ライフサイエンスコーパス: arthropod vector

1 er potential for acquisition of virus by the arthropod vector.

2 ug ELQ-502 decreases parasite fitness in the arthropod vector.

3 cant sequence similarity, and share the same arthropod vector.

4 s impacts B. burgdorferi colonization of its arthropod vector.

5 by a rickettsial pathogen to survive in its arthropod vector.

6 ersal of cells within the mammalian host and arthropod vector.

7 context of the gut epithelial barrier of an arthropod vector.

8 during the transition between human host and arthropod vector.

9 AP) restricts bacterial colonization of this arthropod vector.

10 xic levels of heme present in the gut of the arthropod vector.

11 y are initiated to allow colonization of the arthropod vector.

12 tant to B. burgdorferi's survival within its arthropod vector.

13 nd the maintenance of spirochetes within the arthropod vector.

14 migrate to the salivary gland, and exit the arthropod vector.

15 mammalian hosts, but is downregulated in the arthropod vector.

16 lichiosis, which is naturally transmitted by arthropod vectors.

17 toms and the breadth of causative agents and arthropod vectors.

18 r bacteria that are typically transmitted by arthropod vectors.

19 ve evolved the capacity to be transmitted by arthropod vectors.

20 alaria and leishmaniasis, are transmitted by arthropod vectors.

21 ission cycles involving vertebrate hosts and arthropod vectors.

22 emerging flavivirus transmitted primarily by arthropod vectors.

23 etabolism beyond mammalian hosts and towards arthropod vectors.

24 ard vertebrate hosts and their blood-feeding arthropod vectors.

25 approach; IVM strategies aim only to control arthropod vectors.

26 ens in either their vertebrate reservoirs or arthropod vectors.

27 that could also apply to other blood-feeding arthropod vectors.

28 mals, and plants are transmitted by specific arthropod vectors.

29 istic or commensal organisms when colonizing arthropod vectors.

30 rate viral pathogens that are transmitted by arthropod vectors.

31 fe, and highly unlikely to be transmitted by arthropod vectors.

32 that are transmitted between vertebrates by arthropod vectors.

33 imal reservoirs and transmitted to humans by arthropod vectors.

34 f these microbes in both mammalian hosts and arthropod vectors.

35 The defense responses of mosquito and other arthropod vectors against parasites are important for un

36 ition to harboring beneficial microbes, many arthropods (vectors) also transmit pathogens to the anim

37 Filarial nematodes require both an arthropod vector and a mammalian host to complete their

38 isease, must adapt to two diverse niches, an arthropod vector and a mammalian host.

39 or disrupting the viral disease cycle in the arthropod vector and could be putative determinants of v

40 between a human pathogenic bacterium and its arthropod vector and delineate what we believe to be a n

41 st adapt to the distinct environments of its arthropod vector and mammalian host during its complex l

42 Thus survival of this spirochaete in an arthropod vector and mammalian host requires that it can

43 disease, selectively expresses genes in the arthropod vector and mammalian host.

44 capabilities during its enzootic cycle in an arthropod vector and mammalian host.

45 ue as B. burgdorferi transitions between its arthropod vector and mammalian host.

46 multiple adhesins to interact with both the arthropod vector and mammalian hosts it colonizes.

47 vironmental signals as it cycles between the arthropod vector and mammalian hosts, including temperat

48 ession in response to changes imposed by its arthropod vector and mammalian hosts.

49 interactions between B. burgdorferi and its arthropod vector and suggest additional targets to inter

50 gy employed by B. henselae to survive in the arthropod vector and the mammalian host.

51 throughout the spirochaete life cycle in the arthropod vector and the murine host.

52 burgdorferi shuttles back and forth between arthropod vector and vertebrate host, it encounters vast

53 c agent of Lyme disease, persists in both an arthropod vector and vertebrate hosts, usually wild rode

54 Establishing the source of alpha-gal in arthropod vectors and the immune response to vector bite

55 ) involves infection and replication in both arthropod vectors and vertebrate hosts.

56 ow fever virus (YFV) are transmitted between arthropod vectors and vertebrate hosts.

57 sophila, other common genetic model species, arthropod vectors and/or human biology.

58 al transfer between a vertebrate host and an arthropod vector, and acquisition of virus from an infec

59 of the Lyme disease agent within the feeding arthropod vector, and strategies for interfering with th

60 development within and transmission from the arthropod vector are known for many bacterial and protoz

61 Different arthropod vectors are ecologically and behaviorally dist

62 abolism influences biochemical networks, and arthropod vectors are endowed with an immune system that

63 ruses are transmitted via a diverse range of arthropod vectors, as well as rodents, and have establis

64 isolating viruses from humans, animals, and arthropod vectors at field stations in Latin America, Af

65 In the gut of the obligately hematophagous arthropod vector, bartonellae are exposed to concentrati

66 nderstanding transmission dynamics driven by arthropod vectors between wildlife populations is critic

67 nticipate our method can be applied to other arthropod vector-borne diseases.

68 PCD in arthropod vectors can be manipulated by arboviruses, lea

69 present major human pathogens transmitted by arthropod vectors, causing significant morbidity and mor

70 nce of working with viruses originating from arthropod vector cells in investigations of the cell bio

71 e molecularly detected among a wide range of arthropods, vector competence becomes an imperative aspe

72 These findings show that some arthropod vector-derived factors, such as this chemotact

73 on the CpG dinucleotides of viral genomes in arthropod vectors directly opposes the pressure present

74 ently transit between its mammalian host and arthropod vector during tick feeding.

75 direct transmission, arboviruses utilize an arthropod vector (e.g., mosquitos, sandflies, and ticks)

76 adaptation of B. quintana to the hemin-rich arthropod vector environment.

77 Arthropod vectors experience a complex suite of environm

78 Thus, transit in its arthropod vector exposes Y. pestis to favourable conditi

79 Saliva from arthropod vectors facilitates blood feeding by altering

80 ely to become an even greater problem as the arthropod vectors for these viruses expand into new geog

81 ble component of Rickettsia biology involves arthropod vectors: for instance, typhus group rickettsia

82 The understanding of life history traits in arthropod vectors has been hampered by technological dif

83 Recently, arthropod vectors have been involved in emerging anaphyl

84 viral attachment and possibly in entry into arthropod vector host cells.

85 tablishment of a persistent infection in the arthropod vector; however, the nature of the virus-arthr

86 tracellular bacteria that cause a variety of arthropod vectored human diseases.

87 tick, Ixodes scapularis, is the predominant arthropod vector in the United States and is responsible

88 the evolution of the DTN in a diverse set of arthropod vectors, including ticks, and its role in prot

89 ued expansion of the range and number of its arthropod vectors increases the likelihood that OROV wil

90 nd C; as B. burgdorferi transitions from its arthropod vector into mammalian tissue, ospC is upregula

91 Efficient transmission of pathogens by an arthropod vector is influenced by the ability of the pat

92 of the mammalian host and colonization of an arthropod vector is required for the ongoing transmissio

93 ature in an enzootic cycle that involves the arthropod vector Ixodes scapularis and mammalian reservo

94 first encounters natural antibodies when its arthropod vector, Ixodes scapularis, begins feeding on a

95 known about the current status of viruses of arthropod vectors located in such northerly locations.

96 Control of feline infestation with this arthropod vector may provide an important strategy for t

97 virus particles produced in and delivered by arthropod vectors may preferentially target vertebrate h

98 tanding the sophisticated interactions among arthropod vectors, microbiota, and arboviruses may offer

99 Arthropod vectors of disease are particularly sensitive

100 c bioinformatics approaches in Drosophila to arthropod vectors of infectious diseases.

101 ng different stages of its life cycle in the arthropod vector or the mammalian host.

102 ression in response to signals unique to its arthropod vector or vertebrate hosts.

103 others circulate among multiple hosts, need arthropod vectors, or can survive in environmental reser

104 nimal cross-reactivity to mammalian host and arthropod vector organisms.

105 of infectivity of the mammalian host for the arthropod vector, plague epizootics require a high flea

106 ystem functioning of reducing or eliminating arthropod vector populations remains poorly understood.

107 stand their dynamics of infection in natural arthropod vector populations.

108 ty, induction of the PhoP-PhoQ system in the arthropod vector prior to transmission may preadapt Y. p

109 ion of sfRNA for flavivirus infection of the arthropod vector, providing an explanation for the stric

110 attenuated isolate of B. burgdorferi by the arthropod vector results in the generation of spirochete

111 Whether arthropod vectors retain competence for transmission of

112 ility, and specific loci that correlate with arthropod vector, serotype, and disease severity.

113 Arthropod vectors serve as native reservoirs and transmi

114 e demonstrate the existence of two plausible arthropod vectors, specifically reptile ticks.

115 viruses are transmitted by distantly related arthropod vectors such as mosquitoes (class Insecta) and

116 re transmitted to vertebrate hosts by biting arthropod vectors such as mosquitoes, ticks, and midges.

117 Globally, diseases transmitted by arthropod vectors, such as mosquitoes, remain a major ca

118 in both an immunocompetent mammal and in an arthropod vector suggests that they have evolved elegant

119 In arthropod vectors, symbiotic microorganisms residing in

120 ption of vertical transmission of USUV in an arthropod vector that should consequently be considered

121 Historical exposure to animals and arthropod vectors that can harbor hemotropic Mycoplasma

122 but where transmission involves a biological arthropod vector, this change is constrained by the sele

123 Among arthropod vectors, ticks transmit the most diverse human

124 acteria and a variety of vertebrate host and arthropod vector tissues.

125 in the transmission of spirochetes from the arthropod vector to the mammalian host.

126 to successfully make the transition from the arthropod vector to the vertebrate host.

127 viruses are enveloped viruses transmitted by arthropod vectors to vertebrate hosts.

128 Arthropod vectors transmit African and American trypanos

129 aviruses establish a persistent infection in arthropod vectors which is essential for the effective t

130 less clear, especially for parasites such as arthropod vectors, which generally spend only a short ti

131 context, that the core genome evolved in the arthropod vector with differential regulation, allowing

132 us Orthobunyavirus, which are transmitted by arthropod vectors with a broad cellular tropism in vitro