Geographical difference of disease association in Streptococcus bovis bacteraemia

doi:10.1099/jmm.0.05199-0

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Geographical difference of disease association in Streptococcus bovis bacteraemia

Rodney A. Lee¹, Patrick C.Y. Woo¹, Amanda P.C. To¹, Susanna K.P. Lau¹, Samson S.Y. Wong¹ and Kwok-Yung Yuen^1,2

¹Department of Microbiology, The University of Hong Kong, University Pathology Building, Queen Mary Hospital, Hong Kong ²HKU-Pasteur Research Centre, Hong Kong

Correspondence Kwok-Yung Yuen hkumicro{at}hkucc.hku.hk

Received January 29, 2003
Accepted July 1, 2003

From 1996 to 2001, 48 Streptococcus bovis strains were isolatedfrom blood cultures of 37 patients in one hospital. Median patientage was 68 years (range: 1 day–88 years). The male : femaleratio was 23 : 14. Most patients (97 %) had underlying diseases,including biliary tract disease in 14 (38 %), diabetes mellitusin 12 (32 %), liver parenchymal disease in seven (19 %), carcinomaof the colon in four (11 %) and other malignancies in four (11%). No infective foci (indicative of primary bacteraemia) wereidentified in 15 patients (40 %) and 14 (38 %) had acute cholangitis/cholecystitis,but only four (11 %) had infective endocarditis. Two (5 %),three (8 %) and 32 (87 %) patients had S. bovis of biotypesI, II/1 and II/2, respectively, and three (8 %), two (5 %) and32 (87 %) patients had S. bovis of genotypes 1, 2a and 2b, respectively.All isolates were sensitive to penicillin, cephalothin and vancomycin,24 (65 %) were resistant to erythromycin and 15 (41 %) wereresistant to clindamycin (these strains were also resistantto erythromycin). Thirteen isolates that were erythromycin-and clindamycin-resistant possessed the ermB gene, 10 possessedthe ermT gene and one possessed both the ermB and ermT genes.Overall, seven patients (19 %) died. In contrast to most otherreports from western countries, where carcinoma of the colonand infective endocarditis were the major underlying diseaseand infective focus associated with S. bovis bacteraemia, biliarytract disease and acute cholangitis and/or cholecystitis werethe major underlying diseases associated with S. bovis bacteraemiain our locality.

INTRODUCTION

TOP
INTRODUCTION
METHODS
RESULTS AND DISCUSSION
ACKNOWLEDGEMENTS
REFERENCES

Streptococcus bovis is frequently recovered as a commensal inboth humans and animals. Isolation of S. bovis from blood culturesof patients has a documented association with carcinoma of thecolon and infective endocarditis (Klein et al., 1977, 1979;Steinberg & Naggar, 1977; Murray & Roberts, 1978; Reynolds et al., 1983;Kupferwasser et al., 1998). Two reports have alsodemonstrated an association of S. bovis bacteraemia with chronicliver parenchymal disease (Zarkin et al., 1990; Gonzalez-Quintela et al., 2001).Phenotypically, the API 20 STREP system (bioMérieux)subdivides S. bovis into three distinct biotypes, namely I,II/1 and II/2 (Ruoff et al., 1989). Many reports have identifiedS. bovis biotype I as the predominant isolate in cases of bacteraemiacaused by the S. bovis group (Murray et al., 1999; Songy et al., 2002);it is also the biotype that is particularly associatedwith carcinoma of the colon and infective endocarditis (Murray et al., 1999).Genotypic studies that used DNA sequencing ofa 500 bp fragment of the 16S rRNA gene have shown that thereis concordance between different biotypes and genotypes (Clarridge et al., 2001).Recently, based on a combination of DNA homologystudies, whole-cell protein analysis and sequencing of the sodAgene, suggestions have been made for the revision of S. bovistaxonomy. Streptococcus gallolyticus, Streptococcus infantariusand Streptococcus pasteurianus have been proposed to replaceS. bovis I, S. bovis II/1 and S. bovis II/2, respectively (Facklam, 2002).

One study showed a high incidence of erythromycin resistancein S. bovis (Teng et al., 2001). Despite in-depth phenotypicand genotypic characterization and disease association studiesin western countries, none have attempted to study the epidemiologyand disease association of S. bovis bacteraemia in countriesoutside North America and Europe.

In this study, we characterized 48 S. bovis strains that wereisolated from blood cultures of 37 bacteraemic patients overa 6-year period by using a combination of phenotypic and genotypictechniques. Epidemiology, underlying diseases, clinical diseaseassociations and outcome of S. bovis bacteraemia in relationto the different biotypes and genotypes of S. bovis and molecularepidemiology of erythromycin resistance in S. bovis strainswere investigated.

METHODS

TOP
INTRODUCTION
METHODS
RESULTS AND DISCUSSION
ACKNOWLEDGEMENTS
REFERENCES

Patients and microbiological methods.

The 37 patients in this study were hospitalized at the QueenMary Hospital in Hong Kong during a 6-year period (1996–2001).All clinical data were collected as described previously (Woo et al., 2001c).Suspect colonies were identified by standardconventional biochemical methods (Murray et al., 1999). In addition,the API 20 STREP system (bioMérieux) was used for identificationof all Streptococcus-like (Streptococcus, Enterococcus, Granulicatella,Abiotrophia and Gemella) isolates and biotyping of S. bovisisolates. Antimicrobial susceptibility was tested by the Kirby–Bauerdisc-diffusion method and results were interpreted accordingto NCCLS criteria (Bauer et al., 1966).

Extraction of bacterial DNA.

Bacterial DNA extraction was modified from our previously publishedprotocol (Woo et al., 1997). In brief, 80 µl NaOH (0.05M) was added to 20 µl bacterial cells suspended in distilledwater and the mixture was incubated at 60 °C for 45 min,followed by addition of 6 µl Tris/HCl (pH 7.0) to achievea final pH of 8.0. The resultant mixture was diluted 100x and5 µl diluted extract was used for PCR.

Genotyping by 16S rRNA gene sequencing.

PCR amplification and DNA sequencing of a 500 bp fragment ofthe 16S rRNA gene were performed as described previously (Woo et al., 2000, 2001a, b, 2002a,b, c; Yuen et al., 2001; Lau et al., 2002)by using primers LPW601 (5'-ATGGGAGAGTTTGATCCCTG-3')and LPW602 (5'-TACCCG CGGCTGCTGGCACG-3') (Gibco-BRL). Sequencesof PCR products were compared with known 16S rRNA gene sequencesin GenBank by multiple sequence alignment with the CLUSTAL Wprogram (Thompson et al., 1994) and phylogenetic tree constructionwas performed by using PileUp with GrowTree (Genetics ComputerGroup).

erm gene sequencing.

PCR amplification and DNA sequencing of the erm genes were performedaccording to a previously published method (Teng et al., 2001)by using primers LPW632 (5'-GAAAAGGTACT CAACCAAATA-3') and LPW633(5'-AGTAACGGTACTTAAATT GTTTAC-3') for the ermB gene and LPW636(5'-GCTAATATTGTT TAAATCGTCAATTCC-3') and LPW637 (5'-GGATCAGGAAAAGGACATTTTAC-3') for the ermT gene (Gibco-BRL). Sequences of PCRproducts were compared with known erm gene sequences in GenBankby multiple sequence alignment with the CLUSTAL W program (Thompson et al., 1994)and phylogenetic tree construction was performedby using PileUp with GrowTree (Genetics Computer Group).

RESULTS AND DISCUSSION

TOP
INTRODUCTION
METHODS
RESULTS AND DISCUSSION
ACKNOWLEDGEMENTS
REFERENCES

In a 6-year period (1996–2001), 48 strains of S. boviswere isolated from blood cultures of 37 patients and were identifiedas S. bovis by the API 20 STREP system. S. bovis strains recoveredfrom the same patient exhibited the same biotype and genotypebased on 16S rRNA gene sequence analysis. Characteristics ofthe 37 patients with S. bovis bacteraemia were as follows: medianage was 68 years (range: 1 day–88 years) and 23 patients(63 %) were over 60 years of age. The male : female ratio was23 : 14. Most patients (97 %) had underlying diseases: the majorunderlying diseases included biliary tract disease in 14 (38%), diabetes mellitus in 12 (32 %), liver parenchymal diseasein seven (19 %), carcinoma of the colon in four (11 %) and othermalignancies in four (11 %). The only patient without underlyingdisease was a 2-year-old boy with gastroenteritis; the S. bovisstrain in this patient's blood had probably translocated fromthe gastrointestinal tract as a result of intestinal inflammation.No infective foci (indicative of primary bacteraemia) were identifiedin 15 patients (40 %), whereas 14 (38 %) had acute cholangitis/cholecystitis,four (11 %) had infective endocarditis, one (3 %) had secondaryperitonitis due to a perforated appendix, one (3 %) had neonatalmeningitis, one (3 %) had spontaneous bacterial peritonitisand one (3 %) had cellulitis. All patients had community-acquiredS. bovis bacteraemia. S. bovis was recovered from a single bloodculture from 32 patients (87 %), whereas the organism was isolatedfrom multiple blood cultures from five patients (13 %). Two(5 %), three (8 %) and 32 (87 %) patients had S. bovis of biotypesI, II/1 and II/2, respectively. Three (8 %), two (5 %) and 32(87 %) patients had S. bovis of genotypes 1, 2a and 2b, respectively(Fig. 1). S. bovis was the only bacterium recovered from bloodcultures of 25 patients (68 %) whereas in 12 patients (32 %),other bacteria were recovered concomitantly with S. bovis fromblood cultures (Escherichia coli in five patients, Citrobacterfarmeri in one patient, Klebsiella pneumoniae in one patient,Escherichia coli and K. pneumoniae in two patients, Escherichiacoli and Enterococcus faecalis in one patient, Escherichia coli,Bacteroides fragilis and Fusobacterium sp. in one patient andEscherichia coli, K. pneumoniae and Aeromonas hydrophila inone patient). Only one patient, with neonatal meningitis, hadS. bovis recovered at other sites in addition to blood (cerebrospinalfluid and nasal swab). Isolates recovered from all patientswere sensitive to penicillin, cephalothin and vancomycin, whereasthose recovered from 24 patients (65 %) were resistant to erythromycinand those recovered from 15 patients (41 %) were resistant toclindamycin (these strains were also resistant to erythromycin).Overall, seven patients (19 %) died.

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Fig. 1. Phylogenetic tree showing the relationship of S. bovis strains recovered from 37 patients. The tree was inferred from 500 bp of the 16S rRNA gene sequence by the neighbour-joining method. Names and accession numbers are given as cited in GenBank. Bar, 1 substitution per 100 bases (estimated by using the Jukes–Cantor correction).

The erm genes of the 24 S. bovis isolates that were resistantto erythromycin were amplified and sequenced. Thirteen isolatesthat were erythromycin- and clindamycin-resistant possessedthe ermB gene, 10 possessed the ermT gene and one possessedboth the ermB and ermT genes (Fig. 2).

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Fig. 2. Phylogenetic tree showing the relationship of the amino acid sequences of the ermB and ermT genes of the 24 erythromycin-resistant S. bovis strains to those of other erm genes. The tree was inferred from 174 aa sequence data by the neighbour-joining method. Names and accession numbers are given as cited in GenBank. Bar, 5 substitutions per 100 amino acids (estimated by using the Kimura correction).

In this study, we describe the characterization of 48 S. bovisstrains isolated from 37 patients with S. bovis bacteraemia.Similarly to a recent study that described the characterizationof 22 clinical strains of S. bovis (Clarridge et al., 2001),we also demonstrated concordance between the different biotypes(as identified by the API 20 STREP system) and genotypes (basedon 16S rRNA gene sequencing). Similarly to this recent studyand another in Taiwan (in which 88 % of 60 blood culture isolateswere of biotype II/2) (Teng et al., 2001), biotype II/2 or genotype2b was the most predominant type of S. bovis found in our patients(Table 1). This is different from the findings of previous studiesthat demonstrated that biotype I was the predominant type ofS. bovis isolated from their bacteraemic patients (Ruoff et al., 1989).

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Table 1. Comparison of characteristics from major studies of Streptococcus bovis bacteraemia References: 1, Murray & Roberts, 1978; 2, Reynolds et al., 1983; 3, Pigrau et al., 1988; 4, Ruoff et al., 1989; 5, Zarkin et al., 1990; 6, Clarridge et al., 2001; 7, Gonzalez-Quintela et al., 2001; 8, Teng et al., 2001; 9, present study. Unless stated, data are number of patients with the characteristic, with percentage in parentheses. NM, Not mentioned.

In contrast to previous studies that described a strong associationbetween S. bovis bacteraemia and carcinoma of the colon andinfective endocarditis (Steinberg & Naggar, 1977; Klein et al., 1977, 1979;Murray & Roberts, 1978; Reynolds et al., 1983;Kupferwasser et al., 1998), the association betweenS. bovis bacteraemia and these clinical conditions was not strongin our population (Table 1). Previous studies have shown thatassociations between S. bovis bacteraemia and carcinoma of thecolon and infective endocarditis were even higher for S. bovisbiotype I isolates, with 94 % association of S. bovis biotypeI bacteraemia with infective endocarditis and 71 % associationof S. bovis biotype I bacteraemia with colonic carcinoma (Murray et al., 1999).On the other hand, for S. bovis isolates of biotypeII, association between bacteraemia and infective endocarditiswas only 18 % and that between bacteraemia and carcinoma ofthe colon was only 17 % (Murray et al., 1999). As our S. bovisstrains mainly belonged to biotype II/2, it is not surprisingthat we have found a weak association between S. bovis bacteraemiaand infective endocarditis and carcinoma of the colon. In thepresent study, the rate of endocarditis and carcinoma of thecolon was only 11 %. Interestingly, none of the four patientswith infective endocarditis and the four with carcinoma of thecolon had bacteraemia caused by S. bovis biotype I.

Biliary tract disease and acute cholangitis and/or cholecystitiswere the predominant underlying diseases and diagnoses associatedwith S. bovis bacteraemia in our locality. An association betweenS. bovis bacteraemia and chronic liver parenchymal disease hasbeen reported previously (Table 1) (Zarkin et al., 1990; Gonzalez-Quintela et al., 2001).Pigrau et al. (1988) first noted that four of16 cases of S. bovis bacteraemia had liver cirrhosis; subsequently,in a study by Zarkin et al. (1990), evidence of liver parenchymaldisease was observed in 45 of 92 patients with S. bovis bacteraemia.More recently, Gonzalez-Quintela et al. (2001) described 11of 20 patients with S. bovis bacteraemia that had chronic liverparenchymal disease. In the present study, 14 of 37 patients(38 %) had biliary tract disease and the same number of patientshad acute cholangitis and/or cholecystitis. We speculate thatthe association of biliary tract disease with S. bovis bacteraemiais due to the following facts: firstly, that biliary tract diseaseis prevalent in our locality. In one study, it was demonstratedthat biliary tract sepsis is the second most common cause ofcommunity-acquired bacteraemia after urinary tract infection(French et al., 1990). This uniquely high incidence of biliarysepsis in this part of the world is attributed to high prevalenceof clonorchiasis and recurrent pyogenic cholangitis (Lo et al., 1997;Woo et al., 1998). Secondly, in contrast to most ${alpha}$ -haemolyticstreptococci, S. bovis is able to grow in bile (Luk et al., 1998).This property renders it able to survive in bile andcause acute cholecystitis and cholangitis, especially in thepresence of pre-existing biliary tract disease. Therefore, inour locality, biliary tract disease should be actively lookedfor in any future case of unexplained S. bovis bacteraemia.

The ermB and ermT genes in the S. bovis isolates studied arehighly homologous to those found in other bacteria of the gastrointestinaltract. Incidence and molecular epidemiology of erythromycinresistance in the present study are similar to those reportedin a recent study from Taiwan (Teng et al., 2001). Similarlyto the Taiwan study, which reported that 63 % of S. bovis bacteraemicisolates were erythromycin-resistant, 65 % of S. bovis isolatesin our locality were erythromycin-resistant. Furthermore, 58and 46 % of our erythromycin-resistant isolates contained theermB or ermT genes, respectively, which is also similar to thecorresponding incidences of 63 and 37 % reported in that study.The ermB and ermT genes in S. bovis showed high homology tothe ermB genes in Clostridium difficile, Clostridium perfringens,Lactobacillus reuteri, Streptococcus agalactiae, Enterococcusfaecalis, Enterococcus faecium, Lactobacillus fermentum andEscherichia coli and the ermT genes in L. reuteri and anotherLactobacillus species, which are all bacteria from the gastrointestinaltract (Fig. 2). We therefore speculate that these genes in S.bovis were acquired through horizontal gene transfer from otherbacteria that reside in the gastrointestinal tract.

ACKNOWLEDGEMENTS

TOP
INTRODUCTION
METHODS
RESULTS AND DISCUSSION
ACKNOWLEDGEMENTS
REFERENCES

This work is partly supported by the University DevelopmentFund, University Research Grant Council and the Committee forResearch and Conference Grant, The University of Hong Kong.

REFERENCES

TOP
INTRODUCTION
METHODS
RESULTS AND DISCUSSION
ACKNOWLEDGEMENTS
REFERENCES

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				J.-C. Tsai, P.-R. Hsueh, H.-J. Chen, S.-P. Tseng, P.-Y. Chen, and L.-J. Teng The erm(T) Gene Is Flanked by IS1216V in Inducible Erythromycin-Resistant Streptococcus gallolyticus subsp. pasteurianus Antimicrob. Agents Chemother., October 1, 2005; 49(10): 4347 - 4350. [Abstract] [Full Text] [PDF]

				S. K. P. Lau, P. C. Y. Woo, A. P. C. To, A. T. K. Lau, and K.-y. Yuen Lack of Evidence that DNA in Antibiotic Preparations Is a Source of Antibiotic Resistance Genes in Bacteria from Animal or Human Sources Antimicrob. Agents Chemother., August 1, 2004; 48(8): 3141 - 3146. [Abstract] [Full Text] [PDF]

				P. C. Y. Woo, A. P. C. To, S. K. P. Lau, A. M. Y. Fung, and K.-y. Yuen Phenotypic and Molecular Characterization of Erythromycin Resistance in Four Isolates of Streptococcus-Like Gram-Positive Cocci Causing Bacteremia J. Clin. Microbiol., July 1, 2004; 42(7): 3303 - 3305. [Abstract] [Full Text] [PDF]

				P. C. Y. Woo, A. P. C. To, H. Tse, S. K. P. Lau, and K.-y. Yuen Clinical and Molecular Epidemiology of Erythromycin-Resistant Beta-Hemolytic Lancefield Group G Streptococci Causing Bacteremia J. Clin. Microbiol., November 1, 2003; 41(11): 5188 - 5191. [Abstract] [Full Text] [PDF]