BIOINSECTICIDES AS FUTURE MAINSTREAM PEST CONTROL AGENTS: OPPORTUNITIES AND CHALLENGES
Mingbo QU1,2, Hans MERZENDORFER3(), Bernard MOUSSIAN4(), Qing YANG1,2,5()
1. School of Bioengineering, Dalian University of Technology, Dalian 116024, China. 2. State Key Laboratory for Biology of Plant Diseases and Insect Pests, Institute of Plant Protection, Chinese Academy of Agricultural Sciences, Beijing 100193, China. 3. Institute of Biology, University of Siegen, 57076 Siegen, Germany. 4. Interfaculty Institute of Cell Biology, University of Tübingen, 72076 Tübingen, Germany. 5. Shenzhen Branch, Guangdong Laboratory for Lingnan Modern Agriculture, Genome Analysis Laboratory of the Ministry of Agriculture and Rural Affairs, Agricultural Genomics Institute at Shenzhen, Chinese Academy of Agricultural Sciences, Shenzhen 518120, China.
•Wide use of botanical insecticides is limited by the availability of certain plants.
•Studies are needed to improve RNAi efficiency and to assess their safety risk.
•Microbial insecticides are promising, but they only control a narrow range of pests.
•Multitarget approach should be a promising strategy in future pest control.
•Nanoformulation could enhance stability and control the release of bioinsecticides.
Bioinsecticides are naturally-occurring substances from different sources that control insect pests. Ideal bioinsecticides should have low toxicity to non-target organisms. They should also be easily degraded in sewage treatment works and natural environments, highly effective in small quantities and affect target pests only. Public concerns about possible side-effects of synthetic pesticides have accelerated bioinsecticide research and development. However, to develop bioinsecticides into mainstream products, their high production costs, short shelf-life and often uncertain modes of action need to be considered. This review summarizes current progress on bioinsecticides which are categorized as biochemical insecticides and their derivatives, plant-incorporated protectants, and microbial bioinsecticides. The current constraints that prevent bioinsecticides from being widely used are discussed and future research directions are proposed.
Corresponding Author(s):
Hans MERZENDORFER,Bernard MOUSSIAN,Qing YANG
引用本文:
. [J]. Frontiers of Agricultural Science and Engineering, 2022, 9(1): 82-97.
Mingbo QU, Hans MERZENDORFER, Bernard MOUSSIAN, Qing YANG. BIOINSECTICIDES AS FUTURE MAINSTREAM PEST CONTROL AGENTS: OPPORTUNITIES AND CHALLENGES. Front. Agr. Sci. Eng. , 2022, 9(1): 82-97.
These hormones are chemically unstable, thus their agonists and antagonist are widely used as insecticides
[4,5]
Ecdysone
Ecdysone receptor
Semiochemicals
Aldehydes, terpenes, alkanes, triglycerides and so on
–
They are applied to suppress insect pests using strategies such as attract-and-kill, mass trapping, mating disruption, monitoring and push–pull
[6–10]
Animal toxins
Spider venoms
Postsynaptic receptors
They are mostly used as PIPs generating transgenic plants or for viral vector construction
[11]
β-Toxins
Insect voltage-gated sodium channels
[12]
Microbial
Chemicals
Avermectins
Glutamate-gated Cl− channels
They are widely applied as insecticides. The high resistance by the pests has been developed, and toxicity to humans and animals has been reported
[13,14]
Spinosyns
Nicotinic acetylcholine receptor
Okaramines
L-glutamate-gated chloride channels
It could be developed as new insecticide
[15]
Microbial toxins
Bt endotoxins
Receptor in the insect midgut cells
They have been sprayed to control mosquito larvae in breeding areas. More frequently, they have been introduced into transgenic crops or sold with live spores to control insect pests
[16–18]
Botanical insecticides
Essential oils
Neem oil, orange oil, rosemary oil, peppermint oil
Multiple targets such as P450 cytochromes, octopamine receptors
They have been widely used as bioinsecticides. However, many essential oils are restricted to local, indigenous use because of their lack of widespread cultivation
[19–22]
Pyrethrins
–
Voltage-gated sodium channels
It has been widely used in agricultural pest control, structural pest control and for public health
[23]
Azadirachtin
–
Insect growth regulator
It has been widely used for decades against insect pest
[24–26]
Rotenone
–
Site I respiration in mitochondria
It has been used as an insecticide for more than 150 years, but fallen out of favor in most industrialized countries because of mammalian toxicity
[14]
Plant alkaloids
Nicotine
Cholinergic acetylcholine nicotinic receptor
It has been used for many years as a fumigant for the control of many insects. But it is very toxic to humans by inhalation or skin contact
[27]
Ryania
Calcium channels in the sarcoplasmic reticulum
It has limited use as insecticides because they are moderately toxic to mammals, but very toxic to fish
[28]
Sabadilla
Voltage-sensitive sodium channels
It is used for the control of thrips on citrus, avocados, and mangos
[28]
Plant-Incorporated Protectants
Insecticidal proteins-based PIPs
Bt toxins
–
Receptor in the insect midgut cells
Bt genes have been approved for commercialized cultivation in most of the major grain and economic crops. Other insecticidal proteins have also been evaluated as potential PIPs
[29–31]
RNAi-based PIPs
–
Multiple targets
RNAi-based PIPs are highly specific and provide an environmentally friendly method to control insect pests. Public resentment toward genetically modified plants generally limits their acceptance
Release toxins targeting receptor in the insect midgut cells
B. thuringiensis is the most widely used species to control a variety of insect pests in agriculture, forestry and public health. To date, over one hundred B. thuringiensis-based bioinsecticides have been developed
Attack integument or gut epithelium, utilizing nutrients in the hemocoel, some release toxins
They have been widely evaluated as control agents for a diverse variety of noxious arthropods of agricultural importance
[35]
Viral bioinsecticides
–
Nucleopolyhedroviruses, granuloviruses
Cell lysis
The use of entomopathogenic viruses in global crop protection has grown in the last decade, mainly to control lepidopteran pests
[36]
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