MOLECULAR CHARACTERIZATION OF EXTENDED SPECTRUM BETA-LACTAMASE PRODUCING ENTEROBACTER CLOACAE, ESCHERICHIA COLI, KLEBSIELLA PNEUMONIAE FROM ASYMPTOMATIC PREGNANT WOMEN

ABSTRACT

Extended spectrum beta-lactamases (ESBL) are enzymes produced by members of the Enterobacteriaceae which can hydrolyze the beta-lactam antibiotics such as penicillins and cephalosporins, and thereby conferring antibiotic resistance on strains producing them. Bacterial isolates producing ESBLs have spread to different parts of the world. The ESBLs are encoded by several different genetic elements borne on the chromosome and plasmids. This study was carried out to investigate the prevalence of ESBL producing bacterial uropathogens among asymptomatic pregnant women in the study area and to characterize the genes associated with ESBL among the isolates. Mid-stream urine sample was collected from a total of 660 pregnant women between July and December 2018. A questionnaire to access the risk factors for acquiring ESBL producing bacteria was filled. The specimens were inoculated on MacConkey agar and incubated at 37oC for 24h. The biochemical characterization of the isolates was done using the Microbact 24E (Oxoid Ltd, UK). Antibiotic susceptibility testing was done by Kirby-Bauer disc agar diffusion method. The isolates were tested for the production of ESBL, using Double Disk Synergy test and CHROMagar ESBL. Genomic and plasmid DNA from ESBL producing strains was extracted and amplified using the Polymerase Chain Reaction (PCR) with primers for blaTEM, blaSHV and blaCTX-M-15genes. A total of 252 uropathogenic bacterial isolates were encountered. Of this number, 231 (92%) were ESBL producers. The distribution of bacterial pathogens were as follows: Enterobacter cloacae (25.7%) followed by Escherichia coli (20.2%), Klebsiella pneumoniae (16.3%), Citrobacter spp. (1.2%), and Hafnia alvei (6.7%). E. cloacae were the most frequently isolated ESBL producer (25%), followed by E. coli (19%) and K.  pneumoniae (15%). There was significant association (P<0.005) between age, marital status, previous use of antibiotics, personal hygiene and parity with the occurrence of ESBL producing bacteria. Extended spectrum beta-lactamase producers revealed a higher level of antibiotic resistance (90%) compared to non-ESBLs. Carbapenems were the most effective treatment options for these bacteria. Genotypic characterization of the ESBL producing isolates showed blaCTX-M-15 to be the most prevalent (26%). The carriage of multiple bla genes was low, ranging from 2-6 % of different combinations. This study has shown the existence of multiple bla genes in the Gram-negative bacterial isolates from pregnant women in Ikot Ekpene, Eket and Oron Local Government Areas. This calls for appropriate antibiotic use through creating awareness in order to combat the potential negative effects of the spread of resistant bacteria carrying genes for resistance to extended spectrum beta-lactam antibiotics.

TABLE OF CONTENTS

TITLE                                                                                                                  PAGE

Title Page                                                                                                                    i

Declaration                                                                                                                  ii

Certification                                                                                                                iii

Dedication                                                                                                                  iv

Acknowledgements                                                                                                    v

Table of Contents                                                                                                       vi

List of Tables                                                                                                              x

List of Figures                                                                                                             xi

List of Plates                                                                                                               xii

List of Appendices                                                                                                     xiii

Abstract                                                                                                                      xiv

CHAPTER 1: INTRODUCTION

1.1       Background of the Study                                                                               1

1.2       Statement of Research Problem                                                                      3

1.3       Justification of the Study                                                                               4

1.4       Aim and Objectives of the Study                                                                   4

1.5       Null Hypothesis                                                                                              5

CHAPTER 2: LITERATURE REVIEW

2.1       Asymptomatic Bacteriuria                                                                              6

2.2       Classification of Urinary Tract Infections                                                      6

2.2.1.   Complicated urinary tract infections                                                              6

2.2.2    Uncomplicated urinary tract infections                                                          7

2.2.3    Upper urinary tract infections                                                                         7

2.3       Pathogenesis of Urinary Tract Infections                                                       8

2.4       Risk Factors for Asymptomatic Bacteriuria in Pregnancy                              9

2.5       Prevalence of Asymptomatic Bacteriuria in Pregnancy                                  10

2.6       Virulence Factors of Uropathogens                                                                11

2.7       Immunology of the Urinary Tract                                                                   12

2.8       Defense against Uropathogens                                                                       13

2.9       Antibiotic Use in Pregnancy                                                                           14

2.10     Commonly Implicated Organisms in Asymptomatic Bacteriuria                   16

2.11     Classification of Antibiotics                                                                           20

2.12     Antibiotic Resistance                                                                                      33

2.12.1  The advent of antibiotic resistance                                                                 34

2.12.2 Causes of antibiotic resistance                                                                         35

2.12.3  Antibiotic resistance transmission                                                                   36

2.12.4 Antibiotic resistance and bacterial virulence                                                  37

2.12.5  Mechanism of bacterial resistance                                                                  38

2.12.6  Multiple antibiotic resistance index                                                                42

2.12.7  Microbact-24E bacterial identification system                                               43

2.13     The Biochemical Resistance Mechanism                                                        44

2.14     Beta-lactamases                                                                                              47

2.15     Beta-lactamase Classifications                                                                        48

2.15.1  Mode of action of beta-lactamases                                                                 51

2.16     Bacterial Resistance Mechanism to Beta-lactam drugs                                  52

2.17     Earliest and Recent β-lactamase Inhibitor Combinations                               54

2.18     Penicillin-binding Protein (PBP), the Targets of β-lactam Antibiotics           57

2.19     Extended Spectrum Beta-lactamases (ESBLs)                                              59

2.19.1  Types of ESBLs                                                                                              60

2.20     Epidemiology of ESBL producers                                                                 64

2.21     Risk of Acquiring ESBL Infections with ESBL Producing Bacteria                        67

2.22    Detection of ESBLs in Clinical Laboratory                                                   67

2.22.1  Phenotypic methods                                                                                       68

2.22.2  Double disk synergy test (DDST)                                                                  68

2.22.3  CLSI phenotypic confirmatory tests (PCT)                                                    69

2.22.4 ESBLs confirmatory test                                                                                71

2.23     Identifying Genes that encode resistance to antibiotics                                 72

2.23.1 Polymerase chain reactions (PCR)                                                                  73

2.23.2 DNA microarrays                                                                                             74

2.24     PCR-based DNA Finger Printing Technique                                                 75

2.24.1 Random Amplified Polymorphic DNA (RAPD)                                            75

2.24.2 Agarose gel electrophoresis                                                                             76

2.25     Control of Antimicrobial Resistance                                                              77       

CHAPTER 3: MATERIALS AND METHODS

3.1       Study Area                                                                                                      79

3.2       Study Design                                                                                                  79

3.3       Study Population                                                                                            80

3.4       Inclusion and Exclusion Criteria                                                                     80

3.5       Ethical Approval                                                                                             80

3.6       Sample Size                                                                                                     80

3.7       Sample Collection                                                                                           81

3.8       Specimen Processing                                                                                       81

3.8.1    Biochemical identification of isolates                                                             82

3.8.2    Identification of bacterial isolates by PCR and DNA sequencing                 84

3.8.3   Antibiotic susceptibility test                                                                            85

3.8.4    Detection of Extended-Spectrum Beta-lactamase                                         85

3.8.5    Double disk synergy test                                                                                85

3.9       Molecular Studies                                                                                           86

3.9.1    Plasmid DNA extraction                                                                                86

3.9.2    Genomic DNA extraction                                                                               87

3.9.3    Quantification of plasmid DNA                                                                     88

3.9.4    Amplification of blaCTX-M-15, SHV and TEM resistant gene by PCR        88

3.9.5    Random amplified polymorphic DNA                                                           91

3.9.6    Statistical analysis                                                                                           93

CHAPTER 4: RESULTS AND DISCUSSION

4.1       Results                                                                                                            94

4. 2      Discussion                                                                                                       131

CHAPTER 5: CONCLUSION AND RECOMMENDATIONS

5.1       Conclusion                                                                                                     149

5.2       Recommendations                                                                                          150

References                                                                                                      151

Appendices                                                                                                     178

LIST OF TABLES

LIST OF FIGURES

LIST OF PLATES

LIST OF APPENDICES

CHAPTER 1

INTRODUCTION

1.1       BACKGROUND OF THE STUDY

Urinary tract infections (UTIs) are recurrent infections with potentially fatal symptoms. The rise in antibiotics resistance, together with our heightened awareness of the adverse effects of broad-spectrum antibiotics on beneficial host microbiota, has generated difficulties in the existing treatment trend for UTIs (Roger and Scott, 2020). The most prevalent form of infection among women is urinary tract infection (UTI) most notably pregnant women, due to hormonal and morphological changes that occur during pregnancy. In various studies, this prevalence ranges between 5 and 20% and differs depending on the health status in the respective countries (Tadesse et al., 2014; Szweda and Jóźwik, 2016)

There are three distinct clinical types of UTI linked to pregnancy; asymptomatic bacteriuria, cystitis, and pyelonephritis.  Obstetric complications can lead to death and small birth weights (Oladeinde et al., 2015; Szweda and Jóźwik, 2016). The most common reason for antibiotic use in primary care is urinary tract infections (UTIs) (Plate et al., 2020). Abuse of antibiotics used in treating UTIs contributes to high incidence of resistance (Rodriguez et al., 2019). Studies showed that asymptomatic infection alone affects 2–12 % of women (Steele et al., 2017).

Urinary tract infection was found to be prevalent in 12.5 % of pregnant women (Azami et al., 2019). A prevalence rate of 31% and 6.4% has been reported in Ogun State and Akwa Ibom State respectively (Ochei et al., 2018; Nseobong et al., 2019). Other researchers reported a prevalence rate of 21.2%, 29.1% and 6.3% respectively in Ethopia, Kenya, and Iraq (Tadesse et al., 2018a; Taye et al., 2018; Goruntla et al., 2019).

Beta-lactam antibiotics are one of the commonly used drug classes with a wide range of therapeutic applications. Since their introduction in the 30s of the twentieth century they, have dramatically altered the scenario of the war against bacterial infectious diseases. However, their use conflicts with the disturbing occurrence of antimicrobial resistance, which is now a global health problem (Thakuria et al., 2013). Resistance to β-lactams is growing increasingly as new β-lactamases (enzymes which destroy β-lactams) are discovered daily; example is the discovery of β-lactamases (ESBL) with the ability to inactivate certain cephalosporins by hydrolyzing the beta-lactam ring.  Extended spectrum betalactamases diversity is rapidly growing, so far more than 170 variants have been identified for a single genotype, encoding the bla CTX-M ESBL (Sadeeq et al., 2018 and Warawan et al., 2018).

Extended spectrum beta-lactamases are frequently found in the Enterobacteriaceae family of Gram negative organisms, especially the Klebsiella species, Escherichia coli and E. cloacae but also in other species such as Pseudomonas aeroginosa, Citrobacter species and Enterobacter species (Giwa et al., 2018). Several studies have identified the prevalence of ESBLs producing uropathogens in Nigeria (Onanuga et al., 2019). In North Western Nigeria, Giwa et al. (2018) recorded a prevalence rate of 34.3 %. Kalaivani et al. (2018) have also documented a prevalence rate of 73.3 %. In addition, Oloso et al. (2018) recorded a nationwide geographic distribution trend of antimicrobial resistance based on geographical zones which showed that the highest number of reports were from South West Nigeria and, in descending order, from South-South, North-West, North-Central, North-East and South-East as lowest.

Clinically, ESBLs limit the efficacy of β-lactams including extended-spectrum cephalosporins, and are associated with high morbidity and mortality (Rawat and Nair, 2010). More than 2.8 million antimicrobial-resistant infections occur in the U.S. each year, and more than 35,000 people die as a result. In 2017, there were an estimated 197,400 cases of ESBL-producing Enterobacterales among hospitalized patients and 9,100 estimated deaths in the United States (CDC, 2019).

Colonization of pregnant women with extended spectrum β-lactamase (ESBL)-producing micro-organisms might lead to the transmission of these bacteria to neonates resulting in severe and extreme morbidity due to these pathogens (Jalilian et al., 2019). Detection and case management of an ESBL infection is critical now as ESBL infections tend to be ascribable to resistant organisms (Sahni et al., 2018). The aim of this study is to investigate the prevalence of ESBL producing uropathogens among pregnant women in the study area and to characterize the genes associated with ESBL among the bacterial isolates.

1.2       STATEMENT OF THE PROBLEM

Antibiotic resistance has become a global issue due to the exponential increase of multidrug-resistant infections. In particular, there is a high rate of urinary tract infection and treatment failure in pregnant women, which has resulted in increased mortality and morbidity, as well as longer hospital stays. Antibiotics are available for purchase without prescription and even when prescribed, there is poor patients’ compliance in underdeveloped nations. There is inadequate information on the prevalence of bacteria that produce ESBLs in pregnant women from Ikot Ekpene, Oron, and Eket Local Government Areas of Akwa Ibom. This study will bridge the knowledge gap by determining the prevalence of ESBLs producing organism in these three study areas and also characterise the ESBLs genes harboured by these bacteria using molecular biology. The knowledge of antibiotic susceptibility pattern of ESBLs producing isolates from the pregnant women will guide the clinicians in prescriptions and will reduce maternal mortality and treatment failure hence help in more efficient health care of pregnant women.

1.3       JUSTIFICATION OF THE STUDY

Owing to the spread of multidrug-resistant bacteria, their encoding genes on easily transferrable plasmids, and shortage of successful eradication methods for virulent strains that exist in humans, ESBL-producing bacteria pose a difficult challenge to address (De Kraker et al., 2013; Tacconelli et al., 2014). The consequences of morbidity and death are numerous (O'Neill, 2016; Musicha et al., 2017). Therefore, more information about the precise prevalence of ESBL-producing bacteria and the characterization of antibiotic resistant genes in pregnant women is necessary to help health policymakers and providers deliver adequate prevention and treatment measures to pregnant women.

1.4       AIMS AND OBJECTIVES

The aim of this study is to investigate the prevalence of ESBL producing uropathogens among pregnant women in the study area and to characterize the genes associated with ESBL among the bacterial isolates.

Specific objectives

1.                  To access the risk factors for acquiring ESBL producing bacteria using questionnaire.

2.                  To isolate and identify bacterial uropathogens.

3.                  To assess the prevalence of bacterial uropathogens among pregnant women attending antenatal at General Hospital, Ikot Ekpene, Eket and Oron.

4.                  To determine the antibiotic susceptibility pattern of bacterial isolates from urine specimens of pregnant women attending antenatal at General Hospital, Ikot Ekpene, Eket, and Oron.

5.                  To screen resistant isolates for Extended Spectrum Beta Lactamases (ESBL) production using two different methods (Double disk synergy test and Chrom Agar ESBL).

6.                  To characterize the ESBL genes in ESBLs producing isolates using Polymerase Chain Reaction (PCR).

7.                  To conduct a molecular epidemiology of some of the isolates using RAPD.

1.5       NULL HYPOTHESIS

1.      At least 90% of the bacterial isolates from the urine specimen of pregnant women in the study area are not susceptible to all commonly used antimicrobial agents available in the study area.

2.      Antimicrobial resistance that may be detected among the bacterial isolates from the pregnant women in the study area is not due to ESBL production.

3.      Antimicrobial resistant bacterial isolates in the study area carry unrelated resitance genes.

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