Megaloptera
EOL Text
Order Megaloptera has two families and sixty genera. All alderflies, dobsonflies, and fishflies have aquatic larvae. The adult alderflies are diurnal. The adult dobsonflies and fishflies are nocturnal. They all have large wings and the hind wings are pleated to aid folding. They have compound eyes and chewing mandibles. Megaloptera undergo complete metamorphosis. Males use vibrations or scent glands to attract a mate. The females lay their eggs on rocks or leaves near water. They have predaceous larvae that capture other aquatic insects. They become scavengers when kept in captivity. The larvae take several years to reach maturity. Once they are mature, they create a chamber where they take several days to molt and pupate. The adults have a lifespan ranging from a few hours to a few days. Their primary concern is reproduction and most species do not feed, but will sometimes drink water. Megaloptera have been around since the Permian.
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The order Megaloptera, formerly considered a suborder (Sialodea) of Neuroptera, is generally considered to be among the most primitive of the holometabolous insect orders. It contains two families, the Sialidae (alderflies) and the Corydalidae, the latter subdivided into the Corydalinae (dobsonflies) and the Chauliodinae (fishflies). The fauna of Megaloptera consists of about 300 extant species worldwide (New and Theischinger 1993). A list of all megalopteran genera is available here.
A typical dobsonfly male with elongated mandibles. Corydalus imperiosus Contreras-Ramos (Corydalidae: Corydalinae), Misiones, Argentina. Photograph copyright © 1997, Atilano Contreras-Ramos
Like Ephemeroptera, Odonata, Plecoptera, and Trichoptera, the order Megaloptera is entirely aquatic, i.e., all--or nearly all--megalopteran species have at least one aquatic stage. Adults of Corydalidae are particularly noteworthy for their frequently large size, and, in many species of the genera Corydalus and Acanthacorydalis, for the extremely elongated mandibles of adult males. Adult fishflies and dobsonflies are generally nocturnal and secretive, while alderflies are diurnal yet not too frequently collected. At the right place and time of the year (e.g., near the edge of clean lakes in Minnesota, U.S.A., around June), however, it is possible to find individuals of the fishfly Chauliodes rastricornis Rambur congregating under lights, or aggregates of alderflies on vegetation during day time.
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| Rights holder/Author | Atilano Contreras-Ramos, Tree of Life web project |
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Adults of Megaloptera can be identified by the enlarged and fan-folded anal area of their hind wings (Borror et al. 1989). Those of Corydalidae are large (forewing longer than 15 mm, wingspan up to 180 mm), pale yellowish to brownish or spotted black, with ocelli, and their 4th tarsal segment is simple; while those of Sialidae are small (forewing 15 mm or less), dark brown to gray and black (sometimes with orange spots on the head), lack ocelli, and their 4th tarsal segment is bilobed.
Larvae are elongate, moderately flattened, prognathous, have a distinct labrum, and measure 10-90 mm when mature. Mouth parts are of the chewing type, well developed. Larvae bear lateral abdominal filaments (on segments 1-8 in Corydalidae, and 1-7 in Sialidae) and either a pair of anal prolegs (Corydalidae) or a single caudal filament (Sialidae). Members of the subfamily Corydalinae also possess tufts of accesory tracheal gills under the lateral filaments of segments 1-7 (Evans and Neunzig 1996, Theischinger 1991).
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| Rights holder/Author | Atilano Contreras-Ramos, Tree of Life web project |
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Oviposition
Megaloptera adults lay their egg masses on rocks, tree trunks, leaves, and other substrates adjacent to water, and the young larvae fall or crawl into the water shortly after hatching. Sialid egg masses are single layered, whereas corydalids lay their eggs in egg masses of one to five layers (Evans & Neunzig 1996).
There does not seem to be a clear preference for oviposition substrates in Neotropical dobsonflies. Nevertheless, a certain selectivity for substrates may be hard to determine in some cases, as egg masses of Chloronia, Corydalus, and Platyneuromus are quite similar (whitish, chalky, coin size). Canterbury (1978) reports a general selection of vegetation hanging over the water for the oviposition of eastern North American sialids, however, some species preferred leaves, and other species oviposited on twigs or branches.
Larval Habitats
Typically, alderfly larvae are associated with lentic habitats (sediments of lakes and depositional zones of streams), while corydalid larvae (hellgrammites) mostly occur in lotic environments (riffles and other erosional zones, from small mountain streams to large rivers). Some Australian fishflies are known from swamps (Theischinger 1991), whereas North American Chauliodes are typically associated with lakes, ponds, and swamps (Cuyler 1958). Canterbury (op. cit.) found that some Sialis species seemed to be confined to one type of aquatic habitat (e.g., small clear streams, larger streams, small woodland ponds, or bays and inlets of lakes). Hayashi (1989), as well, points out a possible habitat seggregation between Parachauliodes japonicus (MacLachlan) and Protohermes grandis (Thunberg) larvae in Japanese streams. The former apparently restrict themselves to shallow edge waters, where they can utilize abdominal respiratory tubes in the event of an oxygen decrease, while the latter prefer the central part of riffles (larvae having gill tufts, but lacking respiratory tubes). On the same token, Geijskes (1984) found in Suriname an apparent preference of Corydalus nubilus Erichson and C. affinis Burmeister to large open rivers, while C. batesii MacLachlan and Chloronia hyeroglyphica (Rambur) seemed to be restricted to small shaded creeks.
Recent findings indicate the occurrence of Chauliodes and Sialis larvae in "unusual" habitats, such as tree holes and purple pitcher plants (Fashing 1994, Hamilton et al. 1996, Pittman et al. 1996). This is additional evidence of this group's larval endurance to cope with potentially inhospitable conditions. This is the case in other fishfly species, such as Neohermes californicus (Walker), whose first instar larvae bury into the substrate of dry intermittent streams during summer in California, remaining in cells until rains reappear in late fall and streams flow once again (Smith 1970).
Larval Development
Alderflies are very difficult to find in tropical climates (Henry et al. 1992). Although they occur through most of the world (with the exception of much of Africa), life histories of species of temperate climates are better known. In Europe, the life cycle of Sialis lutaria L. has been found to take from one to two years and even three years in high altitude lakes (Dall 1989), whereas in North America Sialis species have shown life cycles of one to two years (Azam & Anderson 1969, Pritchard & Leischner 1973). There are 10 larval instars in the development of Sialis under natural conditions (New & Theischinger 1993, Evans & Neunzig 1996).
Evans (1972) estimated that development of western North American fishflies might take from two (Neohermes) to four and five years (Dysmicohermes, Orohermes, Protochauliodes), while Hayashi (1989) estimated a two-year larval period for Parachauliodes japonicus. He (1988a) also determined a two to three year larval period for Protohermes grandis (Thunberg).
Bowles (1990) cites studies on Nearctic Corydalus cornutus (L.) that report life histories of one (southern latitudes) to five years (northern latitudes), the larvae having 10-12 instars. Hayashi (1994) found larval periods that varied from one to three years in Japanese Protohermes, period length depending strongly on water temperature.
Immature Megaloptera. a. larva of Platyneuromus soror (Hagen) (Corydalidae, Corydalinae), Nuevo León, Mexico; b. male pupa of Corydalus cornutus (L.) (Corydalidae, Corydalinae), Alabama, USA; c. female pupa of Nigronia fasciatus (Walker) (Corydalidae, Chauliodinae), Alabama, USA. Photographs copyright © 1997, Atilano Contreras-Ramos
Larval Feeding Ecology
Megalopteran larvae are generalist predators and, at least in captivity, scavengers. Stewart et al. (1973) found larvae of black flies (Diptera: Simuliidae) and net spinning caddisflies (Trichoptera: Hydropsychidae) as the main items in the diet of the dobson fly Corydalus cornutus (L.) hellgrammites in a Texan river, but 17 other aquatic insect groups (in addition to individuals of its own species!) were also eaten. Hayashi (1988b) found larvae of the Japanese fish fly Protohermes grandis to feed on a wide variety of benthic macroinvertebrates including mayflies, stoneflies, and chironomids, showing some degree of cannibalism as well. Similar patterns have been observed for alder flies, although a certain specificity has been detected. For instance, the North American Sialis itascae Ross was observed to prey mostly on ostracods, even when several other prey were available (Lilly et al. 1978, cited by New & Theischinger 1993).
Pupae and Adults
When mature, the larvae leave the water and build a chamber under a rock or log, not too far from the aquatic habitat. In these chambers they spend several days as prepupae (generally about a week), then they molt and become decticous and exarate pupae which are capable of limited movement, including a strong defensive bite. After several more days (8-24 days in Corydalidae, 5-8 days to about a month in Sialidae; New & Theischinger 1993) the adults emerge and the life cycle is completed.
Adults are short-lived and generally do not feed, though they may drink water or sweet solutions. Parfin (1952) recorded an average of eight days for the adult longevity of Nearctic Corydalus cornutus. Mexican adult Platyneuromus soror (Hagen) lived for up to a week in captivity, however actual life span might be longer in nature since specimens had been collected with black light; moreover damage on wings and antennae points out injuries due to confinement conditions (Contreras-Ramos 1999a).
Reproductive Biology
Mating and courtship behavior are better known in Sialidae than in Corydalidae. Several studies on Sialis (New & Theischinger 1993) reported reciprocal signalling, which implies a vertical vibration of the abdomen by males and females. Vibrations allow mutual recognition of species and sex. In some dobsonflies (e.g., Corydalus texanus Banks and Platyneuromus soror), males may use female attractant scents from eversible glands near the genitalia (between 8th and 9th abdominal segments and under the 9th sternum; Evans 1972; Contreras-Ramos 1998, 1999a).
Corydalus males fight when encountering each other (Evans 1972, Parfin 1952). Platyneuromus males only display a threatening position (mandibles open) but do not fight (Contreras-Ramos 1990). Premating behavior in Corydalus involves touching of antennae between male and female while facing one another, as well as male wing fluttering (Parfin 1952, Evans 1972). In Platyneuromus soror, males actively pursue females, at the same time fluttering their wings and lifting their genitalia (10th tergites) above the level of the wings in an "arrogant" position (Contreras-Ramos 1999a).
Fertilization involves the transfer of a gelatinous spermatophore (Hayashi 1992, 1993). This reproductive strategy might cause low levels of sexual selection ("female choice" pattern, sensu Eberhard 1985), resulting in a rather conservative morphology of male genitalia (Contreras-Ramos 1998).
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| Rights holder/Author | Atilano Contreras-Ramos, Tree of Life web project |
| Source | http://tolweb.org/Megaloptera/8218 |
Tree represents standard accepted classification.
The monophyly of Megaloptera is generally accepted, however adult synapomorphies remain obscure (New and Theischinger 1993, Kristensen 1991). Boudreaux (1979) suggested the following traits as apomorphies for the order: (i) wing pterostigma secondarily unpigmented, (ii) loss of the terminal bifurcations of the main veins, (iii) larvae aquatic (the embryonic limb buds become leglike structures into which respiratory tracheae appear to penetrate), (iv) larval maxillary stipes elongated, as in the adult condition. Similarly, the monophyly of each family (and so the sister group relationship of Chauliodinae and Corydalinae) has not been demonstrated explicitly through a phylogenetic analysis. It is, however, a general assumption in current classifications.
Boudreaux (1979) proposed the following features as derived. Corydalidae: (i) enlarged jugal area with a prominent jugal bar in the hind wing, (ii) hind wing folding among the posterior anal veins (not at the jugal fold as in other endopterygotes and Sialidae). Sialidae: (i) adult gula, cervical region, and the prothoracic sternum secondarily desclerotized, (ii) ocelli lost, (iii) 4th tarsomeres strongly bilobed, (iv) claspers of the male genitalia reduced, and (v) larval pygopods (anal prolegs) lost.
Since Sialidae appears to be the group with more specializations, such as the secondary desclerotization of the gular region and the reduction of structures in the male genitalia, among others, there should be caution as to grouping Chauliodinae and Corydalinae on the basis of primitive characters (however this question deserves a thorough phylogenetic analysis of its own).
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| Rights holder/Author | Atilano Contreras-Ramos, Tree of Life web project |
| Source | http://tolweb.org/Megaloptera/8218 |
Barcode of Life Data Systems (BOLD) Stats
Specimen Records:1730
Specimens with Sequences:1517
Specimens with Barcodes:1461
Species:83
Species With Barcodes:79
Public Records:1431
Public Species:29
Public BINs:107