Tung-Ching Chung

Inactivation of mrcA gene derepresses the basal-level expression of L1 and L2 β-lactamases in Stenotrophomonas maltophilia

OBJECTIVES To characterize the relationship between inactivation of the mrcA gene and β-lactamase expression and β-lactams resistance in Stenotrophomonas maltophilia KJ and to investigate the involvement of ampR, ampN-ampG, ampD(I) and creBC in this. METHODS The mrcA deletion mutant KJΔmrcA was constructed to investigate the role of this putative penicillin-binding protein 1a (PBP1a) in β-lactamase expression and β-lactam resistance. The ΔampR, ΔampNG, ΔampDI and ΔcreBC alleles were introduced into KJΔmrcA, and KJΔDIΔBC and KJΔDIΔmrcAΔBC were also constructed for comparison. All the mutants and their corresponding parent strains were assayed for β-lactamase activities and MICs of β-lactams. RESULTS Inactivation of mrcA caused basal L1/L2 β-lactamase production to increase by ∼100-fold, but made little difference to cefuroxime-induced β-lactamase activity and the MICs of β-lactams. The ΔmrcA-derived basal β-lactamase hyperproduction was ampR and ampN-ampG dependent. Simultaneous inactivation of ampD(I) and mrcA did not augment β-lactamase production over and above that seen in an ampD(I) mutant alone. Furthermore, we could find no evidence for a role of the creBC two-component regulatory system in β-lactamase hyperproduction in a ΔampD(I) or ΔmrcA background. CONCLUSIONS Inactivation of mrcA, predicted to encode PBP1a, causes basal L1/L2 β-lactamase hyperproduction in S. maltophilia.

AmpN-AmpG Operon Is Essential for Expression of L1 and L2 β-Lactamases in Stenotrophomonas maltophilia

ABSTRACT AmpG is an inner membrane permease which transports products of murein sacculus degradation from the periplasm into the cytosol in Gram-negative bacteria. This process is linked to induction of the chromosomal ampC beta-lactamase gene in some members of the Enterobacteriaceae and in Pseudomonas aeruginosa. In this study, the ampG homologue of Stenotrophomonas maltophilia KJ was analyzed. The ampG homologue and its upstream ampN gene form an operon and are cotranscribed under the control of the promoter PampN. Expression from PampN was found to be independent of β-lactam exposure and ampN and ampG products. A ΔampN allele exerted a polar effect on the expression of ampG and resulted in a phenotype of null β-lactamase inducibility. Complementation assays elucidated that an intact ampN-ampG operon is essential for β-lactamase induction. Consistent with ampG of Escherichia coli, the ampN-ampG operon of S. maltophilia did not exhibit a gene dosage effect on β-lactamase expression. The AmpG permease of E. coli could complement the β-lactamase inducibility of ampN or ampG mutants of S. maltophilia, indicating that both species have the same precursor of activator ligand(s) for β-lactamase induction.

NagZ-Dependent and NagZ-Independent Mechanisms for β-Lactamase Expression in Stenotrophomonas maltophilia

ABSTRACT β-N-Acetylglucosaminidase (NagZ), encoded by the nagZ gene, is a critical enzyme for basal-level ampC derepression (ampC expression in the absence of β-lactam challenge) in ampD and dacB mutants of Pseudomonas aeruginosa. Three mutants with a phenotype of basal-level L1 and L2 β-lactamase derepression in Stenotrophomonas maltophilia have been reported, including KJΔDI (ampDI mutant), KJΔmrcA (mrcA mutant), and KJΔDIΔmrcA (ampDI and mrcA double mutant). In this study, nagZ of S. maltophilia was characterized, and its roles in basal-level β-lactamase derepression, induced β-lactamase activities, and β-lactam resistance of KJΔDI, KJΔmrcA, and KJΔDIΔmrcA were evaluated. Expression of the nagZ gene was constitutive and not regulated by AmpR, AmpDI, AmpN, AmpG, PBP1a, and NagZ. Introduction of ΔnagZ into KJΔDI nearly abolished basal-level derepressed β-lactamase activity; conversely, introduction of ΔnagZ into KJΔmrcA did not affect it. At least two activator ligands (ALs) are thus considered responsible for β-lactamase expression in the S. maltophilia system, specifically, the NagZ-dependent (AL1) and NagZ-independent (AL2) ligands responsible for the basal-level derepressed β-lactamase activities of KJΔDI and KJΔmrcA, respectively. The contributions of AL1 and AL2 to the induced β-lactamase activities may vary with the types of β-lactams. nagZ inactivation did not affect aztreonam-, cefoxitin-, and carbenicillin-induced β-lactamase activities, but it attenuated cefuroxime- and piperacillin-induced β-lactamase activities. Introduction of ΔnagZ into KJ, KJΔDI, KJΔmrcA, and KJΔDIΔmrcA did not significantly change the MICs of the β-lactams tested except that the MICs of cefuroxime and piperacillin moderately decreased in strains KJΔZ and KJΔDIΔZ (nagZ mutants).

Construction and characterization of nisin-controlled expression vectors for use in Lactobacillus reuteri

The Nisin-controlled gene expression (NICE) system, which was discovered in Lactococcus lactis, was adapted to Lactobacillus reuteri by ligating nisA promoter (PnisA) and nisRK DNA fragments into the Escherichia coli-Lb. reuteri shuttle vector pSTE32. This chimerical plasmid (pNICE) was capable of expressing the heterologous amylase gene (amyL) under nisin induction. Optimization of induction factors for this Lb. reuteri/pNICE system, including nisin concentration (viz. 50 ng/ml), growth phase of culture at which nisin be added (viz. at the early exponential phase), and the best time for analyzing the gene product after inoculation (viz. at the 3rd h), allowed the amylase product to be expressed in high amounts, constituting up to about 18% of the total intracellular protein. Furthermore, the signal peptide (SP) of amyL gene (SPamyL) from Bacillus licheniformis was ligated to the downstream of PnisA in pNICE, upgrading this vector to a NICE-secretion (NIES) level, which was then designated pNIES (Sec+, secretion positive). Characterization of pNIES using an amyL-SPΔ gene (amyL gene lacking its SP) as a reporter revealed the 3rd h after induction as the secretion peak of this system, at which the secretion efficiency and the amount of α-amylase being secreted into the culture supernatant were estimated to reach 77.6% and 27.75 mg/l. Expression and secretion of AmyL products by pNIES in Lb. reuteri was also confirmed by SDS–PAGE and immunoblotting analysis.

SmQnrR, a DeoR-type transcriptional regulator, negatively regulates the expression of Smqnr and SmtcrA in Stenotrophomonas maltophilia

OBJECTIVES To characterize the role of SmqnrR in the expression of Smqnr and SmtcrA, and the role of SmtcrA in drug resistance in Stenotrophomonas maltophilia. METHODS SmqnrR, a DeoR-type regulator gene, is situated between a quinolone resistance gene (Smqnr) and a putative major facilitator superfamily transmembrane transporter gene (SmtcrA). To assess the regulatory role of SmQnrR in the expression of Smqnr and SmtcrA, the transcripts of Smqnr and SmtcrA genes were determined in the wild-type KJ and the SmqnrR isogenic mutant KJΔQnrR. An SmqnrR polar mutant, KJΔQnrRΩ, was constructed to investigate the possibility that SmqnrR and SmtcrA form an operon. The contribution of Smqnr and SmtcrA genes to the intrinsic and acquired resistance of S. maltophilia was evaluated using susceptibility testing. RESULTS SmQnrR acted as a repressor for the expression of Smqnr and SmtcrA genes. SmqnrR and SmtcrA genes formed an operon, which was negatively autoregulated by SmQnrR. Smqnr and SmtcrA contributed only slightly to intrinsic resistance in S. maltophilia. Nevertheless, overexpression of Smqnr and SmtcrA by inactivating SmqnrR conferred a slight increase in quinolone MICs and a more marked increase in tetracycline MIC. CONCLUSIONS The SmQnrR protein is a transcriptional repressor for the contiguous Smqnr and SmtcrA genes, and SmQnrR is a negative regulator of SmqnrR-SmtcrA operon expression. Inactivation of SmqnrR contributes to an acquired increase in quinolone and tetracycline MICs for S. maltophilia.

Comparison of Genospecies and Antimicrobial Resistance Profiles of Isolates in the Acinetobacter calcoaceticus-Acinetobacter baumannii Complex from Various Clinical Specimens

ABSTRACT This study was conducted to compare the prevalences of antimicrobial resistance profiles of clinical isolates in the Acinetobacter calcoaceticus-Acinetobacter baumannii complex from sterile and nonsterile sites and to further study the relationship of antimicrobial resistance profiles and genospecies by amplified rRNA gene restriction analysis (ARDRA). A total of 1,381 isolates were tested with 12 different antibiotics to show their antimicrobial susceptibility profiles. A total of 205 clinical isolates were further analyzed by ARDRA of the intergenic spacer (ITS) region of the 16S-23S rRNA gene. It was found that the overall percentage of isolates from nonsterile sites (urine, sputum, pus, or catheter tip) that were resistant to the 12 antibiotics tested was significantly higher than that of isolates from sterile sites (cerebrospinal fluid [CSF], ascites fluid, and bloodstream) (46% versus 22%; P < 0.05). After ARDRA, it was found that 97% of the 62 isolates resistant to all antibiotics tested were the A. baumannii genospecies, which was identified in only 31% of the isolates susceptible to all antibiotics tested. More genospecies diversity was identified in the isolates susceptible to all antibiotics tested, including genospecies of 13TU (34%), genotype 3 (29%), and A. calcoaceticus (5%). Furthermore, as 91% (10/11) of the isolates from CSF were susceptible to all antibiotics tested, the A. calcoaceticus-A. baumannii complex isolates with multidrug resistance could be less invasive than the more susceptible isolates. This study also indicated current emergence of carbapenem-, fluoroquinolone-, aminoglycoside-, and cephalosporin-resistant A. calcoaceticus-A. baumannii complex isolates in Taiwan.

Characterization of tetracycline resistance lactobacilli isolated from swine intestines at western area of Taiwan.

To investigate the frequency of tetracycline resistance (Tet-R) lactobacilli in pig intestines, a total of 256 pig colons were analyzed and found to contain typical colonies of Tet-R lactic acid bacteria in every sample, ranging from 3.2 × 10(3) to 6.6 × 10(5) CFU/cm(2). From these samples, a total of 159 isolates of Tet-R lactobacilli were obtained and identified as belonging to 11 species, including Lactobacillus reuteri, Lactobacillus amylovorus, Lactobacillus salivarius, Lactobacillus plantarum, Lactobacillus ruminis, Lactobacillus kefiri, Lactobacillus fermentum, Lactobacillus sakei, Lactobacillus coryniformis, Lactobacillus parabuchneri and Lactobacillus letivazi. Based on the EFSA (2008) breakpoints, all isolates, after MIC analysis, were qualified as Tet-R, from which the significant high Tet-R MIC(50) and MIC(90) values indicated an ecological distribution of Tet-R lactobacilli mostly with high resistance potency in pig colons. PCR-detection identified 5 tet genes in these isolates, the most predominant one being tet (W), followed by tet (M), (L), (K), and (Q). Their detection rates were 82.0%, 22.5%, 14.4%, 8.1% and 0.9%, respectively. Noteworthily, isolates of the same species carrying identical tet gene(s) usually had a wide different MIC values. Furthermore, strain-subtyping of these isolates by REP-PCR demonstrated a notable genotypic biodiversity % (average = 62%).

Characterization of the Replication Region of the Lactobacillus reuteri Plasmid pTC82 Potentially Used in the Construction of Cloning Vector

A 3.2 kb DNA fragment containing the replication region (RR) from pTC82 was cloned, sequenced, and found to contain elements typical of plasmids that replicate via a rolling-circle mechanism of replication (RCR), including double-strand origin (DSO), replication protein gene (rep), and single-strand origin (SSO). The DSO of pTC82 contains two domains showing 55.5% and 84.6% similarities in nucleotide (nt) sequence to the conserved functional elements bind and nic, respectively, which are required for the initiation of the leading strand typical of the pC194-RCR family. Although the predicted rep gene product of pTC82 (Rep82) shares little identity (less than 24%) with other known Reps, a region containing three motifs, characteristic of the pC194-family Reps, was identified, indicating the Rep82 as a novel Rep protein of this family. Downstream of the rep82 gene, strong similarity to the typical palT type-SSO could be detected. This is the first palT type-SSO to be identified from Lactobacillus. Through a series of deletion studies, the minimal replicon of the cloned RR was found to be 2.66 kb in size including the DSO region and rep gene. This RR was further identified as being highly stable in L. reuteri and also bearing a very narrow host-range property, suggesting it to be a good replicon potentially useful in vector construction for developing L. reuteri as a vaccine carrier.

Characterization of a small cryptic plasmid pK50-2 isolated from Lactobacillus reuteri K50.

The complete nucleotide sequence of a cryptic plasmid, pK50-2, from Lactobacillus reuteri K50 had been determined. It consisted of an 1866 bp circular molecule with a G+C content of 35%, from which two putative open reading frames (orfs) could be predicted. Based on sequence similarity, the orf1 was not homologous to any known protein, while the N-terminus of the orf2 shared 56% and 64% identities with RepB proteins of plasmid pAR141 and an unnamed plasmid in L. reuteri strain PA-16, members of the rolling-circle replication (RCR) pMV158 family, respectively. Downstream of orf2, a sequence containing two conserved regions (i.e., bind and nick), possibly involved in the binding and nicking of Rep protein, similar to the dso (double strand origin) of RCR-pMV158 family was also identified. Furthermore, a sequence capable of forming the characteristic secondary structure of ssoT (single-strand origin type T) was subsequently determined upstream of the orf2 gene. Thus, the three elements essential for a RCR plasmid (i.e., dso, sso, and rep gene) were all deducible in the pK50-2. Noteworthy was that a conserved alpha helix-turn-alpha helix (HTH) motif, thus far only seen in theta-type plasmids, was for the first time identified in Rep protein of RCR plasmid, pK50-2. To estimate the pK50-2 could be an expression vector to deliver exogenous antigens, a shuttle vector pK50-S containing both pK50-2 and pUE80 (-) was used to analyze the segregational stability and copy-number, which were shown that pK50-S in L. reuteri DSM 20016 were estimated to be 98%, 77%, and 75% after 36, 72, and 100 generations and about 50 copies per chromosome equivalent by real-time PCR.

Ciprofloxacin and tetracycline susceptibility of lactobacilli isolated from indigenous children's feces

To investigate the frequency of ciprofloxacin and tetracycline resistance lactobacilli in children feces, a total of 160 feces samples were cultured on Lactobacilli-selective Rogosa agar supplemented with 0.1 mg/ml of cycloheximide and 0.5% of CaCO 3, and identified Lactobacillus species were identified by analysis of the PCR sequenced-16S rRNA gene through BLAST against the deposited GenBank database. In these samples, 96 isolates were obtained and identified as belonging to 6 species, including Lactobacilli plantarum, Lactobacilli helveticusi, Lactobacilli salivarius, Lactobacilli casei, Lactobacilli fermentum and Lactobacilli pentosus. Strain-subtyping of these isolates by repetitive extragenic palindromic (REP)-PCR demonstrated a notable genotypic biodiversity of 65.6%. Antimicrobial susceptibility of ciprofloxacin and tetracycline had a wide different minimum inhibitory concentration (MIC) values in these isolates. The MIC50 and MIC90 of ciprofloxacin both was 64 µg/ml for both, while the MIC50 and MIC90 of tetracycline were 128 and 512 µg/ml. These results indicate that high-level resistant activity of ciprofloxacin and tetracycline among Lactobacillus species in indigenous children’s intestines was prevalent in mountain district at the central area of Taiwan.