A larva's appearance is generally very different from the adult form (e.g.caterpillars and
butterflies) including different unique structures and organs that do not occur in the adult form. Their diet may also be considerably different.
Larvae are frequently adapted to different environments than adults. For example, some larvae such as
tadpoles live almost exclusively in aquatic environments, but can live outside water as adult
frogs. By living in a distinct environment, larvae may be given shelter from predators and reduce competition for resources with the adult population.
Animals in the larval stage will consume food to fuel their transition into the adult form. In some organisms like
polychaetes and
barnacles, adults are immobile but their larvae are mobile, and use their mobile larval form to distribute themselves.[1][2] These larvae used for dispersal are either
planktotrophic (feeding) or lecithotrophic (non-feeding).
Some larvae are dependent on adults to feed them. In many eusocial
Hymenoptera species, the larvae are fed by female workers. In Ropalidia marginata (a paper wasp) the males are also capable of feeding larvae but they are much less efficient, spending more time and getting less food to the larvae.[3]
The larvae of some organisms (for example, some
newts) can become
pubescent and do not develop further into the adult form. This is a type of
neoteny.[4]
It is a misunderstanding that the larval form always
reflects the group's evolutionary history. This could be the case, but often the larval stage has evolved secondarily, as in insects.[5][6] In these cases[clarification needed], the larval form may differ more than the adult form from the group's common origin.[7]
Within
Insects, only
Endopterygotes show complete metamorphosis, including a distinct larval stage.[9][10] Several classifications have been suggested by many
entomologists,[11][12] and following classification is based on
Antonio Berlese classification in 1913. There are four main types of endopterygote larvae types:[13][14]
Apodous larvae – no legs at all and are poorly sclerotized. Based on
sclerotization. All Apocrita are apodous. Three
apodous forms are recognized.
Hemicephalus – with a reduced head capsule, retractable in to the thorax. Found in
Tipulidae and
Brachycera families.
Acephalus – without head capsule. Found in
Cyclorrhapha
Protopod larvae – larva have many different forms and often unlike a normal insect form. They hatch from eggs which contain very little
yolk. E.g. first
instar larvae of parasitic hymenoptera.
Polypod larvae – also known as eruciform larvae, these larvae have abdominal prolegs, in addition to usual thoracic legs. They are poorly sclerotized and relatively inactive. They live in close contact with their food. Best example is
caterpillars of lepidopterans.
Oligopod larvae – have well developed head capsule and mouthparts are similar to the adult, but without compound eyes. They have six legs. No abdominal prolegs. Two types can be seen:
Campodeiform – well sclerotized, dorso-ventrally flattened body. Usually long legged predators with
prognathous mouthparts. (lacewing, trichopterans, mayflies and some coleopterans).
Scarabeiform – poorly sclerotized, flat thorax and abdomen. Usually short legged and inactive burrowing forms. (
Scarabaeoidea and other coleopterans).
^Sen, R; Gadagkar, R (2006). "Males of the social wasp Ropalidia marginata can feed larvae, given an opportunity". Animal Behaviour. 71 (2): 345–350.
doi:
10.1016/j.anbehav.2005.04.022.
S2CID39848913.
^Wakahara, Masami (1996). "Heterochrony and Neotenic Salamanders: Possible Clues for Understanding the Animal Development and Evolution". Zoological Science. 13 (6): 765–776.
doi:
10.2108/zsj.13.765 (inactive 2024-04-10).
ISSN0289-0003.
PMID9107136.
S2CID35101681.{{
cite journal}}: CS1 maint: DOI inactive as of April 2024 (
link)
^Nagy, Lisa M.; Grbić, Miodrag (1999), "Cell Lineages in Larval Development and Evolution of Holometabolous Insects", The Origin and Evolution of Larval Forms, Elsevier, pp. 275–300,
doi:
10.1016/b978-012730935-4/50010-9,
ISBN978-0-12-730935-4
^Moore, R.C. (1959). Arthropoda I – Arthropoda General Features, Proarthropoda, Euarthropoda General Features, Trilobitomorpha.
Treatise on Invertebrate Paleontology. Vol. Part O. Boulder, Colorado/Lawrence, Kansas: Geological Society of America/University of Kansas Press. pp. O121, O122, O125.
ISBN978-0-8137-3015-8.
^JOHNSON, NORMAN. TRIPLEHORN, CHARLES A. (2020). BORROR AND DELONG'S INTRODUCTION TO THE STUDY OF INSECTS. CENGAGE LEARNING CUSTOM P.
ISBN978-0-357-67127-6.
OCLC1163940863.{{
cite book}}: CS1 maint: multiple names: authors list (
link)
Brusca, R. C. & Brusca, G. J. (2003). Invertebrates (2nd ed.). Sunderland, Mass. : Sinauer Associates.
Hall, B. K. & Wake, M. H., eds. (1999). The Origin and Evolution of Larval Forms. San Diego: Academic Press.
Leis, J. M. & Carson-Ewart, B. M., eds. (2000). The Larvae of Indo-Pacific Coastal Fishes. An Identification Guide to Marine Fish Larvae. Fauna Malesiana handbooks, vol. 2. Brill, Leiden.
Minelli, A. (2009). The larva. In: Perspectives in Animal Phylogeny and Evolution. Oxford University Press. p. 160–170.
link.
Shanks, A. L. (2001). An Identification Guide to the Larval Marine Invertebrates of the Pacific Northwest. Oregon State University Press, Corvallis. 256 pp.
Smith, D. & Johnson, K. B. (1977). A Guide to Marine Coastal Plankton and Marine Invertebrate Larvae. Kendall/Hunt Plublishing Company.
Stanwell-Smith, D., Hood, A. & Peck, L. S. (1997). A field guide to the pelagic invertebrates larvae of the maritime Antarctic. British Antarctic Survey, Cambridge.
A larva's appearance is generally very different from the adult form (e.g.caterpillars and
butterflies) including different unique structures and organs that do not occur in the adult form. Their diet may also be considerably different.
Larvae are frequently adapted to different environments than adults. For example, some larvae such as
tadpoles live almost exclusively in aquatic environments, but can live outside water as adult
frogs. By living in a distinct environment, larvae may be given shelter from predators and reduce competition for resources with the adult population.
Animals in the larval stage will consume food to fuel their transition into the adult form. In some organisms like
polychaetes and
barnacles, adults are immobile but their larvae are mobile, and use their mobile larval form to distribute themselves.[1][2] These larvae used for dispersal are either
planktotrophic (feeding) or lecithotrophic (non-feeding).
Some larvae are dependent on adults to feed them. In many eusocial
Hymenoptera species, the larvae are fed by female workers. In Ropalidia marginata (a paper wasp) the males are also capable of feeding larvae but they are much less efficient, spending more time and getting less food to the larvae.[3]
The larvae of some organisms (for example, some
newts) can become
pubescent and do not develop further into the adult form. This is a type of
neoteny.[4]
It is a misunderstanding that the larval form always
reflects the group's evolutionary history. This could be the case, but often the larval stage has evolved secondarily, as in insects.[5][6] In these cases[clarification needed], the larval form may differ more than the adult form from the group's common origin.[7]
Within
Insects, only
Endopterygotes show complete metamorphosis, including a distinct larval stage.[9][10] Several classifications have been suggested by many
entomologists,[11][12] and following classification is based on
Antonio Berlese classification in 1913. There are four main types of endopterygote larvae types:[13][14]
Apodous larvae – no legs at all and are poorly sclerotized. Based on
sclerotization. All Apocrita are apodous. Three
apodous forms are recognized.
Hemicephalus – with a reduced head capsule, retractable in to the thorax. Found in
Tipulidae and
Brachycera families.
Acephalus – without head capsule. Found in
Cyclorrhapha
Protopod larvae – larva have many different forms and often unlike a normal insect form. They hatch from eggs which contain very little
yolk. E.g. first
instar larvae of parasitic hymenoptera.
Polypod larvae – also known as eruciform larvae, these larvae have abdominal prolegs, in addition to usual thoracic legs. They are poorly sclerotized and relatively inactive. They live in close contact with their food. Best example is
caterpillars of lepidopterans.
Oligopod larvae – have well developed head capsule and mouthparts are similar to the adult, but without compound eyes. They have six legs. No abdominal prolegs. Two types can be seen:
Campodeiform – well sclerotized, dorso-ventrally flattened body. Usually long legged predators with
prognathous mouthparts. (lacewing, trichopterans, mayflies and some coleopterans).
Scarabeiform – poorly sclerotized, flat thorax and abdomen. Usually short legged and inactive burrowing forms. (
Scarabaeoidea and other coleopterans).
^Sen, R; Gadagkar, R (2006). "Males of the social wasp Ropalidia marginata can feed larvae, given an opportunity". Animal Behaviour. 71 (2): 345–350.
doi:
10.1016/j.anbehav.2005.04.022.
S2CID39848913.
^Wakahara, Masami (1996). "Heterochrony and Neotenic Salamanders: Possible Clues for Understanding the Animal Development and Evolution". Zoological Science. 13 (6): 765–776.
doi:
10.2108/zsj.13.765 (inactive 2024-04-10).
ISSN0289-0003.
PMID9107136.
S2CID35101681.{{
cite journal}}: CS1 maint: DOI inactive as of April 2024 (
link)
^Nagy, Lisa M.; Grbić, Miodrag (1999), "Cell Lineages in Larval Development and Evolution of Holometabolous Insects", The Origin and Evolution of Larval Forms, Elsevier, pp. 275–300,
doi:
10.1016/b978-012730935-4/50010-9,
ISBN978-0-12-730935-4
^Moore, R.C. (1959). Arthropoda I – Arthropoda General Features, Proarthropoda, Euarthropoda General Features, Trilobitomorpha.
Treatise on Invertebrate Paleontology. Vol. Part O. Boulder, Colorado/Lawrence, Kansas: Geological Society of America/University of Kansas Press. pp. O121, O122, O125.
ISBN978-0-8137-3015-8.
^JOHNSON, NORMAN. TRIPLEHORN, CHARLES A. (2020). BORROR AND DELONG'S INTRODUCTION TO THE STUDY OF INSECTS. CENGAGE LEARNING CUSTOM P.
ISBN978-0-357-67127-6.
OCLC1163940863.{{
cite book}}: CS1 maint: multiple names: authors list (
link)
Brusca, R. C. & Brusca, G. J. (2003). Invertebrates (2nd ed.). Sunderland, Mass. : Sinauer Associates.
Hall, B. K. & Wake, M. H., eds. (1999). The Origin and Evolution of Larval Forms. San Diego: Academic Press.
Leis, J. M. & Carson-Ewart, B. M., eds. (2000). The Larvae of Indo-Pacific Coastal Fishes. An Identification Guide to Marine Fish Larvae. Fauna Malesiana handbooks, vol. 2. Brill, Leiden.
Minelli, A. (2009). The larva. In: Perspectives in Animal Phylogeny and Evolution. Oxford University Press. p. 160–170.
link.
Shanks, A. L. (2001). An Identification Guide to the Larval Marine Invertebrates of the Pacific Northwest. Oregon State University Press, Corvallis. 256 pp.
Smith, D. & Johnson, K. B. (1977). A Guide to Marine Coastal Plankton and Marine Invertebrate Larvae. Kendall/Hunt Plublishing Company.
Stanwell-Smith, D., Hood, A. & Peck, L. S. (1997). A field guide to the pelagic invertebrates larvae of the maritime Antarctic. British Antarctic Survey, Cambridge.