Summary
The digestive tract of the common woodlouse, Tracheoniscus rathkei Brandt (Isopoda: Oniscoidea), contains digestive enzymes active against α-1,4-glucans, which are the chief storage polysaccharides of vascular plants, algae, fungi, and animals, and β-1,3-glucans, which are present in algae and fungi. Digestive tract extracts also exhibit significant activity toward xylan and carboxymethyl-cellulose but negligible activity toward microcrystalline cellulose, substrates representative of the major structural polysaccharides of vascular plants. Low activity was detected toward pectin, and no activity was detected toward chitin. Activity toward xylan is due in part to microbial enzymes acquired from the leaf litter which was the isopod's normal food. Although ingested microbial xylanases are stable and active in the gut fluid, they do not make a quantitatively significant contribution to the isopod's ability to assimilate the hemicellulosic component of its diet. However, the assimilation of carbon from labeled plant fiber is enhanced in isopods which have acquired a cellulase by ingestion of leaf litter amended with a commercial preparation of the cellulase complex from the fungus, Penicillium funiculosum. This result demonstrates the potential contribution of acquired enzymes to the digestion of plant fiber in terrestrial detritivores. We urge caution, however, in assigning an important digestive function to ingested enzymes on the basis of evidence that only indicates that such enzymes are present in the gut fluid without additional evidence that their presence results in an enhancement of digestive efficiency.
This is a preview of subscription content, log in via an institution to check access.
Similar content being viewed by others
References
Abo-Khatwa N (1978) Cellulase of fungus growing termites: a new hypothesis on its origin. Experientia 34:559–560
Anderson NH, Sedell JR (1979) Detritus processing by macroinvertebrates in stream ecosystems. Annu Rev Entomol 24:351–377
Baker JH, Bradnam LA (1976) The role of bacteria in the nutrition of aquatic detritivores. Oecologia (Berlin) 24:95–104
Bärlocher F (1982) The contribution of fungal enzymes to the digestion of leaves by Gammarus fossarum Koch (Amphipoda). Oecologia (Berlin) 52:1–4
Bernfeld P (1955) Amylases, α and β. In: colowick SP, Kaplan NO (eds) Methods in Enzymology, vol 1. Academic Press, New York, pp 149–150
Berrie AD (1976) Detritus, microorganisms and animals in fresh water. In: Anderson JM, Macfadyen A (eds) The Role of Terrestrial and Aquatic Organisms in Decomposition Processes. Blackwells, Oxford, pp 328–338
Burns RG (ed) (1978) Soil Enzymes. Academic Press, London
Calow P, Fletcher CR (1972) A new radiotracer technique involving 14C and 51Cr for estimating the assimilation efficiencies of aquatic, primary consumers. Oecologia (Berlin) 9:155–170
Cummins KW, Klug MJ (1979) Feeding ecology of stream invertebrates. Annu Rev Ecol Syst 10:147–172
Edney EB, Allen W, McFarlane J (1974) Predation by terrestrial isopods. Ecology 55:428–433
Espinoza-Fuentes FP, Ferreira C, Terra W (1984) Spatial organization of digestion in the larval and imaginal stages of the sciarid fly Trichosia pubescens. Insect Biochem 14:631–638
Findlay S, Meyer JL, Smith PJ (1984) Significance of bacterial biomass in the nutrition of a fresh-water isopod (Lirceus sp.). Oecologia (Berlin) 63:38–42
Hartenstein R (1964) Feeding, digestion, glycogen, and the environmental conditions of the digestive system in Oniscus asellus. J Ins Physiol 10:611–621
Hassall M, Jennings JB (1975) Adaptive features of gut structure and digestive physiology in the terrestrial isopod Philoscia muscorum (Scopoli) 1763. Biol Bull 149:348–364
Herscowitz B, McKillip TW (1974) A simple method for liquid scintillation counting of 125Iodine and 51Chromium used in antigen binding and cytotoxicity studies. J Immunol Meth 4:253–262
Kelley WA, Adams RP (1977) Preparation of extracts from juniper leaves for electrophoresis. Phytochemistry 16:513–516
Kukor JJ, Martin MM (1983) Acquisition of digestive enzymes by siricid woodwasps from their fungal symbiont. Science 220:1161–1163
Kukor JJ, Martin MM (1986) Cellulose digestion in Monochamus marmorator Kby. (Coleoptera: Cerambycidae): the role of acquired fungal enzymes. J Chem Ecol (in press)
Linkins AE, Atlas RL, Gustin P (1978) Effects of surface applied crude oil on soil and vascular plant root respiration, soil cellulase, and aryl hydrocarbon hydroxlase at Barrow, Alaska. Arctic 31:355–365
Ljungdahl LG, Erikkson K-E (1985) Ecology of microbial cellulose degradation. Adv Microbial Ecol 8:237–299
Martin MM, Kukor JJ (1984) Role of mycophagy and bacteriophagy in invertebrate nutrition. In: Klug MJ, Reddy CA (eds) Current Perspectives in Microbial Ecology. American Society for Microbiology, Washington, D.C., pp 257–263
Martin MM, Martin JS (1978) Cellulose digestion in the midgut of the fungus-growing termite Macrotermes natalensis: the role of acquired digestive enzymes. Science 199:1453–1455
Martin MM, Martin JS (1979) The distribution and origins of the cellulolytic enzymes of the higher termite Macrotermes natalensis. Physiol Zool 52:1–11
Martin MM, Martin JS, Kukor JJ, Merritt RW (1980) The digestion of protein and carbohydrate by the stream detritivore, Tipula abdominalis (Diptera: Tipulidae). Oecologia (Berlin) 46:360–364
Martin MM, Kukor JJ, Martin JS, O'Toole TE, Johnson MW (1981) Digestive enzymes of fungus-feeding beetles. Physiol Zool 54:137–145
Nielsen CO (1962) Carbohydrases in soil and litter invertebrates. Oikos 13:200–215
Nielsen CO (1963) Laminarinases in soil and litter invertebrates. Nature 199:1001
Paris OH (1963) The ecology of Armadillidium vulgare (Isopoda: Oniscoidea) in California grassland: food, enemies, and weather. Ecol Monogr 33:1–22
Piccioni R, Bellemare G, Chua N-H (1982) Methods of polyacrylamide gel electrophoresis in the analysis and preparation of plant polypeptides. In: Edelman M, Hallick RB, Chua N-H (eds) Methods in Chloroplast Molecular Biology. Elsevier, Amsterdam, pp 985–1014
Reyes VG, Tiedje JM (1976a) Ecology of the gut microbiota of Tracheoniscus rathkei (Crustacea, Isopoda). Pedobiologia 16:67–74
Reyes VG, Tiedje JM (1976b) Metabolism of 14C-labeled plant materials by woodlice (Tracheoniscus rathkei Brandt) and soil microorganisms. Soil Biol Biochem 8:103–108
Shachak M, Chapman EA, Steinberger Y (1976) Feeding, energy flow and soil turnover in the desert isopod, Hemilepistus reaumuri. Oecologia (Berlin) 24:57–69
Sinsabaugh RL, Benfield EF, Linkins AE (1981) Cellulase activity associated with the decomposition of leaf litter in a woodland stream. Oikos 36:184–190
Sinsabaugh RL, Linkins AE, Benfield EF (1985) Cellulose digestion and assimilation by three leaf shredding aquatic insects. Ecology 66:1464–1471
Swift MJ, Heal OW, Anderson JM (1979) Decomposition in Terrestrial Ecosystems. University of California Press, Berkeley
Taylor EC (1982) Role of aerobic microbial populations in cellulose digestion by desert millipedes. Appl Environ Microbiol 44:281–291
White JJ (1968) Bioenergetics of the woodlouse Tracheoniscus rathkei Brandt in relation to litter decomposition in a deciduous forest. Ecology 49:694–704
Author information
Authors and Affiliations
Rights and permissions
About this article
Cite this article
Kukor, J.J., Martin, M.M. The effect of acquired microbial enzymes on assimilation efficiency in the common woodlouse, Tracheoniscus rathkei . Oecologia 69, 360–366 (1986). https://doi.org/10.1007/BF00377057
Received:
Issue Date:
DOI: https://doi.org/10.1007/BF00377057