ライフサイエンスコーパス: biocontrol

1 f insect-infecting viruses with key roles in biocontrol.

2 ar ways to further increase future safety of biocontrol.

3 an important agent in locust and grasshopper biocontrol.

4 DNA viruses, many of which have been used in biocontrol.

5 the complex ecological processes involved in biocontrol.

6 ing efforts are directed toward using EFN in biocontrol.

7 icrobes to colonize plants and contribute to biocontrol.

8 cular studies, and evolutionary biology; and biocontrol.

9 d indicate some genes that may be related to biocontrol.

10 ng this infection model, we demonstrated the biocontrol ability of a wild-type B. subtilis strain 605

11 everal genes potentially contributing to its biocontrol activities.

12 Pseudozyma flocculosa in the context of its biocontrol activity against Blumeria graminis f.sp. hord

13 strains of fluorescent Pseudomonas spp. with biocontrol activity against soilborne fungal plant patho

14 ic richness and the potential loss of fungal biocontrol activity highlights an important mechanism to

15 e contribution of beta-1,3-glucanases to the biocontrol activity of L. enzymogenes may be due to comp

16 nant bacterial AHL biosensors and to restore biocontrol activity to an HHL-deficient P. aureofaciens

17 he fungal species can trigger or depress the biocontrol activity.

18 taibol antibiotics and their contribution to biocontrol activity.

19 derstand the dynamics of foliar pathogen and biocontrol agent (BCA) populations in order to predict t

20 tation can be prevented by the nonpathogenic biocontrol agent A. radiobacter K84, which prevents dise

21 subtilis is widely used in agriculture as a biocontrol agent able to protect plants from a variety o

22 parasite Coniothyrium minitans, an important biocontrol agent against crop diseases caused by Sclerot

23 B. subtilis M1 was ineffective as a biocontrol agent against P. syringae infectivity in Arab

24 of bioactive COS and fungal protoplasts, as biocontrol agent against pathogenic fungi and insects, t

25 ocin 84 is a LeuRS inhibitor produced by the biocontrol agent Agrobacterium radiobacter K84 that targ

26 Interestingly, the biocontrol agent appears to have acquired genes encoding

27 on of tomato to evaluate the efficacy of the biocontrol agent Bacillus cereus against the seed pathog

28 ovel compound (HSAF) produced by a bacterial biocontrol agent disrupts polarized growth and leads to

29 B. cepacia is currently being developed as a biocontrol agent for large-scale agricultural release, w

30 rans has long been recognized as a potential biocontrol agent for root knot nematodes, but the fastid

31 a polycyclic tetramate macrolactam from the biocontrol agent Lysobacter enzymogenes.

32 a granulovirus (CpGV) is widely applied as a biocontrol agent of codling moth.

33 ydis yet is not a phytopathogen but rather a biocontrol agent of powdery mildews; this relationship m

34 ed by Bacillus subtilis in its behavior as a biocontrol agent on plants.

35 oencapsulation and controlled release of the biocontrol agent Pantoea agglomerans strain E325 (E325),

36 ic basis in the host for interactions with a biocontrol agent suggests new opportunities to exploit n

37 We demonstrate that this biocontrol agent targets A. tumefaciens leucyl-tRNA synt

38 ria-nematode complex has been exploited as a biocontrol agent that is active against several insect p

39 among a broad range of fungi, including the biocontrol agent Trichoderma atroviride, the plant patho

40 x, and could be potentially developed into a biocontrol agent with minimal off-target effects.

41 Tritrophic interactions involving a biocontrol agent, a pathogen and a plant have been analy

42 of the successful use of a microencapsulated biocontrol agent, E325, against E. amylovora, and could

43 r host range and was considered to be a good biocontrol agent.

44 ed predominantly from the perspective of the biocontrol agent.

45 n is critical for ensuring its efficacy as a biocontrol agent.

46 important due to the use of these viruses as biocontrol agents and for protecting ecologically or eco

47 ous environmental bacteria emerging as novel biocontrol agents and new sources of anti-infectives.

48 nisms, which allows them to serve as crucial biocontrol agents and virulence factors during infection

49 , such as Trichoderma harzianum, that act as biocontrol agents by antagonizing M. roreri.

50 strategies aimed at enhancing the impact of biocontrol agents by reducing the immunocompetence of th

51 Second, biocontrol agents can successfully reduce long-term host

52 erstanding parasite-host interactions and as biocontrol agents for insect pests.

53 Trichoderma spp. are effective biocontrol agents for several soil-borne plant pathogens

54 use of "biologicals" as bio-fertilizers and biocontrol agents for sustainable agricultural practices

55 et these are important contributions because biocontrol agents offer disease management alternatives

56 ine the community-wide effects of introduced biocontrol agents on Kauai Island, Hawaii, we constructe

57 es for developing baculoviruses as effective biocontrol agents or for targeting baculoviruses infecti

58 or the successful establishment of effective biocontrol agents over a wide area will be needed to sup

59 nts reached 28% in some species of moth, all biocontrol agents reared had been released before 1945.

60 There is very limited use of microbial biocontrol agents to control plant disease and no indica

61 As such, satellite RNAs could be used as biocontrol agents to reduce the level of disease in fiel

62 These are the improvement of weed-specific biocontrol agents, enhancement of crop competition or al

63 and so improve commercial efficacy of these biocontrol agents.

64 ssibilities for improving the performance of biocontrol agents.

65 g of the strategies exploited by nematicidal biocontrol agents.

66 hytes or endophyte-derived constituents into biocontrol agents.

67 f which may have the potential to be used as biocontrol agents.

68 nd DBL might be developed as naturally-based biocontrol agents.

69 ter prepare us to use defensive symbionts as biocontrol agents.

70 The biocontrol Agrobacterium radiobacter K84 secretes the Tr

71 r heterologous protein production, or on new biocontrol and bioremediation technologies based on Aspe

72 ive soil bacterium potentially important for biocontrol and bioremediation, in soil.

73 teriophage-based products for the detection, biocontrol and biosanitation of foodborne pathogens.

74 New biocontrol and chemical products continue to improve con

75 inematodal compounds have been isolated from biocontrol and other fungi.

76 prokaryotic viruses and their potential for biocontrol and phage therapy applications.

77 at the ooc gene cluster is widespread within biocontrol and phytopathogenic strains of the enterobact

78 ich a role in host-interaction, -regulation, biocontrol, and more, could be posited.

79 ing necrotrophic pathogens are vulnerable to biocontrol, antagonists can be applied directly to the t

80 These results support the use of Wolbachia biocontrol as a multivalent strategy against Ae. aegypti

81 Conversely, the antifungal activity of the biocontrol bacterium Pseudomonas aureofaciens 30-84 is d

82 underpins the development of strategies for biocontrol-based pest management.

83 at 30.5 degrees N, we tested the role of the biocontrol beetle Agasicles hygrophila in mediating warm

84 affects impacts of a multivoltine introduced biocontrol beetle on the non-target native plant Alterna

85 To determine the role of surfactin in biocontrol by B. subtilis, we tested a mutant strain, M1

86 , reduced pathogenicity and slightly reduced biocontrol capacities.

87 dscapes, and the economic impacts of reduced biocontrol caused by increased corn production in 4 U.S.

88 ghly diverse group of insects widely used in biocontrol, depends on a variety of life history strateg

89 with the rhizosphere of plants where it has biocontrol effects on other microorganisms.

90 Biocontrol efficacy could be improved by co-inoculation

91 s of B. subtilis that exhibit high levels of biocontrol efficacy from natural environments and to inv

92 btained six strains that exhibited above 50% biocontrol efficacy on tomato plants against the plant p

93 Thus to increase biocontrol efficacy, it is necessary to frequently apply

94 ent of anti-infectives and the prevention of biocontrol emasculation.

95 represents an exciting potential new form of biocontrol for arboviral diseases, including dengue.

96 aceum and contributes to understanding how a biocontrol fungus and its prey interact with each other.

97 glucosidase was cloned from strain P1 of the biocontrol fungus Trichoderma atroviride (formerly T. ha

98 rder to predict the likelihood of successful biocontrol in relation to the mechanisms involved.

99 r the advancement of phytopathogen-dependent biocontrol, including the generation of optimized Tricho

100 o identify microorganisms with potential for biocontrol, increased testing under semicommercial and c

101 re resources to reproduction than native and biocontrol individuals, and their reproduction is spread

102 and with other control methods, integrating biocontrol into an overall system.

103 r traits, suggesting that the host effect on biocontrol is mediated by different mechanisms.

104 One mechanism of biocontrol is mycoparasitism, and T. virens produces ant

105 g the basis for this phytopathogen-dependent biocontrol is still unknown.

106 ave emerged from the predator diversity-pest biocontrol literature, suggesting that there may be gene

107 potential exploitation in the development of biocontrol measures.

108 Four biocontrol mechanisms (competition, antibiosis, mycopara

109 physiological and genetic enhancement of the biocontrol mechanisms, manipulation of formulations, and

110 al factors on the expression and activity of biocontrol mechanisms.

111 field-testing of wMel introgression for the biocontrol of Ae. aegypti-born arboviruses.

112 e of attenuating satellite RNAs as a form of biocontrol of CMV.

113 ations for understanding the development and biocontrol of locust plagues.

114 e phytobacteria, including those involved in biocontrol of plant diseases, significantly inhibit atta

115 Despite much research on biocontrol of plant diseases, success in field crops has

116 el approaches for biomass deconstruction and biocontrol of plant diseases.

117 tion of organic and inorganic pollutants and biocontrol of plant pathogens.

118 The use of entomopathogenic fungi for biocontrol of plant pests is recently receiving an incre

119 h objectives are evaluation of sciomyzids as biocontrols of disease-carrying or agriculturally import

120 lier than native populations, but later than biocontrol ones.

121 volutionary population processes in both the biocontrol organisms and in the wasps.

122 ns such as intracavity bio/chemical sensing, biocontrolled photonic devices, and biophysics.

123 We show that biocontrol populations have evolved a classic fast life

124 nitrate (e.g. from fertilizers) may enhance biocontrol potential in some circumstances.

125 The pioneering biocontrol products BioSave and Aspire were registered b

126 The limitations of these biocontrol products can be addressed by enhancing biocon

127 During the past ten years, over 80 biocontrol products have been marketed worldwide.

128 Although the number of biocontrol products is increasing, these products still

129 istical difficulties, establishment rates in biocontrol programs are equal or exceed those of abovegr

130 inating a potential consequence of classical biocontrol programs involving insect herbivores and pois

131 e also identified that may contribute to the biocontrol properties of P. fluorescens Pf-5.

132 adequate protection but in combination with biocontrol provide additive or synergistic effects.

133 Analyses of biocontrol releases are critical to evaluating the envir

134 lar probes are powerful tools for monitoring biocontrol releases.

135 general mechanisms for pest control and that biocontrol research might inform disease management and

136 of agricultural intensification and restore biocontrol service through proliferating the role of nat

137 tural enemies to soybean fields and reducing biocontrol services by 24%.

138 This loss of biocontrol services cost soybean producers in these stat

139 ield population processes and the associated biocontrol services is limited because emigration and im

140 gle pest in 1 crop suggest that the value of biocontrol services to the U.S. economy may be underesti

141 ronment, poses a health risk, and undermines biocontrol services.

142 X. fastidiosa biocontrol strain EB92-1 is infectious to grapevines but

143 exacerbated by coinoculation of roots with a biocontrol strain of Pseudomonas putida, but not with a

144 Expression of tri5 in the biocontrol strain Trichoderma harzianum CECT 2413 result

145 conditions, increased emphasis on combining biocontrol strains with each other and with other contro

146 finding could contribute to develop disease biocontrol strategies in plants by activating its innate

147 s of demographic stochasticity may influence biocontrol success in highly disturbed agricultural syst

148 e the need to understand factors influencing biocontrol success, few theoretical studies of host-para

149 gal BCA systems, does not address a specific biocontrol system.

150 actors in determining the final outcome of a biocontrol system.

151 The model considers biocontrol systems for foliar pathogens only and, althou

152 salis and provide clues to develop potential biocontrol techniques against this fruit fly.

153 ntrol products can be addressed by enhancing biocontrol through manipulation of the environment, usin

154 pulation of formulations, and integration of biocontrol with other alternative methods that alone do