Degradation Of Pesticides (Dichlorvos and Lambdaccyhalothrin) In Artificially Contaminated Medium By Wood Rot Fungus, Fusarium Solani

Abstract

Pesticides are widely used in preventing and controlling the diseases and pests of crop, but at the same time pesticide residues have brought serious harm to human’s health and the environment. Hence their elimination from contaminated environmental sites is highly needful and bioremediation is the most convenient option because of its cost-effective and ecofriendly nature.

In this study, the ability of wood rot fungi to degrade pesticides in artificially contaminated medium was investigated to determine whether the fungi would be suitable for the bioremediation of the pesticides in soil. For bioremediation of Dichlorvos and Lambdaccyhalothrin. pesticides, fungal species isolated from decaying wood materials and identified using macroscopic and microscopic features were screened for pesticide degrading ability. Initially, the fungal isolates were inoculated into mineral salts medium with Dichlorvos and Lambdaccyhalothrin. pesticides as the sole source of carbon and incubated for 7days to assay the level of tolerance of these fungal isolates. Although all the fungal isolates were able to grow on pesticide modified-agar plates with high level of tolerance, only one isolate exhibited the highest tolerance for pesticides with great growth on the plates. The fungus with the best tolerance ability was identified by molecular sequencing. Blast result and phylogenetic analysis of nucleotide sequencing suggested that the isolate was closely related to Fusarium solani with 77% sequence identity. Screening of the isolate for its efficiencies in degrading Dichlorvos and Lambdaccyhalothrin. was carried out based on enrichment technique and spectrometric analysis. The fungal isolates were inoculated with each of the two pesticides at a concentration of 150 ppm for 20days. The biodegradation rate of the two pesticides on liquid media was determined using UV spectrophotometer. The results showed that the Fusarium solani isolate had a high efficiency to degrade Dichlorvos showing 66.7% degradation and Lambdaccyhalothrin. with 50.2% removal after the degradation period. Enzyme production (laccase, manganese peroxidase and lignin peroxidase activities) was quantified. Laccase activity ranged from a minimum of 1.62U/ml after 7days to a maximum of 1.90U/ml after 21days while MnP activity ranged from 0.051U/ml to 0.066U/ml. Maximum MnP activity was produced after 21days. LiP activity of the isolate ranged from 0.2 to 0.705U/ml with highest being produced after 21days. The results suggested that the test isolates have the ability to degrade different groups of pesticides, supported by the capacity for expression of a range of extracellular enzymes. Due to their high biodegradation activity, the fungus isolated from this work merit further study as potent biological agents for the remediation of soil or water contaminated with the pesticide Dichlorvos and Lambdaccyhalothrin.

TABLE OF CONTENTS

Title Page i

Declaration ii

Certification iii

Dedication iv

Acknowledgements v

Table of Contents vi

List of Tables ix

List of Figures xi

Abstract xiii

CHAPTER 1: INTRODUCTION

1.0 Introduction 1

1.1 Aims and Objectives 7

CHAPTER 2: LITERATURE REVIEW

2.1 Overview of Pesticides 8

2.2 Classification of Pesticides 12

2.3 Microbial degradation 14

2.4 Fungal involvement in biodegradation of pesticides 15

2.5 Soil contamination 16

2.6 Environmental concerns regarding the contamination with pesticides 17

2.7 Environmental factors affecting biodegradation by fungi 19

2.7.1 Temperature, oxygen and nutrient availability 19

2.7.2 Water availability 20

2.8 Biodegrading capabilities of Fungi 21

2.9. Effect of pesticide on soil microbes and plants 28

2.10 Principles of Pesticide Biodegradation 36

CHAPTER 3

3.0 MATERIAL AND METHODS

3.1 Study Site 46

3.2 Chemicals 46

3.3 Sample Collection 46

3.4 Isolation of Fungi from Cellulosic portion of wood 46

3.5 Identification and Characterization of Fungal Isolates 47

3.6 Viability of fungal Isolates to pesticide containing medium 47

3.7 Determination of the ability of Fungal Isolate to grow in pesticides

(dichlorvos and lamdaccyhalothrin) in Liquid Culture 48

3.8 Molecular Identification and characterization of isolate with best

Biodegradation Ability 48

3.8.1 DNA extraction 49

3.8.2 Gel electrophoresis 50

3.8.3 PCR reaction: amplification of DNA 50

3.8.4 DNA Sequencing 51

3.9 Biodegradation Assay of pesticides by Fusarium solani 51

3.10 Gas Chromatography of pesticides degradation by Fusarium solani 52

3.11 Determination of the Minimum Inhibitory concentration 54

3.12 Analysis of Crude enzymes activities involved in the degradation 54

CHAPTER 4: RESULTS AND DISCUSSION

4.0 Results and discussion 57

4.1 Isolation and characterization of the fungal isolates 57

4.2 Viability of fungal Isolates to Pesticides containing medium 59

4.3 Growth of the Fungal Isolate in pesticide containing medium 68

4.4 Molecular Analysis of Fusarium solani 73

4.5 Biodegradation of Pesticides by Fusarium solani 76

4.5.1 Biodegradation determined by Gas Chromatography 79

4.6 Results on Minimum inhibitory concentration 84

4.7 Crude Enzyme Activities 87

CHAPTER 5: CONCLUSION AND RECOMMENDATIONS 89

References 96

Appendices 110

LIST OF TABLES

TABLE

TITLE

PAGE

4.1

Macroscopic and Microscopic description of fungal Isolates

4.2a

Adaptation of Fusarium solani to dichlovos containing medium.

4.2b

Adaptation of Fusarium solani to Lambdaccyhalothrin containing medium

4.2c

Adaptation of Cladosporum specie to dichlovos containing medium

4.2d

Adaptation of Cladosporum specie to Lambdaccyhalothrin containing medium

4.2e

Adaptation of Penicillium specie to dichlovos containing medium

4.2f

Adaptation of Penicillium specie to Lambdaccyhalothrin containing medium

4.2g

Adaptation of Aspergillus fumigates to dichlovos containing medium

4.2h

Adaptation of Aspergillus fumigates to Lambdaccyhalothrin containing medium

4.3.1a

Biodegradation assay of Fusarium solani in PDA amended with pesticides

4.3.1b

Biodegradation assay of Cladosporum specie in PDA amended with pesticides

4.3.1c

Biodegradation assay of Aspergillus fumigates in PDA amended with pesticides

4.3.1d

Biodegradation assay of Penicillium specie in PDA amended with pesticides

4.4

Nucleotide sequence of Fusarium solani

4.5a

Percentage degradation of Lambdaccyhalothrin by Fusarium solani

4.5b

Percentage degradation of Dichlorvos by Fusarium solani

4.6a

MIC of Dichlorvos on the Isolates

4.6b

MIC of Lambdaccyhalothrin on the Isolates

4.7

Results of Crude enzyme activity of Fusarium solani

LIST OF FIGURES

FIGURE

TITLE

PAGE

4.4

Appearance of Fusarium solani on X400 objective

4.5a

Control result of Dichlovors degradation using Gas Chromatography

4.5b

Result of Dichlovors degradation by Fusarium solani using Gas Chromatography

4.5c

Control result of Lambdacyhalothrin degradation using Gas Chromatography

4.5d

Result of Lambdacyhalothrin degradation by Fusarium solani using Gas Chromatography

Degradation Of Pesticides (Dichlorvos and Lambdaccyhalothrin) In Artificially Contaminated Medium By Wood Rot Fungus, Fusarium Solani

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