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Holometabolism, also called complete metamorphosis, is a form of insect development which includes four life stages: egg, larva, pupa, and imago (or adult). Holometabolism is a synapomorphy trait of all insects in the clade Holometabola. Immature stages of holometabolous insects are very different from the mature stage. In some species the holometabolous life cycle prevents larvae from competing with adults because they inhabit different . The morphology and behavior of each stage are adapted for different activities. For example, larval traits maximize feeding, growth, and development, while adult traits enable dispersal, mating, and egg laying. Some species of holometabolous insects protect and feed their offspring. Other insect developmental strategies include ametabolism and hemimetabolism.
The larval stage is variously adapted to gaining and accumulating the materials and energy necessary for growth and metamorphosis. Most holometabolous insects pass through several larval stages, or , as they grow and develop. The larva must moulting to pass from each larval stage. These stages may look very similar and differ mostly in size, or may differ in many characteristics including, behavior, color, hairs, and spines, and even number of legs. Differences between larval stages are especially pronounced in insects with hypermetamorphosis. It is not uncommon that larval tissue that is broken down during metamorphosis increase in size by cell enlargement, while cells and tissues that will turn into imago grows by an increase in numbers. The Insects: Structure and Function
The flies of superfamily Hippoboscoidea are unusual in that a larva develops inside its mother and is born in the prepupa stage, whereupon it immediately progresses to the pupa stage. If looking at only the time spent outside the mother, then the first stage of the life cycle in Hippoboscoidea would be the prepupa.'', pupa and emerging adult.]]
Pupae can be classified into three types: obtect, exarate, and coarctate. Obtect pupae are compact, with the legs and other appendages enclosed, such as a butterfly chrysalis. Exarate pupae have their legs and other appendages free and extended. Coarctate pupae develop inside the larval skin.
According to the latest phylogenetics, holometabolan insects are monophyly, which suggests that the evolutionary innovation of complete metamorphosis occurred only once. Paleontological evidence shows that the first Pterygota appeared in the Paleozoic. Carboniferous fossil samples (approximately 350 Ma) already display a remarkable diversity of species with functional wings. These fossil remains show that the primitive Apterygota, and the ancient winged insects were ametabolous (completely lacking metamorphosis). By the end of the Carboniferous, and into the Permian (approximately 300 Ma), most Pterygota had post-embryonic development which included separated nymphal and adult stages, which shows that Hemimetabolism had already evolved. The earliest known fossil insects that can be considered holometabolan appear in the Permian strata (approximately 280 Ma). Phylogenetic studies also show that the sister group of Holometabola is Paraneoptera, which includes hemimetabolan species and a number of neometabolan groups. The most parsimonious evolutionary hypothesis is that holometabolans originated from hemimetabolan ancestors.
In 1883, John Lubbock revitalized Harvey's hypothesis and argued that the origin and evolution of holometabolan development can be explained by the precocious pupa of the embryo. Hemimetabolan species, whose larvae look like the adult, have an embryo that completes all developmental stages (namely: "protopod", "polipod", and "oligopod" stages) inside the eggshell. Holometabolan species instead have vermiform larvae and a pupal stage after incomplete development and hatching. The debate continued through the twentieth century, with some authors (like Charles Pérez in 1902) claiming the precocious eclosion theory outlandish, Antonio Berlese reestablishing it as the leading theory in 1913, and Augustus Daniel Imms disseminating it widely among Anglo-Saxon readers from 1925 (see Wigglesworth 1954 for review). One of the most contentious aspects of the precocious eclosion theory that fueled further debate in the field of evolution and development was the proposal that the hemimetabolan nymphal stages are equivalent to the holometabolan pupal stage. Critics of this theory (most notably H. E. Hinton) argue that post-embryonic development in hemimetabolans and holometabolans are equivalent, and rather the last nymphal instar stage of hemimetabolans would be homologous to the holometabolan pupae. More modern opinions still oscillate between these two conceptions of the hemi- to holometabolan evolutionary trend.
J.W. Truman and L.M. Riddiford, in 1999, revitalized the precocious eclosion theory with a focus on endocrine system control of metamorphosis. They postulated that hemimetabolan species hatch after three embryonic "moulting" into a nymphal form similar to the adult, whereas holometabolan species hatch after only two embryonic 'moults' into vermiform larvae that are very different from the adult. In 2005, however, B. Konopová and J. Zrzavý reported ultrastructure studies across a wide range of hemimetabolan and holometabolan species and showed that the embryo of all species in both groups produce three cuticular depositions. The only exception was the fly Cyclorrhapha (unranked taxon of "high" Dipterans, within the infraorder Muscomorpha, which includes the highly studied Drosophila melanogaster) which has two embryonic cuticles, most likely due to secondary loss of the third. Critics of the precocious eclosion theory also argue that the larval forms of holometabolans are very often more specialized than those of hemimetabolans. X. Belles illustrates that the maggot of a fruitfly "cannot be envisaged as a vermiform and apodous (legless) creature that hatched in an early embryonic stage." It is in fact extremely specialized: for example, the cardiostipes and dististipes of the mouth are fused, as in some mosquitoes, and these parts are also fused to the and thus form the typical mouth hooks of fly larvae. Maggots are also secondarily, and not primitively, apodous. They are more derived and specialized than the cockroach nymph, a comparable and characteristic hemimetabolan example.
More recently, an increased focus on the hormone control of insect metamorphosis has helped resolve some of the evolutionary links between hemi- and holometabolan groups. In particular, the orchestration of the juvenile hormone (JH) and ecdysteroids in molting and metamorphosis processes has received much attention. The molecular pathway for metamorphosis is now well described: periodic pulses of ecdysteroids induce molting to another immature instar (nymphal in hemimetabolan and larval in holometabolan species) in the presence of JH, but the programmed cessation of JH synthesis in instars of a threshold size leads to ecdysteroid secretion inducing metamorphosis. Experimental studies show that, with the exception of higher Diptera, treatment of the final instar stage with JH causes an additional immature molt and repetition of that stage. The increased understanding of the hormonal pathway involved in metamorphosis enabled direct comparison between hemimetabolan and holometabolan development. Most notably, the transcription factor Krüppel homolog 1 (Kr-h1) which is another important antimetamorphic transducer of the JH pathway (initially demonstrated in D. melanogaster and in the beetle Tribolium castaneum) has been used to compare hemimetabolan and holometabolan metamorphosis. Namely, the Kr-h1 discovered in the cockroach German cockroach (a representative hemimatabolan species), "BgKr-h1", was shown to be extremely similar to orthologues in other insects from holometabolan orders. Compared to many other genetic sequence, the level of conservation is high, even between B. germanica and D. melanogaster, a highly derived holometabolan species. The conservation is especially high in the C2H2 Zn finger domain of the homologous transducer, which is the most complex binding site. This high degree of conservation of the C2H2 Zn finger domain in all studied species suggests that the Kr-h1 transducer function, an important part of the metamorphic process, might have been generally conserved across the entire class .
In 2009, a retired British planktology, Donald I. Williamson, published a controversial paper in the journal Proceedings of the National Academy of Sciences (via Academy member Lynn Margulis through a unique submission route in PNAS that allowed members to peer review manuscripts submitted by colleagues), wherein Williamson claimed that the caterpillar larval form originated from Onychophora through hybridogenesis with other organisms, giving rising to holometabolan species. This paper was met with severe criticism, and spurred a heated debate in the literature.
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