The Evolution of Flightlessness in Insects.

Table of Contents

Introduction
Why would flightlessness evolve?
Where does flightlessness occur?
How did flightlessness evolve?
Table 1: The taxonomic distribution of flightlessness in insect orders.
References

"Although insects evolved in the Devonian, they did not become markedly successful until taxa capable of flight appeared in the lower Carboniferous" (Wagner and Liebherr 1992)

"Wings have contributed more to the success of insects than any other anatomical structure" (Daly, et al. 1978)

Flightlessness has evolved in the vast majority of insect orders, and multiple times within many of these orders (see table 1). Among insect species some are exclusively (i.e. monomorphic) flightless, some are exclusively (i.e. monomorphic) flyers, and others are dimorphic with both flying and non-flying individuals. Non-flying individuals may be wingless, or they may have reduced/shortened wings (i.e. brachyptery). Flying insects typically have fully-developed, "long" wings (i.e. macroptery).

The current paradigm of evolution of flightlessness views the dimorphic condition is viewed as an intermediate stage between a monomorphic, flying, macropterous ancestor and a monomorphic, flightless descendant. Nearly all published studies explicitly or implicitly incorporate this scenario.

Why would natural selection repeatedly favor the loss of a structure which is generally attributed with being the key evolutionary innovation leading to the success of the group (see Daly, et al. quote above)? This question has intrigued insect systematists ever since Darwin.

Scientists have seeked to anwser this question through two approaches, process analysis and pattern analysis. Process analyses have included investigations into the genetic, hormonal, and environmental control of flightlessness of different species. Investigations into these processes have provided insights regarding how wing conditions are inherited, how their development is hormonally controlled, and what the influence of biotic and abiotic environmental factors are during development. Pattern analyses have included historical/phylogenetic analyses as well as analyses of flightlessness as correlated with latitude, altitude, isolation, habitat stability, and life style.

The most broadly accepted hypotheses for loss of flight in insects have focused on loss of wings resulting from increased fitness of individuals. For example, wingless females can theoretically divert more of their energy into making eggs (rather than making wings and flight muscles, the latter comprising 10-20 percent of most insect's body weight). Such hypotheses are supported by two primary avenues of evidence. First, in insect ontogeny, there is concurrent development of the flight apparatus and ovaries, this has been termed the "oogenesis -flight" syndrome (Darlington 1936, Johnson 1969). In addition, Roff (1986) found in 26 intraspecific comparisons of wing polymorphic species, 21 were more fecund as short winged and 3 were more fecund as long winged. Secondly, many winged females shed their wings and/or autolyse their flight muscles during egg production.

Flightless insects are most often found:

1. In stable habitats where, theoretically, dispersal by flight is not necessary for long-term survival of populations. Cited examples of such stable habitats are: mountains, tropical montane forests, caves, Pleistocene refugia, the ocean surface, deserts, termite and hymenopteran nests, and the body surfaces of homeothermic vertebrates. Insects that live in stable habitats and do not have to rely on flight for daily activities may particularly be selected for flightlessness.
   

2. In isolated areas. Isolated habitats where flightless insects are found include: caves, inland sand dunes, high montane and coastal strand communities (Wagner and Liebherr 1992). Darwin hypothesized that flightlessness occurs on oceanic islands where dispersing individuals should experience higher mortality than non-dispersing individuals. However, recent work has shown that the incidence of flightlessness on islands is comparable to that of the mainland, unless it is a high island (Roff 1990). High (mountainous) islands are considered stable for the same reason that mainland mountains are viewed as stable, because insects came move relatively short distances vertically to compensate for seasonal or long-term climatic fluctuations (rather than relying on flight to move great distances in search of better conditions).
   

3. In areas requiring a great amount of energy for flight. Flightlessness is often encountered where the energetic costs of flight are high (i.e. cold regions or areas of high winds). In many insect groups there is a trend toward increased brachyptery with increasing altitude and latitude.
   

4. As parasites and commensals. Vertebrate ectoparasites contain the oldest and most diverse clades of flightless insects. These include, the Cimicidae (bedbugs), Polyctenidae (batbugs), Phthiraptera (biting lice), and Siphonaptera (fleas). Wing reduction or loss is also seen in termitophiles, myrmecophiles, bee and wasp inquilines.
   

5. As parthenogenetic insects.
   

Studies have shown that for some dimorphic species wing length is controlled by a single gene locus operating in a simple Mendelian fashion with brachyptery dominant (see Lindroth 1945 and Aukema 1990 for carabids; see Jackson 1928 for weevils). However, work on field crickets (Harrison 1979, McFarlane 1962), Heteroptera (Honek 1976), and Homoptera (Rose, 1972) has shown that wing morphology in these groups is under the control of many genes.

Roff (1986) concluded that wing morphology could be controlled either by a single gene locus or a polygene complex, but both can be regulated by a hormonal threshold model. For instance, if the level of a hormone, such as juvenile hormone, exceeds a threshold value during a critical developmental stage of the insect, wing expression could be suppressed (i.e. increased levels in JH lead to more juvenile characters - brachyptery). Topical application of JH to Gryllus crickets during the ultimate and penultimate nymphal instar allowed Zera and Tiebel (1988, 1989) to redirect development from macroptery to brachyptery.

Environmental factors that influence wing development include abiotic factors such as temperature (Aukema 1990) and photoperiod (Kimura and Masaki 1977) as well as biotic factors such as food resources (Aukema 1990) and population density. It could be that these environmental factors are affecting levels of juvenile hormone in the developing embryos or larvae.

Table 1: The taxonomic distribution of flightlessness in insect orders. Complied from Andersen (1997).

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Group	Order	Winged	Dimorphic	Wingless
PALEOPTERA	Ephemeroptera	X	-	-
	Odonata	X	-	-
NEOPTERA	Plecoptera	X	rarely	-
Orthopteroids	Embioptera	-	always	-
	Zoraptera	-	always	-
	Dermaptera	X	commonly	X
	Orthoptera	X	commonly	X
	Phasmatodea	X	commonly	X
	Grylloblattodea	-	-	X
	Isoptera	-	always	-
	Blattodea	X	commonly	X
	Mantodea	X	commonly	X
Hemipteroids	Phthiraptera	-	-	X
	Psocoptera	X	commonly	X
	Thysanoptera	X	commonly	-
	Hemiptera	X	commonly	X
Endopterygota	Coleoptera	X	commonly	X
	Strepsiptera	-	always	-
	Neuroptera	X	rarely	X
	Megaloptera	X	rarely	X
	Raphidioptera	X	-	-
	Mecoptera	X	-	-
	Trichoptera	X	rarely	X
	Siphonaptera	-	-	X
	Diptera	X	rarely	X
	Lepidoptera	X	rarely	X
	Hymenoptera	X	rarely	X

All orders are linked to the respective page in the Tree of Life.

Required papers

• Andersen, N M. 1997. Phylogenetic tests of evolutionary scenarios: The evolution of flightlessness and wing polymorphism in insects. In: Grandcolas, P. (ed.), The Origin of Biodiversity in Insects: Phylogenetic Tests of Evolutionary Scenarios. Memoires du Museum National D'Histoire Naturelle 173(0):91-108.
• Kavanaugh, D.H. 1985. On wing atrophy in carabid beetles (Coleoptera: Carabidae), with special reference to Nearctic Nebria. Pages 408-431 In G.E. Ball, editor. Taxonomy, phylogeny and zoogeography of beetles and ants. Dr. W. Junk Publications, Dordrecht, The Netherlands.

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