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INVESTIGATING INSECTICIDE RESISTANCE MECHANISMS IN DENGUE VECTORS

POPULATION; Aedes aegypti AND Aedes albopictus IN PENANG ISLAND

NUR IWANI JALALUDDIN

UNIVERSITI SAINS MALAYSIA

2019

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INVESTIGATING INSECTICIDE RESISTANCE MECHANISMS IN DENGUE VECTORS

POPULATION; Aedes aegypti AND Aedes albopictus IN PENANG ISLAND

by

NUR IWANI JALALUDDIN

Thesis submitted in fulfillment of the requirements for the degree of

Master of Science

August 2019

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ACKNOWLEDGEMENT

This thesis could not have been realized without a great deal of support and guidance. I would like to extend my appreciation to the following people who has helped me during the hard time encountered in completing this thesis.

First and Foremost, I would like to thank my supervisor, Dr. Intan Haslina Ishak for her never-ending guidance, tireless supervision, encouragement and support throughout the entire research project. I would also like to extend my heartfelt appreciation to my Co-Supervisor, Professor Madya Dr. Abdul Hafiz Ab Majid for his support throughout my research period. May Allah bless both of you and your family with the endless happiness. My research work could not come to a reality without a support from Dr. Mohd Ghows Mohd Azzam, Professor Madya Dr. Mustafa Farid Wajidi (School of Distance Education) and Dr. Veera Singham A/L Ganesan (Centre for Chemical Biology) for allowing me to work in their lab throughout my entire research project. This thesis also would not have been accomplished without the support from Universiti Sains Malaysia for providing the scholarship (USM Fellowship award: September 2016 - September 2017) for personal financial assistance and also Ministry of Higher Education (MyBrain 15: February 2016- August 2017) for the tuition fees.

I am also very grateful to be surrounded by helpful seniors whom always been there for me whenever I need their help especially Dr. Najat Wahidah Dzaki, Dr.

Jamsari Amirul Firdaus Jamaluddin, and Dr Rajiv A/L Ravi for their great help, constructive criticisms and comments. This study would not be a success without permission from Penang State Health Department, Ministry of Health Malaysia for allowing me to conduct my fieldwork in Penang Island.

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I would also like to express my gratitude to my many bestfriend, labmates and helpers during my field and labwork for their valuable ideas, fruitful discussions, mental and physical support.

Last but not least, I would not be able to complete this huge research work without a strong support from my beloved parents, Jalaluddin Bin Omar and Zaharah Binti Rejab, and to my brother, aunties, uncles, cousins and my grandparents for their love, patience and support throughout completing my MSc journey.

Beyond everything, all praise and thanks to Allah SWT the Almighty for giving me the blessing, and the strength to complete this study.

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TABLE OF CONTENTS

Acknowledgement ii

Table of Contents iv

List of Tables x

List of Figures xii

List of Plates xiv

List of Abbreviations xv

Abstrak xviii

Abstract xx

CHAPTER 1: GENERAL INTRODUCTION 1 1.1 Research Objectives 6

CHAPTER 2: LITERATURE REVIEW 2.1 Mosquito classification 7 2.2 Morphology of Aedes mosquito 7 2.3 Distribution of Aedes 9

. 2.3.1 Aedes aegypti Linn. 9

2.3.2 Aedes albopictus Skuse 9

2.4 Medical Importance of Aedes 10

2.4.1 Vectors of dengue fever 10

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2.4.2 Vectors of Chikugunya 11

2.4.3 Vectors of Zika 12

2.5 Vector Control and Management 12

2.5.1 Physical Control 12

2.5.2 Biological Control 13

2.5.3 Chemical Control 15

2.6 Insecticide Classification and Mode of Action 17

2.6.1 Organophosphate 17

2.6.2 Pyrethroid 18

2.6.3 Organochlorine 18

2.6.4 Carbamate 19

2.7 Insecticide Resistance Mechanism 20

2.7.1 Behavioural resistance 21

2.7.2 Penetration resistance 22

2.7.3 Target-site Insensitivity 22

2.7.3(a) Voltage Gated Sodium Channel (VGSC) gene 22 2.7.3(b) Acetylcholinesterase (Ace-1) gene 24

2.7.3(c) GABA receptor 24

2.7.4 Metabolic Detoxification 25

2.7.4(a) The Cytochrome P450 25

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2.7.4(b) Esterases 26

2.7.4(c) Glutathion-S-Transferase 26

2.8 Insecticide Resistance Management 27

CHAPTER 3: ACCESSING THE SUSCEPTIBILITY STATUS OF Aedes aegypti AND Aedes albopictus IN DENGUE HOTSPOT AND NON-OUTBREAK AREAS ON PENANG ISLAND AGAINST INSECTICIDES FROM THE CLASS OF PYRETHROID AND ORGANOPHOSPHATE

3.1 Introduction 29

3.2 Materials and Methods 31

3.2.1 Sampling of field mosquitoes 31

3.2.2 Mosquito rearing 35

3.2.3 WHO Adult mosquito bioassay 37

3.2.4 Data Analysis 38

3.3 Result 40

3.4 Discussion 45

3.5 Conclusion 48

CHAPTER 4: IDENTIFICATION OF TARGET-SITE RESISTANCE MECHANSMS IN VOLTAGE GATED SODIUM CHANNEL (VGSC) GENE AND ACETYLCHOLINESTERASE (Ace-1) GENE OF Aedes aegypti AND Aedes albopictus

4.1 Introduction 50

4.2 Materials and Method 53

4.2.1 Mosquito Samples 53

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4.2.2 Identification of mosquitoes at species level 53

4.2.2(a) Morphology Identification 53

4.2.2(b) Molecular Identification 53

4.2.2(b)(i) Mosquito genomic DNA extraction 53 4.2.2(b)(ii) Check the presence of genomic DNA 54 4.2.2(b)(iii) Species Identification using PCR 55 4.2.3 Detection of knockdown resistance mutation (kdr) in 57

domain II and domain III of VGSC gene in Aedes aegypti and Aedes albopictus.

4.2.4 Detection of Acetylcholinesterase (Ace-1) gene in Aedes 58 aegypti and Aedes albopictus

4.2.5 Data Analysis 59

4.3 Results 60

4.3.1 Species Identification 60

4.3.2 Partial DNA fragment sequence analysis for detection of kdr gene 62 4.3.2(a) Detection of kdr mutation in Ae. aegypti associated with 62 Pyrethroid Resistance

4.3.2(b) Detection of kdr mutation in Ae. albopictus associated 66 with Pyrethroid Resistance

4.3.3 Correlations of S989P and F1534C genotypes and resistant 67 Phenotypes of Ae. aegypti.

4.3.4 The haplotype network for F1534C and S989P mutation 69 in VGSC sequence of Ae. aegypti.

4.3.4(a) The dominancy of F1534 and C1534 alleles in partial 69 sequence of VGSC Gene

4.3.4(b) The dominancy of S989 and P989 alleles in partial 70

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4.3.5 Partial DNA fragment sequence analysis for detection of Ace-1 71 gene.

4.3.5(a) Detection of Ace-1 gene mutation in Ae. aegypti and Ae. 71 albopictus associated with Organophosphate resistance

4.4 Discussion 72

4.5 Conclusion 77

CHAPTER 5: CHARACTERIZING THE DETOXIFICATION GENES INVOLVED IN METABOLIC RESISTANCE OF Aedes aegypti AND Aedes albopictus OF PENANG ISLAND

5.1 Introduction 78

5.2 Materials and Methods 80

5.2.1 Mosquito Samples 80

5.2.2 Biochemical Enzyme Assays 80

5.2.2(a) Mix Function Oxidase (MFO) assay 81 5.2.2(b) Acetylcholinesterase (AchE) assay 81 5.2.2(c) Non-specific esterase (EST) assay 82 5.2.3 Quantitative real time-polymerase chain reaction (qRT-PCR) for 83

screening upregulation of selected detoxification genes

5.2.3(a) RNA extraction 84

5.2.3(b) Reverse-transcription and qPCR 85

5.2.4 Data Analysis 85

5.3 Results 86

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5.3.1 Detection of metabolic detoxification enzymes and genes 86

5.3.1(a) Biochemical enzyme assays for Ae. aegypti 86 5.3.1(b) Biochemical enzyme assays for Ae. albopictus 92 5.3.2 Screening for the elevation of the selected metabolic 98 detoxification gene through quantitative real-time polymerase chain reaction (qRT-PCR). 5.3.2(a) Quantitative real time-polymerase chain reaction 98

(qRT-PCR) for the detection of elevated metabolic detoxification genes in Ae. aegypti 5.3.2(b) Quantitative real time-polymerase chain reaction 99

(qRT-PCR) for the detection of elevated metabolic detoxification genes in Ae. albopictus 5.4 Discussion 101

5.5 Conclusion 105

CHAPTER 6: GENERAL DISCUSSION AND CONCLUSION 106

6.1 Future recommendations 111

6.2 Limitation 111

REFERENCES 112 LIST OF CONFERENCES

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LIST OF TABLES

Page

Table 2.1 Insecticides for space spray treatment (Ong, 2016) 16 Table 3.1 List of mosquito strains and type of strain used in this study 31 Table 3.2 Aedes and Anopheles discriminating dosages for adult 38

WHO insecticide susceptibility test (WHO, 2016a; WHO, 2016b).

Table 3.3 Mortality of Aedes aegypti female adults from Sg. Ara, Jelutong 42 and Balik Pulau strains toward permethrin 0.75%, permethrin

0.25%, malathion 5% and malathion 0.8% after 24 hours Exposure

Table 3.4 Mortality of Aedes albopictus female adults from Sg. Ara, 42 Jelutong and Balik Pulau strain toward permethrin 0.75%,

permethrin 0.25%, malathion 5% and malathion 0.8% after 24 hours exposure

Table 3.5 Knockdown time (KdT) and Resistance ratio (RR) of Aedes 43 aegypti and Aedes albopictus from Sungai Ara, Jelutong and

Balik Pulau tested against permethrin 0.75% and permethrin 0.25%.

Table 3.6 Knockdown time (KdT) and Resistance ratio (RR) of Aedes 44 aegypti and Aedes albopictus from Sungai Ara, Jelutong and

Balik Pulau testedagainst malathion 5% and malathion 0.8%.

Table 4.1 Number of mosquito species identified via molecular 60 identification

Table 4.2 Frequencies of the F1534C and S989P mutations in VGSC 65 gene of Aedes aegypti

Table 4.3 Frequencies of the F1534C and S989P mutations in VGSC 66 gene of Aedes albopictus

Table 4.4 Association between permethrin resistant phenotype and allele 68 of F1534C and S989P in Aedes. aegypti

Table 5.1 List of primers used in qRT-PCR for the screening of 83 upregulation detoxification genes in Aedes aegypti

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Table 5.2 List of primers used in qRT-PCR for the screening of 84 upregulation detoxification genes in Aedes albopictus

Table 5.3 Percentage of insensitive acetylcholinesterase (AchE) 90 activity after propoxur inhibition in Aedes aegypti

Table 5.4 Percentage of insensitive acetylcholinesterase (AchE) 96 activity after propoxur inhibition in Aedes albopictus

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LIST OF FIGURES

Page Figure 1.1 Global Map of Dengue Fever (Guzman & Harris, 2015). 2 Figure 2.1 The white scales on the scutum of Aedes aegypti and 8

Aedes albopictus (Rueda, 2004).

Figure 2.2 Global distribution of Aedes aegypti and Aedes albopictus 10 (Campbell et al., 2015).

Figure 2.3 General structure formula of Organophosphate 17 (Eleršek & Filipič, 2011)

Figure 2.4 Insecticide resistance evolution in dengue vectors 20 (Khan Academy, 2018).

Figure 2.5 Insecticide resistance mechanisms in mosquito 21 (Nkya et al., 2013).

Figure 2.6 The schematic diagram showing the point mutation occuring 23 in the voltage gated sodium channel gene of Ae. aegypti.

Figure 3.1 Map of Penang Island and the sampling sites. 33 Figure 3.2 The red box shows the location of sampling at Jelutong (JG) 33

Figure 3.3 The red box shows the location of Sg. Ara (SA) 34

Figure 3.4: The red box shows the location of Balik Pulau (BP) 34

Figure 4.1 Image of PCR Species Identification by using two-steps 56 PCR

Figure 4.2 Identified mosquito from genus Aedes with 700 bp by using 61 100bp and 1kb DNA ladders

Figure 4.3 Identified species of Aedes. Lane (2-5) Aedes aegypti, Lane 61 6-9 Aedes albopictus.

Figure 4.4 The protein sequenced alignment of domain III segment 6 62 VGSC gene of Ae. aegypti.

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Figure 4.5 The protein sequenced alignment of domain II segment 6 63 VGSC gene of Ae. aegypti.

Figure 4.6 Showing the direct sequencing chromatogram of S989P 63 mutation

Figure 4.7 Showing the direct sequencing chromatogram of F1534C 64 mutation

Figure 4.8 The haplotype network of F1534C mutation in the partial 69 sequence of DIII VGSC gene Aedes aegypti.

Figure 4.9 The haplotype network of S989P mutation in the partial 70 sequence of DII VGSC gene Aedes aegypti.

Figure 4.10 The protein sequenced alignment of Ace-1 gene of 71 Aedes aegypti.

Figure 5.1 Mean optical density of Aedes aegypti from SA, JG, BP 88 and VCRU strain following the microplate enzyme

assays for MFO enzyme.

Figure 5.2 Mean optical density of Aedes aegypti from SA, JG, BP 92 and VCRU strain following the microplate enzyme assays

for EST.

Figure 5.3 Mean oxidases level among non-exposed Aedes albopictus 94 strains.

Figure 5.4 Mean optical density of Aedes albopictus from SA, JG, BP 97 and VCRU strain following the microplate enzyme assays for

EST.

Figure 5.5 Relative fold-change of candidate genes in Aedes aegypti from 99 qRT-PCR

Figure 5.6 Relative fold-change of candidate genes in Ae. albopictus from 100 qRT-PCR

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LIST OF PLATES

Page Plate 3.1 Showing a tray containing larvae of Aedes mosquitoes 36 Plate 3.2 Showing a cage containing adult Aedes mosquito 36 Plate 5.1 The colour formation observed in the well of the 87

elisa microplate tested for the presence of MFO enzyme.

Plate 5.2 The colour formation observed in the well of the elisa 89 Microplate tested for the sensitivity of AchE enzyme

when inhibited by propoxur.

Plate 5.3 The colour formation observed in the well of the elisa 91 microplate tested for the sensitivity of EST enzyme.

Plate 5.4 The colour formation observed in the well of the elisa 93 microplate tested for the presence of MFO enzyme.

Plate 5.5 The colour formation observed in the well of the elisa 95 microplate tested for the sensitivity of AchE enzyme

when inhibited by Propoxur.

Plate 5.6 The colour formation observed in the well of the elisa 96 microplate tested for the sensitivity of EST enzyme.

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LIST OF ABBREVIATIONS

Ach Acetylcholine

AchE Acetylcholinesterase Ace-1 Acetylcholinesterase 1

BP Balik Pulau

BPNE Balik Pulau Non-exposed BPR Balik Pulau Resistance

BPS Balik Pulau Susceptible

Bti Bacillus thuringiensis israelensis

CB Carbamate

cDNA complementary DNA

CHIKV chikungunya virus

CYP450 cytochrome P450

DHF Dengue haemorrhagic fever

DNTP Deoxynucleotide Triphosphate

DTNB 5.5’-Dithio-Bis (2- NItrobenzoic Acid)

EST Esterase

F0 Fillial 0

F1 Fillial 1

GABA Gamma-aminobutyric acid

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gDNA genomic DNA

GST glutathione-S-transferase

IGR insect growth regulator

ITS internal transcribe spacers

JE Japanese encephalitis

JG Jelutong

JGNE Jelutong Non-exposed

JGR Jelutong Resistance

JGS Jelutong Susceptible

kdr knockdown resistance

KdT Knockdown Time

MFO mixed function oxidase

MOH Ministry of Health

OD optical density

OP Organophosphate

OR odd ratio

P. Poecilia

PCR Polymerase chain reaction

PY pyrethroid

qPCR real-time polymerase chain reaction

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Rdl resistance to Dieldrin

RFLP restriction fragment length polymorphisms

RNA ribonucleic acid

RR resistance ratio

SA Sungai Ara

SANE Sungai Ara non-exposed

SAR Sungai Ara resistance

SAS Sungai Ara susceptible

TMBZ 3,3’5,5’-Tetramethylbenzidine USM Universiti Sains Malaysia

ULV ultra low volume

VCRU Vector Control Research Unit VGSC Voltage-gated sodium channel

WHO World Health Organization

ZIKV Zika Virus

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MENYIASAT MEKANISME KERINTANGAN RACUN SERANGGA DALAM POPULASI VEKTOR DENGGI; Aedes aegypti DAN Aedes albopictus

DI PULAU PINANG

ABSTRAK

Di Malaysia, vektor penyakit arbovirus terutamanya Aedes aegypti dan Ae.

albopictus telah lama dikenali sebagai vektor yang boleh menyebarkan virus denggi.

Pada masa ini, kawalan kimia dianggap sebagai cara yang paling berkesan untuk mengawal vektor denggi di dalam kawasan wabak denggi. Walau bagaimanapun, pergantungan melampau terhadap kawalan kimia telah menyebabkan perkembangan terhadap kerintangan racun serangga di dalam vektor denggi akibat kehadiran mekanisme kerintangan racun serangga. Kajian ini mengetengahkan status kerentanan vektor denggi yang terdedah kepada racun serangga permethrin dan malathion melalui ujian bioasai nyamuk dewasa WHO. Mekanisme kerintangan racun serangga yang terlibat dalam vektor denggi dengan menumpukan kepada mekanisme tapak sasaran melalui penjenisan gen voltage gated sodium channel (VGSC) dan gen Acetylcholinesterase (Ace-1) dikenal pasti melalui asai tindak balas berantai polymerase (PCR). Kehadiran mekanisme kerintangan metabolik di dalam sampel vektor denggi dari kawasan Sungai Ara (SA), Jelutong (JG), dan Balik Pulau (BP) di Pulau Pinang telah dikenal pasti melalui ujian biokimia dan PCR kuantitatif (qPCR).

Kajian kerentanan racun serangga menunjukkan bahawa sampel Ae. aegypti dewasa dari kawasan SA, JG, dan BP adalah rintang terhadap permethrin 0.25% dan 0.75%, manakala Ae. aegypti dari semua kawasan pensampelan didapati rentan kepada malathion 5%. Mutasi F1534C dan S989P didapati pada sampel Ae. aegypti yang diuji

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dari semua kawasan pensampelan yang dipilih tetapi tiada korelasi diperhatikan antara fenotip dan genotip rintang di setiap individu Ae. aegypti. Dalam kajian ini, kehadiran kedua-dua kerintangan tapak sasaran dan metabolik dapat dilihat pada sampel Ae.

aegypti dari JG. Sampel Ae. aegypti dari JG dikesan mempunyai gabungan mutasi F1534C, peningkatan dalam enzim oksidasi fungsi campuran (MFO) dan peningkatan regulasi gen CYP9J32. Ujian bioasai pada sampel Ae. albopictus dari semua kawasan penyampelan yang terdedah kepada permethrin 0.75% menunjukkan status kerentanan yang tinggi. Berbeza dengan Ae. aegypti, Ae. albopictus dari SA dan JG didapati rintang terhadap malathion 5%. Walau bagaimanapun, tiada mutasi dikesan pada gen tapak sasaran di dalam sampel yang diuji dari semua kawasan. Peningkatan dalam peratus AchE selepas perencatan oleh propoxur dan kehadiran CYP6N3 dalam sampel Ae. albopictus yang tidak terdedah mungkin menyumbang kepada kerintangan Ae. albopictus terhadap OP. Kajian ini mededahkan bahawa status kerentenan vektor denggi terhadap racun serangga permethrin dan malathion tidak semata-mata bergantung kepada mekanisme kerintangan gen tapak sasaran, tetapi mekanisme rintangan jenis lain seperti mekanisme rintangan detoksifikasi metabolik juga boleh memainkan peranan dalam menyebabkan rintangan permethrin dan malathion dalam sampel vektor denggi dari SA, JG dan BP. Oleh itu, pengurusan kerintangan racun serangga perlu dilakukan untuk mengelakkan keadaan yang lebih teruk di dalam kawasan wabak denggi akibat perkembangan kerintangan racun serangga terhadap racun yang digunakan di dalam program kawalan vektor.

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INVESTIGATING INSECTICIDE RESISTANCE MECHANISMS IN DENGUE VECTORS POPULATION; Aedes aegypti AND Aedes albopictus IN

PENANG ISLAND

ABSTRACT

In Malaysia, the vector of arboviral diseases especially Aedes aegypti and Ae.

albopictus has long been known as a vector that could transmit dengue viruses.

Currently, chemical control is considered as the most efficient way to control the dengue vectors in the dengue outbreak areas. However, the heavy reliance on chemical control has resulted in the development of insecticide resistance in the dengue vectors due to the presence of insecticide resistance mechanism. This study highlights the susceptibility status of both dengue vectors exposed to permethrin and malathion insecticides via WHO adult mosquito bioassay test. The mechanisms involved in the insecticide resistance of dengue vectors by focusing on target-site resistance mechanism via genotyping the voltage gated sodium channel gene (VGSC), and Acetylcholinesterase gene (Ace-1) have been identified via polymerase-chain reaction (PCR) assays. The presence of metabolic resistance mechanisms has been investigated through biochemical enzyme assays and quantitative PCR (qPCR) in the samples of dengue vectors collected from Sungai Ara (SA), Jelutong (JG) and Balik Pulau (BP) areas of Penang Island. The insecticide susceptibility study showed that the adult Ae.

aegypti samples from SA, JG and BP were resistant towards permethrin 0.25% and 0.75%, while the Ae. aegypti from all three sampling areas were susceptible towards malathion 5%. The F1534C and S989P mutation were found in the tested Ae. aegypti samples from all selected sampling areas but no correlation was observed between

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resistant phenotype and genotype in Ae. aegypti individuals. In this study, the presence of both target-site and metabolic resistance mechanisms could be observed in the Ae.

aegypti samples from JG. The samples of Ae. aegypti from JG were detected to have F1534C mutation, elevation in the mixed function oxidase enzyme (MFO) and the upregulation of CYP9J32 gene. The bioassay test on Ae. albopictus samples from all three sampling areas which was exposed to permethrin 0.75% showed a high susceptibility status. In contrast to Ae. aegypti, the Ae. albopictus from SA and JG was found to be resistance towards malathion 5%. However, no mutation in target- site gene were detected in the tested samples of Ae. albopictus from all areas. The elevated level in the percentage of AChE after propoxur inhibition and the presence of CYP6N3 in the non-exposed samples of the Ae. albopictus might contribute to the developing resistance of Ae. albopictus towards OP. Based on this research, it reveals that the susceptibility status of dengue vectors towards permethrin and malathion insecticides does not solely dependent on target-site gene resistance mechanism, however other type of resistance mechanisms such as metabolic detoxification resistance mechanism might also play role in causing the permethrin and malathion resistance in dengue vectors samples from SA, JG and BP. Therefore, a proper insecticide resistance management must be done to avoid a worse situation in the dengue outbreak areas due to the development of insecticide resistance towards the insecticide used in the vector control programmes.

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1 CHAPTER 1

GENERAL INTRODUCTION

Dengue is the most important arthropod-borne virus disease infecting humans worldwide namely in tropical, subtropical and temperate areas (Murray et al., 2013).

Previously, dengue fever is primarily known as an urban disease in tropical and subtropical areas, however, nowadays it has spread into rural areas (Vong et al., 2010).

The dengue virus is carried by mosquitoes particularly from the species of Aedes aegypti and Ae. albopictus. The main vector for dengue transmission is Ae. aegypti, meanwhile the Asian tiger mosquito, Ae. albopictus is the secondary vector that could transmit the dengue virus. Ae. aegypti or known as yellow fever mosquito originates from sub-Saharan Africa whereby their immature stages lived in tree-holes (Powell &

Tabachnick, 2013). The oviposition sites of Ae. aegypti has also been recorded in several types of natural habitats such as rock hole, leaf axils and tree holes (Chadee et al., 1998). This also shows the Ae. aegypti has a wide adaptability by being able to lay their eggs in both natural and man-made container such as in plastic containers and coconut shells or husks in rural areas (Basari et al., 2016; Chareonviriyaphap et al., 2003). Meanwhile, the secondary vector of dengue virus, Aedes albopictus originated from Southeast Asia, and spread to the islands of the Western Pacific and the Indian Ocean (Delatte et al., 2009).

The dengue virus transmitted by these two dengue vectors belong to the genus flavivirus in the family Flaviviridae which has four strains known as DENV-1, DENV-2, DENV-3 and DENV-4 (Guzman et al., 2010). The recent findings on DENV-5 virus which is only found in Sarawak and only found circulating in the sylvatic cycle particularly amongst the non-human primates is believed to be limited

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to the forest canopies of Southeast Asia (Mustafa et al., 2015). A person who gets infected with any four of the dengue virus will have a lifelong immunity to that specific serotype (Murray et al., 2013). However, the infections with one specific serotype would not results in the cross-protective immunity against other serotypes (Gubler & Clark, 1995). Secondary infection by another serotype of dengue virus would cause a severe form of dengue diseases such as dengue haemorrhagic fever due to immune enhancement (Peeling et al., 2010). Other than dengue virus, the recent Zika outbreak in Latin and South America indicates that the Ae. aegypti are also capable in transmitting the Zika virus (Sikka et al., 2016).

Figure 1.1: Global Map of Dengue Fever, 2014 (Guzman & Harris, 2015).

The global expansion of international trade and travel has increased the distribution of Ae. aegypti and Ae. albopictus (Kraemer et al., 2015). Aedes aegypti is widely distributed in tropical and subtropical regions of Asia, Africa, Southern United States, Northern Australia and the Indian Ocean Islands. Meanwhile, Ae. albopictus which originated from Southeast Asia is now present in United States, Northern Australia and some countries in Africa and Europe (Medlock et al., 2012). However, the countries located in tropical and subtropical regions such as in the South-East Asia and Western Pacific Regions are severely affected by dengue fever disease

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(Thisyakorn & Thisyakorn, 2015; WHO, 2009). Historically, the severe form of dengue cases such as dengue haemorrhagic fever (DHF) is first recognized in a few Asian countries such as Phillipines and Thailand starting from the year of 1950s (WHO, 2017a).

In Malaysia, the dengue cases were first reported in the year of 1901-1902 from Penang Island (Skae, 1902). The dengue incidence has continued to increase since 2001 until 2014 due to the uncontrollable factors such as environmental conditions, human behavior, rapid urbanization and also international travel (Mudin, 2015). Recent evidence also shows that insecticide resistance in Malaysian dengue vectors might play a role in the increasing cases of dengue fever (Hasan et al., 2016).

In the mid of 2017, the dengue cases in Malaysia showed a reduction with 43,807 cases compared to the mid of 2016 with 52,185 cases (WHO, 2017b).

In order to control the Aedes mosquito from transmitting the dengue virus, several vector control strategies such as environmental management by modification of building design such as firstly by modifying the house-design that would eliminate the potential breeding habitat e.g eliminate roof gutters and installing mosquito screen on windows and doors (Zainon et al., 2016; Montgomery & Ritchie, 2002).

Furthermore, the cracks and crevices that would allow the mosquito to enter the house and at the same time laying the eggs have to be sealed (McCall et al., 2009). Secondly, environmental sanitation by improving solid waste management, and biological and as well as chemical control of Aedes has to be strictly implemented so that an effective vector control management could be achieved (McCall et al., 2009; Kumarasamy, 2006). Currently in Malaysia, several vector control strategies have been taken into place such as for larval control; sources reduction, usage of Abate larvicides, house

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inspections, enforcement of Destruction of Disease-bearing Insect Act 1975 and environmental management (Ong, 2016). Meanwhile for adult control, fogging activities such as thermal fogging by using Organophosphate in fuel oil or ultra-low volume (ULV) fogging were carried out once a dengue case occurs and the health authority is notified as it could rapidly reduce adult Aedes mosquitoes in the dengue outbreak areas (Ruhil Amal et al., 2011; Lam, 1994). However, the frequent usage of the same classes of chemical insecticides in the fogging activities and larvicides has allowed or increase the chances of insecticide resistance to develop in the targeted dengue vectors.

Generally, insecticide resistance is caused by the insensitivity of an insect population to an insecticide (Insecticide Resistance Action Committee, n.d). This is reflected in the repeated failure of vector control programme when the same classes of chemical insecticides are being used in the control programme. Insecticide resistance in dengue vectors primarily in Aedes aegypti is widespread due to the over- reliance of chemical control used by the public health sectors or the authority (Chanda et al., 2015). Insecticide rotations, mixtures and mosaics have to be implemented to reduce the insecticides resistance problem in the dengue vectors (Hemingway &

Ranson, 2000).

In Malaysia, a few cases of insecticide resistance in dengue vectors has been reported. In the major city such as Kuala Lumpur, resistance profiles show that Ae.

aegypti and Ae. albopictus has developed resistance to pyrethroid (permethrin and deltamethrin), while in a recent study reported that the Ae. albopictus population from a few selected hotspot dengue areas in Kuala Lumpur have a full susceptibility when exposed to permethrin 0.75% (Ishak et al., 2015; Wan-Norafikah et al., 2013).

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Furthermore, both of Ae. aegypti and Ae. albopictus populations from Penang, Kuala Lumpur and Johor Bharu also shows resistance when exposed to carbamate (bendiocarb), meanwhile both Ae. aegypti and Ae. albopictus populations from Kuala Lumpur shows resistance when exposed to organophosphate (Malathion) (Ishak et al., 2015). The development of insecticide resistance in dengue vector is a serious threat to an effective and sustainable vector control programs (WHO, 2014). Insecticides resistance mechanisms such as the alteration in the target-site of the gene and the increase in the detoxification rate of metabolic enzymes are the major insecticide resistance mechanisms involved in the insecticides resistance of dengue vectors (Ranson et al., 2010). Thus, an effective vector control program is important to reduce the number of dengue vectors and at the same time to reduce the amount of human- vector contact. This study is conducted to identify the underlying resistance mechanism of dengue vectors in Penang Island, Malaysia.

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6 1.1 Research Objectives

1) To assess the susceptibility status of Aedes aegypti and Ae. albopictus in Penang Island against permethrin and malathion insecticides used by the Ministry of Health.

2) To identify the main target-site mechanisms associated with the insecticide resistance in Aedes aegypti and Ae. albopictus.

3) To investigate the metabolic resistant mechanisms involved in Aedes aegypti and Ae. albopictus.

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7 CHAPTER 2 LITERATURE REVIEW

2.1 Mosquito classification

Generally there are more than 3400 species of mosquitoes worldwide (Khatik et al., 2014). Mosquito is an arthropod from the order Diptera, suborder Nematocera and family Culicidae (Reinert, 2009). It can be divided into three subfamilies known as Anophelinae, Culicinae and Toxorhynchitinae (Jeffery et al., 2012). The Anophelinae comprises of 430 species with 30 to 40 species are known to be vectors of malarial parasites (Aina et al., 2009). The Culicinae comprises of 3046 species of mosquitoes. The most important species of mosquitoes that can acts as a vector belonging to the genera Anopheles, Culex, Aedes, Ochlerotatus, Psorophora, Haemagogus and Sabethes (Kalaivani et al., 2012). The Anopheles is a vector for malaria and filariasis, Culex is a vector for filariasis and Japanese Encephalities (JE), meanwhile both of Aedes aegypti and Aedes albopictus from the Subfamily Culicinae are the highlighted species in this research as these two species are the main vector for dengue virus as well as yellow fever and chikungunya (Kovendan et al., 2012). In 2016, Zika virus which is known to be transmitted by Ae. aegypti has become epidemic in 18 countries including several regions in America (Ai & Zhang., 2016).

2.2 Morphology of Aedes mosquitoes

The adult stage of Ae. aegypti and Ae. albopictus is easy to recognize especially by observing their morphological characteristics under the stereo microscope with the help of identification keys. The general distinct morphology that distinguishes between the adult of Ae. aegypti and Ae. albopictus is their

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scales on the scutum (Figure 2.1). The Ae. aegypti regardless of male or female has a pair of white lyre-shaped scales on their scutum. Their scutum also has a pair of longitudinal white line scales in between of the white lyre-shaped scales (Andrew & Bar, 2013). The Ae. aegypti also has two separated patches of white scales on the mesepimeron. The clypeus of Ae. aegypti has white scales, whereas the anterior surface of their midfemur has a longitudinal white stripe. Meanwhile, the adult of Ae. albopictus regardless of male or female has a median-longitudinal white scale on their scutum. The white scale patches on mesepimeron of Ae.

albopictus are not separated. The Ae. albopictus also has a clypeus without white scales, and the anterior surface of their midfemur has no longitudinal stripe (Rueda, 2004).

Figure 2.1: The white scales on the scutum of Aedes aegypti and Aedes albopictus (Rueda, 2004).

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9 2.3 Distribution of Aedes

2.3.1 Aedes aegypti Linnaeus

The Ae. aegypti (Linnaeus) (Stegomyia aegypti) mosquito originated from Africa where their original habitat is from the forested area. However, the species has developed an adaptation to live in the peridomestic environment of the urban and suburban area (WHO, 2011). Most females of Ae. aegypti spends their adult life time in or around the houses. The females of Ae. aegypti prefers to rest in bedrooms which is not the same for male Ae. aegypti (Perich et al., 2000). Both male and female Ae.

aegypti prefers to rest indoor. Normally, the Ae. aegypti which is also known as endophilic mosquito tends to rest indoors and at distance of more than 6m from the street (Perich et al., 2000). This behaviour will reduce the efficacy of space spray such as thermal fogging due to fewer insecticide droplets may reach the Ae. aegypti resting place (Mount, 1998 & Lofgren, 1972).

2.3.2 Aedes albopictus Skuse

Ae. albopictus (Skuse) (Stegomyia albopicta) which belongs to the Scutellaris group of the subgenus Stegomyia is also well known as a secondary vector for dengue fever and dengue haemorrhaegic fever (WHO, 2011). Aedes albopictus is known to have less adaptation to urban environment and is less anthropophilic compared to Ae.

aegypti (Rezza, 2012). It originates from the South-East Asia, islands of the Western Pacific and the Indian Ocean (WHO, 2011). It has spread from the South-East Asia to Europe, the Middle East, Africas and Americas over the past 30 years (Kaufmann et al., 2013). Their habitat can be found within urban and suburban areas, peri rural as well as forested area. It breeds in containers containing water such as tyres, vases and tin can (Knudsen, 1995). The Ae. albopictus was more likely to breed and transmit

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dengue virus outside the building and it could normally be found in semi urban and rural areas (Ali et al., 2003). The eggs of Ae. albopictus could withstand the dry season and cold temperature during the winter in temperate region by becoming dormant (Hanson & Craig, 1995).

Figure 2.2: Global distribution of Aedes aegypti and Aedes albopictus (Campbell et al., 2015).

2.4 Medical Importance of Aedes 2.4.1 Vectors of dengue fever

Dengue is found in tropical and subtropical regions worldwide (WHO, 2011). The primary dengue vector is Ae. aegypti, meanwhile the Asian tiger mosquito, Ae.

albopictus is known as the secondary vector of dengue viruses. The dengue viruses which comprises of 4 virus serotypes known as DENV-1, DENV-2, DENV-3 and DENV-4 of the genus flavivirus and family flaviviridae are spread by both of Ae.

albopictus and Ae. aegypti (WHO, 2011). Patient who is infected with one of the virus serotypes will get a lifelong immunity to that serotype. However, if the secondary infection occurs, the patient will obtain a severe form of dengue such as dengue

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haemorrhagic fever or dengue shock syndrome. Patient who suffers from the dengue haemorrhagic fever will have symptoms such as fever, abdominal pain, vomiting, bleeding and breathing difficulty (Teixeira & Barreto., 2009).

2.4.2 Vectors of chikungunya

Chikungunya virus (CHIKV) is the virus that is responsible for the chikungunya fever. The CHIKV virus is from the genus of Alphavirus and family Togaviridae. The first recorded outbreak of chikungunya virus was in Tanzania, Africa in the year of 1952. In Africa, the virus is believed to be circulating in the sylvatic cycle of Aedes spp. mosquitoes among a group of reservoir hosts such as African green monkey (Chlorocebus sabeus), patas monkeys (Erythrocebus patas), and Guinea baboon (Papio papio) (Diallo et al., 2012). In Asia, Chikungunya virus is transmitted by Ae. aegypti and Ae. albopictus and the virus is often transmitted to the humans residing in urban areas (Thiboutot et al., 2010). The person who are infected with the chikungunya virus often have symptoms such as fever, headache, severe joint pain, rashes and lymphadenitis (Chua, 2010). In Malaysia, the first infection of CHIKV is recorded in the year of 1998-1999 in Port Klang which affected more than 51 people followed by the outbreak in Perak in the year of 2006 (Apandi et al., 2009).

The outbreak of the chikungunya virus involving more than 10000 cases with one death has occurred between April 2008 until March 2010 in Malaysia (Sam et al., 2010).

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12 2.4.3 Vectors of Zika

Zika virus (ZIKV) is a virus from the family of flaviviridae. It was first discovered in 1947 in the Zika Forest in Uganda. It is believed to have a sylvatic cycle as it was isolated from both a sentinel rhesus monkey and Aedes africanus mosquitoes (Howard, 2016). In Malaysia, the ZIKV is isolated from the Ae. aegypti mosquitoes (Hayes, 2009). Recently, the ZIKV infection has been associated with microcephaly and other neurological disorders. In the outbreak of ZIKV in French Polynesia in the year of 2013-2014, the neurological disorder such as Guillain-Barré syndrome has been linked with the Zika virus infection (Kindhauser et al., 2016).

2.5 Vector control and management

Preventing the transmission of the dengue virus from spreading across the region depends entirely on the control of the mosquito vectors to reduce the human- vector contact. A few control measures could be taken to prevent the dengue virus from continuously spreading. The steps are physical control, biological control and chemical control.

2.5.1 Physical Control

Physical control such as by having a good environmental management is the key factor that leads to the major reduction of dengue vectors. This is because the dengue vector; Ae. albopictus and Ae. aegypti prefers to breed in the water container such as clogged drain, leftover tin can, abandoned tyres or plastic bottles containing water. Source reduction by clean-up campaigns, regular container cleaning and emptying, installation of water supply systems, solid waste management and urban planning are important elements in the environmental management that must be taken seriously by the responsible authorities and also the public (Guzman et al., 2010).

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Furthermore, the community engagement activities through active involvement of the community in vector control interventions via having routine dengue control measures would help to rapidly reduce the dengue vectors (Lin et al., 2016).

Furthermore, physical control of immature stages of Aedes by using the monomolecular film (polydimethylsiloxane) has proven to be effective in controlling immature stages of mosquitoes. The ability of the Aquatain AMF to spread throughout the water surface by forming a thin film on the surface and reduce the surface tension will eventually suffocate the larvae and drown them to the bottom of the container (Mbare et al., 2014).

2.5.2 Biological Control

Biological control is the use of natural enemies to reduce the number of pest organism (Holmes et al., 2016). In the field, larvivorous fish are used to control the immature stages of mosquito populations. The larvivorous fish used in mosquito control should be able to withstand drought, able to live in either deep or shallow water, having small body size and also able to live in water containers such as water tanks without contaminating the water (Chandra et al., 2008). The most effective larvivorous fish for the control of mosquitoes immature stage are from the family of Poeciliidae, Cyprinidae, Cyprinodontidae and Chichlidae (WHO, 2003b). In Malaysia, the effectiveness of Poecilia reticulata from the family Poeciliidae as the biocontrol agent for the dengue vectors have been studied. The results from the studies showed that the female Poecilia reticulata has the highest rate of predatory on Ae.

aegypti with the highest density in daily feeding rate of 121.3 larvae per day while 105.6 larvae per day for Ae. albopictus (Saleeza et al., 2014). Furthermore, the P.

reticulata or commonly known as the South African guppy has a well-developed

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tolerance with water of high temperature, organically polluted water and it can also live in domestic water storage containers (Saleeza et al., 2014). Besides the larvivorous fish, the larvae of Toxorhynchites spp. can also be used as the natural predator for immature stages of Ae. aegypti and Ae. albopictus. The Toxorhynchites splendens and Toxorhynchites amboinensis have similar breeding habitat preference with the Ae. aegypti and Ae. albopictus which is the artificial container (Steffan &

Evenhuis, 1981). Thus, it could effectively be used as the natural biocontrol agent as they have similar breeding habitat.

Microbial larvicides such as the Bacillus thuringiensis H-14 and Bacillus sphaericus are widely used in vector control programmes to eliminate the dengue vectors in their immature stages. The Bacillus thuringiensis var israelensis (Bti) produced protoxins crystals that could cause mortality of the targeted organisms that ingested the Bti (Araújo et al., 2013). Microbial larvicides could be an alternative in controlling the immature stages of dengue vectors if the mosquito larvae have developed resistance towards the commonly used larvicides such as temephos (Yap et al., 1994). A study conducted in Malaysia by using Bti (VectoBac WG) showed a significant reduction in the ovitrap index of both of Ae. aegypti and Ae. albopictus in the treated sites compared to the untreated sites (Tan et al., 2012).

Furthemore, Wolbachia is another biological based method that could be used in the vector control programme. Wolbachia is a gram-negative intracellular bacterium that could naturally be found in Ae. albopictus (Joanne et al., 2014).

Wolbachia is known for its ability to alter the host reproductivity through cytoplasmic incompatibility (Afizah et al., 2015). A study conducted in Australia showed that the Wolbachia-infected mosquitoes is able to block the dengue virus from replicating thus enable it to be a good biological control technique (Frentiu et al., 2014). In Malaysia,

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the laboratory Wolbachia-infected Ae. aegypti had been released in March 2017 in Keramat area which is situated in Klang Valley and followed by Shah Alam to curb the dengue virus transmission problems (Azil et al., 2018).

2.5.3 Chemical control

Larviciding and adulticiding mosquitoes by using chemical is another option to control the vectors of dengue. Larvicides are the product used to kill mosquitoes at their immature stages while adulticide is used to kill the adult mosquito. Chemical larvicides such as temephos from the group of organophosphates with the trade name of Abate 1-SG™ and Abate 500 EC™ are used by the public health practitioners to control the dengue vectors. Abate 1-SG™ is in granular form, whereas Abate 500EC™ is an emulsifiable concentrate formulation (Lee et al., 2015). The temephos is an organophosphorus compound that is safe, effective and easy to use as larvicides.

It also has a low mammalian toxicity, thus, would not be harmful to human if we consumed the water containing Abate (Edward & Sogbesan, 2007). In Malaysia, the Abate 1-SG™ in granular forms are easily accessible to public (Lam, 1994). The public is encouraged to put the Abate 1-SG™ into large water storage located in their housing compound. Meanwhile, the Abate 500EC™ can be used as both adulticide and larvicide as it usually used as a space-sprayed insecticide (Lee et al., 2015). As a biolarvicide, the insect growth regulator, (IGR) such as pyriproxyfen is also effective in controlling the immature stages of mosquito. The pyriproxyfen will delay the rate of larval development and at the same time will inhibit the pupal emergence. Previous study by using Ae. aegypti showed that the pyriproxyfen shows 100% mortality when tested against larvae of Ae. aegypti except for pupal stage with only 1.5-7.8%

mortality (Wang et al., 2013).

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The adulticide from the class of pyrethroid and organophosphate are normally used in the space spray treatment during fogging activities (Table 2.1). In Malaysia, the thermal or cold fogging via Ultra Low Volume (ULV) machine is carried out at dengue outbreak areas by using insecticides from the class of organophosphate and pyrethroid with the active ingredients such as malathion, pirimiphos-methyl and s- bioallethrin (Ong, 2016; Omar et al., 2011).

Table 2.1: Insecticides for space spray treatment (Ong, 2016).

Product name Active ingredient(s)

Malathion malathion

Sumithion fenitrothion

Bayetex fenthion

Resigen s-bioallethrin + permethrin + piperonyl butoxide

Pesguard d-tetramethrin + cyphenothrin

Gokilat cyphenothrin

Actellic primiphos-methyl

Abate temephos

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2.6 Insecticide Classification and Mode of Action

Insecticides could be classified into different classes with different modes of action. Generally, there are several classes of insecticides. In Malaysia, the insecticides mainly used by Public Health operators are usually from the class of organophosphate and pyrethroid.

2.6.1 Organophosphate

Organophosphate (OP) is a class of insecticide widely used around the world in both agriculture and public health sector. OP is an ester or thiols derived from phosphoric acid (Figure 3) (Balali-Mood & Saber, 2012). OP is highly toxic to vertebrate animals and it is also usually used as a poison to kill targeted insect pest (Costa et al., 2008). OP inhibits AChE activity and causes the accumulation of ACh at the synaptic cleft resulting in over stimulation of the ACh receptors (Costa et al., 2008).

Figure 2.3: General structure formula of organophosphate (Eleršek & Filipič, 2011).

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18 2.6.2 Pyrethroid

Pyrethroid is a synthetic insecticide that was developed to improve the efficacy of pyrethrins. Pyrethrin is an active organic compund derived from the flowers of Chrysanthemum cinerariaefolium or Pyrethrum cinerariaefolium and this organic compound is found in the Pyrethrum extracts (Ensley, 2012). Pyrethroid has a similar chemical structure with pyrethrins, but pyrethroids are more toxic to insects and more stable in the environment depending on the type of soil and species of microbes that will help with pyrethroid degradation process (Mueller-Beilschmidt, 2009).

Pyrethroid is an insecticide recommended by World Health Organisation (WHO) for the treatment of insecticidal materials against mosquitoes of the public health importance due to its strong efficacy while using at a low dose, fast killing effect and relatively low cost of production (Bonnet et al., 2009). Pyrethroid is a non-biomagnify insecticide in which they have low water solubility and strongly absorbed to soil particles (Smith & Stratton, 1986). Pyrethroids are effective against agricultural insect’s pest and urban pest (Nauen, 2007). Most pyrethroid is used by public health personnel in Ultra Low Volume (ULV) spray for mosquito control (Esu et al., 2010).

Furthermore, pyrethroids are known as neurotoxicants because they act directly on excitable membranes (Perger & Szadkowski, 1994). Pyrethroids also causes prolongation of the sodium current thus causing repetitive activity in the nerve fibres of insect (Vijverberg et al., 1982).

2.6.3 Organochlorine

Organochlorine is a synthetic pesticide which belong to the group of chlorinated compounds (Jayaraj et al., 2016). Organochlorine insecticides such as dichlorodiphenyltrichloroethane (DDT) is highly persistence in environment with the

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half-life of 2-15 years (Augustijn-Beckers et al., 1994). Due to its low cost and faster killing effects compared to the other classes of insecticides, DDT has been widely used as a pesticide in the agriculture and vector control programmes to eradicate the insect pest (Davies et al., 2007). The presence of DDT insecticide would normally interfere the peripheral nervous system by causing repetitive firing of the neurons.

The interference in the peripheral nervous system would likely result in the death of the insects due to the muscle spasms (Davies et al., 2007). In the year of 1998, the Vector Borne Disease Control Programme in Malaysia has replaced DDT insecticide with pyrethroid to eliminate the malaria vectors (Rohani et al., 2014). The usage of DDT in both of agricultural and vector control has been banned due to its deteriorating effects to the non-targeted organisms and persistence in the environments (Davies et al., 2007).

2.6.4 Carbamate

Carbamate is an ester derived from the organic compound called as carbamic acid (Jayaraj et al., 2016). Carbamate insecticide such as propoxur is known to have similar mode of action with organophosphate (Gupta et al., 2017). The carbamate insecticides such as propoxur and bendiocarb will inhibit the AChE resulting in the accumulation of the ACh neurotransmitter at the nerve synapse (Gupta et al., 2017).

Furthermore, the carbamate insecticide has been used as an indoor residual spray (IRS) against malaria (Van den Berg et al., 2012).

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20 2.7 Insecticide Resistance Mechanism

Resistance is defined as the ability of some individuals to tolerate doses of toxicant which would cause fatality to the other individuals in a normal population of the same species (Liu et al., 2006). The insecticide resistance in insects might occur due to the natural selection in the population (Mallet, 1989) (Figure 2.4). There are a few mechanisms that are involved in resistance such as behavioral resistance, metabolic detoxification, target-site insensitivity, and physiological resistance mechanisms (Figure 2.5). However, the two main mechanisms responsible for the insecticides resistance are target site insensitivity and increased metabolic detoxification of insecticides (Kamgang et al., 2017).

Figure 2.4: Insecticide resistance evolution in dengue vectors (Khan Academy, 2018).

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21 2.7.1 Behavioral resistance

Behavioral resistance is defined as the development of behaviors that reduce an insect’s exposure to toxic compounds or that allows an insect to survive in an environment that is harmful and/or fatal to the majority of insects of the same species (Liu et al., 2006). Stimulus-dependent and stimulus-independent are two types of behavioral resistance that normally occur in insects. The stimulus-dependent behavioral resistance includes both irritability and repellency (Liu et al., 2006). The Ae. aegypti has been reported to have stimulus-dependent behavioral resistant as contact irritancy was the major behavioral response of Ae. aegypti when it is exposed to Deltamethrin (Kongmee et al., 2004). Contact irritancy refers to an insect leaving the insecticides dealt with location solely after making a tarsal contact with the chemical (Chareonviriyaphap et al., 2013). Meanwhile, the stimulus-independent is an innate behaviour that naturally avoids the insecticide due to their natural ability to avoid the chemical exposure (Chareonviriyaphap et al., 2013).

Figure 2.5: Insecticide resistance mechanisms in mosquito (Nkya et al., 2013).

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22 2.7.2 Penetration resistance

The penetration/ cuticular resistance in insects exist by adjusting the thickness of cuticle or digestive track lining to avoid or delay the rate of insecticide’s penetration through the insect’s cuticle of the cuticular thickness (Ranson et al., 2011). The involvement of the cuticular resistance is proven in the resistant An. gambiae of West Africa whereby it has been found for possessing a thicker layer of cuticle when compared to the susceptible strain. Furthermore, it has also been reported to have an upregulated cuticle genes CPAP3-E, CPLCX1, CPLCG3 and CPRs (Yahouédo et al., 2017).

2.7.3 Target-site insensitivity

The target-site insensitivity refers to the ineffective binding of a given dose of insecticides due to the structural modification or point mutation of the target proteins that the insecticides binds to (Liu, 2012). The target site insensitivity usually occurs in voltage gated sodium channel gene (VGSC) conferring knockdown resistance (kdr), synaptic acetylcholinesterase gene (Ace-1) and the gamma-aminobutyric acid (GABA) receptor gene (Hemingway & Ranson, 2000).

2.7.3(a) Voltage gated sodium channel (VGSC) gene

The insensitivity of the sodium-channel is one of the major resistance mechanism involved in pyrethroid resistance and it is referred to as knockdown resistance (kdr) (Soderlund & Knipple, 2003). For Ae. aegypti and Ae. albopictus, the established target site mutations are found in the sodium channel with the association of pyrethroid and DDT resistance due to the alteration in the sodium channel structure resulting in the insensitivity of the sodium channel to the insecticides binding (Liu, 2015). The kdr mutation has been reported to occur in pyrethroid and DDT resistant

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insect populations across the globe. The VGSC gene of insects contain four domains which have six subunits each and connected by loops (Dong et al., 2014) (Figure 2.4).

There are several kdr mutations encoding VGSC gene in mosquitoes. In dengue vector such as Ae. aegypti, the mutation in domain II of VGSC gene involving S898P, I1011M/V, V1016G/I and in domain III which has the F1534C mutation is responsible for a few reported cases of insecticide resistance (Kawada et al., 2014; Saavedra‐

Rodriguez et al., 2007). Meanwhile the kdr mutation reported occurring in Ae.

albopictus is limited. A few studies reported that the kdr mutation encoded for F1534C have been reported in Brazil, Greece, India and Singapore (Rath & Hazra., 2018;

Aguirre-Obando et al., 2017; Xu et al., 2016; Kasai et al., 2011). However, none of the mutation is found in the Malaysian population of Ae. albopictus (Ishak et al., 2015).

Figure 2.6: The schematic diagram showing the point mutation occurring in the voltage gated sodium channel gene of Ae. aegypti. The numbering is based on the amino acid sequence in housefly sodium channel gene (Kasai et al., 2011).

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24 2.7.3(b) Acetylcholinesterase (Ace-1) gene

The target site responsible for the resistance towards organophospahate (OP) and carbamate (CB) is Acetylcholinesterase enzyme encoding Ace-1 gene (Menozzi, 2004). The point mutation alters the structure of Ace-1 gene resulting the insensitivity of the AchE towards OP and CB (Zhao et al., 2014). In mosquito, the most common Ace-1 gene mutation encoding for G119S position has been reported to occur in Anopheles gambiae, An. albimanus, An. coluzzii, and Culex pipiens (Weill et al., 2004;

Essandoh et al., 2013; Djogbénou et al., 2008 & Liebman et al., 2015). In Ae. aegypti, the synonymous mutation in Ace-1 gene encoding G448S and a silent mutation at the position T506T have been reported occurring in Ae. aegypti in India and Indonesia (Hasmiwati et al., 2018; Muthusamy & Shivakumar, 2015).

2.7.3(c) GABA receptor

The mutation in the RDL encodes the gamma-aminobutyric acid (GABA)

receptor gene is known to be associated with the resistance of insects to Dieldrin insecticides (Wondji et al., 2011). In Africa, the Rdl mutation encoding GABA receptor gene has been reported occurring in An. funestus due to having high resistance towards Dieldrin insecticide (Wondji et al., 2011). Furthermore, the Rdl mutation has also been detected in Ae. albopictus and Cx. quinquefasciatus mosquitoes in La Reunion Island (Tantely et al., 2010).

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