Copidosoma koehleri

Last updated

Copidosoma koehleri
Copidosoma koehleri 03.jpg
Scientific classification OOjs UI icon edit-ltr.svg
Domain: Eukaryota
Kingdom: Animalia
Phylum: Arthropoda
Class: Insecta
Order: Hymenoptera
Family: Encyrtidae
Genus: Copidosoma
Species:
C. koehleri
Binomial name
Copidosoma koehleri
Blanchard, 1940

Copidosoma koehleri belongs to the family Encyrtidae and genus Copidosoma within the order Hymenoptera. [1] It is a parasitoid and its hosts are mainly potato tuber moth (Phthorimaea operculella) but it also infest Andean potato tuber moth (Symmetrischema tangolias), Guatemalan potato tuber moth (Tecia solanivora) and Tomato leafminer (Tuta absoluta). [2] Super-parasitism is associated with C. koehleri. [3]

Contents

Morphology

Adults measure between 1.1–1.4 mm and their middle legs are enlarged which is mainly used for jumping. They have short hairs which cover their wings. [2] Female are different compared to males as the females have antennae which are long and slender with 3 segmented oval clava. Males have short antennae with 7 segments. They have a dark head and thorax with a metallic green sheen. [2]

Distribution

The polyembryonic encryrtid Copidosoma koehleri Blanchard naturally inhabits South America, specifically in regions spanning Brazil, Argentina, and Chile. [4] They originate from regions including: Peru, Uruguay, Ecuador, and Bolivia. [2] They were also introduced to some regions including: Australia (including Tasmania), Cyprus, Kenya, India, Mauritius, USA (California), South Africa, St. Helena, Zimbabwe, and Zambia. [2]

Development stages

Egg

The egg structure in Copidosoma koehleri resembles a dumbbell, comprising a bulb, neck, and a larger base, measuring around 0.17 mm in total length. Up to 40 embryos can emerge from a single fertilised egg in C. koehleri. [2] These embryos differentiate into two distinct forms: one matures into an adult while the other transforms into a soldier, tasked with eliminating other parasitoid species within the host. [2] Unfertilised eggs in C. koehleri naturally develop into male individuals. [4]

Larva

The juvenile larvae have no colour but they change colour after feeding on the host tissue where they become creamy-white opaque. [2] They completely feed on the host while developing into a pupa. [1] The host body acts as a habitat in order for the larvae to develop. [5] The cream-white larvae feed on the host ventricles and they change from creamy-white to orange. The host body then surrounds the parasitoids and then they emerge. [2] This occurs around the twelfth day where the larvae reach maturity and depart from the tubers to undergo pupation. [4]

Pupa

As larval development finishes, the larva produces a cocoon sheath for pupation. Initially, the pupa appears entirely white, but within approximately 24 hours, a brick-red pigmentation colours the eyes. Subsequently, melanization starts, with the abdominal tergites being the initial structures to darken and turn black. [2] Pupation typically takes place around the fourteenth day, and the emergence of adult moths happens approximately on the twentieth day. [4]

Host choice

Selecting the right habitat could significantly impact an individual's survival, foraging abilities, and reproductive success. [5] The quality of the host directly influences the survival, developmental rate, and size of offspring upon emergence. Consequently, C. koehleri frequently make adaptive choices regarding hosts based on their species, size, and developmental stage. [5] Moreover, females frequently refrain from depositing eggs in hosts that have been parasitised before. They tend to avoid hosts previously parasitised by themselves more than those parasitised by other members of their species. This behavior likely diminishes competition among siblings, as the avoidance of self super-parasitism is favoured. [5]

Polyembryony

Polyembryony is an exceptional developmental process that occurs in C. koehleri. [6] Another remarkable aspect of polyembryonic encyrtids involves the creation of a soldier caste. Within the clonal division process, a portion of embryos transforms into sterile soldier larvae. These soldiers engage in combat against competitors within the host but never reach maturity or emerge from the host. [6]

As a pest control

The encyrtid polyembryonic parasitoid, C.koehleri, has been effectively introduced to facilitate the biological control of moths in potato fields across South Africa and Australia. [7] The are effective in the control of the potato tuber moth. [8] Female wasps deposit their eggs inside potato tuber moth eggs, with each egg undergoing multiple divisions to create a cluster of 50 genetically identical embryos. Meanwhile, the host moth progresses through 4 larval instars. [7]

Copidosoma koehleri displays numerous characteristics that are deemed beneficial for biological control agents, including high host specificity, high reproductive rate and targeting hosts at an early stage in its life cycle. [7] In Zimbabwe, classical biological control showed significant success. [2] Upon its implementation in Australia, it began to hold a vital role in controlling P. operculella, particularly following the introduction of a potato integrated pest management program that reduced the necessity for frequent pesticide applications. [2] However, they do not are not efficient in controlling potato tuber moth in stored potatoes. [9]

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">Parasitoid</span> Organism that lives with its host and kills it

In evolutionary ecology, a parasitoid is an organism that lives in close association with its host at the host's expense, eventually resulting in the death of the host. Parasitoidism is one of six major evolutionary strategies within parasitism, distinguished by the fatal prognosis for the host, which makes the strategy close to predation.

<span class="mw-page-title-main">Tachinidae</span> Family of insects

The Tachinidae are a large and variable family of true flies within the insect order Diptera, with more than 8,200 known species and many more to be discovered. Over 1,300 species have been described in North America alone. Insects in this family commonly are called tachinid flies or simply tachinids. As far as is known, they all are protelean parasitoids, or occasionally parasites, of arthropods, usually other insects. The family is known from many habitats in all zoogeographical regions and is especially diverse in South America.

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

The Ichneumonidae, also known as ichneumon wasps, ichneumonid wasps, ichneumonids, or Darwin wasps, are a family of parasitoid wasps of the insect order Hymenoptera. They are one of the most diverse groups within the Hymenoptera with roughly 25,000 species described as of 2016. However, this likely represents less than a quarter of their true richness as reliable estimates are lacking, along with much of the most basic knowledge about their ecology, distribution, and evolution. It is estimated that there are more species in this family than there are species of birds and mammals combined. Ichneumonid wasps, with very few exceptions, attack the immature stages of holometabolous insects and spiders, eventually killing their hosts. They thus fulfill an important role as regulators of insect populations, both in natural and semi-natural systems, making them promising agents for biological 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.

<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.

<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">Encyrtidae</span> Family of wasps

Encyrtidae is a large family of parasitic wasps, with some 3710 described species in about 455 genera. The larvae of the majority are primary parasitoids on Hemiptera, though other hosts are attacked, and details of the life history can be variable. They are found throughout the world in virtually all habitats, and are extremely important as biological control agents. They may also present as an ecological threat to the population of some species. For example, the endangered Papilio homerus butterfly is parasitized at a rate of 77%, making them the main contributor to egg mortality in this butterfly species.

<i>Phthorimaea operculella</i> Species of moth

Phthorimaea operculella, also known as the potato tuber moth or tobacco splitworm, is a moth of the family Gelechiidae. It is an oligophagous insect that feeds on the plant family Solanaceae and is especially known for being a major pest of potato crops. Currently farmers utilize insecticides, parasites, and sprinkler irrigation in order to prevent P. operculella from infesting their croplands.

Polyembryony is the phenomenon of two or more embryos developing from a single fertilized egg. Due to the embryos resulting from the same egg, the embryos are identical to one another, but are genetically diverse from the parents. The genetic difference between the offspring and the parents, but the similarity among siblings, are significant distinctions between polyembryony and the process of budding and typical sexual reproduction. Polyembryony can occur in humans, resulting in identical twins, though the process is random and at a low frequency. Polyembryony occurs regularly in many species of vertebrates, invertebrates, and plants.

<i>Glyptapanteles</i> Genus of wasps

Glyptapanteles is a genus of endoparasitoid wasps found in all continents, except Antarctica. The larvae of Glyptapanteles species are able to manipulate their hosts into serving as bodyguards.

<span class="mw-page-title-main">Wasp</span> Group of insects

A wasp is any insect of the narrow-waisted suborder Apocrita of the order Hymenoptera which is neither a bee nor an ant; this excludes the broad-waisted sawflies (Symphyta), which look somewhat like wasps, but are in a separate suborder. The wasps do not constitute a clade, a complete natural group with a single ancestor, as bees and ants are deeply nested within the wasps, having evolved from wasp ancestors. Wasps that are members of the clade Aculeata can sting their prey.

<i>Ardices canescens</i> Species of moth

Ardices canescens, the dark-spotted tiger moth or light ermine moth, is a moth in the family Erebidae that is found across most of Australia. It originally was included in the genus Spilosoma, but later the generic status of Ardices was proven.

<i>Trigonospila brevifacies</i> Species of fly

Trigonospila brevifacies is a species of true fly in the family Tachinidae native to eastern Australia. This species is also found in New Zealand. Like the vast majority of tachinid flies, T. brevifacies is a parasitoid of other insects, specifically late larval stages of a number of species of Lepidoptera. It is also known as the Australian Leaf-Roller Fly or Leafroller Fly.

<i>Oobius agrili</i> Species of wasp

Oobius agrili is a parasitic non-stinging wasp of family Encyrtidae which is native to North Asia. It is a parasitoid of the emerald ash borer, an invasive species which has destroyed tens of millions of ash trees in its introduced range in North America. As part of the campaign against the emerald ash borer (EAB), American scientists in conjunction with the Chinese Academy of Forestry searched since 2003 for its natural enemies in the wild leading to the discovery of several parasitoid wasps, including Oobius agrili, which is a solitary egg parasitoid of EAB found on ash trees in Jilin province in 2004; it has been recorded to kill up to 60 percent of EAB eggs.

<i>Copidosoma</i> Genus of wasps

Copidosoma is a genus of chalcid wasps, which are parasitoids of Lepidoptera. The wasps are polyembryonic, depositing one or two eggs into their host which then develop into multiple offspring and have a soldier caste and a reproductive caste.

<i>Copidosoma floridanum</i> Species of wasp

Copidosoma floridanum is a species of wasp in the family Encyrtidae which is primarily a parasitoid of moths in the subfamily Plusiinae. It has the largest recorded brood of any parasitoidal insect, at 3,055 individuals. The life cycle begins when a female oviposits into the eggs of a suitable host species, laying one or two eggs per host. Each egg divides repeatedly and develops into a brood of multiple individuals, a phenomenon called polyembryony. The larvae grow inside their host, breaking free at the end of the host's own larval stage.

<i>Evania appendigaster</i> Species of wasp

Evania appendigaster, also known as the blue-eyed ensign wasp, is a species of wasp in the family Evaniidae. Its native range is not known, but it likely originated in Asia. Today it occurs throughout the tropics and subtropics and in many temperate regions. As with the rest of its family, the blue-eyed ensign wasp is a parasitoid known for specializing on cockroach eggs.

<i>Lysiphlebus testaceipes</i> Species of wasp

Lysiphlebus testaceipes is a species of small braconid parasitoid wasp in the subfamily Aphidiinae. L. testaceipes can utilize numerous species of aphids as hosts and has often been used as a biological control agent against aphid pests. It is considered an invasive species in several European countries.

References

  1. 1 2 Hardy, I.C.W (1996). "Precocious larvae in the polyembryonic parasitoid Copidosoma sosares (Hymenoptera: Encyrtidae)". Ent. Ber. Amst. 56 (5): 88–92.
  2. 1 2 3 4 5 6 7 8 9 10 11 12 Canedo, V; Carhuapoma, P; Lopez, E; Kroschel, J (2003). Pet distribution and risk atlas for Africa. pp. 208–219.
  3. Keasar, T; Segoli, M; Barak, R; Steinberg, S; Giron, D; Strand, M.R; Bouskila, A; Harari, A.R (2006). "Costs and consequences of superparasitism in the polyembryonic parasitoid Copidosoma koehleri (Hymenoptera: Encyrtidae)". Ecological Enthomology. 31 (277–283): 277. Bibcode:2006EcoEn..31..277K. doi:10.1111/j.1365-2311.2006.00788.x. S2CID   85965033.
  4. 1 2 3 4 Doutt, R.L (1947). "Polyembryony in Copidosoma koehleri Blanchard 1". The American Naturalist. 81 (801): 435–453. doi:10.1086/281554. S2CID   84412159.
  5. 1 2 3 4 Segoli, M; Keasar, T; Bouskila, A; Harari, A.R (2010). "Host choice decisions in the polyembryonic wasp Copidosoma koehleri (Hymenoptera: Encyrtidae)". Physiological Entomology. 35: 40–45. doi:10.1111/j.1365-3032.2009.00708.x. S2CID   85390330.
  6. 1 2 Segoli, M; Amos, B; Ally, R.H; Tamar, K (2009). "Development patterns in the polyembryonic parasitoid wasp Copidosoma koehleri". Arthropod Structure & Development. 38 (1): 84–90. doi:10.1016/j.asd.2008.05.003. PMID   18638571.
  7. 1 2 3 Tamar, K; Steinberg, S (2008). "Evaluation of the parasitoid Copidosoma koehleri for biological control of the potato tuber moth, Phthorimaea operculella, in Israeli potato fields". Biocontrol Science and Technology. 18 (4): 325–336. Bibcode:2008BioST..18..325K. doi:10.1080/09583150801905596. S2CID   85142510.
  8. Baggen, L.R; Gurr, M.G (1998). "The Influence of Food on Copidosoma koehleri (Hymenoptera: Encyrtidae), and the Use of Flowering Plants as a Habitat Management Tool to Enhance Biological Control of Potato Moth, Phthorimaea operculella (Lepidoptera: Gelechiidae)". Biological Control. 11 (1): 9–17. Bibcode:1998BiolC..11....9B. doi:10.1006/bcon.1997.0566.
  9. Keasar, T; Sadeh, A (2007). "The parasitoid Copidosoma koehleri provides limited control of the potato tuber moth, Phthorimaea operculella, in stored potatoes". Biological Control. 42 (1): 55–60. Bibcode:2007BiolC..42...55K. doi:10.1016/j.biocontrol.2007.03.012.
This page is based on this Wikipedia article
Text is available under the CC BY-SA 4.0 license; additional terms may apply.
Images, videos and audio are available under their respective licenses.