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1  protein search is amenable to selection and biological control.
2  microbial antagonist, for use in optimising biological control.
3 itions, we determine criteria for successful biological control.
4 ce of gene function is obligatory to sustain biological control.
5 18 families, however, which suggests complex biological control.
6 ests and threaten the long-term viability of biological control.
7 ies, biologists can gain deeper insight into biological control.
8 methods for population reduction, preferably biological control.
9 d teaching on soil-borne plant pathogens and biological control.
10 c ecological theory and applications such as biological control.
11  conformational change is a primary means of biological control.
12 assembly of nuclear regulatory machinery for biological control.
13 tions to maximize the use of coccinellids in biological control.
14 but this factor alone is a poor predictor of biological control.
15  between approaches that affect cereal aphid biological control.
16 piration machinery as a potential target for biological control.
17 nes underlying traits that are important for biological control.
18 sy exists over ecological risks in classical biological control.
19 the U.S. Environmental Protection Agency for biological control.
20 cteria and the potential use of Wolbachia in biological control.
21 ergency control are expanding the demand for biological control.
22 eory to this developing area of conservation biological control.
23 are being used to develop strategies for its biological control.
24  mRNA stability may represent a new level of biological control.
25 for landscape planning, invasion biology and biological control.
26 s into further functional studies and better biological control.
27 n-RNA networks are ubiquitous and central in biological control.
28 in classical, augmentative, and conservation biological control.
29 le insects and have been used extensively in biological control.
30 r of these parasitoids and how it relates to biological control.
31  threshold-based selective insecticides, and biological control.
32 ted pest management (IPM) tactics, including biological control.
33 deadly parasites of insects that are used in biological control.
34 ain pests at low abundances is a priority in biological control.
35 s and allowed patients to serve as their own biological controls.
36 vailable to design and produce new drugs and biological controls.
37 e isolation [3] [10] [11] and as an agent of biological control [2] [12] [13].
38 efine crop-specific IPM programs and enhance biological control across invaded landscapes.
39 owerful gene transduction tool and potential biological control agent for Anopheles mosquitoes.
40 eniles of PPN Meloidogyne incognita with the biological control agent KM2501-1 resulted in a mortalit
41 rs or to the initial amounts of pathogen and biological control agent present.
42 he antagonistic fungus Trichoderma viride, a biological control agent that has previously been shown
43 s soil saprophyte that has been applied as a biological control agent to protect plants from fungal p
44                  The species, once used as a biological control agent, is now a worldwide invader.
45 persistence thresholds of host, pathogen and biological control agent, performing an equilibrium anal
46 ggest that M. multispinosus could serve as a biological control agent.
47 get organisms; in this case, a key predatory biological control agent.
48  host-vector disease system and the vector's biological control agent.
49 wing the deliberate introduction of an alien biological control agent: the carnivorous snail Euglandi
50   A few have been introduced deliberately as biological control agents (Anthocoris spp., Montandoniol
51                                        Using biological control agents (BCAs) is an essential compone
52 lis and other Bacilli have long been used as biological control agents against plant bacterial diseas
53 ons are inherent in most naturally occurring biological control agents but development of recombinant
54 densities of problematic plant species using biological control agents can be quantified, but the ris
55 e performance of phenazine producers used as biological control agents for soilborne plant pathogens.
56 alysis of the efficacy of different types of biological control agents in controlling vector-borne di
57 llidae), is one of the most extensively used biological control agents in the field to manage arthrop
58 us, have been studied for their potential as biological control agents of fungi.
59  fungi are attracting attention as potential biological control agents of insect pests.
60 additional applied interest because many are biological control agents of pest insects.
61 failure and economic loss when they occur in biological control agents of pests.
62                       Although parasitism by biological control agents reached 28% in some species of
63 e effectiveness of entomopathogenic fungi as biological control agents require a clear understanding
64 erimental work suggests that interactions of biological control agents with their own natural enemies
65 of parasitoids reared from native moths were biological control agents, 14% were accidental immigrant
66 asitoids of the vector prove to be effective biological control agents, but highly virulent pathogens
67 , the efficacy of phages, as is true of many biological control agents, depends greatly on prevailing
68     In addition to identifying new potential biological control agents, these results expand the gran
69 ry even communities of predator and pathogen biological control agents, typical of organic farms, exe
70 in international trade, and risk analysis of biological control agents.
71 ematodes (EPNs) are insect parasites used as biological control agents.
72 e further assessed for nematode potential as biological control agents.
73     Entomopathogenic nematodes are excellent biological control agents.
74 subsp. Kurstaki is one of the most important biological control agents.
75 interactions, such as agricultural pests and biological-control agents.
76 g techniques and a near complete reliance on biological control and "soft" pesticides, including inse
77 e suggest that the alternatives of classical biological control and area-wide control with the steril
78 defence activators, assess the usefulness of biological control and categorize current approaches tow
79 ns of these results for engineering enhanced biological control and elucidating the basis for hypovir
80 nterest in their potential uses as tools for biological control and genetic manipulation of pests and
81 ify attributes that contribute to successful biological control and how best to manipulate augmentati
82 ent cycling and are widely used as agents in biological control and in the remediation of polluted la
83 lobal change on natural enemies suggest that biological control and other top-down effects of insect
84 elative importance of each of these types in biological control and pest management programs.
85 ssessing the degree of compatibility between biological control and plant resistance approaches to pe
86 egulators (GacA and RpoS) known to influence biological control and secondary metabolism.
87                   Classical and augmentative biological control and SIT-based programs are likely to
88 y approaches have been proposed that utilize biological control and take advantage of intrinsic demog
89 e species may be particularly susceptible to biological control and that increases in resource availa
90                                     Although biological control and use of conventional resistant mai
91 ource have potential uses for more effective biological control and use of organic amendments to fost
92 successful past programs involving classical biological control and/or the sterile insect technique (
93 and behavior, pathogen transmission biology, biological control, and chemical control with respect to
94  seed pathology, soil-borne plant pathogens, biological control, and history of plant pathology.
95 cies' population dynamics and distributions, biological control, and threats to at-risk species) and
96 ood, and their impact on natural enemies and biological control are difficult to predict.
97       Applications of nutritional ecology to biological control are discussed.
98 uently, most efforts to improve and optimize biological control are in essence efforts to reduce refu
99 al implications for conservation biology and biological control are outlined.
100 cticides, plant resistance, and conservation biological control are reviewed.
101 tant providers of ecosystem services such as biological control, are susceptible to landscape-level c
102 e Cu-chitosan NPs are better compatible with biological control as NPs "mimic" the natural elicitatio
103  MicroRNAs are small RNA species involved in biological control at multiple levels.
104   Pseudomonas aureofaciens strain 30-84 is a biological control bacterium that utilizes a two-compone
105 hortcomings, Mexico is better set to develop biological control-based pest control programs, particul
106 athogenic nematodes (EPNs) have been used in biological control but improvement is needed to realize
107 le parasitoid production for the purposes of biological control by manipulation of biotic and abiotic
108  in the aboveground parts of plants and that biological control can be enhanced with induced plant de
109                               In a number of biological control circuits, the communication is carrie
110 ng effects of VTPs on dynamical systems in a biological control context.
111                 Despite these uncertainties, biological control could play a larger role in mitigatio
112 cts and native plants, potentially affecting biological control efficacy and non-target effects on na
113 hasizing the fauna associated with classical biological control efforts against the greenbug and Russ
114 uss how these predictions can inform ongoing biological control efforts for host-vector disease syste
115 opulations in many situations, and classical biological control efforts have focused on the addition
116 red predictably from novel native orthogonal biological control elements using quantitatively in-cont
117                                        While biological control focused at the level of the transcrip
118        Coccinellids have been widely used in biological control for over a century, and the methods f
119 cultured cells have led to new insights into biological control, greater understanding of human patho
120                                              Biological control has been proposed to suppress Panama
121            In contrast, with few exceptions, biological control has failed almost completely in easte
122 establishment of coccinellids in importation biological control have not been examined for most speci
123 ss of intraguild predators used in classical biological control, have a unique biology.
124  control tactics (disease-control chemicals, biological control, host resistance, and cultural contro
125                   We identify conditions for biological control (i) to prevent a pathogen entering a
126 ealing unforeseen trophic relationships with biological control implications.
127 ction, population biology and evolution, and biological control implications.
128 nse and manipulating plant traits to improve biological control in agricultural crops.
129 ed at favoring natural enemies and enhancing biological control in agricultural systems.
130 able promise for its application in food and biological control in analytical applications with high
131 of the four strains exhibiting the strongest biological control in vivo was also investigated in term
132 situation is then examined with reference to biological control, including SIT programs, targeted at
133             Current management is focused on biological control, insecticide protection of high-value
134                                              Biological control is an underlying pillar of integrated
135 ation is that, since it is expected that the biological control is distributed and mutually reinforci
136                             The potential of biological control is examined.
137  importance for management, conservation and biological control is how changing connectivity affects
138                 Impact of hyperparasitism on biological control is reviewed.
139   Habitat management, a form of conservation biological control, is an ecologically based approach ai
140                    Future studies evaluating biological control mechanisms can now focus on genes exp
141 or targeted drug delivery research that uses biological control mechanisms.
142                                 Chemical and biological control methods have reduced the impact of th
143 nder of plant pathology in Europe, pioneered biological control of a major plant disease and introduc
144 replaced with a synthetic material under the biological control of a precisely regulated cross-linkin
145  special case is applied to a problem of the biological control of a structured pest population (e.g.
146              Current evidence indicates that biological control of AC activity occurs through the cyt
147 ius ervi, an important hymenopteran agent of biological control of aphids in agriculture, using a nov
148 aches and methods available for valuation of biological control of arthropod pests by arthropod natur
149 versity has been the rationale for enhancing biological control of arthropod pests through habitat ma
150 iulus cucumeris is a predatory mite used for biological control of arthropod pests.
151 oth healthy and SLE cells suggesting further biological control of C1q-CD33/LAIR-1 processes.
152                 In addition to their use for biological control of certain insects, baculoviruses als
153                                              Biological control of chestnut blight caused by the fila
154 use traditional pest control theory to guide biological control of disease vectors.
155                               In the future, biological control of diseases in greenhouses could pred
156 ed for DNA in vivo, and may be exploited for biological control of genomic processes.
157 er chemical pesticides, in the same way that biological control of greenhouse insects predominates in
158 d Notch signaling interfered with the normal biological control of hemodynamics, permitting a positiv
159 eory on multiple predator effects as well as biological control of insect herbivores.
160 ensis (Bt) are increasingly important in the biological control of insect pests and vectors of human
161 y useful model organism and is deployed as a biological control of insect pests.
162 ema carpocapsae has been widely used for the biological control of insect pests.
163                                              Biological control of insects is an ecosystem service th
164 ange affects species interactions for future biological control of invasive species and conservation
165 nces the prospect of using Wolbachia for the biological control of malaria.
166 st widespread endosymbionts, is a target for biological control of mosquito-borne diseases (malaria a
167                  There have been advances in biological control of nematodes, but field-scale exploit
168 finding potentially has implications for the biological control of other insect crop pests.
169 enuating mycoviruses that have potential for biological control of pathogenic fungi.
170                                              Biological control of pests by natural enemies is a majo
171             Strains of Bcc have been used in biological control of plant diseases and bioremediation,
172 ered fungicides offer a unique niche for the biological control of plant diseases.
173 s the potential to be an effective method of biological control of plant parasite infection.
174 ial of photosynthetic bacterial resources in biological control of plant virus diseases and sustainab
175                                              Biological control of postharvest diseases (BCPD) has em
176 can stabilize unstable conditions and rescue biological control of simpler, ineffective pest manageme
177 and consequently have a direct impact on the biological control of soft scale insects.
178 cetylphloroglucinol (DAPG) contribute to the biological control of soilborne plant diseases by some s
179  that have subsequently been applied for the biological control of soilborne plant pathogens, the ful
180 ll pools; however, little is known about the biological control of the Numb-p53 interaction.
181 nositol 3,4,5-triphosphate, resulting in the biological control of the phosphatidylinositol 3-kinase
182       Here, we estimate the value of natural biological control of the soybean aphid, a major pest in
183                        This enables discrete biological control of these central structural features.
184                                              Biological control of vectors using natural enemies or c
185 tive trait loci (QTL) that contribute to the biological control of voluntary exercise levels, body we
186 rmosa is a parasitoid used worldwide for the biological control of whiteflies on vegetables and ornam
187 udy elucidates some of the environmental and biological controls of temporal variability of delta(15)
188                                              Biological control offers sustainable pest suppression,
189                                      Setting biological control on a firm economic foundation would h
190 ptake rates by biomass will also have strong biological control on silica cycling and export.
191 rature concerning the physical, chemical and biological controls on the sea-air emissions of a wide r
192 introduction of specific fungi into soil for biological control or bioremediation purposes.
193 ed to examine the effects of A. inebrians on biological control organisms and levels of plant disease
194 he results indicate that a dimethyl sulphide biological control over cloud condensation nuclei probab
195        Understanding molecular mechanisms of biological control over COM crystallization is central t
196 ctivity is strictly controlled, but when the biological control over the activity is lost, disease pr
197     Thus, we propose that qE is explained by biological control over the intrinsic dynamic disorder i
198      This condition is thought to arise from biological control over the ocean's nitrogen budget, in
199 ux remains a major frontier in understanding biological controls over soil C.
200 le utility for continuing efforts to enhance biological control potential by balancing hypovirulence
201  pathogenesis, and new avenues for enhancing biological control potential.
202 rulence-attenuating mycoviruses and enhanced biological control potential.
203 uantified, but the risks and net benefits of biological control programs are often derived from socia
204 mopathogenic nematode species for particular biological control programs.
205 nt and habitat manipulations on cereal aphid biological control provide significant and underexplored
206                                    Effective biological control requires careful matching of antagoni
207 ntomophagous arthropods can provide valuable biological control services, but they need to fulfill th
208 th in field and lab, to identify a potential biological control species of the common pest of commerc
209                                              Biological control still focuses almost exclusively on a
210              Gene expression profiles of the biological control strain Pseudomonas protegens Pf-5 inh
211 A. radiobacter K84, a commercially available biological control strain that inhibits certain pathogen
212  but taxonomic distinctions have not enabled biological control strains to be clearly distinguished f
213 ds predictions that are useful in developing biological control strategies for vector-borne diseases.
214                                   Successful biological control strategies will depend on a thorough
215 nitiates molecular studies of this important biological control system.
216 asized, including interactions observed from biological control systems, endosymbiotic relationships,
217 he direct and indirect costs and benefits of biological control that will allow farmers and others to
218             For producers who rely solely on biological control, the value of lost services is much g
219 hnology has the potential to disrupt natural biological control through both direct and indirect side
220  and opportunities for applying economics to biological control to advance integrated pest management
221 major plant disease and introduced the term "biological control" to plant pathology.
222 e partitioning strategies for more effective biological control, to blend organic amendments to foste
223  of novel synthetic biology tools to achieve biological control using genome bioediting technologies
224                           One such method is biological control using nematode trapping fungi such as
225                                              Biological control using predators of key pest species i
226  of insecticides, classical and augmentative biological control, utilization of resistant varieties,
227                        Early experience with biological control was hampered significantly by the inh
228 ve controls to ensure that the dosimetry and biological controls were comparable, the measured oncoge
229 hasis is placed on valuation of conservation biological control, which has received little attention.
230                                 Postharvest, biological controls will be important to remove shellfis

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