The larva of Rhyacophila ferox Graf, 2006 (Trichoptera: Rhyacophilidae) from the Eastern Alps (Carinthia,Austria)

The hitherto unknown larva of Rhyacophila ferox Graf, 2006, is described and discussed in the context of contemporary Rhyacophilidae keys. In addition, zoogeographical and ecological notes are included.     

Differential vulnerability determines the diet of a slow-moving predatory stream insect

1. We investigated the diet and prey electivity of Rhyacophila obliterata, a slow‐moving invertebrate predator capable of hunting in high‐flow microhabitats, and quantified the components of the predation sequence of fifth‐instar larvae foraging on mobile (Baetis mayflies, Amphinemura stoneflies) versus semi‐sessile (larval blackflies) prey. 2. In the field, fifth‐instar Rhyacophila consistently took more larval blackflies than more mobile prey. In behavioural trials, the number of attacks by Rhyacophila differed significantly between prey types, mobile prey being attacked more often than blackflies. Capture success, by contrast, was highest for blackflies, whereas Amphinemura and Baetis were rarely captured. In mixed‐prey feeding trials, Rhyacophila showed strong preference for blackflies and equally strong avoidance of Amphinemura and Baetis. 3. For mobile prey, the risk of being captured by this sluggish predator is very low, so they can afford to be in close contact with it. Rhyacophila was almost unable to capture any other prey but blackflies, resulting in strong passive selection for blackflies. 4. Therefore, the diet of fifth‐instar Rhyacophila can be predicted from laboratory observations and prey behaviour is the major determinant of the diet of this invertebrate predator.     

Contrasting diel activity and feeding patterns of four instars of Rhyacophila dorsalis (Trichoptera)

1. Ontogenetic shifts in prey choice and predator behaviour can affect food‐web structure. Therefore, it is important to establish if the diet and feeding activity differ between life‐stages of the same species. This hypothesis was tested for second, third, fourth and fifth larval instars of Rhyacophila dorsalis by comparing their diel activity and feeding patterns. Second to fifth instars collected from two streams were used either for gut analyses or for observations of their activity and feeding patterns in three stream tanks. Food was provided in excess; being organisms living in bryophytes on top of a large stone in each tank, augmented by different‐sized larvae of Ephemeroptera, Simuliidae and Chironomidae. As few first instars for gut analyses were found in the field, the diet of first instars reared in the laboratory was also studied. 2. Larvae for gut analyses were taken 1 h before dusk or dawn (n = 50 larvae per instar for each day or night sample). First and second instars fed on the smaller food items with no significant day‐night differences in diet. Gut contents indicated a progressive trend from feeding chiefly at night in third instars to almost exclusively at night in fifth instars. Fourth and fifth instars fed on the larger food items, whilst the diet of the third instar larvae overlapped with that of both the earlier and later instars. 3. Diel activity patterns of single larvae differed between instars but not within each instar (n = 20 larvae per instar). Second instars were active throughout the 24 h, with peaks at dusk, around midnight, dawn and around midday. A similar pattern was shown by third instars but the peak of activity at midday was less than the other three peaks. Prey were captured only during these peaks for both instars. Fourth and fifth instars were most active, and fed only, at night. They used an ambush strategy to capture more active prey at dusk and dawn (e.g. Baetis, Gammarus), and a searching strategy to capture more sedentary prey during the night (e.g. chironomids, simuliids). These experiments provided support for the hypothesis under test. If competition and/or interference occur between instars, then it could be reduced between earlier and later instars because of differences in their diet and diel pattern of feeding activity.     

Prey switching in Rhyacophila dorsalis (Trichoptera) alters with larval instar

1. Ontogenetic shifts in predator behaviour can affect the assessment of food‐web structure and the development of predator–prey models. Previous studies have shown that the diel activity pattern and functional response differed between larval instars of the carnivorous caddis, Rhyacophila dorsalis. The present study examines switching by larvae of R. dorsalis presented with different proportions of two prey types; either small (length 2–4 mm) and large (5–8 mm) Chironomus larvae for second, third, fourth and fifth instars of R. dorsalis; or Baetis rhodani (9–12 mm) and large Chironomus larvae for fourth and fifth instars. Experiments were performed in stream tanks with one Rhyacophila larva per tank and 200 prey arranged in nine different combinations of the two prey types (20 : 180, 40 : 160, 60 : 140, 80 : 120, 100 : 100, 120 : 80, 140 : 60, 160 : 40 and 180 : 20). Prey were replaced as they were eaten. A model predicted the functional response in the absence of switching and provided a null hypothesis against which any tendency to switch could be tested. 2. There was no prey switching in the second and third instars, with both instars always showing a preference for small over large Chironomus larvae. Prey switching occurred in the fourth and fifth instars. As the relative abundance of one prey type increased in relation to the alternative, the proportion eaten of the former prey changed from less to more than expected from its availability, the relationship being described by an S‐shaped curve. In the experiments with small and large Chironomus, the two instars switched to large larvae when their percentage of the total available prey exceeded 29% and 37% for fourth and fifth instars, respectively. In the experiments with Baetis and large Chironomus, both instars switched to Baetis larvae when their percentage of the total available prey exceeded 36%. 3. Non‐switching in second and third instars was related to their feeding strategies, both instars preferring smaller prey items. When the fourth and fifth instars foraged actively at night, they preferred larger over small Chironomus larvae, but when they behaved as ambush predators at dusk, they captured the more active Baetis larvae in preference to the more sedentary large Chironomus larvae and only switched to the latter when they were >64% of the available prey.     

Trichoptera fauna from Nakhon Si Thammarat Range (southern Thailand), with the description of a new species of Rhyacophila Pictet, 1834 (Trichoptera: Rhyacophilidae)

Seventy-five species of caddisflies were found near eight waterfalls in the Tai Rom Yen National Park and the Khao Luang National Park, within Nakhon Si Thammarat Range, in southern Thailand. Rhyacophila suratthaniensis sp. n. is described and figured, based on adult males. Rhyacophila suratthaniensis sp. n. is distinguished from other species of the genus by the shape of its paramere: their basal part is broader than the apical one and is separated from it by a step; apex of the paramere bears many strong spines, which are arranged like in a toothbrush. Occurrence of Trichoptera species in the observed and neighbouring areas is discussed.

http://zoobank.org/urn:lsid:zoobank.org:pub:336401B5-DAAA-4818-90EA-5DCB1944D1F0     

Secondary production of Rhyacophila minora,Ameletus sp., and Isonychia bicolor from streams of low and circumneutral pH in the Appalachian Mountains of West Virginia

We estimated the secondary production of Rhyacophila minora, Ameletus sp., and Isonychia bicolor in three acidic streams and one circumneutral stream in Randolph County, West Virginia. Quantitative benthic samples were collected monthly from these second-order streams from November 1990 to October 1991. Mean pH values in the acidic streams were 4.5, 4.8, and 4.8, and mean pH in the circumneutral stream was 6.7. Production estimates for Rhyacophia minora in the acidic streams were 49.6, 19.2, and 15.8 mg m^–2 y^–1. Production of R. minora in the circumneutral stream was 1.0 mg m^–2 y^–1. Ameletus sp. production estimates for the acidic streams were 144.8, 176.8, and 208.3 mg m^–2 y^–1. Ameletus sp. production in the circumneutral stream was 7.4 mg m^–2 y^–1. Secondary production of I. bicolor in the circumneutral stream was 116.6 mg m^–2 y^–1. No Isonychia were collected from the acidic streams. The higher production of R. minora and Ameletus sp. in the acidic streams may be associated with differences in macroinvertebrate community structure.     

Life cycle of Rhyacophila fasciata Hagen, 1859 and Hydropsyche saxonica McLachlan, 1884 in a Dinaric karst river system

Life cycles of Rhyacophila fasciata Hagen, 1859 and Hydropsyche saxonica McLachlan, 1884 were investigated in a Dinaric karst river system. Benthic samples were taken monthly from January to December 2005. Environmental variables were measured simultaneously. Larval stages were defined using head capsule widths. As only instars 2–5 were collected in the field, the head width of first instar larvae was extrapolated using Dyar's rule. R. fasciata showed an extended emergence and recruitment, whereas in H. saxonica a typical univoltine cycle with summer and early autumn emergence was observed. Canonical correspondence analysis was used to define the relationship between environmental variables and larval stages. H. saxonica larval instars were distributed along temporal and nutrient gradients at all sampling sites, but differences were observed among sampling sites. The larval instars, prepupae and pupae of R. fasciata were distributed along water depth and oxygen concentration gradients, but temporal and temperature gradients were less important.     

Ontogenetic shifts in the functional response and interference interactions of Rhyacophila dorsalis larvae (Trichoptera)

1. Ontogenetic shifts in predator behaviour can affect the assessment of food‐web structure and the development of predator–prey models. Therefore, it is important to establish if the functional response and interference interactions differ between life‐stages. These hypotheses were tested by (i) comparing the functional response of second, third, fourth and fifth larval instars of Rhyacophila dorsalis, using three stream tanks with one Rhyacophila larva per tank and one of 10 prey densities between 20 and 200 larvae of Chironomus sp.; (ii) using other experiments to assess interference within instars (two to five larvae of the same instar per tank), and between pairs of different instars (one, two or three larvae per instar; total predator densities of two, four or six larvae per tank). 2. The first hypothesis was supported. The number of prey eaten by each instar increased with prey density, the relationship being described by a type II model. The curvilinear response was stronger for fourth and fifth instars than for second and third instars. Mean handling time did not change significantly with prey density, and increased with decreasing instar number from 169 s for fifth instars to 200 s for second instars. Attack rate decreased progressively with decreasing instar number. Handling time varied considerably for each predator–prey encounter, but was normally distributed for each predator instar. Variations in attack rate and handling time were related to differences in activity between instars, fourth and fifth instars being more active and aggressive than second and third instars, and having a higher food intake. 3. The second hypothesis was partially supported. In the interference experiments between larvae of the same instar or different instars, mean handling time did not change significantly with increasing predator density, and attack rate did not change for second and third instars but decreased curvilinearly for fourth and fifth instars. Interference between some instars could not be studied because insufficient second instars were available at the same time as fourth and fifth instars, and most third instars were eaten by fourth and fifth instars in the experiments. Prey capture always decreased with decreasing attack rate. Therefore, interference reduced prey consumption in fourth and fifth instars, but not in second and third instars. The varying feeding responses of different instars should be taken into account when assessing their role in predator–prey relationships in the field.     

中国原石蛾属五新种(毛翅目:原石蛾科)

本文记述原石蛾属Ｒｈｙａｃｏｐｈｉａ的Ｒ．ｎｉｇｒｏｃｅｐｈａｌａ种团５新种：宽片原石蛾Ｒｈｙａ－ｃｏｐｈｉｌａｅｕｒｙｐｈｙｌａ;楔肢原石蛾Ｒｈｙａｃｏｐｈｉｌａｃｕｎｅａｔａ;隐片原石蛾Ｒｈｙａｃｏｐｈｉｌａｃｅｌａｔａ;小片原石蛾Ｒｈｙａｃｏｐｈｉｌａｅｘｉｌｉｓ和齿肢原石蛾Ｒｈｙａｃｏｐｈｉｌａａｍｂｌｙｏｄｏｎｔａ。模式标本保存在南京农业大学昆虫标本室。     

Unusual behaviour and morphology of some Rhyacophila Pictet, 1834 caddisfly (Trichoptera: Rhyacophilidae) larvae reflect their ability to use the hyporheic zone

We found that larvae of four Rhyacophila Pictet, 1834 species preferred the hyporheic biotope in rapids and glides, which appears to be an unusual habitat among species in this genus. These species, i.e., Rhyacophila nigrocephala Iwata, 1927, R. nipponica Navas, 1933, R. shikotsuensis Iwata, 1927 and R. kawamurae Tsuda, 1940, belonging to the nigrocephala species group, of which six species occur in Japan. To study the movement behaviour of these species in the hyporheic biotope, we introduced their larvae into a small aquarium with a sandy bottom substrate. The larvae of these species burrowed into the sand bed and moved smoothly through interstices using their forelegs and their highly flexible and elastic abdomens. The larval morphology of these six species differs from that of the representatives of the other species group of Japanese Rhyacophila. They have more slender and flatter head capsules, more elongate abdominal segments, shorter thoracic legs and more slender anal prolegs. These features are adaptations that allow these species to effectively use the hyporheic biotope by enabling them to burrow through the interstices.