Biology:Weevil

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Short description: Superfamily of beetles

Weevils
Temporal range: Middle Jurassic - Recent
Weevil September 2008-1.jpg
Lixus pulverulentus
Scientific classification e
Domain: Eukaryota
Kingdom: Animalia
Phylum: Arthropoda
Class: Insecta
Order: Coleoptera
Suborder: Polyphaga
Infraorder: Cucujiformia
Clade: Phytophaga
Superfamily: Curculionoidea
Latreille, 1802
Families

Weevils are beetles belonging to the superfamily Curculionoidea, known for their elongated snouts. They are usually small – less than 6 mm (14 in) in length – and herbivorous. Approximately 97,000 species of weevils are known. They belong to several families, with most of them in the family Curculionidae (the true weevils). It also includes bark beetles, which while morphologically dissimilar to other weevils in lacking the distinctive snout, is a subfamily of Curculionidae. Some other beetles, although not closely related, bear the name "weevil", such as the biscuit weevil (Stegobium paniceum), which belongs to the family Ptinidae.

Many weevils are considered pests because of their ability to damage and kill crops. The grain or wheat weevil (Sitophilus granarius) damages stored grain, as does the maize weevil (Sitophilus zeamais) among others. The boll weevil (Anthonomus grandis) attacks cotton crops; it lays its eggs inside cotton bolls and the larvae eat their way out. Other weevils are used for biological control of invasive plants.

A weevil's rostrum, or elongated snout, hosts chewing mouthparts instead of the piercing mouthparts that proboscis-possessing insects are known for. The mouthparts are often used to excavate tunnels into grains.[1] In more derived weevils, the rostrum has a groove in which the weevil can fold the first segment of its antennae.

Most weevils have the ability to fly (including pest species such as the rice weevil[2][3]), though a significant number are flightless, such as the genus Otiorhynchus.

One species of weevil, Austroplatypus incompertus, exhibits eusociality, one of the few insects outside the Hymenoptera and the Isoptera to do so.

Taxonomy and phylogeny

Because so many species exist in such diversity, the higher classification of weevils is in a state of flux. They are generally divided into two major divisions, the Orthoceri or primitive weevils, and the Gonatoceri or true weevils (Curculionidae). E. C. Zimmerman proposed a third division, the Heteromorphi, for several intermediate forms.[4] Primitive weevils are distinguished by having straight antennae, while true weevils have elbowed (geniculate) antennae. The elbow occurs at the end of the scape (first antennal segment) in true weevils, and the scape is usually much longer than the other antennal segments. Some exceptions occur, such as Nanophyini, primitive weevils with long scapes and geniculate antennae, while among the true weevils, Gonipterinae and Ramphus have short scapes and little or no "elbow".

A 1995 classification system to family level was provided by Kuschel,[5] with updates from Marvaldi et al. in 2002,[6] and was achieved using phylogenetic analyses. The accepted families were the primitive weevils, Anthribidae, Attelabidae, Belidae, Brentidae, Caridae, and Nemonychidae, and the true weevils Curculionidae. Most other weevil families were demoted to subfamilies or tribes. Further work resulted in the elevation of Cimberididae to family from placement as a subfamily of Nemonychidae in 2017[7] and the recognition of the Cretaceous age family Mesophyletidae in 2018 from Burmese amber.[8] The oldest weevils date to the Middle-Late Jurassic boundary, found in the Karabastau Formation of Kazakhstan, the Shar-Teg locality of Mongolia, the Daohugou locality in Inner Mongolia, China, and the Talbragar site in Australia.[9] The extinct family Obrieniidae, with species dating from the Ladinian stage of the Triassic through to tentatively the Oxfordian, have sometimes been considered weevils. Genera of the family have been only found in three formations in Kazakhstan, with most named in 1993.[10] However, their phylogenetic position is contested, with others considering it part of Archostemata.[11]

The interfamilial relationships of Curculionoidea have been generally well resolved.[6][7][12][13][14] The phylogeny by Li et al. (2023) based on phylogenomic data is suggested below:[14]

Cimberididae

Nemonychidae

Anthribidae

Belidae

Attelabidae

Caridae

Brentidae

Curculionidae

Families

Sexual dimorphism

Rhopalapion longirostre exhibits an extreme case of sexual dimorphism. The female rostrum is twice as long and its surface is smoother than in the male. The female bores egg channels into the buds of Alcea rosea. Thus, the dimorphism is not attributed to sexual selection. It is a response to ecological demands of egg deposition.[15]

Another example of extreme dimorphism in weevils is that of the New Zealand giraffe weevil, males measure up to 90 mm (3.5 in), and females 50 mm (2.0 in), although there is an extreme range of body sizes in both sexes.

References

  1. Moon, Myung-Jin (2015). "Microstructure of mandibulate mouthparts in the greater rice weevil, Sitophilus zeamais (Coleoptera: Curculionidae)" (in en). Entomological Research 45 (1): 9–15. doi:10.1111/1748-5967.12086. ISSN 1748-5967. 
  2. "What Is a Weevil and How Did That Bug Get in My Food?". https://www.thespruce.com/what-is-a-weevil-2656439. 
  3. "Weevils on Stored Grain (Department of Entomology)". http://ento.psu.edu/extension/factsheets/weevils-on-stored-grain. 
  4. E. C. Zimmerman (1994). Australian weevils (Coleoptera: Curculionidae). Volume 1. Orthoceri: Anthribidae to Attelabidae: the primitive weevils. East Melbourne: CSIRO. pp. 741 pp. 
  5. G. Kuschel (1995). "A phylogenetic classification of Curculionoidea to families and subfamilies". Memoirs of the Entomological Society of Washington 14: 5–33. 
  6. 6.0 6.1 Marvaldi, Adriana E.; Sequeira, Andrea S.; O'Brien, Charles W.; Farrell, Brian D. (2002). "Molecular and morphological phylogenetics of weevils (Coleoptera, Curculionidae): do niche shifts accompany diversification?". Systematic Biology 51 (5): 761–785. doi:10.1080/10635150290102465. PMID 12396590. 
  7. 7.0 7.1 Shin, Seunggwan; Clarke, Dave J.; Lemmon, Alan R.; Lemmon, Emily Moriarty; Aitken, Alexander L.; Haddad, Stephanie; Farrell, Brian D.; Marvaldi, Adriana E. et al. (2018). "Phylogenomic data yield new and robust insights into the phylogeny and evolution of weevils". Molecular Biology and Evolution 35 (4): 823–836. doi:10.1093/molbev/msx324. PMID 29294021. 
  8. Dave J. Clarke; Ajay Limaye; Duane D. McKenna; Rolf G. Oberprieler (2018). "The weevil fauna preserved in Burmese amber—snapshot of a unique, extinct lineage (Coleoptera: Curculionoidea)". Diversity 11 (1): Article 1. doi:10.3390/d11010001. 
  9. Legalov, A. A. (April 2022). "Review of the Jurassic Weevils of the Genus Belonotaris Arnoldi (Coleoptera: Nemonychidae) with a Straight Rostrum". Paleontological Journal 56 (2): 199–207. doi:10.1134/s0031030122020071. ISSN 0031-0301. http://dx.doi.org/10.1134/s0031030122020071. 
  10. Legalov, A. A. (2010). "Checklist of Mesozoic Curculionoidea (Coleoptera) with description of new taxa". Baltic Journal of Coleopterology 10 (1): 71–101. 
  11. Legalov, A. (2020). "Fossil History of Curculionoidea (Coleoptera) from the Paleogene" (in en). Geosciences 10 (9): 358. doi:10.3390/geosciences10090358. Bibcode2020Geosc..10..358L. 
  12. Marvaldi, A. E.; Morrone, J. J. (2000). "Phylogenetic systematics of weevils (Coleoptera: Curculionoidea): A reappraisal based on larval and adult morphology". Insect Systematics & Evolution 31: 43–58. doi:10.1163/187631200X00309. 
  13. Marvaldi, Adriana E.; Duckett, Catherine N.; Kjer, Karl M.; Gillespie, Joseph J. (2009). "Structural alignment of 18S and 28S rDNA sequences provides insights into phylogeny of Phytophaga (Coleoptera: Curculionoidea and Chrysomeloidea)". Zoologica Scripta 38: 63–77. doi:10.1111/j.1463-6409.2008.00360.x. 
  14. 14.0 14.1 Li, Yan-Da; Engel, Michael S.; Tihelka, Erik; Cai, Chenyang (2023). "Phylogenomics of weevils revisited: data curation and modelling compositional heterogeneity". Biology Letters 19 (9): 20230307. doi:10.1098/rsbl.2023.0307. PMID 37727076. 
  15. G. Wilhelm (2011). "Sexual dimorphism in head structures of the weevil Rhopalapion longirostre: a response to ecological demands of egg deposition". Biological Journal of the Linnean Society 104: 642–660. doi:10.1111/j.1095-8312.2011.01751.x. 

Further reading

External links

Wikidata ☰ Q383963 entry

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