies of up to 84 transformants per microgram of transforming DNA were achieved. Benomyl-resistant transformants were obtained that could tolerate greater than 30 μg ml⁻¹ benomyl. Southern blot analysis of genomic DNA reveals that the mechanism of genetic transformation of all transformants was by homologous gene replacement of the β-tubulin allele.     

Cloning of Streptococcus pneumoniae DNA: its use in pneumococcal transformation and in studies of mismatch repair

EcoRI fragments of the amiA locus in Streptococcus pneumoniae were cloned either into a derivative of lambda or into pBR325 plasmid. Mutations in the amiA locus confer resistance to aminopterin. Pneumococcal DNA fractions were enriched for the desired EcoRI fragments by agarose gel electrophoresis. Recombinant clones were detected directly by transformation with DNA and lambda plaques or from single-colony lysates containing pBR325. The use of cloned DNA in pneumococcal transformation has revealed a number of features pertinent to transformation in general, and also the mismatch repair process. High transformation levels can be achieved, from 40 to 80% of a competent culture. These high levels of transformation with cloned DNA made in a foreign host are taken to confirm the absence of restriction effects on transformation in S. pneumoniae. At saturation, similar transformation levels are obtained with hybrid phage or hybrid plasmid DNAs, but the DNA amount required is 20 to 25 times lower for hybrid plasmid than for hybrid phage, probably because plasmid DNA is 10 times shorter than phage DNA. There is no "end effect" with intact hybrid DNA, i.e. similar transformation levels are achieved for markers whatever their map position on the cloned pneumococcal fragment. Cloned DNA has been used to study the action of the mismatch repair process (hex system). The presence of two mismatches in the same cell is not enough to saturate the hex system, and is not enough to kill the colony-forming center (cfc).     

细菌自然转化的分子机制研究进展

自然环境中,具备自然转化能力的细菌可以自发地从外界获取DNA,从而获得新的遗传性状。为能够自然地被转化,细菌需首先建立一个被称作感受态的生理状态并在此状态下表达DNA摄取和加工相关的基因。DNA摄取基因的表达产物可组装一个能将外源DNA摄入细胞质的蛋白复合物。在细胞质中,进入的DNA可同基因组DNA发生同源重组或建立成一个独立的质粒。一般DNA摄入细胞的过程可分为两个阶段,即从外部基质到细胞周质和跨细胞内膜的转运。近年来,包括作者在内的研究人员发现大肠杆菌中存在新的自然质粒转化模式。本文将首先综述近年来细菌自然转化的分子机制,随后简要介绍大肠杆菌中独特的自然质粒转化模式。     

Molecular and cellular biology of pneumococcal infection

The complete pneumococcal genome sequence was released in November, 1997. This advance has been combined with new understanding of physiology and pathogenesis including characterization of a family of surface proteins adducted to choline, regulation of virulence, and the regulon for natural DNA transformation. These developments in our understanding of molecular and cellular biology of pneumococcal infection will allow the development of new vaccines and antibiotics against this community acquired pathogen.     

细菌自然转化的分子机制及生物学功能研究进展

基因的水平转移在细菌的进化中起着非常重要的作用。自然界中的细菌之间主要通过3种机制进行基因水平转移:由噬菌体介导的转导、接合转移和自然转化。自然转化是指自然感受态的细菌能够自发地从外界环境中摄取DNA分子并整合到自身基因组上的过程。该现象首先发现于肺炎链球菌,目前至少有83种细菌被发现具有发生自然转化的能力,其中革兰氏阳性菌以肺炎链球菌(Streptococcus pneumoniae,S. pneumoniae)为代表,革兰氏阴性菌以奈瑟氏菌(Neisseria)为代表,对其自然转化机制的研究和认识较为清楚,但不同细菌之间自然转化的机制有所差异。自然转化的生物学功能一直以来有以下几种推测:获取营养、修复DNA损伤、生物进化,而近年来对此认识争论不休。本文将详细描述细菌自然转化的分子机制,并对其主要的生物学功能争论焦点进行评述,以期对细菌自然转化有更深入的理解和认识。     

Molecular cloning, overexpression and biochemical characterization of hypothetical beta-lactamases of Mycobacterium tuberculosis H37Rv

Aim:  Molecular cloning, overexpression and biochemical characterization of the genes from the Mycobacterium tuberculosis H37Rv genome having hypothetical β-lactamases activity.
Methods and Results:  Analysis of the M. tuberculosis H37Rv genome revealed that Rv 2068c , Rv 0406 c and Rv 3677 c gene products were predicted to exhibit β-lactamases activity. All the three genes were cloned in pET28a vector and overexpressed in C41 (DE3) Escherichia coli cells. The His-tagged recombinant proteins were confirmed by immunoblotting and were shown to have β-lactamase activity by the hydrolysis of nitrocefin and other β-lactams. Catalytic parameters for all the recombinant proteins were derived followed by the enzyme inhibition studies. Antibiotic susceptibility studies using the recombinant strains showed an increased resistance against different classes of β-lactam antibiotics.
Conclusion:  The study revealed the possibility of more than one gene in M. tuberculosis , encoding proteins having β-lactamase or β-lactamase-like activity, giving wide spectrum of resistance against β-lactams.
Significance and Impact of the Study:  Systematic study of hypothetical β-lactamases of M. tuberculosis and related species and their correlation with β-lactam and inhibitor susceptibility profile might be useful in developing new antibiotic regime for the treatment of tuberculosis caused by multiple drug resistant (MDR) strains.     

Conversion of phenylacetyl-cysteinyl-valine in vitro into penicillin G by isopenicillin N synthase of Streptomyces lactamdurans

Abstract Purified isopenicillin N synthase of Streptomyces lactamdurans JC1843 converted phenylacetyl-cysteinyl-valine, a structural analogue of the natural substrate (α-amino-adipyl-cysteinyl-valine), into a penicillinase-sensitive β-lactam antibiotic. The antibiotic was identified as penicillin G by HPLC. Cyclization of phenylacetyl cysteinylvaline into penicillin G required dithiothreitol (DTT), ascorbic acid and Fe²⁺. The affinity of the enzyme for phenylacetyl cysteinylvaline was about 20 times lower than the affinity for α-aminoadipyl-cysteinyl-valine.     

Natural transformation of Neisseria gonorrhoeae: from DNA donation to homologous recombination

Gonococci undergo frequent and efficient natural transformation. Transformation occurs so often that the population structure is panmictic, with only one long-lived clone having been identified. This high degree of genetic exchange is likely necessary to generate antigenic diversity and allow the persistence of gonococcal infection within the human population. In addition to spreading different alleles of genes for surface markers and allowing avoidance of the immune response, transformation facilitates the spread of antibiotic resistance markers, a continuing problem for treatment of gonococcal infections. Transforming DNA is donated by neighbouring gonococci by two different mechanisms: autolysis or type IV secretion. All types of DNA are bound non-specifically to the cell surface. However, for DNA uptake, Neisseria gonorrhoeae recognizes only DNA containing a 10-base sequence (GCCGTCTGAA) present frequently in the chromosome of neisserial species. Type IV pilus components and several pilus-associated proteins are necessary for gonococcal DNA uptake. Incoming DNA is subject to restriction, making establishment of replicating plasmids difficult but not greatly affecting chromosomal transformation. Processing and integration of transforming DNA into the chromosome involves enzymes required for homologous recombination. Recent research on DNA donation mechanisms and extensive work on type IV pilus biogenesis and recombination proteins have greatly improved our understanding of natural transformation in N. gonorrhoeae. The completion of the gonococcal genome sequence has facilitated the identification of additional transformation genes and provides insight into previous investigations of gonococcal transformation. Here we review these recent developments and address the implications of natural transformation in the evolution and pathogenesis N. gonorrhoeae.