ライフサイエンスコーパス: insecticide resistance

1 ding of the molecular basis and evolution of insecticide resistance.

2 of the most important mechanisms involved in insecticide resistance.

3 to evolutionary pressures, thereby avoiding insecticide resistance.

4 and controlled vocabularies for anatomy and insecticide resistance.

5 most have not previously been implicated in insecticide resistance.

6 t nervous system is known to be important in insecticide resistance.

7 ween kdr allele expression and the levels of insecticide resistance.

8 insecticides, leading to the development of insecticide resistance.

9 laria control, particularly in areas of high insecticide resistance.

10 sion level of an adjacent gene which creates insecticide resistance.

11 lex, suggest that this AO may play a role in insecticide resistance.

12 nt part in understanding both antibiotic and insecticide resistance.

13 gulatory mutations playing a central role in insecticide resistance.

14 ction of the normal gene product can lead to insecticide resistance.

15 tegies most likely to minimise the spread of insecticide resistance.

16 ation of association between the Vgsc CN and insecticide resistance.

17 y undermines vector control programs through insecticide resistance.

18 d LLIN effectiveness in the presence of high insecticide resistance.

19 iont interactions, and several mechanisms of insecticide resistance.

20 ave important implications for the spread of insecticide resistance.

21 ecting the insecticide against the spread of insecticide resistance.

22 nsporters have previously been implicated in insecticide resistance.

23 ravel and commerce in addition to widespread insecticide resistance.

24 ya vector, is threatened by growing cases of insecticide resistance.

25 entation of new technologies that circumvent insecticide resistance.

26 proteins-or genes are likely responsible for insecticide resistance.

27 ance, nutrition, reproduction, genetics, and insecticide resistance.

28 ology, interactions with the host animal and insecticide resistance.

29 r understanding of the molecular genetics of insecticide resistance.

30 lutionary and heritable feature and roles in insecticide resistance.

31 from metabolic families previously linked to insecticide resistance.

32 e mutations is a common event in response to insecticide resistance across different Cx. quinquefasci

33 divergence island, which includes a suite of insecticide-resistance alleles.

34 Insecticide resistance amongst disease vectors is a grow

35 me fusion brought two major genes conferring insecticide resistance and clusters of genes involved in

36 transmission that assesses the evolution of insecticide resistance and immunity in the human populat

37 he An. funestus group and review research on insecticide resistance and its mechanisms.

38 Rising insecticide resistance and lack of efficacious vaccines

39 emics in later years because of evolution of insecticide resistance and loss of herd immunity.

40 get to develop new insecticides with reduced insecticide resistance and low toxicity to mammals, fish

41 y in sub-Saharan Africa, because of drug and insecticide resistance and social and environmental chan

42 annel of resistant mosquitoes in response to insecticide resistance and the inheritance of these muta

43 articular importance due to the evolution of insecticide resistance and the proposed release of trans

44 of gene expression signatures associated to insecticide resistance and their suppression could great

45 osquitoes is threatened by the appearance of insecticide resistance and therefore new control chemica

46 We stratified studies into three levels of insecticide resistance, and ITNs were compared with untr

47 evidence suggest that P450 genes involved in insecticide resistance, and perhaps insecticide detoxifi

48 e involvement of miRNAs in the regulation of insecticide resistance, and shed light on the novel targ

49 flexible, two-locus model for the spread of insecticide resistance applicable to mosquito species th

50 on era, it is vital that the implications of insecticide resistance are understood and strategies to

51 hat interpretations of species compositions, insecticide resistance assays, host preference studies,

52 a therefore suggest that multiple origins of insecticide resistance (associated with specific point m

53 ve facilitated a genome-wide analysis of the insecticide resistance-associated genes in insects.

54 ispersive Culex mosquito have suggested that insecticide resistance-associated mutations (specificall

55 Such an insecticide-resistance-associated minigene should form a

56 Differing levels of insecticide resistance between two African malaria vecto

57 of infectious disease through antibiotic and insecticide resistance, but recent theory suggests disea

58 P450 monooxygenases play a critical role in insecticide resistance by allowing resistant insects to

59 Synergists can counteract metabolic insecticide resistance by inhibiting detoxification enzy

60 Insecticide resistance can arise from a variety of mecha

61 ogy resource for storing genomic variations, insecticide resistance data and their associated metadat

62 ed populations in response to high levels of insecticide resistance, demonstrating that the co-existe

63 es associated with hematophagy, immunity and insecticide resistance, directly involved in vector-huma

64 llows progress in the analysis of cyclodiene insecticide resistance from the initial isolation of the

65 alyze the allele replacement observed in the insecticide resistance gene Ester in the mosquito Culex

66 al inversions in one chromosome arm (2R), an insecticide resistance gene on 2L, and this single X-lin

67 n which we model the evolution and spread of insecticide resistance genes and also suggest that paral

68 id not appear to be directly associated with insecticide-resistance genes.

69 control, for understanding the mechanisms of insecticide resistance, genetic adaptation to high patho

70 t role played by P450s in the development of insecticide resistance has been extensively studied but

71 Insecticide resistance has decreased the efficacy of the

72 Fitness-related costs of evolving insecticide resistance have been reported in a number of

73 owever, measurements of the fitness costs of insecticide resistance have used diverse methods to cont

74 ndation for future research on mechanisms of insecticide resistance, human-bed bug and symbiont-bed b

75 otype previously shown to be associated with insecticide resistance in Drosophila melanogaster.

76 eptor (RyR) was highly correlated to diamide insecticide resistance in field populations of Plutella

77 Insecticide resistance in malaria vectors could presage

78 is study investigated the molecular basis of insecticide resistance in Malaysian populations of Ae. a

79 of tolerance has influenced the evolution of insecticide resistance in managed systems and the evolut

80 gene regulation governing the development of insecticide resistance in mosquitoes and discusses the p

81 lation system involved in the development of insecticide resistance in mosquitoes Culex quinquefascia

82 their precise function in the development of insecticide resistance in mosquitoes will provide new in

83 drug resistance in the Plasmodium parasites, insecticide resistance in mosquitoes, and the lack of an

84 In the wake of the development of insecticide resistance in mosquitoes, novel strategies f

85 ifications and polymorphisms associated with insecticide resistance in mosquitoes.

86 Given the spread of insecticide resistance in natural mosquito populations,

87 Africa, but their efficacy is threatened by insecticide resistance in some malaria mosquito vectors.

88 nzymes have been associated with the diamide insecticide resistance in the diamondback moth, Plutella

89 The role of cuticle changes in insecticide resistance in the major malaria vector Anoph

90 The emergence of insecticide resistance in the mosquito poses a serious t

91 been an increase in the number of reports of insecticide resistance in the past ten years.

92 number of independent origins of cyclodiene insecticide resistance in the red flour beetle Tribolium

93 sents a mechanism for the rapid evolution of insecticide resistance in this important vector of human

94 elling strategy to investigate the spread of insecticide resistance in vector populations and demonst

95 ering a significant step forward in managing insecticide resistance in vector-control operations.

96 Genetic changes in insects that lead to insecticide resistance include point mutations and up-re

97 Insecticide resistance is a growing threat to mosquito c

98 Insecticide resistance is a major obstacle to control of

99 Insecticide resistance is a model phenotype that can be

100 Insecticide resistance is an ideal model to study the em

101 nagement enables potato production, although insecticide resistance is becoming an issue.

102 The evolution of insecticide resistance is conferred through mechanisms,

103 Understanding the molecular basis of insecticide resistance is key to improve the surveillanc

104 Insecticide resistance is one of the most prevalent exam

105 Insecticide resistance is one of the most widespread gen

106 Insecticide resistance is typically associated with alte

107 ontrol and eradication is challenging due to insecticide resistance, lack of effective products, and

108 burden and the continued spread of drug and insecticide resistance make malaria elimination both via

109 s used provide a template for evidence-based insecticide resistance management by malaria control pro

110 This will be a major advance for insecticide resistance management in malaria vectors, wh

111 The implications of insecticide resistance management of B. tabaci on Indian

112 w being reintroduced for IRS in a rotational insecticide resistance management program.

113 The implementation of successful insecticide resistance management strategies for malaria

114 A major impediment to the implementation of insecticide resistance management strategies is that evi

115 With the exception of target site mutations, insecticide resistance mechanisms in the principle malar

116 An understanding of insecticide resistance mechanisms would help to develop

117 ic pests, veterinary/medical entomology, and insecticide resistance monitoring.

118 contribute significantly to the evolution of insecticide resistance, most commonly by increasing the

119 recent introgression of a strongly selected insecticide-resistance mutation (Vgsc-1014F) located wit

120 s for insect pest management has resulted in insecticide resistance now being recorded in >500 specie

121 function of GPCRs and GPCR-related genes in insecticide resistance of mosquitoes, Culex quinquefasci

122 ant to antimalarial drugs and the increasing insecticide resistance of mosquitoes-may cause the numbe

123 istance to antimalarial drugs and increasing insecticide resistance of the vector threaten to reduce

124 The impact of insecticide resistance on insect-borne disease programs

125 The detrimental impact of insecticide resistance on mating competiveness observed

126 ts epidemiological importance, the impact of insecticide resistance on vector-parasite interactions a

127 he spread of genes, such as genes conferring insecticide resistance or possibly refractoriness to par

128 ed our understanding of the genetic basis of insecticide resistance over the last decade, we still kn

129 ent agenda, the potential negative impact of insecticide resistance, particularly on LLINs, for which

130 f the environmental background in developing insecticide resistance phenotypes, and caution for the i

131 population genetics including variation and insecticide-resistance phenotypes.

132 Insecticide resistance poses a serious threat to current

133 Insecticide resistance poses a significant and increasin

134 in but also repressed the expression of four insecticide resistance-related P450 genes, suggesting th

135 iological functions of P450s associated with insecticide resistance remain largely unknown.

136 s, however, the precise function of GPCRs in insecticide resistance remains unclear.

137 identified Anopheles funestus mosquitoes in insecticide resistance tests were found to be other spec

138 es are now resurgent, largely because of the insecticide resistance that has developed in mosquito ve

139 ed in malarial control is the acquisition of insecticide resistance that has developed in mosquitoes

140 the adaptive genomic changes associated with insecticide resistance that have been characterized to d

141 ound that unlike many P450 genes involved in insecticide resistance that were reported previously, CY

142 By identifying novel DNA markers of insecticide resistance, this study opens the way for tra

143 Insecticide resistance threatens the success achieved th

144 However, increasing drug and insecticide resistance threatens the successes made with

145 improve efficacy, an urgent need as emerging insecticide resistance threatens their future.

146 tigating the possible association of CN with insecticide resistance, three assays were compared for t

147 pact of Plasmodium infection on the level of insecticide resistance to dichlorodiphenyltrichloroethan

148 udy is a summary of the current level of the insecticide resistance to selected organophosphates, pyr

149 urveys have yet to reveal the development of insecticide resistance to these chemical compounds.

150 ersal, extreme polyphagy, and development of insecticide resistance, together with human activities,

151 tand the role of Cyp6a2 and related genes in insecticide resistance, we have isolated and characteriz

152 All interventions caused the emergence of insecticide resistance, which, with the loss of herd imm

153 germanica L.) populations, which differed in insecticide resistance, with either nutritionally rich o

154 However, the emergence of insecticide resistance within mosquito vectors risks jeo