Montana Field Guide

Trichoptera is the largest order of insects that is entirely aquatic, with over 12,600 species worldwide (de Moor and Ivanov 2008). Caddisflies are most closely related to Lepidoptera (butterflies and moths), and they share characteristics such as spinning silk. Rhyacophilids make up one of the largest genera of Trichoptera and are some of the most primitive caddisflies.

Caddisflies spend most of their life in the water as aquatic larvae and most species build portable, protective cases made from plant material or stones. Most caddisflies either filter small particles from the water by building nets spun from silk or shredded organic matter (e.g., leaves) into smaller pieces. The genus Rhyacophila is a unique group because they do not build portable cases and are mainly predators. Not all Rhyacophila have gills; those lacking gills absorb oxygen through their skin and thus require cold, oxygen-rich, fast-flowing water to breathe.

Caddisflies typically have five larval instars before pupation. Despite larvae being free-living, Rhyacophila construct a shelter of small stones tied together with silk for pupation, and the pupa uses its mandibles to break through the case and emerge (Anderson 1976). Adults can live anywhere from a few days to several weeks.

Adult caddisflies are medium-sized insects with tent-shaped wings. They resemble moths, but caddisflies do not have a coiled proboscis and their wings are covered in hairs rather than scales. They tend to be secretive and slow-flying riparian insects (Anderson 1976). Rhyacophila usually inhabit cool mountain streams and have small distributions, often restricted to only one or two mountain ranges (Anderson 1976).

Rhyacophila kernada is part of the Coloradensis Rhyacophila group, and larvae of this group cannot be distinguished reliably to the species level yet. Rhyacophila bifila larvae can only be separated from the larvae of R. jenniferae and R. kernada by the absence of a distinct marking on the dorsum of the head (Giersch and Wisseman 2012); however, color patterns on the head are highly variable within a species and between instars. Besides color patterns, R. kernada, Rhyacophila bifila, R. jenniferae, and R. coloradensis larvae are not distinguishable, and all four species have been collected in Montana or in bordering states of Montana. Giersch and Wisseman (2012) provide a key to identify larval Rhyachophila.

In the Coloradensis group, gills are present in larvae in the shape of short, broad tubercles. Coloradensis group larvae are most readily recognized by the presence of fleshy bilobed lateral protuberances on the abdomen (Giersch and Wisseman 2012). In early instars, these protuberances may not be developed, and larvae can be confused with larvae of the Hyalinata group. Larvae of the Hyalinata group have a thicker and darker dorsal seta on the dorsum of the anal claw. Larvae in the Coloradensis group additionally have a unique anal claw with two large ventral teeth and a forked distal tooth, along with no anal proleg apicolateral spur.

Rhyacophila kernada is approximately 16-18mm long in its 5th and final instar. Its head is light yellow with two dark bands, and is widest about 2/3 of the way from the anterior margin. Its pronotum is light yellow with a light brown line across the middle line; however, the lateral and posterior margins of the pronotum are black. This species’ legs are light yellow-brown with black bands on the coxa, trochanter, and basal edge of femur (Peck and Smith 1977). For a more detailed description of distinguishing features, see Peck and Smith 1977. Adults of R. kernada have not been described.

Rhyacophila kernada is most likely the same species as Rhyacophila reana (Denning and Schmid 1971).

The Coloradensis Group larvae are common in foothill and basin streams and rivers in North America (Giersch and Wisseman 2012). In drier regions, their longitudinal distribution is displaced upstream towards the headwaters. Larvae are found in erosional habitats, often in very swift water on boulder tops (Giersch and Wisseman 2012).

Little is known about exactly what water temperatures this species inhabits; however, another Rhyacophila species (Rhyacophila vao) was recorded in a stream with an average annual water temperature of 3.7?. Additionally, R. vao was found to not pupate until stream temperature exceeded 3? (Dixon and Wrona 1992).

More sensitive taxa (mayflies, caddisflies, and stoneflies) are usually found in areas with less deposited sediment, while the abundance of tolerant taxa (fingernail clams, scuds, and non-biting midges) increases with the percent of fine sediment in the stream (Waters 1995, Cole et al. 2003).

When timber harvest and forest regeneration is concerned, many studies have found that macroinvertebrate densities decrease as forest stand age increases; however, these young stands exhibit higher dominance by just a few taxa that are tolerant to disturbance due to increased solar radiation increasing primary production (Cole et al. 2003). Older stands show lower dominance of tolerant taxa likely because stream conditions are more stable, thus allowing the abundance of sensitive taxa like caddisflies to increase.

Larval Rhyacophilids are predaceous, but their feeding patterns change as they grow. Larvae in early instars tend to have a diet dominated by moss, diatoms, and detritus, but then eat more animal material after the third instar. Later instars of Rhyacophila mainly eat Chironomidae (non-biting midge) and other small fly larvae, Ephemeroptera (mayfly), Plecoptera (stonefly), other Trichopterans, Copepoda (crustacean), Acari (water mite), and even fish eggs (Thut 1969, Dudgeon and Richardson 1988). Rather than engulfing their prey whole, larval Rhyacophila only consume the soft parts of their prey, discarding tougher structures like legs and head capsules (Giersch 2002).

Little is known about the diet of adult Rhyacophila, but other adult caddisflies do not have developed mouthparts and only eat nectar or sap from plants during their short time as an adult.

Rhyacophila species are often sympatric, with several species occurring together at one site (Giersch 2002).

The lifecycle of R. kernada has not been studied. Most caddisflies have a one-year life cycle, though some species reproduce more than once per year and others require two years to fully develop. Some species that are univoltine in lower elevation temperate streams may be semivoltine (more than one year) at higher latitudes or elevations where the growing season is too short for larvae to complete development in one year (Giersch 2002). After a short pupation phase, Rhyacophila transitions from the aquatic to the terrestrial environment. Adult R. kernada likely emerge in late summer or early autumn (Martin 1985, Hrovat and Urbanic 2012). The remainder of their lives are spent mating and reproducing. Adult caddisflies lay their eggs in or near water, either as strings surrounded by a cement-like matrix or as gelatinous masses (Anderson 1976). As adults, they use trees as roosting places.

Caddisfly adults tend to remain near the emergence site where oviposition occurs. Although dispersal flights are common, they are relatively short and only occur immediately following emergence. Dispersal from emergence sites tends to be negatively correlated with vegetation density (Collier and Smith 1998). In other words, caddisflies tend to disperse shorter distances in dense forest compared with more open areas.

There are no known threats to Rhyacophila kernada, but many Rhyacophila in Montana populations include sediment and temperature increases resulting from road building, timber harvests, and other disturbances in forested riparian areas (Stagliano et al. 2007). Global climate change is also predicted to pose a threat to R. kernada and other cold-water, mountain stream insects.