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Detection of blaNDM-1 and Genetic Relatedness in Clinical Isolates of Escherichia coli Producing Extended Spectrum β-Lactamase from Tertiary Care Centres in South India

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DOI: 10.4236/aim.2016.63013    1,776 Downloads   2,260 Views   Citations


Background: Extended spectrum β-lactamases (ESBL) producing E. coli co-producing other β-lactamases and exhibiting co-resistance to different antibiotic classes continue to emerge as a threat to clinical field. This study aimed to analyze the co-production of New Delhi metallo-β-lactamase-1 (blaNDM-1) in ESBL producing plasmid-bearing clinical isolates collected from two tertiary care centres in Kerala, South India, and to understand their genetic relatedness. Methods: Antibiotic resistance phenotypes of 44 clinical isolates were determined by disc-diffusion method. Plasmid-bearing isolates, detected by the alkaline-lysis method, which also tested positive for ESBL production, were screened for the presence of blaNDM-1 by polymerase chain reaction. Plasmid, random amplified polymorphic DNA profiles and blaNDM-1 sequence-based phylogenetic tree were analyzed to understand the genotypic similarities among the isolates. Results: Beta-lactam antibiotics, quinolones, cephalosporins, used in this study, and AZM were found to be ineffective against the isolates as significantly high number of isolates were resistant to these antibiotics (P < 0.01). Plasmid bearing isolates constituted 57% (n = 25), all of which were found to be ESBL producers. blaNDM-1 amplicons were noticed in four (16%) isolates and these DNA sequences showed homology between them and with similar sequences reported from other countries like Japan and Korea. Plasmid and RAPD profiles demonstrated that most of the isolates, including those harbouring blaNDM-1 shared genetic similarities as well as an apparent geographical distinctiveness. Conclusion: The predominance of ESBL production and the occurrence of blaNDM-1 in plasmid-bearing isolates observed in our study corroborate the worldwide drug-resistance scenario. This study thus warrants the need for constant surveillance in the face of sparse information available in Kerala State on the emerging drug resistance in clinical bacteria.

Cite this paper

Narayanan, N. , Suresh, M. , Rajamma, J. and Ramakrishnan, M. (2016) Detection of blaNDM-1 and Genetic Relatedness in Clinical Isolates of Escherichia coli Producing Extended Spectrum β-Lactamase from Tertiary Care Centres in South India. Advances in Microbiology, 6, 125-132. doi: 10.4236/aim.2016.63013.

Received 11 January 2016; accepted 7 March 2016; published 10 March 2016

1. Introduction

Extended spectrum β-lactamases (ESBL) producing clinical bacterial isolates are emerging rapidly worldwide. These enzymes can hydrolyse broad spectrum cephalosporins and monobactams [1] [2] . ESBL production is a major characteristic of Enterobacteriaceae especially E. coli and Klebsiella spp. though other organisms also produce these enzymes less frequently [3] - [5] . A significant increase in the number of ESBL producing E. coli has been observed during the past decades which impacts clinical and community settings [6] - [8] . Since most of the ESBL genes are located on plasmids carrying resistance genes against other antibiotic classes, ESBL producers frequently exhibit resistance to multiple antibiotics posing a threat to healthcare management [3] [5] [9] .

Carbapenems are the effective agents commonly used against ESBL producing bacteria whereas isolates resistant to these antibiotics and even the “last resort” agents like tigecyclins and polymyxins are now emerging in the clinical field [10] . Carbapenem resistance is mainly attributed to the production of various carbapenemases and one of these, the New Delhi metallo β-lactamase-1 (blaNDM-1), first identified in India, caused widespread alarm recently [11] . In addition, isolates co-producing various β-lactamases have also been frequently encountered in hospital settings from various parts of the world including India [12] - [15] . All these enzymes act as weapons to fight against the bactericidal and bacteriostatic effects of multiple antibiotics, facilitating evolution of deadly bacterial pathogens.

The aim of this study was to determine the prevalence and coproduction of ESBL and blaNDM-1 type carbapenemase in clinical isolates of E. coli collected from two tertiary care centers in Kerala. The closest relatives of the blaNDM-1 gene sequences have also been analyzed by constructing a phylogenetic tree. Plasmid profiles and Random Amplified Polymorphic DNA (RAPD) fingerprints were also analyzed to determine the genetic similarities and dissimilarities among the isolates.

2. Materials and Methods

2.1. Bacterial Isolates and Identity

Bacterial isolates were collected from two tertiary care centers in Kerala, South India. Isolate identity was confirmed by biochemical tests and ribotyping using Microbial Type Culture Collection (MTCC) E. coli strain 41 as reference. LPW57-5’ AGTTTGATCCTGGCTCAG3’ and LPW58-5’ AGGCCCGGGAACGTATTCAC3’ [16] were used as forward and reverse primers respectively for ribotyping. Isolates which were found to harbour plasmid DNA, detected by the alkaline lysis method, which also tested positive for ESBL production, were included in this study.

2.2. Antimicrobial Susceptibility Testing

Antibiotic sensitivity against 10 antibiotics, belonging to five different classes, was tested by Kirby-Bauer disc diffusion [17] method according to Clinical and Laboratory Standards Institute (CLSI) manual [18] . The antibiotic discs (Hi Media laboratories, Mumbai, India) used in this study were Ampicillin (AMP)―10 mcg, Ceftazidime (CAZ)―30 mcg, Cefotaxime (CTX)―30 mcg, Piperacillin/Tazobactam (PIT)―100/10 mcg, Azithromycin (AZM)―15 mcg, Gentamicin (GEN)―10 mcg, Nalidixic acid (NA)―30 mcg, Ciprofloxacin (CIP)―5 mcg, Meropenem (MRP)―10 mcg and Chloramphenicol (C)―30 mcg.

2.3. Plasmid and Genomic DNA Isolation

Plasmids and genomic DNA were isolated by alkaline lysis method [19] and the procedure described by Keller and Manak (1989) [20] respectively. The plasmid DNA was electrophoresced at 100 V for 1 h and 30 min in 0.5× Tris-Borate-EDTA (TBE), using 0.8% (w/v) agarose to obtain the plasmid profiles of different isolates. Molecular weights of plasmid DNA was determined using AlphaView (AV) version software.

2.4. Screening and Confirmation of ESBL Production

Phenotypic screening and confirmation of ESBL production was performed as per CLSI manual. Disc diffusion technique was applied on Mueller-Hinton Agar (MHA) using ceftazidime (CAZ)―30 mcg, aztreonam (AT)― 30 mcg and cefotaxime (CTX)―30 mcg, discs for screening and ceftazidime, ceftazidime-clavulanic acid (CAC)―30/10 mcg, and cefotaxime, cefotaxime-clavulanic acid (CEC)―30/10 mcg, discs for confirmation. Lawn culture of isolates was prepared on MHA and the culture with appropriate antibiotic discs was incubated at 37˚C for 18 h. The diameter of zone of inhibition was measured and the results were interpreted as per CLSI recommendations. E. coli MTCC41 served as the negative control.

2.5. PCR Amplification of blaNDM-1

A PCR-based screening was conducted to detect the presence of blaNDM-1 gene on plasmid DNA from the isolates, using primers NDM-F―5’GGTTTGGCGATCTGGTTTTC3’, and NDM-R―5’CGGAATGGCTCAT- CACGATC 3’ [21] [22] . The PCR reactions were performed in a minicycler (MJ Research, USA) in a volume of 25 µl containing 1× PCR buffer, 1.5 mM MgCl2, 200 µM each of dNTPs, 2 U of Taq DNA polymerase, 0.5 µM primer and 100 ng template DNA. All reagents were purchased from Bangalore Genei Pvt. Ltd. HPLC purified primers were purchased from Sigma Aldrich Chemicals Pvt. Ltd. (Bangalore).

The PCR products were sequenced at a commercial facility (Xcelris Labs Limited, Ahmedabad). The nucleotide sequences and deduced protein sequences were analyzed with Basic Local Alignment Search Tool (BLAST) programs of National Center for Biotechnology Information (NCBI) (www.ncbi.nlm.nih.gov). Presence of open reading frames (ORFs) and conserved regions were detected by ORF finder (www.ncbi.nlm.nih.gov/gorf/gorf.html).

2.6. Phylogenetic Analysis

The DNA sequences of blaNDM-1 amplicons obtained in the present study were compared with those of Klebsiella pnemoniae, Citrobacter freundii, E. coli, Serratia sp. and Acinetobacter soli strains retrieved from the NCBI GenBank database. Nucleotide BLAST (BLASTN) was used for the sequence searches with default parameters and those DNA sequences, which showed hits with the study sequence, with minimum “E value” and maximum “query coverage” were considered for phylogenetic analysis. To determine the nearest phylogenetic neighbours, each sequence was subjected to the nucleotide sequence homology searches using BLAST homology search tool [23] . All the sequences were aligned using default configuration of multiple sequence comparison by log-expectation (MUSCLE) embedded in MEGA 5 (Molecular Evolutionary Genetics Analysis) software [24] [25] . The phylogenetic tree has been constructed by neighbour-joining method with 1000 heuristic bootstrap replicates and substitution model as “p distance”.

2.7. RAPD Analysis

Initial screening of genomic DNA samples was carried out with 10 different decameric oligonucleotide primers―RBaC 1 - 10 (Bangalore Genei, Pvt. Ltd.) to check for the reproducibility of the fingerprints. Of the few primers which produced consistently reproducible pattern of discrete bands, the primer, RBaC5 with the sequence AGGGGCGGCA (Accession. no. AM911680) was selected for generating fingerprints of the isolates. As described earlier, 25 µl reactions were subjected to thermal cycling according to manufacturer’s instructions. The photographs of RAPD gels were used to construct the dendrogram employing NTSYS pc2.0 (Numerical Taxonomy and Multivariate Analysis System) software by unweighed pair-group method arithmetic mean (UPG-MA).

2.8. Statistical Analysis

Statistical analysis was carried out using SPSS (Statistical Package for Social Sciences) software version 20. Significance of difference between two independent proportions was analyzed by Z-test. A two-tailed P < 0.01 was considered significant.

3. Result

3.1. Bacterial Isolates

A total of 44 E. coli isolates were collected all of which were found to produce an amplicon having same molecular weight as that of E. coli MTCC 41. This particular band was sequenced for confirmation of the reliability of identification. The sequence showed identity with E. coli 16S rRNA sequences.

3.2. Antibiotic Sensitivity

All the isolates were found to be resistant to AMP, β-lactam/β-lactam inhibitor combination―PIT, 1st and 2nd generation quinolone―NA and CIP, 3rd generation cephalosporins―CTX and CAZ. Significantly high resistance was observed against AZM [(77%) (P < 0.01)]. However, comparatively decreased resistance was observed in isolates against GEN (57%), MRP (59%) and C (25%).

3.3. Plasmid Isolation and ESBL Production

Plasmids could be isolated from 25 (57%) of the isolates which were designated as E1 to E25. All of the plasmid bearing isolates were found to be ESBL producers as they gave positive results during screening (zone of inhibition was ≤22, ≤27 and ≤27 around CAZ, AT, and CTX respectively) which were further confirmed by employing CAZ and CTX antibiotics alone and in combination with clavulanic acid [ceftazidime-clavulanic acid (CAC―30/10 mcg) and cefotaxime-clavulanic acid (CEC―30/10 mcg)]. The zone of inhibition around CAC disc was found to increase in diameter (>5 mm) than that around CAZ in all the isolates. CEC was found to be ineffective.

3.4. Phylogenetic Analysis of blaNDM-1 Sequences

blaNDM-1 specific amplicons were observed in only four (16%) isolates (E7, E8, E10 and E23) which were found to vary in size from ~580 to 850 bp Figure 1. The DNA sequence identity was confirmed using BLASTN analysis. These four DNA sequences together with six similar sequences, retrieved from NCBI GenBank database, based on the criteria mentioned above, were used to construct the phylogenetic tree in order to understand the nearest neighbour of the study sequences. The genetic divergence and homogeneity of the sequences are apparent in the phylogenetic tree Figure 2. Among the DNA sequences obtained from our study, those from isolates E23 and E8 were found to form distinct lineages, whilst those from E7 and E10 shared similarity. Interestingly, these sequences were closely placed in the phylogenetic tree and their genetic similarity with sequences from other countries like Japan (Accession no: KP347609.1), Korea (Accession no: CP012754.1) and china (Accession no: KP987216.1) as well as with two sequences reported from India (Accession no: KR872634.1 and KR872624.1) was also clearly discernible in the tree.

Figure 1. Agarose gel (1.0%) showing blaNDM-1 amplicons from plasmid DNA of four E. coli isolates: Lane M denotes 100 bp DNA ladder. The other four lanes show blaNDM-1 amplicons from isolates―E7, E8, E10 and E23.

Figure 2. Phylogenetic analysis based on blaNDM-1 gene sequences obtained from the four E. coli isolates in this study and six sequences retrieved from GenBank database (NCBI). Numbers on nodes represent bootstrap support values.

3.5. Plasmid Profile and RAPD Analysis

All the isolates were found to exhibit some genotypic similarities, as evident from their plasmid profile Figure 3(a) and RAPD dendrogram. Three major plasmid profile types (a-c) could be noticed, with molecular weights ranging from 1.3 to >21 kb Table 1, on agarose gel electrophoresis of the isolated plasmids. The isolates which were found to share the plasmid profiles were grouped under type a, and those with similar profiles were included under subtypes of a (a1, a2, a3 and a4) Figure 3(b). The 2nd type of profile (b) included isolates showing unique profiles and the 3rd type (c) included those which exhibited a single band of >21 kb on agarose gel. Isolates which displayed the same plasmid profile also showed an apparent congruence in their resistance phenotypes as well. Minor similarities were also observed in the subtypes of profile a. Out of 25 isolates, 13 (52%) belonged to type a, 10 (40%) to type b and the remaining to type c profile. It is interesting to note that, all the blaNDM-1 positive isolates were found to be included under type a, except E23, with E7 and E10 showing identical profile (a4) and E8 with a1profile Table 1. The isolate E23, which exhibited a unique plasmid profile, was collected from Calicut area.

The RAPD profiles generated employing random decameric primer-RBaC 5 were analysed to construct a dendrogram using NTSYS pc2.0 software which also displayed a similar picture. The dendrogram showed two major clusters-A and B Figure 4. The major clusters could be further subdivided into sub-clusters-A1, A2 and B1, B2. All the isolates collected from Calicut area were found to be included in the same sub-cluster A1. Interestingly, the two isolates with similarity index 1.000, E21 and E22 (sub-cluster A1) were also from the same place of collection. Likewise, isolates E15, E18 and E19 (sub-cluster A2) with similarity index 1.000 also showed a similar antibiotic resistance phenotype. Notably, all isolates within this sub-cluster except E15 exhibited identical plasmid profile-a1 Table 1. Among the blaNDM-1 positive isolates, E10, however, failed to be amplified with the random primer, while the other three (E7, E8 and E23) were found to be included in a same distant subcluster of A1 with E7 and E8 showing greater similarity. This observation is line with the results of our plasmid profile analysis.

4. Discussion

Increasing emergence of ESBL producing E. coli, co-producing other β-lactamases and exhibiting co-resistance to many classes of antibiotics, poses a significant threat worldwide [26] [27] . This is also the case in the Indian subcontinent, where the emergence of a new metallo-β-lactamase (MBL) gene―the blaNDM-1, was reported recently [28] [29] . The subsequent worldwide reports on the emergence of blaNDM-1 producing bacteria clearly showed the role of plasmid vectors in their dissemination as they were found to be residents on large plasmids. Occurrence of blaNDM-1 producing E. coli from patients with a history of previous hospitalization in India was first reported in 2011 from Germany [30] . Nielsen et al., 2012, reported that an NDM-1 producing E. coli obtained in Denmark has a genetic profile similar to an NDM-1 producing E. coli isolate from UK, suggesting dissemination of a common plasmid into various sequence types of E. coli [31] . In contrast, a new NDM-1-pro- ducing E. coli has been first reported from China from patients without any travel history [32] . However, such studies and reports from Kerala are sparse with few available in published literature. In this study, prevalence of ESBL producers was observed among clinical isolates of E. coli collected from two tertiary care centers in Kerala. Co-existance of blaNDM-1 has been observed in four isolates. The genetic similarity between isolates

Figure 3. Plasmid profiles. (a) From 18 representative E. coli isolates; lanes denoted MW represent Lambda DNA EcoRI/Hind III double digest molecular weight marker; strain designations have been indicated against the lanes; (b) A regrouping of lanes showing identical patterns―a1, a2, a3 and a4.

Figure 4. RAPD Dendrogram showing clonal relatedness among E. coli isolates. Clustering was done by UPGMA.

Table 1. Grouping of plasmid-bearing isolates based on plasmid profile characteristics.

was apparent in the antibiogram, plasmid profile and RAPD dendrogram. The similarities observed in the plasmid profiles of blaNDM-1 positive isolates as well as their blaNDM-1 gene sequences, suggest a common plasmid vehicle related dissemination of the β-lactamase gene. Diversity among isolates from different geographical areas, however, was also apparent in our study.

5. Conclusion

In conclusion, a predominance of ESBL producing E. coli isolates was observed in this study. The blaNDM-1 specific amplicons in these plasmid-bearing isolates were found to be genetically similar to each other. Further, these sequences also showed similarities with those previously reported from Japan, Korea and China. Thus, this study warns urgent implementation of strict control measures to prevent spread of resistance genes and warrants the need for constant surveillance. In the face of sparse information available from Kerala State on the emerging drug resistance in clinical bacteria, it is imperative to further expand the study in terms of larger samplings of pathogens from across the state and country followed by critical evaluation.


This work was supported by a grant from Indian Council of Medical Research to N.N.


*Corresponding author.

Conflicts of Interest

The authors declare no conflicts of interest.


[1] Alipourfard, I. and Nili, N.Y. (2010) Antibiogram of Extended Spectrum Beta-Lactamase (ESBL) Producing Escherichia coli and Klebsiella pneumoniae Isolated from Hospital Samples. Bangladesh Journal of Medical Microbiology, 4, 32-36.
[2] Brolund, A. (2014) Overview of ESBL-Producing Enterobacteriaceae from a Nordic Perspective. Infection Ecology and Epidemiology, 4, 24555.
[3] Chaudhary, U. and Aggarwal, R. (2004) Extended Spectrum β-Lactamases (ESBL)—An Emerging Threat to Clinical Therapeutics. Indian Journal of Medical Microbiology, 22, 75-80.
[4] Auer, S., Wojna, A. and Hell, M. (2010) Oral Treatment Options for Ambulatory Patients with Urinary Tract Infections Caused by Extended-Spectrum-β-Lactamase-Producing Escherichia coli. Antimicrobial Agents and Chemotherapy, 54, 4006-4008.
[5] Dhillon, R.H.-P. and Clark, J. (2012) ESBLs: A Clear and Present Danger? Critical Care Research and Practice, 2012, 11 p.
[6] Nakamura, T., Komatsu, M., Yamasaki, K., Fukuda, S., Miyamoto, Y., Higuchi, T., Ono, T., Nishio, H., Sueyoshi, N., Kida, K., Satoh, K., Toda, H., Toyokawa, M., Nishi, I., Sakamoto, M., Akagi, M., Nakai, I., Kofuku, T., Orita, T., Wada, Y., Zikimoto, T., Koike, C., Kinoshita, S., Hirai, I., Takahashi, H., Matsuura, N. and Yamamoto, Y. (2012) Epidemiology of Escherichia coli, Klebsiella Species, and Proteus mirabilis Strains Producing Extended-Spectrum β-Lactamases from Clinical Samples in the Kinki Region of Japan. American Journal of Clinical Pathology, 137, 620-626.
[7] Mohanalakshmi, T., Sandhya Rani, T., Sankeerthi, C.H., Sai Ravi Kiran, B., Sreenivasulu Reddy, V. and Prabhakar Reddy, E. (2014) A Report on Extended-Spectrum β-Lactamases (ESBLs) Producing Escherichia coli Isolated from Clinical Samples. Current Research in Microbiology and Biotechnology, 2, 347-350.
[8] Rath, S., Dubey, D., Sahu, M.C. and Padhy, R.N. (2014) Surveillance of ESBL Producing Multidrug Resistant Escherichia coli in a Teaching Hospital in India. Asian Pacific Journal of Tropical Disease, 4, 140-149.
[9] Morosini, M.-I., Garcia-Castillo, M., Coque, T.M., Valverde, A., Novais, A., Loza, E., Baquero, F. and Canton, R. (2006) Antibiotic Coresistance in Extended-Spectrum-β-Lactamase-Producing Enterobacteriaceae and in Vitro Activity of Tigecycline. Antimicrobial Agents and Chemotherapy, 50, 2695-2699.
[10] Alagesan, M., Gopalakrishnan, R., Panchatcharam, S.N., Dorairajan, S., Ananth, T.M. and Venkatasubramanian, R. (2015) A Decade of Change in Susceptibility Patterns of Gram-Negative Blood Culture Isolates: A Single Center Study. Germs, 5, 65-77.
[11] Nordmann, P., Naas, T. and Poirel, L. (2011) Global Spread of Carbapenemase-Producing Enterobacteriaceae. Emerging Infectious Diseases, 17, 1791-1798.
[12] Zhang, X., Lou, D., Xu, Y., Shang, Y., Li, D., Huang, X., Li, Y., Hu, L., Wang, X. and Yu, F. (2013) First Identification of Coexistence of blaNDM-1 and blaCMY-42 among Escherichia coli ST167 Clinical Isolates. BMC Microbiology, 13, 282.
[13] Doi, Y., O’Hara, J.A., Lando, J.F., Querry, A.M., Townsend, B.M., Pasculle, A.W. and Muto, C.A. (2014) Co-Production of NDM-1 and OXA-232 by Klebsiella pneumoniae. Emerging Infectious Diseases, 20, 163-165.
[14] Khajuria, A., Praharaj, A.K., Kumar, M. and Grover, N. (2014) Emergence of Escherichia coli, Co-Producing NDM-1 and OXA-48 Carbapenemases, in Urinary Isolates, at a Tertiary Care Centre at Central India. Journal of Clinical and Diagnostic Research, 8, DC01-DC04.
[15] Pokhrel, R.H., Thapa, B., Kafle, R., Shah, P.K. and Tribuddharat, C. (2014) Co-Existence of Beta-Lactamases in Clinical Isolates of Escherichia coli from Kathmandu, Nepal. BMC Research Notes, 7, 694.
[16] Woo, P., Leung, P., Leung, K. and Yuen, K.Y. (2000) Identification by 16S Ribosomal RNA Gene Sequencing of an Enterobacteriaceae Species from a Bone Marrow Transplant Recipient. Molecular Pathology, 53, 211-215.
[17] Bauer, A.W., Kirby, W.M., Sherris, J.C. and Turck, M. (1966) Antimicrobial Susceptibility Testing by a Standardized Single Disc Method. American Journal of Clinical Pathology, 45, 493-496.
[18] Clinical and Laboratory Standards Institute (CLSI) (2012) Performance Standards for Antimicrobial Susceptibility Testing. 22nd Informational Supplement: M100-S22.
[19] Sambrook, J., Fritsch, E.F. and Maniatis, T. (1989) Molecular Cloning—A Laboratory Manual. 2nd Edition, Cold Spring Harbor Laboratory Press, Cold Spring Harbor.
[20] Keller, G.H. and Manak, M.M. (1989) Extraction of DNA from Bacterial Cells. DNA Probes, Macmillan Publishers Ltd.
[21] Poirel, L., Dortet, L., Bernabeu, S. and Nordmann, P. (2011) Genetic Features of blaNDM-1-Positive Enterobacteriaceae. Antimicrobial Agents and Chemotherapy, 55, 5403-5407.
[22] Poirel, L., Walsh, T.R., Cuvillier, V. and Nordmann, P. (2011) Multiplex PCR for Detection of Acquired Carbapenemase Genes. Diagnostic Microbiology and Infectious Disease, 70, 119-123.
[23] Altschul, S.F., Madden, T.L., Schaffer, A.A., Zhang, J., Zhang, Z., Miller, W. and Lipman, J. (1997) Gapped BLAST and PSI-BLAST: A New Generation of Protein Database Search Programs. Nucleic Acids Research, 25, 3389-3402.
[24] Edgar, R.C. (2004) MUSCLE: Multiple Sequence Alignment with High Accuracy and High Throughput. Nucleic Acids Research, 32, 1791-1797.
[25] Tamura, K., Peterson, D., Peterson, N., Stecher, G., Nei, M. and Kumar, S. (2011) MEGA5: Molecular Evolutionary Genetics Analysis Using Maximum Likelihood, Evolutionary Distance, and Maximum Parsimony Methods. Molecular Biology and Evolution, 28, 2731-2739.
[26] Mushtaq, S., Irfan, S., Sarma, J.B., Doumith, M., Pike, R., Pitout, J., Livermore, D.M. and Woodford, N. (2011) Phylogenetic Diversity of Escherichia coli Strains Producing NDM-Type Carbapenemases. Journal of Antimicrobial Chemotherapy, 66, 2002-2005.
[27] Cai, J.C., Zhang, R., Hu, Y.Y., Zhou, H.W. and Chen, G.-X. (2014) Emergence of Escherichia coli Sequence Type 131 Isolates Producing KPC-2 Carbapenemase in China. Antimicrobial Agents and Chemotherapy, 58, 1146-1152.
[28] Yong, D., Toleman, M.A., Giske, C.G., Cho, H.S., Sundman, K., Lee, K. and Walsh, T.R. (2009) Characterization of a New Metallo-β-Lactamase Gene, blaNDM-1, and a Novel Erythromycin Esterase Gene Carried on a Unique Genetic Structure in Klebsiella pneumoniae Sequence Type 14 from India. Antimicrobial Agents and Chemotherapy, 53, 5046-5054.
[29] Ahmed, G.U., Bora, A., Hazarika, N.K., Prasad, K.N., Randhawa, V., Sarma, J.B. and Shukla, S.K. (2013) Incidence of blaNDM-1 Gene in Escherichia coli Isolates at a Tertiary Care Referral Hospital in Northeast India. Indian Journal of Medical Microbiology, 31, 250-256.
[30] Pfeifer, Y., Witte, W., Holfelder, M., Busch, J., Poirel, L. and Nordmann, P. (2011) NDM-1-Producing Escherichia coli in Germany. Antimicrobial Agents and Chemotherapy, 55, 1318-1319.
[31] Nielsen, J.B., Hansen, F., Littauer, P., Schonning, K. and Hammerum, A.M. (2012) An NDM-1-Producing Escherichia coli Obtained in Denmark Has a Genetic Profile Similar to an NDM-1-Producing E. coli Isolate from the UK. Journal of Antimicrobial Chemotherapy, 67, 2049-2051.
[32] Liu, Z., Li, W., Wang, J., Pan, J., Sun, S., Yu, Y., Zhao, B., Ma, Y., Zhang, T., Qi, J., Liu, G. and Lu, F. (2013) Identification and Characterization of the First Escherichia coli Strain Carrying NDM-1 Gene in China. PLoS ONE, 8, e66666.

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