ライフサイエンスコーパス: biological control agent

1 cialist moth, Pareuchaetes pseudoinsulata (a biological control agent).

2 ggest that M. multispinosus could serve as a biological control agent.

3 get organisms; in this case, a key predatory biological control agent.

4 host-vector disease system and the vector's biological control agent.

5 s second group appear to be well suited as a biological control agent.

6 ncreased the efficacy of this classical weed biological control agent.

7 subsp. Kurstaki is one of the most important biological control agents.

8 ematodes (EPNs) are insect parasites used as biological control agents.

9 in international trade, and risk analysis of biological control agents.

10 e further assessed for nematode potential as biological control agents.

11 Entomopathogenic nematodes are excellent biological control agents.

12 nd Beauveria bassiana are widely used insect biological control agents.

13 otics of baculoviruses and for using them as biological control agents.

14 il where it could come into contact with EPN biological control agents.

15 ct the success of parasites and pathogens as biological control agents.

16 as a potential target for the improvement of biological control agents.

17 interactions, such as agricultural pests and biological-control agents.

18 of parasitoids reared from native moths were biological control agents, 14% were accidental immigrant

19 mported from Asia into Africa as a classical biological control agent against the pod borer Maruca vi

20 actions and show their potential for use as biological control agents against fungal diseases.

21 lis and other Bacilli have long been used as biological control agents against plant bacterial diseas

22 ns a number of economically important pests, biological control agents and disease carriers.

23 A few have been introduced deliberately as biological control agents (Anthocoris spp., Montandoniol

24 ct, preventing a priori ranking of candidate biological control agents based on their traits.

25 t growth-promoting rhizobacteria (PGPR) as a biological control agent (BCA) to reduce the use of agro

26 Using biological control agents (BCAs) is an essential compone

27 es the need for strain-specific screening of biological control agents before wide-spread adoption.

28 ons are inherent in most naturally occurring biological control agents but development of recombinant

29 asitoids of the vector prove to be effective biological control agents, but highly virulent pathogens

30 densities of problematic plant species using biological control agents can be quantified, but the ris

31 , the efficacy of phages, as is true of many biological control agents, depends greatly on prevailing

32 owerful gene transduction tool and potential biological control agent for Anopheles mosquitoes.

33 e performance of phenazine producers used as biological control agents for soilborne plant pathogens.

34 , host plant-R-AEF interactions and R-AEF as biological control agents have been studied independentl

35 pectin-derived oligogalacturonides (OGs) as biological control agents in agriculture, very little in

36 successful application of bacteriophages as biological control agents in clinical therapy, food proc

37 alysis of the efficacy of different types of biological control agents in controlling vector-borne di

38 llidae), is one of the most extensively used biological control agents in the field to manage arthrop

39 The species, once used as a biological control agent, is now a worldwide invader.

40 eniles of PPN Meloidogyne incognita with the biological control agent KM2501-1 resulted in a mortalit

41 us, have been studied for their potential as biological control agents of fungi.

42 fungi are attracting attention as potential biological control agents of insect pests.

43 additional applied interest because many are biological control agents of pest insects.

44 failure and economic loss when they occur in biological control agents of pests.

45 persistence thresholds of host, pathogen and biological control agent, performing an equilibrium anal

46 rs or to the initial amounts of pathogen and biological control agent present.

47 ned sequences from an economically important biological control agent, Puccinia suaveolens, to highli

48 Although parasitism by biological control agents reached 28% in some species of

49 al approaches, the mode of action of natural biological control agents related to pathogens can be sy

50 e success of Bacillus amyloliquefaciens as a biological control agent relies on its ability to outgro

51 e effectiveness of entomopathogenic fungi as biological control agents require a clear understanding

52 he antagonistic fungus Trichoderma viride, a biological control agent that has previously been shown

53 orweed (Alternanthera philoxeroides) and its biological control agent the alligatorweed flea beetle (

54 wing the deliberate introduction of an alien biological control agent: the carnivorous snail Euglandi

55 In addition to identifying new potential biological control agents, these results expand the gran

56 s soil saprophyte that has been applied as a biological control agent to protect plants from fungal p

57 ticularly when insect herbivores are used as biological control agents to manage invasive plants.

58 istance, and many greenhouse growers rely on biological control agents to regulate T. vaporariorum po

59 ry even communities of predator and pathogen biological control agents, typical of organic farms, exe

60 erimental work suggests that interactions of biological control agents with their own natural enemies