Novel mechanisms of resistance to protein synthesis inhibitors in Streptococcus pneumoniae

Streptococcus pneumoniae is a leading cause of pneumonia, bacteremia, meningitis, otitis media and sinusitis, and is responsible for significant morbidity and mortality worldwide. The burden of pneumococcal disease has been greatly impacted by the high prevalence of HIV, especially in developing cou...

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Main Author: Wolter, Nicole
Format: Others
Language:en
Published: 2008
Subjects:
Online Access:http://hdl.handle.net/10539/4762
id ndltd-netd.ac.za-oai-union.ndltd.org-wits-oai-wiredspace.wits.ac.za-10539-4762
record_format oai_dc
collection NDLTD
language en
format Others
sources NDLTD
topic Streptococcus pneumoniae
antibiotic resistance mechanisms
macrolides
telithromycin
linezolid
gene conversion
South Africa
spellingShingle Streptococcus pneumoniae
antibiotic resistance mechanisms
macrolides
telithromycin
linezolid
gene conversion
South Africa
Wolter, Nicole
Novel mechanisms of resistance to protein synthesis inhibitors in Streptococcus pneumoniae
description Streptococcus pneumoniae is a leading cause of pneumonia, bacteremia, meningitis, otitis media and sinusitis, and is responsible for significant morbidity and mortality worldwide. The burden of pneumococcal disease has been greatly impacted by the high prevalence of HIV, especially in developing countries. Macrolides are commonly used for the treatment of pneumococcal infections with the resulting effect of increasing resistance. Pneumococci develop resistance to macrolides predominantly by two mechanisms; target modification and drug efflux. Target modification occurs through the acquisition of an erm(B) gene (MLSB phenotype) or through ribosomal mutation, and drug efflux occurs through the acquisition of a mef(A) gene (M phenotype). Alternative protein synthesis-inhibiting antibiotics such as linezolid and telithromycin have been developed in response to the increasing level of antibiotic resistance. In this study, novel mechanisms of resistance to protein synthesis-inhibiting antibiotics, and the current prevalence and epidemiology of macrolide resistance in South Africa were investigated. Two clinical isolates of S. pneumoniae resistant to macrolides, linezolid and chloramphenicol were identified in the PROTEKT surveillance study and the ABCs program of the CDC. The isolates were found to each contain a 6 bp deletion, resulting in the deletion of two amino acids from a highly conserved region of ribosomal protein L4 (64PWRQ67 to 64P_Q67 and 67QKGT70 to 67Q_T70). The genes encoding the mutant ribosomal proteins transformed susceptible strain R6 to macrolide, linezolid and chloramphenicol resistance, proving that the ii deletions conferred the resistance on the isolates, and indicating that these antibiotics share a common binding site. Growth studies of the R6 transformants showed increased mass doubling times, suggesting that the L4 mutations were associated with a fitness cost, but the original strains showed evidence of fitness compensation. The L4 mutations in these isolates represent a novel mechanism of cross-resistance to macrolides, linezolid and chloramphenicol. A macrolide-resistant clinical isolate of S. pneumoniae with mutations in 23S rRNA showed a heterogeneous phenotype and genotype. A mutant gene encoding 23S rRNA from this isolate transformed susceptible strain R6 to resistance. Transformants displayed similar heterogeneity to the isolate. Culture of resistant strain R6 in the presence of antibiotic maintained resistance, however culture of the strain in the absence of antibiotic pressure resulted in a reversion to susceptibility. By DNA sequencing, gene conversion was shown to occur between the wild-type and mutant 23S rRNA alleles. Growth studies indicated that the resistant phenotype was associated with a fitness cost. Therefore, under antibiotic selective pressure alleles converted to the mutant form, and in the absence of selective pressure alleles reverted to wild-type, in order to regain fitness. Through gene conversion the pneumococcus has the ability to rapidly adapt to the environment, with implications for susceptibility testing and patient treatment. A rare clinical isolate of S. pneumoniae, highly resistant to telithromycin, was received from the Canadian Bacterial Surveillance Network and was investigated for the mechanism of resistance. The isolate was found to contain an erm(B) gene iii with a truncated control peptide, as well as a mutant ribosomal protein L4, containing a number of mutations. Transformation of susceptible strain PC13, containing a wild-type erm(B) gene, with the mutant erm(B) gene decreased the susceptibility of PC13 to telithromycin, but did not confer high-level resistance. Transformation of PC13 with the mutant L4 gene or a fragment of the L4 gene containing only the 69GTG71 to TPS mutation, conferred high-level resistance on PC13. In contrast, transformation of R6, which did not contain an erm(B) gene, with the L4 gene or L4 fragment only conferred reduced telithromycin susceptibility. High-level telithromycin resistance was therefore conferred by a combination of an erm(B) gene with a 69GTG71 to TPS mutation in a highly conserved region of ribosomal protein L4. The combination of mechanisms inhibited the binding of telithromycin to the ribosome, whereas neither mechanism individually was sufficient. A telithromycin-resistant clinical isolate of S. pneumoniae was received from the PROTEKT surveillance study and was investigated for the resistance mechanism. The isolate was found to contain a 136 bp deletion in the regulatory region of erm(B). This mutant gene was shown, by transformation studies, to confer resistance on susceptible strain PC13. Expression of erm(B) on the transcriptional level was quantified by real-time reverse transcription PCR. In the presence of erythromycin and telithromycin, erm(B) expression was significantly higher in the mutant PC13 strain than the wild-type strain. Growth studies showed that the mutant PC13 strain had a shorter lag phase than the wild-type strain in the presence of erythromycin. Telithromycin resistance was conferred by the mutant iv erm(B) gene that was expressed at a higher level than the wild-type gene, most likely resulting in higher ribosomal methylation levels sufficient to hinder telithromycin binding. Macrolide resistance in invasive pneumococcal disease in South Africa for the period 2000 to 2005 was investigated through a national laboratory-based surveillance system. Viable isolates (n=15982) collected during the six-year period were phenotypically characterised, by determination of MICs and serotyping. Two hundred and sixty random isolates from 2005 were genotypically screened for the presence of erm(B) and mef(A). Macrolide resistance increased significantly from 9% in 2000 to 14% in 2005. Resistant isolates were received from all provinces of South Africa, with Gauteng and the Western Cape having the highest incidence. Serotype 14 was the most common macrolide-resistant serotype and 96% of macrolide-resistant isolates in 2005 were serotypes included in the 7-valent pneumococcal conjugate vaccine and serotype 6A. Macrolide resistance was significantly higher in children <5 than in individuals 5 years and older. The majority of strains (75%) over the six-year period displayed the MLSB phenotype. Of the 260 strains genotypically screened, 57% were positive for erm(B), 27% were positive for mef(A), 15% contained both erm(B) and mef(A), and 1% were negative for both genes and were found to contain ribosomal mutations. Eighty percent of isolates containing both erm(B) and mef(A) were serotype 19F and were found to be clonal by PFGE and MLST. These multidrug-resistant isolates were related to the Taiwan19F-14 global clone. v Many protein synthesis-inhibiting antibiotics share overlapping binding sites on the large ribosomal subunit. Alterations in 23S rRNA and ribosomal proteins L4 and L22, within the binding pocket, confer resistance and often cross-resistance to many of these antibiotics. The ability of the pneumococcus to develop resistance and the global spread of resistant strains highlights the importance of monitoring resistance levels and understanding resistance mechanisms.
author Wolter, Nicole
author_facet Wolter, Nicole
author_sort Wolter, Nicole
title Novel mechanisms of resistance to protein synthesis inhibitors in Streptococcus pneumoniae
title_short Novel mechanisms of resistance to protein synthesis inhibitors in Streptococcus pneumoniae
title_full Novel mechanisms of resistance to protein synthesis inhibitors in Streptococcus pneumoniae
title_fullStr Novel mechanisms of resistance to protein synthesis inhibitors in Streptococcus pneumoniae
title_full_unstemmed Novel mechanisms of resistance to protein synthesis inhibitors in Streptococcus pneumoniae
title_sort novel mechanisms of resistance to protein synthesis inhibitors in streptococcus pneumoniae
publishDate 2008
url http://hdl.handle.net/10539/4762
work_keys_str_mv AT wolternicole novelmechanismsofresistancetoproteinsynthesisinhibitorsinstreptococcuspneumoniae
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spelling ndltd-netd.ac.za-oai-union.ndltd.org-wits-oai-wiredspace.wits.ac.za-10539-47622019-05-11T03:41:42Z Novel mechanisms of resistance to protein synthesis inhibitors in Streptococcus pneumoniae Wolter, Nicole Streptococcus pneumoniae antibiotic resistance mechanisms macrolides telithromycin linezolid gene conversion South Africa Streptococcus pneumoniae is a leading cause of pneumonia, bacteremia, meningitis, otitis media and sinusitis, and is responsible for significant morbidity and mortality worldwide. The burden of pneumococcal disease has been greatly impacted by the high prevalence of HIV, especially in developing countries. Macrolides are commonly used for the treatment of pneumococcal infections with the resulting effect of increasing resistance. Pneumococci develop resistance to macrolides predominantly by two mechanisms; target modification and drug efflux. Target modification occurs through the acquisition of an erm(B) gene (MLSB phenotype) or through ribosomal mutation, and drug efflux occurs through the acquisition of a mef(A) gene (M phenotype). Alternative protein synthesis-inhibiting antibiotics such as linezolid and telithromycin have been developed in response to the increasing level of antibiotic resistance. In this study, novel mechanisms of resistance to protein synthesis-inhibiting antibiotics, and the current prevalence and epidemiology of macrolide resistance in South Africa were investigated. Two clinical isolates of S. pneumoniae resistant to macrolides, linezolid and chloramphenicol were identified in the PROTEKT surveillance study and the ABCs program of the CDC. The isolates were found to each contain a 6 bp deletion, resulting in the deletion of two amino acids from a highly conserved region of ribosomal protein L4 (64PWRQ67 to 64P_Q67 and 67QKGT70 to 67Q_T70). The genes encoding the mutant ribosomal proteins transformed susceptible strain R6 to macrolide, linezolid and chloramphenicol resistance, proving that the ii deletions conferred the resistance on the isolates, and indicating that these antibiotics share a common binding site. Growth studies of the R6 transformants showed increased mass doubling times, suggesting that the L4 mutations were associated with a fitness cost, but the original strains showed evidence of fitness compensation. The L4 mutations in these isolates represent a novel mechanism of cross-resistance to macrolides, linezolid and chloramphenicol. A macrolide-resistant clinical isolate of S. pneumoniae with mutations in 23S rRNA showed a heterogeneous phenotype and genotype. A mutant gene encoding 23S rRNA from this isolate transformed susceptible strain R6 to resistance. Transformants displayed similar heterogeneity to the isolate. Culture of resistant strain R6 in the presence of antibiotic maintained resistance, however culture of the strain in the absence of antibiotic pressure resulted in a reversion to susceptibility. By DNA sequencing, gene conversion was shown to occur between the wild-type and mutant 23S rRNA alleles. Growth studies indicated that the resistant phenotype was associated with a fitness cost. Therefore, under antibiotic selective pressure alleles converted to the mutant form, and in the absence of selective pressure alleles reverted to wild-type, in order to regain fitness. Through gene conversion the pneumococcus has the ability to rapidly adapt to the environment, with implications for susceptibility testing and patient treatment. A rare clinical isolate of S. pneumoniae, highly resistant to telithromycin, was received from the Canadian Bacterial Surveillance Network and was investigated for the mechanism of resistance. The isolate was found to contain an erm(B) gene iii with a truncated control peptide, as well as a mutant ribosomal protein L4, containing a number of mutations. Transformation of susceptible strain PC13, containing a wild-type erm(B) gene, with the mutant erm(B) gene decreased the susceptibility of PC13 to telithromycin, but did not confer high-level resistance. Transformation of PC13 with the mutant L4 gene or a fragment of the L4 gene containing only the 69GTG71 to TPS mutation, conferred high-level resistance on PC13. In contrast, transformation of R6, which did not contain an erm(B) gene, with the L4 gene or L4 fragment only conferred reduced telithromycin susceptibility. High-level telithromycin resistance was therefore conferred by a combination of an erm(B) gene with a 69GTG71 to TPS mutation in a highly conserved region of ribosomal protein L4. The combination of mechanisms inhibited the binding of telithromycin to the ribosome, whereas neither mechanism individually was sufficient. A telithromycin-resistant clinical isolate of S. pneumoniae was received from the PROTEKT surveillance study and was investigated for the resistance mechanism. The isolate was found to contain a 136 bp deletion in the regulatory region of erm(B). This mutant gene was shown, by transformation studies, to confer resistance on susceptible strain PC13. Expression of erm(B) on the transcriptional level was quantified by real-time reverse transcription PCR. In the presence of erythromycin and telithromycin, erm(B) expression was significantly higher in the mutant PC13 strain than the wild-type strain. Growth studies showed that the mutant PC13 strain had a shorter lag phase than the wild-type strain in the presence of erythromycin. Telithromycin resistance was conferred by the mutant iv erm(B) gene that was expressed at a higher level than the wild-type gene, most likely resulting in higher ribosomal methylation levels sufficient to hinder telithromycin binding. Macrolide resistance in invasive pneumococcal disease in South Africa for the period 2000 to 2005 was investigated through a national laboratory-based surveillance system. Viable isolates (n=15982) collected during the six-year period were phenotypically characterised, by determination of MICs and serotyping. Two hundred and sixty random isolates from 2005 were genotypically screened for the presence of erm(B) and mef(A). Macrolide resistance increased significantly from 9% in 2000 to 14% in 2005. Resistant isolates were received from all provinces of South Africa, with Gauteng and the Western Cape having the highest incidence. Serotype 14 was the most common macrolide-resistant serotype and 96% of macrolide-resistant isolates in 2005 were serotypes included in the 7-valent pneumococcal conjugate vaccine and serotype 6A. Macrolide resistance was significantly higher in children <5 than in individuals 5 years and older. The majority of strains (75%) over the six-year period displayed the MLSB phenotype. Of the 260 strains genotypically screened, 57% were positive for erm(B), 27% were positive for mef(A), 15% contained both erm(B) and mef(A), and 1% were negative for both genes and were found to contain ribosomal mutations. Eighty percent of isolates containing both erm(B) and mef(A) were serotype 19F and were found to be clonal by PFGE and MLST. These multidrug-resistant isolates were related to the Taiwan19F-14 global clone. v Many protein synthesis-inhibiting antibiotics share overlapping binding sites on the large ribosomal subunit. Alterations in 23S rRNA and ribosomal proteins L4 and L22, within the binding pocket, confer resistance and often cross-resistance to many of these antibiotics. The ability of the pneumococcus to develop resistance and the global spread of resistant strains highlights the importance of monitoring resistance levels and understanding resistance mechanisms. 2008-04-15T09:05:10Z 2008-04-15T09:05:10Z 2008-04-15T09:05:10Z Thesis http://hdl.handle.net/10539/4762 en 84676 bytes 941355 bytes 10769 bytes application/pdf application/pdf application/pdf application/pdf application/pdf application/pdf