ライフサイエンスコーパス: disease vector

1 uticular resistance mechanisms in this major disease vector.

2 ce relies on its itchy bite and potential as disease vector.

3 be determined, wildlife was implicated as a disease vector.

4 itat to human settlements for this important disease vector.

5 experiments are performed in this important disease vector.

6 rgeting the mosquito's ability to serve as a disease vector.

7 in the southern part of its range is also a disease vector.

8 Ag-Aper1 is the first cloned PM gene from a disease vector.

9 g ongoing distributional shifts of pests and disease vectors.

10 iseases through preventing bites and killing disease vectors.

11 germline transformation of insect pests and disease vectors.

12 pened new interpretations for systematics of disease vectors.

13 e population of agricultural pests and human disease vectors.

14 the growth of aquatic vegetation that hosts disease vectors.

15 ecome reproductively competent and effective disease vectors.

16 the goal of eliminating invasive species or disease vectors.

17 portant for controlling invasive species and disease vectors.

18 ing order Hemiptera, that includes pests and disease vectors.

19 cies competition in these globally important disease vectors.

20 lling economically relevant pest species and disease vectors.

21 a suitable tool for controlling plagues and disease vectors.

22 en insects, including pollinators, pests and disease vectors.

23 ven population dynamics models for important disease vectors.

24 global spread of Aedes species, which act as disease vectors.

25 world's most damaging insect crop pests and disease vectors.

26 l targets for efforts to control these human disease vectors.

27 ta to evolution of insecticide resistance in disease vectors.

28 nning for the biological control of mosquito disease vectors.

29 t to effectively control wild populations of disease vectors.

30 control efforts in these and other arthropod disease vectors.

31 rategies such as gene drive systems to fight disease vectors.

32 and may represent targets for the control of disease vectors.

33 ity to control insect agricultural pests and disease vectors.

34 tive to current insecticides used to control disease vectors.

35 ons at risk for emergence and propagation of disease vectors.

36 ds is a serious global obstacle for managing disease vectors.

37 id resistance in various arthropod pests and disease vectors.

38 rtance, as well as a variety of invertebrate disease vectors.

39 ich have a critical role in public health as disease vectors.

40 ics, and by the ability to genetically alter disease vectors.

41 quitination during bacterial colonization of disease vectors.

42 in mosquitoes and other arthropod pests and disease vectors.

43 hosts and other organisms, including insect disease vectors.

44 ontrol theory to guide biological control of disease vectors.

45 rough populations with a view to controlling disease vectors.

46 or completion of egg development in mosquito disease vectors.

47 ded to infect mammalian hosts or transmit to disease vectors.

48 ito biology and their ability to function as disease vectors.

49 rget olfactory-dependent behaviors of insect disease vectors.

50 pread threats to humans and other animals as disease vectors [1].

51 zes in biting humans, making it an efficient disease vector(1).

52 romotes survival by encouraging avoidance of disease vectors(1) but is also implicated in prejudice t

53 ontrol and genetic manipulation of pests and disease vectors [15-16].

54 alter the genotype or phenotype of mosquito disease vectors, according to specific health goals and

55 onment promote the presence and abundance of disease vectors across large spatial extents.

56 to create genome assemblies of the mosquito disease vectors Aeaegypti and Culex quinquefasciatus, ea

57 9 have been developed for the major mosquito disease vector Aedes aegypti Here, we describe the gener

58 new strategies to manage wild populations of disease vectors, agricultural pests, and invasive specie

59 of nuisance insects, agricultural pests, and disease vectors alike.

60 ite mutation identified in various pests and disease vectors alters the voltage gated sodium channel

61 neration vector control strategies to combat disease vectors and agricultural pests.

62 ides allow control of agricultural pests and disease vectors and are vital for global food security a

63 importance of mosquitoes beyond operating as disease vectors and open the door toward understanding t

64 The potential for bed bugs to serve as disease vectors and optimal methods for bed bug pest con

65 We examine evidence for local adaptation in disease vectors and present conceptual models for unders

66 . gallinae increasingly suspected of being a disease vector, and reports indicating that attacks on a

67 e reproductive microbiome of important human disease vectors, and identifies a panel of core and endo

68 s, the immunological control of infection in disease vectors, and the determinants that facilitate tr

69 ng behavior and host preferences of mosquito disease vectors, and the implications for vector-borne d

70 edes albopictus mosquitoes-a highly invasive disease vector-and how these cues influence biting, feed

71 Introductions of tick disease vectors are inevitable in our changing world.

72 s antagonize antiviral small RNA pathways in disease vectors are unknown.

73 o Aedes aegypti is one of the most important disease vectors because it transmits two major arbovirus

74 Mosquitoes are major disease vectors because most species must feed on blood

75 Female mosquitoes are effective disease vectors, because they take blood from vertebrate

76 and are implicated in host-seeking by insect disease vectors, but have not previously been implicated

77 incidence of bacterial wilt disease (a fatal disease vectored by cucumber beetles).

78 geneity of exposure to malaria and arboviral disease vectors by national control programs.

79 terations in source-sink patterns, and viral diseases vectored by aphids, which are phloem-feeding pe

80 esearch can be translated to combating human diseases vectored by arthropods.

81 natural ecosystems may affect the hazard of diseases vectored by the tick Ixodes ricinus at differen

82 fects interact to impact the epidemiology of diseases vectored by these mosquitoes.

83 understanding of how this important group of disease vectors came to be.

84 If streets are shown to be barriers to disease vectors, city blocks could be used as a convenie

85 Chagas disease vector control relies on prompt, accurate identi

86 inherent improved return for investment for disease vector control.

87 rgets for developing novel methods of insect disease vector control.

88 applications in agriculture, eradication of disease vectors, control of invasive species, and the sa

89 nsect pests (e.g., Rhyacionia frustrana) and disease vectors (e.g., Culex spp).

90 , and Diptera, including many crop pests and disease vectors, fly at heights up to 1 km above this 60

91 t exploit the transmission lifecycle of this disease vector for preventative and therapeutic purposes

92 d Aedes mosquitoes, the former identified as disease vectors for malaria and the latter for Zika, yel

93 secticides have been produced for control of disease vectors for public health in developing countrie

94 on for chordate, selected model organism and disease vector genomes.

95 for chordate and selected model organism and disease vector genomes.

96 g, (2) population genetics, (3) pathogen and disease-vector genomic surveillance, (4) allergen and na

97 ularly in the larval stage, with other known disease vectors give this invasive subspecies the potent

98 The hard tick, Ixodes ricinus, a main Lyme disease vector, harbors an intracellular bacterial endos

99 that cause greater fitness disadvantages to disease vectors (i.e., bona fide pathogens) in contrast

100 isk landscape for human exposure to the Lyme disease vector-I. scapularis.

101 partitiviruses infecting model organisms and disease vectors.IMPORTANCE Galbut virus is a recently di

102 ed tick (Ixodes pacificus), the primary Lyme disease vector in western North America, to projected cl

103 y of human exposure to malaria and arboviral disease vectors in an urban area of northern Senegal, us

104 e portable to many species, including insect disease vectors in which confinable gene drives could be

105 es of Aedes aegypti mosquitoes (an arboviral disease vector) in houses, such as exposed lower section

106 s and discuss the implication of learning in disease vector insects in perspective with control strat

107 of odorant-binding site structures in ORs of disease vector insects.

108 host preference and parasite transmission by disease vector insects.

109 biting and host preference behavior of this disease vector is largely influenced by its sense of sme

110 Insecticide resistance amongst disease vectors is a growing problem and novel compounds

111 A potential approach to control mosquito disease vectors is the sterile insect technique (SIT).

112 Saliva of the hard tick and Lyme disease vector, Ixodes scapularis, has a repertoire of c

113 ying these microorganisms in both humans and disease vectors, laboratory models are commonly used for

114 infectious diseases, a.o. through impacting disease vector life-cycles.

115 n developing homing gene drives for mosquito disease vectors, little progress has been made with agri

116 mosquito attractants in the process of this disease vector management.

117 from molecular biology research to pest and disease-vector management, and will help advance the stu

118 ungunya, all of which are transmitted by the disease vector mosquito Aedes aegypti.

119 of a protein family with orthologs in other disease vector mosquitoes and appear to be important eff

120 s sensu stricto is one of the most important disease vector mosquitoes in temperate zones across the

121 the generalist Vavraia culicis, pathogens of disease vector mosquitoes.

122 to observe in their natural habitat, such as disease vectoring mosquitoes.

123 and disease, for example, via attraction of disease-vector mosquitoes or use in medical diagnostics.

124 oural evolution and provide insight into how disease-vectoring mosquitoes came to specialize on human

125 Microbiomes modulate the capacity of insect disease vectors (mosquitoes, tsetse flies, sandflies) to

126 orant receptor complexes containing ORs from disease-vector mosquitos Aedes aegypti or Anopheles gamb

127 This is unique evidence in a disease vector of cross-resistance associated with a sin

128 f surveillance and control programs for this disease vector of substantial global public health impor

129 approach outlined here can be applied to any disease vector or pest species and type of environmental

130 suggest that human-biting in this important disease vector originally evolved as a by-product of bre

131 Understanding drivers of disease vectors' population dynamics is a pressing chall

132 netic methods of manipulating or eradicating disease vector populations have long been discussed as a

133 ecies with substantial biting activity, high disease vector potential, and a global distribution that

134 ication of the vertebrate species on which a disease vector previously parasitized is imperative to s

135 The endosymbiont of the Chagas disease vector, Rhodnius prolixus, has been transformed

136 geny that resolves the position of the major disease vector species and the major mosquito lineages.

137 in Aedes sierrensis, a congener of the major disease vector species that experiences large thermal gr

138 ut genome-scale screening in cell lines from disease vector species.

139 a wide range of applications in the study of disease vectors species.

140 ciations between aquatic invasive plants and disease vectors such as mosquitoes.

141 overview of the relationship between insect disease vectors, such as tsetse flies and mosquitoes, an

142 c stability and knockdown time for important disease vectors, suggesting that manipulation of the sol

143 river of pathogen-carrying mosquito species (disease vectors) that pose a health risk to humans and l

144 The abundance of an alternate host for disease vectors, the grasshopper mouse (Onychomys leucog

145 the life history observations of two common disease vectors, the southern (Culex quinquefasciatus) a

146 d mice as seed predators and dispersers, and disease vectors, these shifts have far-reaching implicat

147 In mosquito disease vectors this is of particular importance due to

148 al species of hard ticks, including the Lyme disease vector tick, Ixodes scapularis.

149 is given to host-targeted devices to control disease vector ticks infesting wildlife, to pheromone-im

150 host-seeking behavior, the susceptibility of disease vectors to arboviruses, the immunological contro

151 nd potential nonlinearity in the response of disease vectors to environmental change.

152 -sectional data of infestation by the Chagas disease vector Triatoma infestans in the city of Arequip

153 e position of major clades (e.g., the Chagas disease vectors Triatominae).

154 lyphyletic Reduviinae and the blood-feeding, disease-vectoring Triatominae, and allows us, for the fi

155 The control of arthropod disease vectors using chemical insecticides is vital in

156 fects of future climate on human exposure to disease vectors, we argue that research on vector-borne

157 Fourteen known disease vectors were taxonomically identified.

158 Our findings extend the list of disease vectors where engineered homing gene drives have

159 can lead to the evolution of more competent disease vectors, which can feed back to impact disease r

160 physiology, behavior, and evolution of human disease vectors within the context of the global health

161 Mosquitoes are the most common disease vectors worldwide.