Aquatic organisms 9 “Is ditch water dull? Naturalists with microscopes have told me that it teems with quiet fun.” — G.K. Chesterton A healthy stream is a highly diversified the quality of available water. Fish occupy an ecosystem. Its complex food chain ranges important position in the aquatic food chain and from microscopic diatoms and algae to obtain their food supply from several sources. large fish, birds and mammals. The diversity of The amount of food available in a stream is species, particularly aquatic organisms, and their determined by the physical and biological condi- numbers are important to any stream study for tions of the area. When producers are plentiful, two reasons: consumers also flourish. Diatoms coating a rock feed primary consumers such as mayflies. They, • as indicators of water quality in the stream in turn, feed higher-order consumers like and stoneflies and fish. (cid:127) as parts of various food chains, including Overhanging Vocabulary fish. vegetation supplies a benthic A wide variety of organisms inhabit water. variety of terrestrial hyporheic The size and diversity of a population depend on insects to the menu. plankton Oregon Department of Fish & Wildlife Aquatic organisms • 307 Many aquatic insects use streamside vegetation underground and under-river ecosystem. These during emergence and adult stages of their life organisms contribute to the health and productiv- cycle. ity of the river by supporting the aquatic food Some aquatic insects leave their positions chain that extends to and beyond the water’s among boulders and gravel in riffles and are surface. carried downstream short distances before reat- taching to the stream bottom. When insects are moving in a water column, as drift or during The diversity of species, emergence, they are most vulnerable to being eaten. particularly aquatic organisms Benthic (bottom dwelling) organisms are and their numbers, are found on stones or in mud or vegetation. Because a streambed serves as a place for attachment, important to any stream. most organisms in a fast-moving stream will be benthic. Organisms in fast water have many special- ized methods for obtaining food. To gather food Evidence suggests that hyporheic (from in a water column, they grasp it quickly or filter Greek for “below” and “flow”) exchange is it from the water while remaining stationary. significant in large streams, like the Santiam Others gather food on the bottom. River of Oregon’s Willamette Valley. Some Plankton can be producers or consumers and scientists feel the stability of many streams may float or swim freely throughout a stream. Few depend largely on these hyporheic zones, which organisms can live in rapid sections of streams exchange water and materials with the river without being swept downstream by the current. channel. The hyporheic zone may extend 15 feet Consequently, plankton are abundant in slower to 30 feet below the river bottom and two miles waters of large streams and rivers. to either side of the river. Stream ecologists have found a complex The knowledge of hyporheic zones, and the community of small animals living in the ground organisms found there, challenges traditional water below the stream channel and sometimes views of how rivers work. It may have an effect for miles on each side. Many types of small blind on river system assessments. It could also mean shrimp, primitive worms, bacteria, algae, and that measures to protect streams from pollution various kinds of immature insects live most, if or alteration may need expansion to include not all, of their lives in a maze of channels in this wider areas along the watercourses. 308 (cid:127) The Stream Scene: Watersheds, Wildlife and People Oregon Department of Fish & Wildlife Food processing 9.1 “And in the water winding weeds move round.” —Wallace Stevens I n autumn, forest floors are piled high with Functional feeding groups leaves. But in spring, the Earth’s load is light- What or who is responsible for all this aerobic ened; the leafy carpet has worn thin and decomposition? Leaf litter can be broken down seems to disappear with the melting snow. Where and decomposed slowly by abrasion and micro- have the leaves gone? Those that stay where they bial action, but streams also harbor invertebrates fall are decomposed, for the most part, by soil invertebrates and microbes. But many of the “disappearing leaves” are carried down hill slopes into small, heavily canopied forest What is important is streams. Most leaves and other organic materials not so much what, blown by the wind, washed from the surrounding landscape, or fallen directly from overhanging but how the animals eat. limbs into watercourses do not get very far. They are trapped by rocks, logs and branches close to where they entered the water. They become part of the food or energy base of the stream. that help decompose leaves and other organic Some of this material settles out in pools and materials under a variety of conditions. A rich, backwaters. Leaves that get buried will decom- diverse population of aquatic insects is keyed to pose anaerobically. Because anaerobic processes the varied quality of this food base. are much slower than aerobic ones, buried leaves Although most of us have seen our share of remain intact longer. These leaves can be recog- crayfish and snails, other aquatic invertebrates, a nized by their black color. Eventually the buried bit smaller and often a bit quicker, can easily leaves are re-exposed, and decomposition contin- elude us. The aquatic invertebrates we are inter- ues aerobically, much as if they had never been ested in here are inconspicuous aquatic insect buried. larvae and nymphs (immature forms). It is hard to distinguish one species from another at this Vocabulary aerobic gatherers This section is adapted from “Turning Over a anaerobic predators Wet Leaf,” by Rosanna Mattingly, and used collectors scrapers with permission from The Science Teacher, September 1985. filters shredders Oregon Department of Fish & Wildlife Food processing (cid:127) 309 immature stage, and the nymphs’ names are and fruits—by biting into them or by cutting or based, in general, on their adult characteristics. boring through them. These insects are called So, rather than identify these animals individu- shredders. Shredders generally reduce whole ally, we can group them according to the mode of leaves to masses of small particles, but they often feeding for which each animal is adapted. What leave the midrib and veins intact. Thus, they is important is not so much what, but how the “skeletonize” the leaves. Many shredders prefer animals eat, hence the distinct functional feeding leaves that have been partially decomposed by groups. microbes; with microbial decomposition, leaves become tender and digestible. Shredders In the Pacific Northwest, litter from many Some aquatic invertebrates feed on leaves or soft-leaved shrubs is quickly colonized by mi- other organic material—such as wood, needles crobes. This microbe conditioning makes leaves Figure 11. Food Processing in Streams Direction of energy flow or "eaten by" Contributes to FPOM SUN Food source Feeding group Coarse Particulate Fine Particulate S Organic Matter Organic Matter T (CPOM) (FPOM) N leaves, needles, cones, fecal pellets, plant A and twigs fragments Algae L (mostly green P algae and N Bacteria and Bacteria and diatoms) other microbes other microbes A I R A Shredders Collectors Scrapers P Examples: Examples: Examples: I Organic case caddis Net-spinning caddis Minneral case caddis R Craneflies Midge larvae Snails Dull color stoneflies Blackfly larvae Mayflies Most often found: Mayflies Most often found: Leaf packs Most often found: Rocks Water-logged wood On rocks and in mud Open-canopied areas Headwater streams Lower stream reaches Mid-stream reaches Predators Examples: Mottled stoneflies, beetle larvae, dragonfly larvae, free-living caddis, fish Most often found: Throughout stream Adapted from: Ken Cummins, “From Headwater Streams to Rivers,” American Biology Teacher, May 1977, p. 307. 310 (cid:127) The Stream Scene: Watersheds, Wildlife and People Oregon Department of Fish & Wildlife into palatable, nourishing invertebrate meals filterers and gatherers feed, at least for short before most other leaves are ready. Though they periods, on particles of little or no nutritional are somewhat slower to decompose than herba- value. Apparently, some appear to pay no atten- ceous leaves, alder leaves are also a favorite. tion to what they are eating. Other types of leaves must remain in a stream Filter feeders include blackfly larvae— longer before they become soft enough for the elongate animals that are bulbous near the bot- animals to eat, so shredders end up with a “time- tom end where they attach themselves to stream release” menu. substrates. Blackfly larvae have fans with which they strain particles from the water column. These fans are coated with a sticky substance that catches small particles that would otherwise pass through their fans. Collectors are often more Freshwater clams feed in a similar manner by passing food over mucous-covered gills that filter abundant than shredders in out small food particles. Some free-living low-gradient streams. caddisflies spin nets of various mesh sizes and thereby selectively collect particles of certain By chewing on leaves, shredders expose leaf In streams, organic materials surfaces and edges to further attack by microbes. Shredders also biochemically alter organic sub- are produced, received, strates as the material passes through their diges- tive tracts. So, shredders excrete material usually stored and decomposed. composed of particles that are smaller and of a different quality than what they ate. Many stonefly and caddisfly larvae are shredders. Caddisflies are especially intriguing sizes. Mayfly nymphs and beetle and fly larvae because many use the same leaf bits and other are particularly abundant gathering collectors. organic fragments they eat to construct the cases Collectors are often more abundant than in which they live. shredders in low-gradient streams where fine particles are not washed away so rapidly. These streams provide pools and other areas where Collectors particles can settle out of the water. Fairly large Collectors are animals that feed on particles of numbers of collectors live all year long, unlike organic material less than 1 millimeter in diame- shredders, which are abundant during the fall in ter. These particles may not be very wide, but most streams. they are a mouthful for most collectors. One major food source for collectors is fecal pellets Scrapers of other stream organisms. One group of collec- tors, called filterers, uses nets or mucus-coated Scrapers (sometimes called grazers) harvest fans to filter these small particles from the water. algae and other materials from rocks and stream Others, gatherers, eat particles deposited or surfaces. Diatoms and other algae associated growing on the bottom of a stream channel. with these surfaces (periphyton) are generally Collectors eat algae, fragments of plants and most abundant in spring before leaves develop on animals, dissolved organic matter that has come overhanging tree limbs and block the sun. together (flocculated) to form a particle, bacteria, Periphyton also flourish in wide streams where and inorganic particles such as sand, in addition the canopy does not stretch across the width. to the feces of shredders and other animals. Some Algae will thrive again in autumn, in part Oregon Department of Fish & Wildlife Food processing (cid:127) 311 because more light and nutrients reach a stream Diversity and adaptability after leaves fall. Predictably, the abundance of In streams, organic materials are produced, scrapers follows the same pattern. received, stored and decomposed. A large flood Scrapers include certain mayfly larvae, some one year can introduce material from a flood- of which are flat. Their flatness lets them stay plain. A fairly mild discharge another year can close to rock surfaces to avoid being swept away promote storage. Even nearby streams sometimes by swift currents. Some scrapers have suction differ remarkably in gradient and riparian vegeta- disks on their abdomens. With these disks the tion. The kinds and amounts of invertebrates vary insects can attach to surfaces and feed in rapidly along with each stream’s characteristics. But the flowing water where diatoms and other algae grow. Some scraper caddisflies construct their cases with small stones that afford the animals additional protection from the current. The similarity between Snails also harvest algae. They use feeding structures called radulae to rasp food from stone the types of invertebrates surfaces and to rasp at leaf surfaces. the world over is striking. Predators Those invertebrates and other aquatic organisms, similarity between the types of invertebrates the such as fish, that capture live members of other world over is striking. functional groups can be classified as predators. Dividing stream invertebrates into shredders, Predators may be among the first animals spotted collectors, scrapers and predators is artificial, in a sample collected from a stream because because some of these immature forms fit into many of these animals, particularly predacious more than one category. For example, scrapers stoneflies, are comparatively active and con- may eat a lot of detritus while they graze algae. spicuously patterned or colored. However, they may not grow as well or may Crane fly larvae and odonates (dragonflies pupate at a smaller size in areas where relatively and damselflies) differ from stoneflies as preda- less algae is available. Collectors may eat algae, tors because they are more non-descript and bacteria, animals and sand. Some collectors also relatively inactive. Odonates often sit still and shred leaves, and some shredders can survive on hidden (some bury themselves in sediment with fine particles when leaves are not available. But only their eyes protruding) with their hinged, these distinctions are valuable. By looking at the retractile mouthparts aimed at unsuspecting prey. feeding habits of these young invertebrates, you Predators can be subdivided into piercers, can begin to sort out different roles these animals which suck the body fluids of their prey, or play in the ecology of watersheds. engulfers, which ingest their prey whole. 312 (cid:127) The Stream Scene: Watersheds, Wildlife and People Oregon Department of Fish & Wildlife River continuum ties in a stream that change in a somewhat pre- dictable pattern from headwaters to the mouth. This pattern is influenced by: Each year, large amounts of organic material fall (cid:127) structure and gradient of the channel, into the headwaters of forested streams. Of this material, only 20% to 35% is flushed down- (cid:127) bank stability, stream. The remaining organic input is retained (cid:127) sediment loads, in the system and used by stream organisms. It (cid:127) riparian habitats and cover, can be processed by bacterial and fungal meta- bolic action, physical abrasion or consumed by (cid:127) light penetration, and insects. However it is processed, the debris is (cid:127) temperature. broken into smaller pieces, which increases the Predictions work particularly well for for- surface area of debris particles and subjects them ested mountain streams. As might be expected, to further degradation by microbial action. with a model of this type, there are several ex- In this way, small first- and second-order ceptions to the pattern outlined in Figure 12 streams send partially prepared food into larger (p. 315). But the concept shows what might be streams. Processing continues as small debris expected in a stream system. If a factor does moves downstream through the system. A stream show up differently, it should act as a red flag, is a continuum that transports progressively encouraging any researcher to question why it smaller food materials. does not match the concept. The river continuum concept models running water systems. It describes biological communi- Adapted from Ken Cummins, The Ecology of Running Waters: Theory and Practice, pp. 287- 290; and Jerry F. Franklin et al., Ecological Characteristics of Old-Growth Douglas-fir Forests, 1981, pp. 8-11. Oregon Department of Fish & Wildlife Food processing (cid:127) 313 Figure 12. The River Continuum A diagram of the river continuum theory is those of headwaters or larger rivers. The shown at right. The forests at the headwaters variety of organic substrates and physical (first- to third-order streams, see page 35) components found in midreach streams can have less influence as a stream gets larger. also have an effect. With less input from the riparian habitat, the Turbidity increases in the lower reaches energy base relies more on algae that is (sixth- and higher-order streams) due to the produced from the opening of the canopy and greater loads of fine sediments from tributar- on processed materials brought in from ies and downstream movement of processed intermediate or midreach (third- to fifth- particulate matter. Collectors dominate these order) streams. As the kind of organic mate- reaches, and the diversity of other organisms rial changes, there is a decrease in the decreases. Increased turbidity reduces light number of shredders and an increased num- penetration and thereby reduces the effi- ber of collectors and scrapers (grazers). ciency and photosynthetic production of The diversity of species that live in the algae in larger streams. Large plankton midreaches of a stream system is greater than communities are important in these areas. In either upstream or downstream. The reason summary, as the size of a stream changes, for this is not completely understood, but there is a shift in dominant organisms and the researchers have pointed out that midreach role they play. water temperatures can change more than 314 (cid:127) The Stream Scene: Watersheds, Wildlife and People Oregon Department of Fish & Wildlife Figure 12. The River Continuum Source: Ken Cummins, “From Headwater Streams to Rivers,” The American Biology Teacher, May 1977, p. 306. Oregon Department of Fish & Wildlife Food processing (cid:127) 315 Figure 13. Headwaters The headwaters—or source— story vegetation is limited by organic matter (CPOM) of a watershed are usually first- heavy shading. An abundance of falling into the stream. These to third-order streams. These shredder invertebrate organisms streams are narrow, generally small streams constitute nearly are found because of large only 1½ feet to 20 feet in width. 85% of the total length of run- amounts of coarse particulate ning water in our country. Forested headwater streams receive significant organic debris from surrounding ripar- ian habitat that heavily shades streams. As a result, small streams are generally het- erotrophic, deriving most of their energy base from coarse organic input, rather than from aquatic plants. These streams are characterized by high gradi- ents, low light and a fairly constant temperature. Under- Figure 14. Midreaches Midreaches are composed of There is also a shift from debris and more fine matter third- to fifth-order streams. coarse debris to fine particu- means a change from shredders This size usually distinguishes late organic matter (FPOM) to collectors in the invertebrate streams from rivers. These as the network of incoming population of the stream. streams are wider than headwa- headwater streams concentrates Greater biological diversity is ter streams, often more than 30 nutrients and partially processed found in these reaches than in feet. As a result, the riparian particulate matter from up- either upstream or downstream canopy does not cover the stream reaches. Less coarse areas. stream. Floodplain widths also increase. Because the canopy is more open, more deciduous riparian vegetation is present and more sunlight reaches the water’s surface. This allows an increase in primary photosynthetic pro- duction by algae and rooted plants. A shift from consumers to producers as the primary energy base of the stream oc- curs. 316 (cid:127) The Stream Scene: Watersheds, Wildlife and People Oregon Department of Fish & Wildlife
Description: