Trichogramma japonicum

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Trichogramma japonicum
Scientific classification OOjs UI icon edit-ltr.svg
Domain: Eukaryota
Kingdom: Animalia
Phylum: Arthropoda
Class: Insecta
Order: Hymenoptera
Family: Trichogrammatidae
Genus: Trichogramma
Species:
T. japonicum
Binomial name
Trichogramma japonicum
Ashmead, 1904

Trichogramma japonicum is a minute wasp parasitoid from the Trichogrammatidae family in the order Hymenoptera . T. japonicum parasitizes the eggs of many pest species, especially Lepidoptera found in many monocultures. [1] They are entomophagous parasitoids that deposit their eggs inside the host species' egg, consuming the host egg material and emerging from the egg once development is complete. T. japonicum can be found naturally in rice ecosystems, but are dispersed commercially to many monocultures as a biological control. [2] The mitochondrial genomes of T. japonicum are significantly rearranged when comparing it to related insects. [3]

Contents

Reproduction

Trichogramma japonicum is an egg parasitoid of several insect species, many pests to crops. [4] Sex pheromones are released by females to attract males who are searching for suitable mates. [5] Once the female's eggs have been fertilized, she will search for a host species to lay her eggs in. Each female produces approximately 45 offspring. [2] T. japonicum uses chemical signals produced from herbivore-induced damaged host plants to locate the eggs of the host insects. [6] Once a suitable host is found, she will use her dramatically long ovipositor to insert her eggs directly into the host egg's deep layers. [1]

Chemical sensing

Trichogramma japonicum senses chemicals through olfactory receptors located mainly on the face. [7] Females have more chemoreceptors on their heads than males, which may be due to females needing to identify and locate volatile odours during host or mate localization. [7] T. japonicum relies on long-range chemical emissions from damaged plants in order to locate hosts. [8] They are able to discriminate between plants that have been injured and plants that are untouched by sensing the chemical emissions. The parasitoid will also respond to close-range chemical emissions from various Lepidopteran by-products. [1] Lepidoptera will inadvertently leave behind chemical-inducing objects that can attract the egg parasitoid. Lepidoptera can leave behind female wing scales, larva saliva, footprints, and egg wash which will act like kairomones and attract the parasitoid. [1] T. japonicum will not start looking for a host if there is no volatile stimulation. [8]

Ecological influence

Biological control agent

Trichogramma japonicum is an important natural enemy of pests in agro-eco-systems. [5] T. japonicum is a very successful biological control for the rice stem borer, Scirpophaga incertulas . [6] In order for this species to be a successful biological control, the wasps need to have time-specific multiple releases. [9] The times for these releases would be based on the climate conditions and pest biology. [9] The consideration of these variables allows for the wasps to be the most effective. Other factors can also influence T. japonicum's activity against the rice yellow stem borer. The synthetic forms of natural chemicals were found to increase the parasitic activity of the wasps by enhancing their egg parasitism [1] T. japonicum is also an amazing biological control for Cnaphalocrocis medinalis. These wasps have been found to be a better control agent than insecticides [10]

While T. japonicum may not be as effective as insecticides for all agricultural pests, such as Chilo suppressalis. The wasps can still prevent adverse effects of Chilo suppressalis to a controlled range, it just isn't as effective as some pesticides. [10] Even though T. japonicum is not always as efficient as insecticides, it should be considered a very good initial option. T. japonicum as a biological could greatly improve natural enemy populations, which will help prolong the effects of pest control. [10] The use of these wasps will also help protect the ecological environment, reduce pollination of fields, and ensure safe agricultural products. [10]

Effects of insecticides

The two most toxic types of pesticides for T. japonicum are organophosphates and carbamates. [4] [2] One study found that the highest mortality rate in T. japonicum is observed when acephate, an organophosphate, is used as a treatment. [4] The introduction of these insecticides when T. japonicum are being used will greatly reduce the wasps' effectiveness as a biological control. If a pesticide is to be used alongside T. japonicum, it should be an insect growth regulator as it has the lowest toxicity rate. [2] The adverse effects of insecticides are primarily seen in adults as they are more sensitive to the pesticides than juvenile forms. [2] The larval stages of T. japonicum are protected from the insecticides by the egg of the host species.

Related Research Articles

<span class="mw-page-title-main">Biological pest control</span> Controlling pests using other organisms

Biological control or biocontrol is a method of controlling pests, whether pest animals such as insects and mites, weeds, or pathogens affecting animals or plants by using other organisms. It relies on predation, parasitism, herbivory, or other natural mechanisms, but typically also involves an active human management role. It can be an important component of integrated pest management (IPM) programs.

<span class="mw-page-title-main">Chalcid wasp</span> Superfamily of wasps

Chalcid wasps are insects within the superfamily Chalcidoidea, part of the order Hymenoptera. The superfamily contains some 22,500 known species, and an estimated total diversity of more than 500,000 species, meaning the vast majority have yet to be discovered and described. The name "chalcid" is often confused with the name "chalcidid", though the latter refers strictly to one constituent family, the Chalcididae, rather than the superfamily as a whole; accordingly, most recent publications (e.g.,) use the name "chalcidoid" when referring to members of the superfamily.

<span class="mw-page-title-main">Integrated pest management</span> Approach for economic control of pests

Integrated pest management (IPM), also known as integrated pest control (IPC) is a broad-based approach that integrates both chemical and non-chemical practices for economic control of pests. IPM aims to suppress pest populations below the economic injury level (EIL). The UN's Food and Agriculture Organization defines IPM as "the careful consideration of all available pest control techniques and subsequent integration of appropriate measures that discourage the development of pest populations and keep pesticides and other interventions to levels that are economically justified and reduce or minimize risks to human health and the environment. IPM emphasizes the growth of a healthy crop with the least possible disruption to agro-ecosystems and encourages natural pest control mechanisms." Entomologists and ecologists have urged the adoption of IPM pest control since the 1970s. IPM allows for safer pest control.

<i>Trichogramma</i> Genus of parasitic insects

Trichogramma is a genus of minute polyphagous wasps that are endoparasitoids of insect eggs. Trichogramma is one of around 80 genera from the family Trichogrammatidae, with over 200 species worldwide.

<i>Manduca quinquemaculata</i> Species of moth

Manduca quinquemaculata, the five-spotted hawkmoth, is a brown and gray hawk moth of the family Sphingidae. The caterpillar, often referred to as the tomato hornworm, can be a major pest in gardens; they get their name from a dark projection on their posterior end and their use of tomatoes as host plants. Tomato hornworms are closely related to the tobacco hornworm Manduca sexta. This confusion arises because caterpillars of both species have similar morphologies and feed on the foliage of various plants from the family Solanaceae, so either species can be found on tobacco or tomato leaves. Because of this, the plant on which the caterpillar is found does not indicate its species.

<span class="mw-page-title-main">Parasitoid wasp</span> Group of wasps

Parasitoid wasps are a large group of hymenopteran superfamilies, with all but the wood wasps (Orussoidea) being in the wasp-waisted Apocrita. As parasitoids, they lay their eggs on or in the bodies of other arthropods, sooner or later causing the death of these hosts. Different species specialise in hosts from different insect orders, most often Lepidoptera, though some select beetles, flies, or bugs; the spider wasps (Pompilidae) exclusively attack spiders. More rarely, parasitoid wasps may use plant seeds as hosts, such as Torymus druparum.

<span class="mw-page-title-main">Eucharitidae</span> Family of wasps

The Eucharitidae are a family of parasitic wasps. Eucharitid wasps are members of the superfamily Chalcidoidea and consist of three subfamilies: Oraseminae, Eucharitinae, and Gollumiellinae. Most of the 55 genera and 417 species of Eucharitidae are members of the subfamilies Oraseminae and Eucharitinae, and are found in tropical regions of the world.

<span class="mw-page-title-main">Trichogrammatidae</span> Family of wasps

The Trichogrammatidae are a family of tiny wasps in the Chalcidoidea that include some of the smallest of all insects, with most species having adults less than 1 mm in length, with species of Megaphragma having an adult body length less than 300 μm. The over 840 species are placed in about 80 genera; their distribution is worldwide. Trichogrammatids parasitize the eggs of many different orders of insects. As such, they are among the more important biological control agents known, attacking many pest insects.

<span class="mw-page-title-main">Mediterranean flour moth</span> Species of moth

The Mediterranean flour moth or mill moth is a moth of the family Pyralidae. It is a common pest of cereal grains, especially flour. This moth is found throughout the world, especially in countries with temperate climates. It prefers warm temperatures for more rapid development, but it can survive a wide range of temperatures.

<i>Maruca vitrata</i> Species of moth

Maruca vitrata is a pantropical insect pest of leguminous crops like pigeon pea, cowpea, mung bean and soybean. Its common names include the maruca pod borer, bean pod borer, soybean pod borer, mung moth, and the legume pod borer. The species was first described by Johan Christian Fabricius in 1787.

<i>Scirpophaga incertulas</i> Species of moth

Scirpophaga incertulas, the yellow stem borer or rice yellow stem borer, is a species of moth of the family Crambidae. It was described by Francis Walker in 1863. It is found in Afghanistan, Nepal, north-eastern India, Sri Lanka, Bangladesh, Myanmar, Vietnam, Thailand, Malaysia, Singapore, Sumatra, Java, Borneo, Sumba, Sulawesi, the Philippines, Taiwan, China and Japan.

Trichogramma brassicae is a species of parasitoid wasps from the Trichogrammatidae family. It mainly parasitizes Lepidopteran hosts in agricultural fields. They are entomaphagous parasitoids that deposit their own eggs inside the host's eggs, consuming the host egg material and emerging upon full development. They are a common biological control species that have been used commercially since the late 1970s. Inundative releases of T. brassicae, recently, can be done by means of drones and integrated control with Bacillus thuringiensis subs. kurstaki were demonstrated effective as chemical insecticide treatments and of course without negative environmental side effects.

<i>Trissolcus japonicus</i> Species of wasp

Trissolcus japonicus, the samurai wasp, is a parasitoid wasp species in the family Scelionidae, native to east Asia but now found in Europe, North America, and Chile. It is chiefly known for parasitizing Halyomorpha halys. It deposits eggs into the eggs of the stink bug, and as the wasp larvae develop, they kill the stink bug eggs. A single adult wasp emerges from each stink bug egg.

<i>Ostrinia furnacalis</i> Species of moth

Ostrinia furnacalis is a species of moth in the family Crambidae, the grass moths. It was described by Achille Guenée in 1854 and is known by the common name Asian corn borer since this species is found in Asia and feeds mainly on corn crop. The moth is found from China to Australia, including in Java, Sulawesi, the Philippines, Borneo, New Guinea, the Solomon Islands, and Micronesia. The Asian corn borer is part of the species complex, Ostrinia, in which members are difficult to distinguish based on appearance. Other Ostrinia such as O. orientalis, O. scapulalis, O. zealis, and O. zaguliaevi can occur with O. furnacalis, and the taxa can be hard to tell apart.

Chilo infuscatellus, the yellow top borer or sugarcane shoot borer, is a moth in the family Crambidae. It was described by the Dutch entomologist Samuel Constantinus Snellen van Vollenhoven in 1890. It is found in India, Myanmar, Tajikistan, Afghanistan, Korea, Taiwan, Malaysia, the Philippines and on Java and Timor.

Scirpophaga excerptalis, the white top borer or sugarcane top borer, is a moth in the family Crambidae. It was described by Francis Walker in 1863. It is found in southern Asia from the Indian Subcontinent in the west to southern China in the east, south to New Guinea, possibly Australia and the Solomon Islands.

Bacillus thuringiensis subsp. kurstaki (Btk) is a group of bacteria used as biological control agents against lepidopterans. Btk, along with other B. thuringiensis products, is one of the most widely used biological pesticides due to its high specificity; it is effective against lepidopterans, and it has little to no effect on nontarget species. During sporulation, Btk produces a crystal protein that is lethal to lepidopteran larvae. Once ingested by the insect, the dissolution of the crystal allows the protoxin to be released. The toxin is then activated by the insect gut juice, and it begins to break down the gut.

<i>Telenomus podisi</i> Species of wasp

Telenomus podisi is a species of egg parasitoid wasps described by William Harris Ashmead in 1893 and placed in the family of Platygastridae. It is a parasitoid of the brown stink bug, Euschistus heros and can be raised in labs on the eggs of Cosmopepla lintneriana, Podisus maculiventris, and Euschistus servus. This wasp can be used in integrated pest management to control E. heros. The insecticide Imidacloprid is lethal for these wasps, and other insecticides have been shown to negatively impact rates of egg parasitism.

<i>Dicladispa armigera</i> Species of beetle

Dicladispa armigera is a species of leaf beetle from Southeast Asia, often known by its common name: the "rice hispa". These beetles are a well known invasive pest, and are responsible for significant crop damage across many countries. The male to female ratio is between 1:1.26 and 1:1.46.

Li Liying is a research fellow at the Institute of Zoology of Guangdong Academy of Sciences. She has developed pest control techniques that are used to treat millions of hectares of crops and forests worldwide. She has published more than 110 papers and 9 books.

References

  1. 1 2 3 4 5 Murali‐Baskaran, Ramasamy Kanagaraj; Sridhar, Jandrajupalli; Chander Sharma, Kailash; Jain, Lata; Senthil‐Nathan, Sengottayan; Hunter, Wayne Brain; Kumar, Jagdish; Kaushal, Pankaj (2020). "Kairomones effect on parasitic activity of Trichogramma japonicum against rice yellow stem borer, Scirpophaga incertulas". Journal of Applied Entomology. 144 (5): 373–381. doi:10.1111/jen.12747. S2CID   216171558.
  2. 1 2 3 4 5 Zhao, Xueping; Wu, Changxing; Wang, Yanhua; Cang, Tao; Chen, Liping; Yu, Ruixian; Wang, Qiang (2012). "Assessment of Toxicity Risk of Insecticides Used in Rice Ecosystem on Trichogramma japonicum, an Egg Parasitoid of Rice Lepidopterans". Journal of Economic Entomology. 105 (1): 92–101. doi: 10.1603/EC11259 . PMID   22420260. S2CID   25746852.
  3. Chen, Long; Chen, Peng-Yan; Xue, Xiao-Feng; Hua, Hai-Qing; Li, Yuan-Xi; Zhang, Fan; Wei, Shu-Jun (2018). "Extensive gene rearrangements in the mitochondrial genomes of two egg parasitoids, Trichogramma japonicum and Trichogramma ostriniae (Hymenoptera: Chalcidoidea: Trichogrammatidae)". Scientific Reports. 8 (1): 7034. Bibcode:2018NatSR...8.7034C. doi:10.1038/s41598-018-25338-3. PMC   5935716 . PMID   29728615.
  4. 1 2 3 Uma, S; Lyla, K. R. (2014). "Acute contact toxicity of selected conventional and novel insecticides to Trichogramma japonicum Ashmead (Hymenoptera: Trichogrammatidae)" (PDF). Journal of Biopesticides. 7: 133–136.
  5. 1 2 Wu, Jia-Dong; Shen, Zhao-Can; Hua, Hai-Qing; Zhang, Fan; Li, Yuan-Xi (2017-08-23). "Identification and sex expression profiling of odorant-binding protein genes in Trichogramma japonicum (Hymenoptera: Trichogrammatidae) using RNA-Seq". Applied Entomology and Zoology. 52 (4): 623–633. doi:10.1007/s13355-017-0516-x. S2CID   32684820.
  6. 1 2 Murali-Baskaran, R. K.; Sridhar, J.; Sharma, K. C.; Jain, L. (2021). "Kairomone gel formulations enhance biocontrol efficacy of Trichogramma japonicum Ashmead on rice yellow stem borer, Scirpophaga incertulas Walker". Crop Protection. 146: 105655. doi:10.1016/j.cropro.2021.105655. S2CID   235540666.
  7. 1 2 Li, Si-Sheng; Yan, Zhi-Chao; Zhao, Juan-Juan; Li, Yuan-Xi (2021). "Transcriptomic analyses of chemosensory genes in Trichogramma japonicum (Hymenoptera: Trichogrammatidae)". Comparative Biochemistry and Physiology Part D: Genomics and Proteomics. 37: 100755. doi:10.1016/j.cbd.2020.100755. PMID   33166853. S2CID   226295639.
  8. 1 2 Rani, P. Usha; Sandhyarani, K. (2012). "Specificity of systemically released rice stem volatiles on egg parasitoid, Trichogramma japonicum Ashmead behaviour". Journal of Applied Entomology. 136 (10): 749–760. doi:10.1111/j.1439-0418.2012.01705.x. S2CID   83242811.
  9. 1 2 Murali-Baskaran, Ramasamy Kanagaraj; Chander Sharma, Kailash; Sridhar, Jandrajupalli; Jain, Lata; Kumar, Jagdish (2021). "Multiple releases of Trichogramma japonicum Ashmead for biocontrol of rice yellow stem borer, Scirpophaga incertulas (Walker)". Crop Protection. 141: 141. doi:10.1016/j.cropro.2020.105471. S2CID   229386093.
  10. 1 2 3 4 Yang, L.; Qiu-sheng, Y.; Yu-zhu, Z.; Bao-hua, F.; Wei, K.; Guo-qi, Z. (2018). "Main Rice Pests Control with Trichogramma japonicum". Agricultural Science & Technology. 19 (2): 28–32.
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