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Coccinellidae

February 15, 2024

"Lady Bug" and "Ladybug" redirect here. For other uses, see Lady Bug (disambiguation).
"Ladybird" redirects here. For other uses, see Ladybird (disambiguation).

Coccinellidae (/ˌkɒksɪˈnɛlɪd/)[3] is a widespread family of small beetles. They are commonly known as ladybugs in North America and ladybirds in the United Kingdom; "lady" refers to mother Mary. Entomologists use the names ladybird beetles or lady beetles to avoid confusion with true bugs. The more than 6,000 described species have a global distribution and are found in a variety of habitats. They are oval beetles with a domed back and flat underside. Many of the species have conspicuous aposematic (warning) colours and patterns, such as red with black spots, that warn potential predators that they taste bad.

Ladybird, ladybug, lady beetle
Temporal range: EocenePresent
Coccinella septempunctata
Scientific classification
Domain: Eukaryota
Kingdom: Animalia
Phylum: Arthropoda
Class: Insecta
Order: Coleoptera
Suborder: Polyphaga
Infraorder: Cucujiformia
Superfamily: Coccinelloidea
Family: Coccinellidae
Latreille, 1807[1]
Subfamilies[1]

(traditional, but see below):

Synonyms
  • Cerasommatidiidae
  • Epilachnidae

Most coccinellid species are carnivorous predators, preying on insects such as aphids and scale insects. Other species are known to consume non-animal matter, including plants and fungi. They are promiscuous breeders, reproducing in spring and summer in temperate regions and during the wet season in tropical regions. Many predatory species lay their eggs near colonies of prey, providing their larvae with a food source. Like most insects, they develop from larva to pupa to adult. Temperate species hibernate and diapause during the winter; tropical species are dormant during the dry season. Coccinellids migrate between dormancy and breeding sites.

Species that prey on agricultural pests are considered beneficial insects. Several species have been introduced outside their range as biological control agents, with varying degrees of success. Some species are pests themselves and attack agricultural crops, or can infest people's homes, particularly in winter. Invasive species like Harmonia axyridis can pose an ecological threat to native coccinellid species. Other threats to coccinellids include climate change and habitat destruction. These insects have played roles in folklore, religion and poetry, and are particularly popular in nursery rhymes.

Etymology

The name Coccinellidae, created by Pierre André Latreille in 1807,[4] is derived from the Latin word coccineus meaning 'scarlet'.[5] The common English name ladybird originated in Britain where the insects became known as "Our Lady's birds".[6][7] Mary ("Our Lady") was often depicted wearing a red cloak in early art, and the seven spots of the species Coccinella septempunctata (the most common in Europe) were said to represent her seven joys and seven sorrows.[8] In the United States, the name was popularly adapted to ladybug.[9] Entomologists prefer the names ladybird beetles or lady beetles to avoid confusion with true bugs.[9][10][11][12] Names in some other countries may be similar; for example, in Germany they are known as Marienkäfer meaning 'Marybeetle' or 'ladybeetle'.[9]

Description

Coccinellids range in size from 0.8 to 18 mm (0.03–0.7 in).[13] They are sexually dimorphic; adult females tend to be slightly larger than males.[14] They are generally oval with domed backs and flattened undersides.[7] They have large compound eyes and clubbed antennae with seven to eleven segments. The powerful mandibles (equivalent to jaws) typically have pairs of "teeth" which face each other.[15] The coccinellid prothorax (front of thorax) is broad and convex, and can cover the back of the head.[16][17] Being beetles, they have hardened, non-overlapping forewings, known as elytra, which cover up the more fragile hindwings when the insects are not in flight. Their legs are relatively short,[16] with a tarsal formula of 4-4-4 or 3-3-3.[18] The tarsus (end of leg) has two claws at the tip.[16]

As adults, these beetles differ from their closest relatives with the following morphological characteristics:[18]

  • Five pairs of spiracles (holes) on the abdomen
  • A tentorium (internal supports inside the head) with separated branches at the front and no bridge
  • No line dividing the frons and clypeus (frontoclypeal suture)
  • Maxillary palps with non-needle-shaped tips,
  • Divided galea and lacinia (lobes at the end of the mouthparts)
  • Smaller molar (flattened) area of the mandible
  • Coxal cavities (holes where the leg articulates with the thorax) that open from the back in the front of the thorax and from the front in the middle of the thorax
  • Epimeron (corner plates) on the metathorax with parallel edges
  • Lines on the second abdominal sternum
  • Tube-shaped, siphon-like genitalia in the male

Coccinellids are often distinctively coloured and patterned. The elytron may be light with dark spots or dark with light spots. Light areas are typically yellow, red, orange or brown, and the spots vary in size and shape and numbers. Some species have striped or checkered patterns. The pigment carotene creates the lighter colours, and melanins create darker colours. Other parts of the body also vary in colouration.[7][19] These colour patterns typically serve as warning colouration, but some can act as camouflage, attract mates or even regulate heat.[7][20] Several individual species may display polymorphism and even change colour between seasons.[7]

Coccinellid larvae are elongated with square heads.[21] They are covered in hairs or setae, the abdominal segments, in particular, each having six divided into pairs, and one to three segmented antennae.[18][7] Their colouration varies from grey, blue-grey, grey-brown or brown and spotted with white, yellow, red or orange. They tend to brighten as they get closer to adulthood.[22]

Evolution

Fossil history

Over 6,000 living species of Coccinellidae have been described.[13] They are sparsely preserved in the fossil record.[23] Although molecular clock estimates have placed their origin in the Cretaceous, the oldest fossils of the group are known from the Oise amber of France, dating to the Early Eocene (Ypresian) around 53 million years ago, which belong to the extant genera Rhyzobius and Nephus.[24] The greatest number of fossils comes from the younger Eocene Baltic amber, including members of the extant genera Serangium[25] and Rhyzobius as well as extinct genera belonging to the tribes Microweiseini (Baltosidis)[26] and Sticholotidini (Electrolotis).[23]

Phylogeny

Further information: List of Coccinellidae genera

The Coccinellidae are within the superfamily Coccinelloidea, which in turn is part of the infraorder Cucujiformia, a group containing most of the plant-eating beetles. The ladybirds form the majority of the species in the Coccinelloidea; many of the rest are fungus-feeding beetles or scavengers.[27]

Coccinellidae have historically been divided into up seven subfamilies (Chilocorinae, Coccidulinae, Coccinellinae, Epilachninae, Microweiseinae, Scymninae and Sticholotidinae) and 35 tribes based on morphology. However, genetics studies have called into question the monophyly (single ancestry) of most of these subfamilies. The monophyly of Coccinellinae has the most support.[28][29]

A 2021 genetic study sampling many species, identified three subfamilies, Microweiseinae (with three tribes), Coccinellinae (26 tribes) and a newly identified group, the Monocoryninae (one tribe). All three subfamilies were strongly supported, but the study noted that although the tribes are mostly monophyletic, their relationships are only weakly supported. The study suggests that the crown group appeared some 143 Mya in the Early Cretaceous, and that the group diversified rapidly during the Late Cretaceous, perhaps because the growth in diversity of angiosperm plants then encouraged the radiation of insects of the clade Sternorrhyncha such as aphids, on which ladybirds could feed.[30]

Coccinellidae

Microweiseinae  

Monocoryninae

Coccinellinae

Stethorini  

Coccinellini  

other tribes  

An earlier 2009 study concluded that consumption of scale insects is the most basal diet of Coccinellidae. Aphid-eating evolved three separate times and leaf-eating evolved twice, one of which evolved from a clade that contains both aphid-eating and pollen-eating. The fungi-eating also evolved from aphid-eating.[28]

Biology and ecology

Flight

Coccinellids mostly fly during the day.[31] Springy, cylindrical veins in the hindwings stiffen when in flight and bend when folding. Folding of the wings is further aided by creases in the membrane.[32] These beetles may migrate long distances to hibernation and breeding sites, and areas with more food. They appear to be drawn to recognisable landmarks.[33] The more crowded an area is, the more individuals leave, but will remain if there are enough prey species to feed on.[34] "Trivial flights" refer to flying while foraging or when finding a place to lay eggs.[33] One study of species in Britain found that coccinellids can fly as far as 120 km (75 mi). They flew at speeds of 30 km/h (19 mph) and could reach altitudes close to 1,100 m (3,600 ft).[35]

Life cycle

In temperate climates, coccinellids typically breed from late spring to early summer. In warmer temperate regions, reproduction may occur in spring, fall and winter; tropical species reproduce during the wet season.[7][36] Mating is promiscuous. In some species, females appear to be selective in their partners, preferring males of a certain size and colour. Males produce sperm packets each with 14,000 sperm, and insert three of them into the female, even though she can only hold 18,000 sperm. This is likely a form of sperm competition.[7][37] Like other insects, coccinellids develop from egg, to larva, to pupa and finally adult. Eggs tend to be bright yellow, and the females lay them close together, standing upright and near where they can access food.[7] The number of eggs in a cluster can vary depending on the species; it is typically in the double digits but some species can lay over a thousand eggs in their lifetime.[38]

After hatching, the larvae will begin eating, including the other eggs in their clutch.[7] Certain species lay extra infertile trophic eggs with the fertile eggs, providing a backup food source for the larvae when they hatch. The ratio of infertile to fertile eggs increases with scarcity of food at the time of egg laying.[39] Larvae typically have four instar stages with three moults between them.[40] The larva eventually transitions into a pupa; which involves the development of a hunch, the fusion of the legs to the body, and the attachment of the posterior to the surface.[7][18][40]

Pupae may be uncovered, partially covered or fully covered by larval skin depending on the species. The pupa is mostly immobile, but the head can move in response to irritation. When the adult emerges, it has its hindwings, while the elytron starts out softer and lighter in colour, with no patterns.[41] The length of each development stage varies based on climate and between species. For Adalia bipunctata, eggs hatch after four to eight days, the larva stage lasts around three weeks and the pupa lasts seven to ten days.[7] Adult coccinellids develop much of their final colouration within hours, but may not fully darken for weeks or months.[42] The lifespan of an adult reaches up to a year.[7]

In temperate areas, coccinellids may hibernate or enter diapause during the winter. Individuals during this period gather in clumps, large or small depending on the species. Overwintering insects can be found both in lowland areas, aggregating under dead vegetation, and at the tops of hills, hibernating under rocks and on grass tussocks.[43] In areas with particularly hot summers, the insects experience summer dormancy or aestivation; in the tropics, coccinellids enter dormancy during the dry season.[7]

  • Life cycle
  •  
    Adults mating
  •  
    Eggs (match for scale)
  •  
    Larva
  •  
    Pupa

Trophic roles

Coccinellids act both as predators, prey and parasitic hosts in food webs.[44] The majority of coccinellids are carnivorous and predatory, typically preying on Sternorrhyncha insects like aphids, scale insects, whiteflies, psyllids and adelgids. Some species feed on the larvae of moths and other beetles, as well as mites. Since much of their prey are agricultural pests, coccinellids are considered to be beneficial insects.[45][46][47] A 2009 metastudy by Hodek and Honěk found that aphid-eaters constituted around 68 percent of species that live in temperate areas but only 20 percent of species worldwide. Around 36 percent of total species mostly feed on scale insects.[47] Larvae and adults eat the same foods, unlike in other insect groups.[7]

Ladybird species vary in dietary specificity. An example of a specialist species is those of the genus Stethorus, which feed on spider mites. Aphid-eaters tend to be generalist; they have a high voracity and can multiply quickly in response to outbreaks, and switch to other prey when the ephemeral aphids become scarce. Predators of scale insects tend to be less voracious and are slower breeders and developers; matching their prey.[48] Under pressure from coccinellid predation, aphid species have evolved to become more toxic, forcing coccinellids to develop immunities.[49] Coccinellid predators of aphids need to defend themselves against ants that tend and defend aphids for their honeydew,[50] and coccinellid eggs laid near aphids are disposed of.[44] Some species including Coccinella magnifica and Diomus have adapted to grow within ant nests as larvae, and some like Diomus thoracicus are predators of the brood of the ant Wasmannia auropunctata.[51][52]

Cannibalism has been recorded in several species; which includes larvae eating eggs or other larvae, and adults feeding on individuals of any life stage.[53] Some coccinellids are mostly non-predatory, such as some species in the genera Epilachna and Henosepilachna.[54][55] The majority of predatory species may also supplement their diet with other sources of food both in their larval and adult stages.[56] Non-animal matter consumed include leaves, pollen, nectar, sap, fungi, and honeydew.[45][56][57] Members of the tribe Halyziini of the subfamily Coccinellinae are obligate fungus feeders.[58]

Coccinellids of any lifestage are preyed on by predators such as birds, spiders, ants and lacewings.[59] They are also hosts for parasites, including some flies, ticks, mites, hymenopterans and nematodes, and pathogens, including bacteria, fungi and protozoa.[44][60] Wolbachia bacteria infects eggs and kills male zygotes.[61] The promiscuity of Coccinellids has led to their being affected by sexually transmitted infections.[62]

Defense

 
Coccinella septempunctata reflex bleeding

The bright warning colouration of many coccinellids discourage potential predators, warning of their toxicity. A 2015 study of five ladybird species found that their colouration honestly signalled their toxicity, implying the warning is genuine. Species with more contrast with the background environment tended to be more toxic.[63] Coccinellid haemolymph (blood) contains toxic alkaloids, azamacrolides and polyamines, as well as foul-smelling pyrazines.[64] Coccinellids can produce at least 50 types of alkaloids. When disturbed, ladybirds further defend themselves with reflex bleeding, exuding drops from their tibio-femoral (knee) joints, effectively presenting predators with a sample of their toxic and bitter body fluid.[59] Predator-deterring poisons are particularly important for the immobile pupa.[65] Access to food can affect the concentration of both pigments and toxins.[66]

The similarity of coccinellid patterning in red and orange with black markings has led to suggestions that they and some species of chrysomelids[67] form Müllerian mimicry rings[68] particularly to defend them from birds.[69] Despite their chemical defenses, coccinellids are preyed on by some clerid beetles in the genus Enoclerus, several species of which are brightly coloured in red and black, and which possibly sequester the toxins of the prey to defend themselves against other predators.[70]

As an anti-predator defense, spiders of the genus Eresus, known as ladybird spiders, have evolved to replicate the patterns of coccinellids. This is a form of Batesian mimicry, as the spiders lack the chemicals. This resemblance is limited to adult male spiders which are actively searching for females and exposed – unlike the females and young, which remain sheltered in burrows.[71]

Distribution and status

 
The widespread and invasive Harmonia axyridis

Coccinellidae are found on every continent except Antarctica.[72] Asian and African species are less studied than others.[73] Coccinellids can be found in a variety of habitats, both on the ground and in the trees. They may specialise using certain plants. Some species can live in extreme environments such as high mountains, arid deserts and cold regions.[74] Several of the most famous species have wide ranges, but others are more endemic and possibly threatened.[73]

Threats to coccinellids include climate change, agriculture, urbanisation, and invasive species. Coccinellid biodiversity will likely be affected by the rising of both average temperatures and heat fluctuations. Climate change may lead to smaller larvae, as well as increase energy and metabolic needs and interspecific predation. Agriculture and urbanisation threatens these insects though habitat destruction and homogenisation and the use of pesticides. Invasive threats include other coccinellids, particularly C. septempunctata in North America and H. axyridis globally.[73] These invaders outcompete the native species as well as eat their eggs.[73][75]

As of 2022, the IUCN Red List does not list the conservation status for any coccinellid, though there is an IUCN SSC Ladybird Specialist Group. Conservationists have suggested several measures for protecting the insects, including citizen science and education programs, habitat preservation and restoration, prevention of the spread of invasive species and a global monitoring program.[73]

Relationship to humans

Biological control

Further information: Biological pest control
 
Biological control: larval Novius cardinalis feeding on Icerya purchasi

Coccinellids have been valued in biological pest control, as they prey on agricultural pests such as aphids and scale insects. Their importance in controlling pests was noted as far back as 1814 in England.[7] Their efficiency can vary: sometimes they have a relatively small effect on aphid populations; at others they cause significant seasonal declines.[76]

Several species have been introduced to areas outside their native range; the first being the vedalia beetle, Novius cardinalis.[7] The larva of the species was introduced to California in 1887 from Australia, to protect citrus trees from cottony cushion scale. The project was markedly successful, costing $1,500 in 1889,[77] making it "a textbook example of the great potential of classical biological control as a tactic for suppressing invasive pests." The beetle was then used in 29 countries, again with success; reasons for this include its high prey specificity, fast development, multiple generations each year, efficient discovery of host patches, and larval development completed on a single host insect.[78]

There have been many further attempts to use ladybird species against pests, with varying degrees of success.[79][7] Scale insect-eating coccinellids have been more successfully used than aphid predators.[7] Out of 155 deliberate introductions meant to control aphids by the year 2000, only one was deemed to be "substantially successful". This is due to aphid-eating species being fast-breeding, generalist and voracious, and thus difficult to control.[80]

As pests

 
Cluster of invasive Asian lady beetles inside a farm building after the fall harvest in South Dakota

Coccinellids can also act as pests. Harmonia axyridis is native to East Asia, but has been introduced to the Americas, Europe and Africa.[73] In North America, this species begins to appear indoors in the autumn when they leave their summer feeding sites to search out places to stay for winter. Typically, when temperatures warm to the mid-60s °F (around 18 °C) in the late afternoon, they swarm onto or into buildings illuminated by the sun from nearby fields and forests.[81][82] After an abnormally long period of hot, dry weather in the summer of 1976 in the UK, a marked increase in the aphid population was followed by a "plague" of the native Coccinella septempunctata; there were many reports of people being bitten as the supply of aphids dwindled.[83][84][85]

H. axyridis, C. septempunctata and Hippodamia convergens are the most common causes of ladybird taint in wine. As few as 1.3 to 1.5 coccinellids per 1 kilogram (2.2 lb) of grapes can affect wine quality when they are present during the wine-making process.[86] The Mexican bean beetle is an agricultural pest as it primarily feeds on plants, especially legumes, instead of insects.[87]

In culture

Coccinellids have had important roles in culture and religion, being associated with luck, love, fertility and prophecy. "Ladybird" is an affectionate term for someone, such as a loved one. In European folklore, an insect acts as a matchmaker, crawling on a woman and then flying to their true love. Coccinellids have been said to predict the future, particularly weather conditions and how well the crops will grow.[88][89] Contrary to a popular saying, the age of a lady bug cannot be determined by counting its spots.[90]

In Christianity, coccinellids have been seen as the literal gatekeepers of Heaven. A Swedish name for the insects, Himmelska nycla, means "Keys of Heaven". Jews have referred to the insects as the "Cow of Moses our Teacher". The Cherokee have revered them as the "Great Beloved Woman"; this was used as a title for the highest-ranking woman in the government, who would be painted in the colours and patterns of the insect during ceremonies.[91]

Coccinellids have been popularly featured in poems and nursery rhymes, the most famous being Ladybird! Ladybird!. This has come in several forms, including:[92]

Ladybird, ladybird, fly away home,
Thy house is on fire, thy children all roam,
Except little Nan, who sits on her pan,
Weaving gold laces as fast as she can.


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Sources

  • Hodek, I.; Honěk, A. (1996). Ecology of Coccinellidae (Series Entomologica, 54). Springer. ISBN 978-0792341772.
  • Hodek, I; Honěk, A; Van Emden, H. F., eds. (2012). Ecology and Behaviour of the Ladybird Beetles (Coccinellidae). John Wiley & Sons. ISBN 978-1-118-22321-5. OCLC 792685088.
  • Majerus, M (2016). Roy, H. E.; Brown, P. M. J. (eds.). A Natural History of Ladybird Beetles. Cambridge University Press. ISBN 978-1-107-11607-8.

External links

  •   Media related to Coccinellidae at Wikimedia Commons
  •   Data related to Coccinellidae at Wikispecies

February 15, 2024
coccinellidae, lady, ladybug, redirect, here, other, uses, lady, disambiguation, ladybird, redirects, here, other, uses, ladybird, disambiguation, widespread, family, small, beetles, they, commonly, known, ladybugs, north, america, ladybirds, united, kingdom, . Lady Bug and Ladybug redirect here For other uses see Lady Bug disambiguation Ladybird redirects here For other uses see Ladybird disambiguation Coccinellidae ˌ k ɒ k s ɪ ˈ n ɛ l ɪ d iː 3 is a widespread family of small beetles They are commonly known as ladybugs in North America and ladybirds in the United Kingdom lady refers to mother Mary Entomologists use the names ladybird beetles or lady beetles to avoid confusion with true bugs The more than 6 000 described species have a global distribution and are found in a variety of habitats They are oval beetles with a domed back and flat underside Many of the species have conspicuous aposematic warning colours and patterns such as red with black spots that warn potential predators that they taste bad Ladybird ladybug lady beetleTemporal range Eocene Present PreꞒ Ꞓ O S D C P T J K Pg NCoccinella septempunctataScientific classificationDomain EukaryotaKingdom AnimaliaPhylum ArthropodaClass InsectaOrder ColeopteraSuborder PolyphagaInfraorder CucujiformiaSuperfamily CoccinelloideaFamily CoccinellidaeLatreille 1807 1 Subfamilies 1 traditional but see below Chilocorinae Mulsant 1846 Coccidulinae Mulsant 1846 Coccinellinae Latreille 1807 Epilachninae Mulsant 1846 Microweiseinae Leng 1920 2 Scymninae Mulsant 1846 Sticholotidinae Weise 1901SynonymsCerasommatidiidae EpilachnidaeMost coccinellid species are carnivorous predators preying on insects such as aphids and scale insects Other species are known to consume non animal matter including plants and fungi They are promiscuous breeders reproducing in spring and summer in temperate regions and during the wet season in tropical regions Many predatory species lay their eggs near colonies of prey providing their larvae with a food source Like most insects they develop from larva to pupa to adult Temperate species hibernate and diapause during the winter tropical species are dormant during the dry season Coccinellids migrate between dormancy and breeding sites Species that prey on agricultural pests are considered beneficial insects Several species have been introduced outside their range as biological control agents with varying degrees of success Some species are pests themselves and attack agricultural crops or can infest people s homes particularly in winter Invasive species like Harmonia axyridis can pose an ecological threat to native coccinellid species Other threats to coccinellids include climate change and habitat destruction These insects have played roles in folklore religion and poetry and are particularly popular in nursery rhymes Contents 1 Etymology 2 Description 3 Evolution 3 1 Fossil history 3 2 Phylogeny 4 Biology and ecology 4 1 Flight 4 2 Life cycle 4 3 Trophic roles 4 4 Defense 5 Distribution and status 6 Relationship to humans 6 1 Biological control 6 2 As pests 6 3 In culture 7 References 8 Sources 9 External linksEtymologyThe name Coccinellidae created by Pierre Andre Latreille in 1807 4 is derived from the Latin word coccineus meaning scarlet 5 The common English name ladybird originated in Britain where the insects became known as Our Lady s birds 6 7 Mary Our Lady was often depicted wearing a red cloak in early art and the seven spots of the species Coccinella septempunctata the most common in Europe were said to represent her seven joys and seven sorrows 8 In the United States the name was popularly adapted to ladybug 9 Entomologists prefer the names ladybird beetles or lady beetles to avoid confusion with true bugs 9 10 11 12 Names in some other countries may be similar for example in Germany they are known as Marienkafer meaning Marybeetle or ladybeetle 9 DescriptionCoccinellids range in size from 0 8 to 18 mm 0 03 0 7 in 13 They are sexually dimorphic adult females tend to be slightly larger than males 14 They are generally oval with domed backs and flattened undersides 7 They have large compound eyes and clubbed antennae with seven to eleven segments The powerful mandibles equivalent to jaws typically have pairs of teeth which face each other 15 The coccinellid prothorax front of thorax is broad and convex and can cover the back of the head 16 17 Being beetles they have hardened non overlapping forewings known as elytra which cover up the more fragile hindwings when the insects are not in flight Their legs are relatively short 16 with a tarsal formula of 4 4 4 or 3 3 3 18 The tarsus end of leg has two claws at the tip 16 As adults these beetles differ from their closest relatives with the following morphological characteristics 18 Five pairs of spiracles holes on the abdomen A tentorium internal supports inside the head with separated branches at the front and no bridge No line dividing the frons and clypeus frontoclypeal suture Maxillary palps with non needle shaped tips Divided galea and lacinia lobes at the end of the mouthparts Smaller molar flattened area of the mandible Coxal cavities holes where the leg articulates with the thorax that open from the back in the front of the thorax and from the front in the middle of the thorax Epimeron corner plates on the metathorax with parallel edges Lines on the second abdominal sternum Tube shaped siphon like genitalia in the maleCoccinellids are often distinctively coloured and patterned The elytron may be light with dark spots or dark with light spots Light areas are typically yellow red orange or brown and the spots vary in size and shape and numbers Some species have striped or checkered patterns The pigment carotene creates the lighter colours and melanins create darker colours Other parts of the body also vary in colouration 7 19 These colour patterns typically serve as warning colouration but some can act as camouflage attract mates or even regulate heat 7 20 Several individual species may display polymorphism and even change colour between seasons 7 Coccinellid larvae are elongated with square heads 21 They are covered in hairs or setae the abdominal segments in particular each having six divided into pairs and one to three segmented antennae 18 7 Their colouration varies from grey blue grey grey brown or brown and spotted with white yellow red or orange They tend to brighten as they get closer to adulthood 22 Appearance of different species nbsp Coccinella septempunctata black spots on red nbsp Psyllobora vigintiduopunctata black spots on yellow nbsp Vibidia duodecimguttata whitish spots on brown nbsp Brumoides suturalis longitudinally striped nbsp Rhyzobius chrysomeloides brown unspottedEvolutionFossil history Over 6 000 living species of Coccinellidae have been described 13 They are sparsely preserved in the fossil record 23 Although molecular clock estimates have placed their origin in the Cretaceous the oldest fossils of the group are known from the Oise amber of France dating to the Early Eocene Ypresian around 53 million years ago which belong to the extant genera Rhyzobius and Nephus 24 The greatest number of fossils comes from the younger Eocene Baltic amber including members of the extant genera Serangium 25 and Rhyzobius as well as extinct genera belonging to the tribes Microweiseini Baltosidis 26 and Sticholotidini Electrolotis 23 Phylogeny Further information List of Coccinellidae genera The Coccinellidae are within the superfamily Coccinelloidea which in turn is part of the infraorder Cucujiformia a group containing most of the plant eating beetles The ladybirds form the majority of the species in the Coccinelloidea many of the rest are fungus feeding beetles or scavengers 27 Cucujiformia Lymexyloidea nbsp Tenebrionoidea nbsp Cleroidea nbsp Chrysomeloidea nbsp Curculionoidea nbsp Cucujoidea nbsp Coccinelloidea Bothrideridae and allies nbsp Latridiidae nbsp Akalyptoischiidae nbsp Alexiidae nbsp Corylophidae and allies nbsp Endomychidae nbsp Coccinellidae nbsp Coccinellidae have historically been divided into up seven subfamilies Chilocorinae Coccidulinae Coccinellinae Epilachninae Microweiseinae Scymninae and Sticholotidinae and 35 tribes based on morphology However genetics studies have called into question the monophyly single ancestry of most of these subfamilies The monophyly of Coccinellinae has the most support 28 29 A 2021 genetic study sampling many species identified three subfamilies Microweiseinae with three tribes Coccinellinae 26 tribes and a newly identified group the Monocoryninae one tribe All three subfamilies were strongly supported but the study noted that although the tribes are mostly monophyletic their relationships are only weakly supported The study suggests that the crown group appeared some 143 Mya in the Early Cretaceous and that the group diversified rapidly during the Late Cretaceous perhaps because the growth in diversity of angiosperm plants then encouraged the radiation of insects of the clade Sternorrhyncha such as aphids on which ladybirds could feed 30 Coccinellidae Microweiseinae nbsp MonocoryninaeCoccinellinae Stethorini nbsp Coccinellini nbsp other tribes nbsp An earlier 2009 study concluded that consumption of scale insects is the most basal diet of Coccinellidae Aphid eating evolved three separate times and leaf eating evolved twice one of which evolved from a clade that contains both aphid eating and pollen eating The fungi eating also evolved from aphid eating 28 Biology and ecologyFlight Coccinellids mostly fly during the day 31 Springy cylindrical veins in the hindwings stiffen when in flight and bend when folding Folding of the wings is further aided by creases in the membrane 32 These beetles may migrate long distances to hibernation and breeding sites and areas with more food They appear to be drawn to recognisable landmarks 33 The more crowded an area is the more individuals leave but will remain if there are enough prey species to feed on 34 Trivial flights refer to flying while foraging or when finding a place to lay eggs 33 One study of species in Britain found that coccinellids can fly as far as 120 km 75 mi They flew at speeds of 30 km h 19 mph and could reach altitudes close to 1 100 m 3 600 ft 35 Behaviour nbsp Coccinella transversalis elytra in the open position nbsp Full wings of a Harmonia axyridis taking flightLife cycle In temperate climates coccinellids typically breed from late spring to early summer In warmer temperate regions reproduction may occur in spring fall and winter tropical species reproduce during the wet season 7 36 Mating is promiscuous In some species females appear to be selective in their partners preferring males of a certain size and colour Males produce sperm packets each with 14 000 sperm and insert three of them into the female even though she can only hold 18 000 sperm This is likely a form of sperm competition 7 37 Like other insects coccinellids develop from egg to larva to pupa and finally adult Eggs tend to be bright yellow and the females lay them close together standing upright and near where they can access food 7 The number of eggs in a cluster can vary depending on the species it is typically in the double digits but some species can lay over a thousand eggs in their lifetime 38 After hatching the larvae will begin eating including the other eggs in their clutch 7 Certain species lay extra infertile trophic eggs with the fertile eggs providing a backup food source for the larvae when they hatch The ratio of infertile to fertile eggs increases with scarcity of food at the time of egg laying 39 Larvae typically have four instar stages with three moults between them 40 The larva eventually transitions into a pupa which involves the development of a hunch the fusion of the legs to the body and the attachment of the posterior to the surface 7 18 40 Pupae may be uncovered partially covered or fully covered by larval skin depending on the species The pupa is mostly immobile but the head can move in response to irritation When the adult emerges it has its hindwings while the elytron starts out softer and lighter in colour with no patterns 41 The length of each development stage varies based on climate and between species For Adalia bipunctata eggs hatch after four to eight days the larva stage lasts around three weeks and the pupa lasts seven to ten days 7 Adult coccinellids develop much of their final colouration within hours but may not fully darken for weeks or months 42 The lifespan of an adult reaches up to a year 7 In temperate areas coccinellids may hibernate or enter diapause during the winter Individuals during this period gather in clumps large or small depending on the species Overwintering insects can be found both in lowland areas aggregating under dead vegetation and at the tops of hills hibernating under rocks and on grass tussocks 43 In areas with particularly hot summers the insects experience summer dormancy or aestivation in the tropics coccinellids enter dormancy during the dry season 7 Life cycle nbsp Adults mating nbsp Eggs match for scale nbsp Larva nbsp PupaTrophic roles Coccinellids act both as predators prey and parasitic hosts in food webs 44 The majority of coccinellids are carnivorous and predatory typically preying on Sternorrhyncha insects like aphids scale insects whiteflies psyllids and adelgids Some species feed on the larvae of moths and other beetles as well as mites Since much of their prey are agricultural pests coccinellids are considered to be beneficial insects 45 46 47 A 2009 metastudy by Hodek and Honek found that aphid eaters constituted around 68 percent of species that live in temperate areas but only 20 percent of species worldwide Around 36 percent of total species mostly feed on scale insects 47 Larvae and adults eat the same foods unlike in other insect groups 7 Ladybird species vary in dietary specificity An example of a specialist species is those of the genus Stethorus which feed on spider mites Aphid eaters tend to be generalist they have a high voracity and can multiply quickly in response to outbreaks and switch to other prey when the ephemeral aphids become scarce Predators of scale insects tend to be less voracious and are slower breeders and developers matching their prey 48 Under pressure from coccinellid predation aphid species have evolved to become more toxic forcing coccinellids to develop immunities 49 Coccinellid predators of aphids need to defend themselves against ants that tend and defend aphids for their honeydew 50 and coccinellid eggs laid near aphids are disposed of 44 Some species including Coccinella magnifica and Diomus have adapted to grow within ant nests as larvae and some like Diomus thoracicus are predators of the brood of the ant Wasmannia auropunctata 51 52 Cannibalism has been recorded in several species which includes larvae eating eggs or other larvae and adults feeding on individuals of any life stage 53 Some coccinellids are mostly non predatory such as some species in the genera Epilachna and Henosepilachna 54 55 The majority of predatory species may also supplement their diet with other sources of food both in their larval and adult stages 56 Non animal matter consumed include leaves pollen nectar sap fungi and honeydew 45 56 57 Members of the tribe Halyziini of the subfamily Coccinellinae are obligate fungus feeders 58 Coccinellids of any lifestage are preyed on by predators such as birds spiders ants and lacewings 59 They are also hosts for parasites including some flies ticks mites hymenopterans and nematodes and pathogens including bacteria fungi and protozoa 44 60 Wolbachia bacteria infects eggs and kills male zygotes 61 The promiscuity of Coccinellids has led to their being affected by sexually transmitted infections 62 Diet nbsp Henosepilachna guttatopustulata an herbivore feeding on a potato leaf nbsp Yellow shouldered ladybird Apolinus lividigaster eating an aphid nbsp Harmonia axyridis larva cannibalismDefense nbsp Coccinella septempunctata reflex bleedingThe bright warning colouration of many coccinellids discourage potential predators warning of their toxicity A 2015 study of five ladybird species found that their colouration honestly signalled their toxicity implying the warning is genuine Species with more contrast with the background environment tended to be more toxic 63 Coccinellid haemolymph blood contains toxic alkaloids azamacrolides and polyamines as well as foul smelling pyrazines 64 Coccinellids can produce at least 50 types of alkaloids When disturbed ladybirds further defend themselves with reflex bleeding exuding drops from their tibio femoral knee joints effectively presenting predators with a sample of their toxic and bitter body fluid 59 Predator deterring poisons are particularly important for the immobile pupa 65 Access to food can affect the concentration of both pigments and toxins 66 The similarity of coccinellid patterning in red and orange with black markings has led to suggestions that they and some species of chrysomelids 67 form Mullerian mimicry rings 68 particularly to defend them from birds 69 Despite their chemical defenses coccinellids are preyed on by some clerid beetles in the genus Enoclerus several species of which are brightly coloured in red and black and which possibly sequester the toxins of the prey to defend themselves against other predators 70 As an anti predator defense spiders of the genus Eresus known as ladybird spiders have evolved to replicate the patterns of coccinellids This is a form of Batesian mimicry as the spiders lack the chemicals This resemblance is limited to adult male spiders which are actively searching for females and exposed unlike the females and young which remain sheltered in burrows 71 Distribution and status nbsp The widespread and invasive Harmonia axyridisCoccinellidae are found on every continent except Antarctica 72 Asian and African species are less studied than others 73 Coccinellids can be found in a variety of habitats both on the ground and in the trees They may specialise using certain plants Some species can live in extreme environments such as high mountains arid deserts and cold regions 74 Several of the most famous species have wide ranges but others are more endemic and possibly threatened 73 Threats to coccinellids include climate change agriculture urbanisation and invasive species Coccinellid biodiversity will likely be affected by the rising of both average temperatures and heat fluctuations Climate change may lead to smaller larvae as well as increase energy and metabolic needs and interspecific predation Agriculture and urbanisation threatens these insects though habitat destruction and homogenisation and the use of pesticides Invasive threats include other coccinellids particularly C septempunctata in North America and H axyridis globally 73 These invaders outcompete the native species as well as eat their eggs 73 75 As of 2022 the IUCN Red List does not list the conservation status for any coccinellid though there is an IUCN SSC Ladybird Specialist Group Conservationists have suggested several measures for protecting the insects including citizen science and education programs habitat preservation and restoration prevention of the spread of invasive species and a global monitoring program 73 Relationship to humansBiological control Further information Biological pest control nbsp Biological control larval Novius cardinalis feeding on Icerya purchasiCoccinellids have been valued in biological pest control as they prey on agricultural pests such as aphids and scale insects Their importance in controlling pests was noted as far back as 1814 in England 7 Their efficiency can vary sometimes they have a relatively small effect on aphid populations at others they cause significant seasonal declines 76 Several species have been introduced to areas outside their native range the first being the vedalia beetle Novius cardinalis 7 The larva of the species was introduced to California in 1887 from Australia to protect citrus trees from cottony cushion scale The project was markedly successful costing 1 500 in 1889 77 making it a textbook example of the great potential of classical biological control as a tactic for suppressing invasive pests The beetle was then used in 29 countries again with success reasons for this include its high prey specificity fast development multiple generations each year efficient discovery of host patches and larval development completed on a single host insect 78 There have been many further attempts to use ladybird species against pests with varying degrees of success 79 7 Scale insect eating coccinellids have been more successfully used than aphid predators 7 Out of 155 deliberate introductions meant to control aphids by the year 2000 only one was deemed to be substantially successful This is due to aphid eating species being fast breeding generalist and voracious and thus difficult to control 80 As pests nbsp Cluster of invasive Asian lady beetles inside a farm building after the fall harvest in South DakotaCoccinellids can also act as pests Harmonia axyridis is native to East Asia but has been introduced to the Americas Europe and Africa 73 In North America this species begins to appear indoors in the autumn when they leave their summer feeding sites to search out places to stay for winter Typically when temperatures warm to the mid 60s F around 18 C in the late afternoon they swarm onto or into buildings illuminated by the sun from nearby fields and forests 81 82 After an abnormally long period of hot dry weather in the summer of 1976 in the UK a marked increase in the aphid population was followed by a plague of the native Coccinella septempunctata there were many reports of people being bitten as the supply of aphids dwindled 83 84 85 H axyridis C septempunctata and Hippodamia convergens are the most common causes of ladybird taint in wine As few as 1 3 to 1 5 coccinellids per 1 kilogram 2 2 lb of grapes can affect wine quality when they are present during the wine making process 86 The Mexican bean beetle is an agricultural pest as it primarily feeds on plants especially legumes instead of insects 87 In culture Coccinellids have had important roles in culture and religion being associated with luck love fertility and prophecy Ladybird is an affectionate term for someone such as a loved one In European folklore an insect acts as a matchmaker crawling on a woman and then flying to their true love Coccinellids have been said to predict the future particularly weather conditions and how well the crops will grow 88 89 Contrary to a popular saying the age of a lady bug cannot be determined by counting its spots 90 In Christianity coccinellids have been seen as the literal gatekeepers of Heaven A Swedish name for the insects Himmelska nycla means Keys of Heaven Jews have referred to the insects as the Cow of Moses our Teacher The Cherokee have revered them as the Great Beloved Woman this was used as a title for the highest ranking woman in the government who would be painted in the colours and patterns of the insect during ceremonies 91 Coccinellids have been popularly featured in poems and nursery rhymes the most famous being Ladybird Ladybird This has come in several forms including 92 Ladybird ladybird fly away home Thy house is on fire thy children all roam Except little Nan who sits on her pan Weaving gold laces as fast as she can nbsp Card cutout ladybirds for a children snature trail nbsp Ladybird flying over cyclamen detail by Maria Sibylla Merian 1690s nbsp Depiction of the Ladybird Ladybird rhyme in Hunter Valley Gardens AustraliaReferences a b Coccinellidae Latreille 1807 Integrated Taxonomic Information System Retrieved 24 July 2012 Wikispecies Microweiseinae 2012 Retrieved 9 March 2013 coccinellid The New Oxford Dictionary of English Clarendon Press 1998 p 351 ISBN 0 19 861263 X coccinellid kɒksɪ nɛlɪd noun a beetle of a family coccinelidae that includes the ladybirds Latreille Pierre A 1807 Genera crustaceorum et insectorum secundum ordinem naturalem Vol 3 Amand Koenig pp 70 75 Brown L ed 2007 Shorter Oxford English Dictionary Vol 1 6 ed Oxford University Press p 441 ISBN 978 0199231768 Majerus 2016 p 2 a b c d e f g h i j k l m n o p q r s Majerus Michael E N 2003 Ladybugs In Resh Vincent H Carde Ring T eds Encyclopedia of Insects Academic Press pp 618 622 ISBN 0 12 586990 8 Roy Helen E Brown Peter M J et al 2013 Ladybirds 2nd ed Pelagic Publishing p 1 ISBN 978 1 9078 0707 7 a b c Frank J Howard Mizell Russell F common name ladybirds ladybird beetles lady beetles ladybugs of Florida Featured creatures University of Florida Retrieved 6 December 2022 Holland Mary 2016 Naturally curious day by day a photographic field guide and daily visit to the forests fields and wetlands of Eastern North America Stackpole Books p 173 ISBN 978 0811714129 Johnson Ken 4 June 2020 Ladybug Ladybug extension illinois edu University of Illinois Extension Retrieved 17 January 2023 Common Names of Insects Database www entsoc org Entomological Society of America Retrieved 20 January 2023 a b Seago Ainsley E Giorgi Jose Adriano Li 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31610 zsr 2012 21 1 131 Szawaryn Karol Szwedo Jacek 21 May 2018 Have ladybird beetles and whiteflies co existed for at least 40 Mya PalZ 92 4 593 603 doi 10 1007 s12542 018 0409 5 S2CID 90619916 Szawaryn Karol 29 November 2021 The first fossil Microweiseini Coleoptera Coccinellidae from the Eocene of Europe and its significance for the reconstruction of the evolution of ladybird beetles Zoological Journal of the Linnean Society 193 4 1294 1309 doi 10 1093 zoolinnean zlaa180 Robertson James A Slipinski Adam Moulton Matthew et al 2015 Phylogeny and classification of Cucujoidea and the recognition of a new superfamily Coccinelloidea Coleoptera Cucujiformia Systematic Entomology 40 4 745 778 doi 10 1111 syen 12138 S2CID 55206626 a b Giorgi J A et al 2009 The evolution of food preferences in Coccinellidae Biological Control 51 2 215 231 doi 10 1016 j biocontrol 2009 05 019 Magro A Lecompte E Magne F Hemptinne J L Crouau Roy B 2010 Phylogeny of ladybirds Coleoptera Coccinellidae Are the 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a coccinellid myrmecophile Oikos 89 2 345 359 doi 10 1034 j 1600 0706 2000 890216 x Vantaux Amelie Roux Olivier Magro Alexandra Orivel Jerome 2012 Evolutionary Perspectives on Myrmecophily in Ladybirds Psyche A Journal of Entomology 2012 1 7 doi 10 1155 2012 591570 ISSN 0033 2615 Majerus 2016 pp 107 115 Li C S 1 August 1993 Review of the Australian Epilachninae Coleoptera Coccinelledae Australian Journal of Entomology 32 3 209 224 doi 10 1111 j 1440 6055 1993 tb00577 x S2CID 84783346 Majerus 2016 p 119 a b Almeida Lucia M Correa Geovan H Giorgi Jose A Grossi Paschoal C September 2011 New record of predatory ladybird beetle Coleoptera Coccinellidae feeding on extrafloral nectaries Revista Brasileira de Entomologia 55 3 447 450 doi 10 1590 S0085 56262011005000028 Lundgren Jonathan G 2009 Nutritional aspects of non prey foods in the life histories of predaceous Coccinellidae Biological Control 51 2 294 305 doi 10 1016 j biocontrol 2009 05 016 Sutherland Andrew M Parrella Michael P 2009 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Monika Fuchs Roman 2009 What constitutes optical warning signals of ladybirds Coleoptera Coccinellidae towards bird predators colour pattern or general look Biological Journal of the Linnean Society 98 1 234 242 doi 10 1111 j 1095 8312 2009 01277 x Rifkind Jacques 2016 Enoclerus Gahan predators of chemically protected ladybird beetles Coleoptera Cleridae and Coccinellidae Insecta Mundi 0514 1 5 ISSN 1942 1354 Raska J Pekar S 2018 Do ladybird spiders really mimic ladybird beetles Biological Journal of the Linnean Society 126 1 168 177 doi 10 1093 biolinnean bly152 Majerus 2016 p 49 a b c d e f Soares A O Haelewaters D et al 2022 A roadmap for ladybird conservation and recovery Conservation Biology 37 1 e13965 doi 10 1111 cobi 13965 hdl 1854 LU 01H03C9PDA695QF4CYS2M54G5E PMID 35686511 S2CID 249544157 Majerus 2016 p 71 Cottrell T 2005 Predation and cannibalism of lady beetle eggs by adult lady beetles Biological Control 34 2 159 164 doi 10 1016 j biocontrol 2005 04 008 Obrycki J J Harwood J D Kring T J O Neil R J 2009 Aphidophagy by Coccinellidae Application of biological control in agroecosystems Biological Control 51 2 244 254 doi 10 1016 j biocontrol 2009 05 009 Caltagirone L E Doutt R L 1989 The History of the Vedalia Beetle Importation to California and its Impact on the Development of Biological Control Annual Review of Entomology 34 1 1 16 doi 10 1146 annurev en 34 010189 000245 ISSN 0066 4170 Hodek Honek amp Van Emden 2012 p 491 Hodek Honek amp Van Emden 2012 pp 491 492 Hodek Honek amp Van Emden 2012 pp 492 493 Potter Michael F Bessin Ric Townsend Lee Asian Lady Beetle Infestation of Structures University of Kentucky College of Agriculture Cooperative Extension Service Retrieved 9 December 2022 Easton Sally 2 February 2012 Ladybird contamination on the rise The Drinks Business Union Press Retrieved 21 June 2013 Anonymous 5 July 2001 Phew what a scorcher The Northern Echo Archived from the original on 4 July 2009 Retrieved 8 April 2010 Wainwright Martin 17 May 2006 The great drought The Guardian Retrieved 8 April 2010 Could the ladybird plague of 1976 happen again BBC News Online 5 March 2016 Archived from the original on 16 October 2016 Retrieved 15 December 2016 Pickering Gary J Botezatu Andreea 17 July 2021 A Review of Ladybug Taint in Wine Origins Prevention and Remediation Molecules 26 14 4341 doi 10 3390 molecules26144341 PMC 8306610 PMID 34299616 Mexican bean beetle Epilachna varivestis Mulsant University of Florida Institute of Food and Agricultural Sciences Retrieved 10 December 2022 Majerus 2016 pp 5 7 Barsevska Z Barsevskis A 2016 A ladybird Coleoptera Coccinellidae motif in croched towel end lace the first example of cultural entomology in Latvia PDF Acta Biol Univ Daugavp 16 2 151 154 Myth buster Can you tell a ladybug s age by its spots In a word no Majerus 2016 pp 3 4 Majerus 2016 p 8 SourcesHodek I Honek A 1996 Ecology of Coccinellidae Series Entomologica 54 Springer ISBN 978 0792341772 Hodek I Honek A Van Emden H F eds 2012 Ecology and Behaviour of the Ladybird Beetles Coccinellidae John Wiley amp Sons ISBN 978 1 118 22321 5 OCLC 792685088 Majerus M 2016 Roy H E Brown P M J eds A Natural History of Ladybird Beetles Cambridge University Press ISBN 978 1 107 11607 8 External links nbsp Media related to Coccinellidae at Wikimedia Commons nbsp Data related to Coccinellidae at Wikispecies Retrieved from https en wikipedia org w index php title Coccinellidae amp oldid 1207345949, wikipedia, wiki, book, books, library,

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