ライフサイエンスコーパス: disease vector

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

2 itat to human settlements for this important disease vector.

3 experiments are performed in this important disease vector.

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

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

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

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

8 id resistance in various arthropod pests and disease vectors.

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

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

11 quitination during bacterial colonization of disease vectors.

12 in mosquitoes and other arthropod pests and disease vectors.

13 hosts and other organisms, including insect disease vectors.

14 ontrol theory to guide biological control of disease vectors.

15 rough populations with a view to controlling disease vectors.

16 or completion of egg development in mosquito disease vectors.

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

18 rget olfactory-dependent behaviors of insect disease vectors.

19 germline transformation of insect pests and disease vectors.

20 pened new interpretations for systematics of disease vectors.

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

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

23 9 have been developed for the major mosquito disease vector Aedes aegypti Here, we describe the gener

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

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

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

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

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

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

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

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

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

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

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

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

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

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

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

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

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

41 inherent improved return for investment for disease vector control.

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

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

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

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

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

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

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

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

50 host preference and parasite transmission by disease vector insects.

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

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

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

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

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

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

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

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

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

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

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

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

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

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

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

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

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

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

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

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

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

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

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

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

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