The family Scarabaeidae, as currently defined, consists of over 35,000 species of beetles worldwide; they are often called scarabs or scarab beetles. The classification of this family has undergone significant change in recent years. Several groups formerly treated as subfamilies have been elevated to family rank (e.g., Bolboceratidae, Geotrupidae, Glaresidae, Glaphyridae, Hybosoridae, Ochodaeidae, and Pleocomidae), and some reduced to lower ranks. The subfamilies listed in this article are in accordance with those in Catalog of Life (2023).[3]

Scarab beetle
Central European scarab beetles
with some anatomical details. Edmund Reitter's Fauna Germanica, 1908
Scientific classification Edit this classification
Domain: Eukaryota
Kingdom: Animalia
Phylum: Arthropoda
Class: Insecta
Order: Coleoptera
Suborder: Polyphaga
Infraorder: Scarabaeiformia
Superfamily: Scarabaeoidea
Family: Scarabaeidae
Latreille, 1802
Subfamilies[1][2][3]
On this high quality closeup, head anatomic details are well visible.

Description edit

 
Sacred scarab in a cartouche of Thutmosis III from Karnak temple of Amun-Ra, Egypt

Scarabs are stout-bodied beetles, many with bright metallic colours, measuring between 1.5 and 160 millimetres (0.059 and 6.3 in). They have distinctive, clubbed antennae composed of plates called lamellae that can be compressed into a ball or fanned out like leaves to sense odours. Many species are fossorial, with legs adapted for digging. In some groups males (and sometimes females) have prominent horns on the head and/or pronotum to fight over mates or resources.[4] The largest fossil scarabaeid was Oryctoantiquus borealis with a length of 50 millimetres (2.0 in).[5]

 
A scarab beetle grub from Australia.

The C-shaped larvae, called grubs, are pale yellow or white. Most adult beetles are nocturnal, although the flower chafers (Cetoniinae) and many leaf chafers (Rutelinae) are active during the day. The grubs mostly live underground or under debris, so are not exposed to sunlight. Many scarabs are scavengers that recycle dung, carrion, or decaying plant material.[6] Others, such as the Japanese beetle, are plant-eaters.

Some of the well-known beetles from the Scarabaeidae are Japanese beetles, dung beetles, June beetles, rose chafers (Australian, European, and North American), rhinoceros beetles, Hercules beetles and Goliath beetles.

Several members of this family have structurally coloured shells which act as left-handed circular polarisers; this was the first-discovered example of circular polarization in nature.[7]

Ancient Egypt edit

In Ancient Egypt, the dung beetle now known as Scarabaeus sacer (formerly Ateuchus sacer) was revered as sacred. Egyptian amulets representing the sacred scarab beetles were traded throughout the Mediterranean world.[4]

See also edit

References edit

  1. ^ Bouchard, Patrice; Bousquet, Yves; Davies, Anthony E.; Alonso-Zarazaga, Miguel A.; et al. (2011). "Family-group names in Coleoptera (Insecta)". ZooKeys (88): 1–972. doi:10.3897/zookeys.88.807. ISSN 1313-2989. PMC 3088472. PMID 21594053.
  2. ^ Dietz, Lars; Seidel, Matthias; Eberle, Jonas; Misof, Bernhard; et al. (2023). "A transcriptome-based phylogeny of Scarabaeoidea confirms the sister group relationship of dung beetles and phytophagous pleurostict scarabs (Coleoptera)". Systematic Entomology. 48 (4). doi:10.1111/syen.12602.
  3. ^ a b "Scarabaeidae Latreille, 1802". Catalogue of Life. Retrieved 2023-09-22.
  4. ^ a b bugguide.net Family Scarabaeidae - Scarab Beetles
  5. ^ Brett Ratcliffe, Dena M. Smith, Diane Marie Erwin. "Oryctoantiquus borealis, New Genus and Species from the Eocene of Oregon, U.S.A., the World's Oldest Fossil Dynastine and Largest Fossil Scarabaeid (Coleoptera: Scarabaeidae: Dynastinae)". 2009. The Coleopterists Bulletin 59(Mar 2005):127-135 DOI:10.1649/0010-065X(2005)059[0127:OBNGAS]2.0.CO;2
  6. ^ Marcos Paulo Gomes Gonçalves (2017). "Relação Entre Tempo e Besouros em Mata de Cocal" [Relationship Between Meteorological Conditions and Beetles in Mata de Cocal]. Revista Brasileira de Meteorologia (in Portuguese). 32 (4): 543–554. doi:10.1590/0102-7786324003.
  7. ^ A. A. Michelson (1911). "On metallic colourings in birds and insects". Philosophical Magazine. 21 (124): 554–567. doi:10.1080/14786440408637061.

Further reading edit

  • RU Ehlers. Current and Future Use of Nematodes in Biocontrol: Practice and Commercial Aspects with Regard to Regulatory Policy Issues. Biocontrol Science and Technology Volume 6, Issue 3, 1996.

External links edit