Euwallacea interjectus

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Euwallacea interjectus
Euwallacea interjectus (lateral).jpg
Scientific classification OOjs UI icon edit-ltr.svg
Domain: Eukaryota
Kingdom: Animalia
Phylum: Arthropoda
Class: Insecta
Order: Coleoptera
Infraorder: Cucujiformia
Family: Curculionidae
Genus: Euwallacea
Species:
E. interjectus
Binomial name
Euwallacea interjectus
(Blandford, 1894)
Synonyms
  • Xyleborus interjectusBlandford, 1894
  • Xyleborus pseudovalidusEggers, 1925

Euwallacea interjectus is a species of ambrosia beetle in the species complex called Euwallacea fornicatus . It is native to Asia but has been introduced to the Western hemisphere over the last century. [1] [2]

Taxonomy

Lateral and dorsal views of Euwallacea species. From top left, Euwallacea fornicatus, E. interjectus, E. similis and E. validus. Euwallacea (10.3897-zookeys.768.24697) Figure 11.jpg
Lateral and dorsal views of Euwallacea species. From top left, Euwallacea fornicatus, E. interjectus, E. similis and E. validus.

The E. interjectus is part of the Asian ambrosia beetle species complex. These insects have a symbiosis with ambrosia fungi. [1]

Euwallacea validus

A sister species in the same genus, Euwallacea validus , looks almost identical to E. interjectus. [1] They differ in their fungal associations, host trees, and potential for detrimental effects on the economy. [1] E. validus and E. interjectus's similar appearance can lead to confusion between the two species. [1] DNA (Deoxyribonucleic acid) sequencing has aided in identification. [1]

To differentiate between the two species morphologically, the shape of the declivity, punctures, and placement of the tubercles on the base of the body can help identify between the two species. [1] In E. interjectus, the declivity (downward slope) is gradually sloped from the base apex, thus giving a smoother appearance. [1]

Morphology

Adult body sizes range from 3.5 to 9 millimetres (0.14 to 0.35 in) in length, with a mean length of 3.78 millimetres (0.149 in), and range in width from 2.4 to 2.64 millimetres (0.094 to 0.104 in). [3] The species is known for its pronotum, a plate-like structure that covers the thorax, and spindles that are present all over the body. [1] These beetles range in color from brown to black. [3] The male body is significantly smaller than the female and thus requires less food. [4] Moreover, females are the ones that have mycangia, a structure that allows for the store of fungi, and males are rarely ones that can infect fungi. [5]

Distribution and Habitat

E. interjectus is native to Asia. However, due to increasing trade and globalization, new populations have been found widely in warm regions of the globe. [1] E. interjectus is found in Myanmar, Japan, North Korea, South Korea, China, Taiwan, Tibet, India, Indonesia (Borneo, Java, Mentawei, Sumatra), Malaysia, Sarawak, Nepal, Philippines, Sri Lanka, Thailand, Vietnam, and recently the United States of America and Argentina. [6] [7] [3] [8]

United States

E. interjectus was first collected in the United States on the island of Oahu, Hawaii, in 1976. [1] The first reported mainland collection was in 2011 in Alachua County, Florida. [1] While it does not appear to be a primary pest on plants, it has been known to be abundant in the U.S., and mass outbreaks on water-stressed boxelder maples have been observed. [9] [1]

As of 2015, E. interjectus occupies the lower southwest of the United States. [1] Genetic studies provide insight to the spread of E. interjectus to the United States, where three separate introductions took place: Hawaii (1976), Louisiana (1984), and Texas (2011). [1] E. interjectus is mostly commonly seen in Alabama, Louisiana, Texas, Georgia, Florida, Mississippi, and South Carolina. [1] E. validus is most present in the northeast United States, however, overlap has been seen around the border of North and South Carolina and around Georgia. [1] Given their similar appearances, confirmation of species distribution is needed. [1]

Argentina

The E. interjectus came to Argentina via trade and were first found in April 2009 on a Populus deltoides plantation. The species has had a detrimental effect on poplars (Populus spp: Salicaceae), [8] , which are used for lumber and reconstituted board products. [8] The non-native species has become incredibly invasive in plantations in Argentina. [8] While E. interjectus typically colonizes dead trees, it has been known to attack live trees also. [8]

Japan

E. interjectus has affected Japanese fig orchards, contributing to fig wilt. [10] E. interjectus acts as a vector of Ceratocystis ficicola, a pathogenic fungus that causes wilt disease in fig trees ( Ficus carica L. ). [10]

China

Shanghai

Despite the eastern China origin of E. interjectus, in April 2014 E. interjectus was found in Pudong New Area in Shanghai, China. [9] These beetles occupied poplar trees (Populus x canadensis), where it was observed that there were "noodle-like frass extrusions and gallery entrances" on poplar trees in the region. [9]

Life cycle

Not much is known about the life cycle of E. interjectus in the wild. However, studies under experimental conditions have provided insights on the life cycle and breeding times. [11] E. interjectus starts as an egg, and then progresses to a larva, then to a pupa, then lives as an adult. [11] The species lives inside plants for all of its life, except during dispersal. E. interjectus breeds throughout the year. [12] [13] [14]

Ambrosia beetle life cycle Ambrosia beetle life cycle.svg
Ambrosia beetle life cycle

E. interjectus act as a fungal vector, transporting fungi to and from their natal galleries in the mycangia. [11] After the fungus is released from the mycangia, the fungi grow in galleries, providing nutrition. [11] The sex ratio of adults from the galleries was about 31:1 female to male, [15] compared to that of the Xyleborini ambrosia beetle, which has an average sex ratio of 13:1. [15]

Mating

E. interjectus, like other ambrosia beetles, are sexually dimorphic, where the role of a male is limited to mating. [4] E. interjectus follows haplodiploid mating—females have two sets of chromosomes but males only one—and inbreeding. Thus, only one female beetle is needed to establish a new population in a new environment, [14] posing a high risk of invasion. Haplodiploid mating has developed as a mechanism that filters out harmful inbreeding-related abnormalities. [16] If inbreeding-related abnormalities such as recessive lethal and deleterious alleles are expressed in haploid males, it leads to the death of these individuals. [14] They rarely appear in diploid females, and thus prevent these deleterious conditions from entering the population. [14]

Diet

Euwallacea interjectus exhibits a mutual symbiotic relationship with ambrosia fungi as a nutritional source. [17] Like other ambrosia beetles, the beetles will create tunnels in dead or stressed trees to cultivate fungal gardens as a food source. E. interjectus is unique in that it will, at times, choose healthy and alive trees as hosts. [17]

E. interjectus mainly invades the phloem and xylem of host plants, with known hosts being poplar and rubber trees. [14] E. interjectus often chooses trees that are weak from droughts or depleted of resources, thus those less resistant to attacks from beetles. [14] In addition, they prefer softer wood trees as hosts. [14] The spread and invasion of E. interjectus has been more apparent in high-density planting sites. [9] Because of more resource competition, high-density planting sites are more prone to weakened host resistance. [9]

Relationship to the environment

Poplar tree Lombardy Poplar tree - geograph.org.uk - 2413525.jpg
Poplar tree

These non-native beetles have entered these various habitats because of human trade as the movement of timber and other tree-based products has acted as vessels for transport. [8] E. interjectus' presence in Argentina serves as an example for the concern of the species' invasiveness. [8] E. interjectus is part of a few species that attack living trees and prefers high-density plantations, thus the species has impacted several plantations globablly. [8] In 1992, it was determined that E. interjectus did not affect poplar trees outside its natural range of distribution, however, these beetles are now abundant in the Delta of Parana River region, and several incidences of mass attack on live water-stressed poplars have been observed. [8]

Relationship with fungi

The mutual symbiotic relationship between E. interjectus and fungi is complex. The fungi are pathogenic to the host tree, which can lead to tree dieback and mortality. [17] This is a result of inoculation with existing fungi or by mass inoculation of fungal pathogens by the pests. [17] Ambrosia beetle-associated fungi compete with pre-existing decaying fungi of the woody tissues and reduce the rate of decay. [18] However, in native areas, it has been seen to have a more promiscuous relationship. [17] Compared to a strictly obligate combination, which is seen in invaded areas. [17] It has also been seen that the proportion of fungal species that an individual holding and consumption volume shifts over the developmental and maturation period. [17]

Cladosporium cladosporioides Cladosporium cladosporioides.jpg
Cladosporium cladosporioides

All over the world, E. interjectus act as vectors for different fungi. In Japan, it was identified that 13 filamentous fungi use E. interjectus as a vector: Fusarium kuroshium, Arthrinium arundinis, Cladosporium cladosporioides, Acremonium sp., Fusarium decemcellulare, Xylariales sp., Pithomyces chartarum, Roussoella sp., Phialophora sp., Stachybotrys longispora, Paecilomyces formosus, Sarocladium implicatum, and Bionectria pityrodes. [15]

Control methods

In order to control E. interjectus infestation, chemical insecticides can be applied to the bark and trunk of trees, or the whole tree, to control the number of adult beetles that emerge from the tunnel. [12] [13] However, because the timing of breeding is difficult to predict, given that E. interjectus "breeds throughout the year in many regions", it makes it difficult to know exactly when to apply the insecticide. [12] [13] However, whole body desiccating of E. interjectus has been incredibly effective against larvae, adults, and symbiotic fungi. [9]

Relationship to humans

Due to the invasive nature of E. interjectus and the damage imposed on trees, they have become a problem for the lumber, pulp, and paper industry. [8] Their effects on the economy have drawn research attention, to develop insecticides and remedies to prevent damage to plantations around the world. [8]

Related Research Articles

Ambrosia beetles are beetles of the weevil subfamilies Scolytinae and Platypodinae, which live in nutritional symbiosis with ambrosia fungi. The beetles excavate tunnels in dead or stressed trees into which they introduce fungal gardens, their sole source of nutrition. After landing on a suitable tree, an ambrosia beetle excavates a tunnel in which it releases its fungal symbiont. The fungus penetrates the plant's xylem tissue, extracts nutrients from it, and concentrates the nutrients on and near the surface of the beetle gallery. Ambrosia fungi are typically poor wood degraders, and instead utilize less demanding nutrients. Symbiotic fungi produce and detoxify ethanol, which is an attractant for ambrosia beetles and likely prevents growth of antagonistic pathogens and selects for other beneficial symbionts. The majority of ambrosia beetles colonize xylem of recently dead trees, but some colonize stressed trees that are still alive, and a few species attack healthy trees. Species differ in their preference for different parts of trees, different stages of deterioration, and in the shape of their tunnels ("galleries"). However, the majority of ambrosia beetles are not specialized to any taxonomic group of hosts, unlike most phytophagous organisms including the closely related bark beetles. One species of ambrosia beetle, Austroplatypus incompertus exhibits eusociality, one of the few organisms outside of Hymenoptera and Isoptera to do so.

<span class="mw-page-title-main">Bark beetle</span> Subfamily of beetles

A bark beetle is the common name for the subfamily of beetles Scolytinae. Previously, this was considered a distinct family (Scolytidae), but is now understood to be a specialized clade of the "true weevil" family (Curculionidae). Although the term "bark beetle" refers to the fact that many species feed in the inner bark (phloem) layer of trees, the subfamily also has many species with other lifestyles, including some that bore into wood, feed in fruit and seeds, or tunnel into herbaceous plants. Well-known species are members of the type genus Scolytus, namely the European elm bark beetle S. multistriatus and the large elm bark beetle S. scolytus, which like the American elm bark beetle Hylurgopinus rufipes, transmit Dutch elm disease fungi (Ophiostoma). The mountain pine beetle Dendroctonus ponderosae, southern pine beetle Dendroctonus frontalis, and their near relatives are major pests of conifer forests in North America. A similarly aggressive species in Europe is the spruce ips Ips typographus. A tiny bark beetle, the coffee berry borer, Hypothenemus hampei is a major pest on coffee plantations around the world.

<span class="mw-page-title-main">Mycangium</span>

The term mycangium is used in biology for special structures on the body of an animal that are adapted for the transport of symbiotic fungi. This is seen in many xylophagous insects, which apparently derive much of their nutrition from the digestion of various fungi that are growing amidst the wood fibers. In some cases, as in ambrosia beetles, the fungi are the sole food, and the excavations in the wood are simply to make a suitable microenvironment for the fungus to grow. In other cases, wood tissue is the main food, and fungi weaken the defense response from the host plant.

<i>Cryphalus</i> Genus of beetles

Cryphalus is a large genus of tiny bark beetles, subfamily Scolytinae, tribe Cryphalini in the family Curculionidae. The genus is widely distributed. The species feed and breed under the inner bark of trees. They infest mainly recently dead, dying or stressed trees. Some species are regarded as invasive pests, harmful to agriculture or forestry.

<span class="mw-page-title-main">Xyleborini</span> Tribe of beetles

Xyleborini are a tribe of ambrosia beetles, highly specialized weevils of the subfamily Scolytinae. Much of the ambrosia beetle fauna in Eurasia and the Americas consists of Xyleborini species. Some Xyleborini are notorious invasive species.

<i>Xyleborus glabratus</i> Species of beetle

Xyleborus glabratus, the redbay ambrosia beetle, is a type of ambrosia beetle invasive in the United States. It has been documented as the primary vector of Raffaelea lauricola, the fungus that causes laurel wilt, a disease that can kill several North American tree species in the family Lauraceae, including redbay, sassafras, and avocado.

<i>Austroplatypus incompertus</i> Species of beetle

Austroplatypus incompertus, a type of ambrosia beetle, is endemic to Australia. They are found in the mesic forests, and subtropical and tropical ecosystems along the east coast of Australia. There are many unique characteristics attributable to the A. incompertus, like their gallery excavation in several Eucalyptus species, their obligate eusocial behavior, their relationship with fungi, and their unique sexual dimorphism. These beetles are one of the only insects that display obligate eusocial behavior. Additionally, their sexually dimorphic traits are of interest, since body size is reversed with males having smaller torsos than female a.incompertus beetles.

<i>Euwallacea fornicatus</i> Species of beetle

Euwallacea fornicatus, also known as tea shot-hole borer, or polyphagous shot-hole borer (PSHB) is a species complex consisting of multiple cryptic species of ambrosia beetles known as an invasive species in California, Israel, South Africa, and Australia. The species has also been unintentionally introduced into exotic greenhouses in several European countries.

<i>Xylosandrus compactus</i> Species of beetle

Xylosandrus compactus is a species of ambrosia beetle. Common names for this beetle include black twig borer, black coffee borer, black coffee twig borer and tea stem borer. The adult beetle is dark brown or black and inconspicuous; it bores into a twig of a host plant and lays its eggs, and the larvae create further tunnels through the plant tissues. These beetles are agricultural pests that damage the shoots of such crops as coffee, tea, cocoa and avocado.

<i>Xyleborus affinis</i> Species of beetle

Xyleborus affinis, the sugarcane shot-hole borer, is a species of ambrosia beetle in the family Curculionidae. It is found on all continents with woodlands and is one of the most widespread ambrosia beetles internationally, primarily in areas with humid tropical climates like Florida. Like other ambrosia beetles, Xyleborus affinis is attracted to dead fallen logs in early stages of decay. Due to the presence of X. affinis on moist timber, this species is mistakenly believed to be the cause of tree death. However, there is insufficient evidence to support their presence as a causal factor. Rather, these beetles are believed to target and accelerate the decay process of trees that are already deteriorated and weak.

<i>Xylosandrus germanus</i> Species of beetle

Xylosandrus germanus, known generally as the alnus ambrosia beetle or black stem borer, is a species of ambrosia beetle in the family Curculionidae. X. germanus poses challenges in woody ornamental species and orchard crops such as apples and pecan. Furthermore, X. germanus is recognized or suspected to act as a vector for plant pathogens to varying extents, potentially leading to the decline of trees. The black stem borer is native to eastern Asia, but is an invasive species in Europe and North America. This species carries and feeds on associated ambrosia fungus, Ambrosiella grosmanniae.

<i>Xyleborinus saxesenii</i> Species of beetle

Xyleborinus saxesenii, commonly known as the fruit-tree pinhole borer, is a species of ambrosia beetle in the family Curculionidae. It is native to the Palaearctic region but has been introduced in many locations, including North America. X. saxesenii typically live in freshly dead wood, but it has also been reported to attack live trees. Such attacks on live trees may lead to economic damage.

Euplatypus parallelus, previously known as Platypus parallelus, is a species of ambrosia beetle in the weevil family Curculionidae. The adults and larvae form galleries in various species of tree and logs. It is native to Central and South America but has spread globally, is present in Africa and is well established in tropical Asia.

Xyleborinus andrewesi, is a species of weevil widely distributed throughout the Old World tropics and introduced to many New World countries.

Euwallacea perbrevis, commonly known as tea shot-hole borer, is a species of weevil native to South and South-East Asia through to Australia, but introduced to Western countries.

Ambrosiella roeperi is the fungal symbiont of the granulate ambrosia beetle, Xylosandrus crassiusculus, facilitating this insect’s capacity to accumulate on and damage a diverse array of woody plants from around the world. It is one of several important nutritional partners derived from order Microascales that sustain and are transported by xylomycetophagous scolytine beetles.

<i>Cryphalus dilutus</i> Species of beetle

Cryphalus dilutus, the spurred bark beetle, is a tropical and subtropical bark beetle which attacks fig and mango trees causing dieback. It belongs to the family Curculionidae, subfamily Scolytinae.

<i>Cryphalus mangiferae</i> Species of beetle

Cryphalus mangiferae, the mango bark beetle, is a tiny tropical bark beetle which attacks mango trees. The species belongs to the family Curculionidae, subfamily Scolytinae. It is often cited as a vector of plant pathogenic fungi infecting mango trees and in some countries like Pakistan it is regarded as a serious threat to mango cultivation.

<i>Euwallacea validus</i> Species of beetle

Euwallacea validus is a species of Euwallacea beetle native to Asia. The beetle species was discovered in Long Island, New York in 1975. Like other Euwallacea species beetles, E. validus is known for its mutualistic symbiotic relationship with fungi, acting as a vector for Fusarium oligoseptatum and Raffaelea subfusca, often using Tree of Heaven as a preferred host. Out of the five confirmed species of Euwallacea spp. in the United States, E. validus is the most widespread and longest established, yet much about their second fungal partner, Raffaelea subfusca, is not known.

<i>Euwallacea</i> Genus of beetles

Euwallacea is a genus of typical bark beetles in the family Curculionidae. They are commonly known as Ambrosia beetles, as all species are symbiotic with Ambrosia fungi. Originally from Asia or Wallacea, they are now found worldwide. Many species are pests, causing damage to, or the death of, tree species valued for their fruit or timber.

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