Chemical properties associated with guts, soil and nest materials of Odontotermes and Macrotermes species from Kenya

Paper Details

Research Paper 01/02/2014
Views (261) Download (7)
current_issue_feature_image
publication_file

Chemical properties associated with guts, soil and nest materials of Odontotermes and Macrotermes species from Kenya

Edith Mnyazi Muwawa, Huxley Mae Makonde, Nancy L.M.Budambula, Zipporah Lagat Osiemo, Hamadi Iddi Boga
J. Bio. Env. Sci.4( 2), 253-263, February 2014.
Certificate: JBES 2014 [Generate Certificate]

Abstract

Termites play important roles in carbon and nitrogen cycles thus affecting soil functioning and ecosystem activities. The study focused on analyzing levels of nitrogen, carbon and pH in the guts, soil and mound materials associated with Odontotermes and Macrotermes termites’ species. Macro- and micro-elements were also evaluated using spectrophotometer methods. The standard soil analyses and concentrations of various forms of nitrogen and carbon were performed using calometric and Bremmer’s methods. Results showed higher clay content in the mounds than the surrounding soil. Most concentrations of ammonia, nitrate and total organic carbon between the termites and within the gut sections were significantly different (p < 0.05). Levels of ammonia (3.00 – 6.00 ppm) and nitrate (6.00 – 11.50 ppm) were highest in the hindguts of all termites analyzed than the respective foreguts and midguts sections. Ammonia (6.00 – 14.50 ppm), nitrate (16.00 – 83.00 ppm) and organic carbon (31.00 – 37.00 %) levels were highest in the fungus comb samples. The levels of all macro-and micro-elements investigated were highest in the fungus combs. It can be concluded that fungus-growing termites accumulate different levels of nitrogenous compounds in their guts and modify soil properties in terms of clay, C, N and mineral contents.

VIEWS 7

Aanen  DK,  Eggleton  P,  Rouland-Lefevre  C, Guldberg-Froslev T, Rosendahl S, Boomsma JJ. 2002. The evolution of fungus growing termites and their mutualistic fungal symbionts. Proceedings of the National Academy of Sciences 99, 14887–14892.

Ackerman IL, Wenceslau GT, Susan JR, Johannes L, Erick CM. 2007. The impact of mound-building termites on surface soil properties in a secondary forest of Central Amazonia. Applied Soil Ecolology 37, 267-276.

Ahmed BM, Nkunika POY, Sileshi WG, French JRJ, Nyeko P, Jain S. 2011. Potential Impact of Climate Change on Termite Distribution in Africa. British Journal of Environment and Climate Change 1, 172-189.

Bignell DE, Eggleton P. 1995. On the elevated intestinal pH of higher termites (Isoptera: Termitidae). Insect Sociaux 42, 57–69.

Black HIJ, Okwakol MJN. 1997. Agricultural intensification, soil biodiversity and agroecosystem function in the tropics: the role of termites. Applied Soil Ecology 6, 37–53.

Brauman A. 2000. Effect of gut transit and mound deposit on soil organic matter transformations in the soil feeding termite: Annual review. European Journal of Soil Biology 36, 117–125.

Chaney AL, Marbach EP. 1962. Modified reagents for the determination of urea and ammonia. Clinical Chemistry 8, 130-132.

DeSouza O, Araújo APA, Reis-Jr R. 2009. Trophic controls delaying foraging by termites: reasons for the ground being brown? Bulleting in Entomological Response 99, 603-609.

Eggleton P, Tayasu I. 2001. Feeding groups, life types and the global ecology of termites. Ecolological Response 16, 941-960.

Eggleton P. 2000. Global patterns of termite diversity. In Abe T, Bignell DE Higashi M, ed. Termites: evolution, sociality, symbioses, ecology volume one. Dordrecht, The Netherlands: Kluwer Academic publisher. 25–51.

Fall S, Hamelin J, Ndiaye F, Assigbetse K, Aragno M, Chotte JL, Brauman A. 2007. Differences between bacterial communities in the Gut of a Soil-Feeding Termite (Cubitermes niokoloensis) and Its Mounds. Applied Environmental Microbiology 73, 5199-5208.

Fall S, Nazaret S, Chotte JL, Brauman A. 2004. Bacterial density and community structure associated with aggregate size fractions of soil-feeding termite mounds. Microbial Ecolology 28, 191–199.

Freymann BP, Buitenwerf R, DeSouza O, Olff H. 2008. The importance of termites (Isoptera) for the recycling of herbivore dung in tropical ecosystems: a review. European Journal of Entomology 105, 165-173.

Garnier-Sillam E, Toutain F, Renoux J. 1988. Comparaison de I’influence de deux termitie`res (humivore et champignonniste) surla stabilite´ structurale des sols forestiers tropicaux. Pedobiology 32, 89–97.

Harry M, Jusseaume N, Gambier B, Garnier-Sillam E. 2001. Use of RAPD markers for the study of microbial community similarity from termite mounds and tropical soils. Soil Biolology and Biochemistry 33, 417–427.

Holt JA, Lepage M. 2000. Termites and soil properties. In: Abe T, Bignell DE, Higashi M, eds. Termites: Evolution, Sociality, Symbioses, Ecology volume one. Dordrecht, The Netherlands: Kluwer Academic Publishers. 25-51.

Ji R, Brune A. 2006. Nitrogen mineralization, ammonia accumulation and emmision of gaseous NH3 by soil feeding termites. Biogeochemistry 78, 267-283.

Jones CG, Lawton JH, Shachak M. 1997. Positive and negative effects of organisms as physical ecosystem engineers. Ecology 78, 1946–1957.

Jouquet P, Lepage M, Velde B. 2002a. Termite soil preferences and particle selections: strategies related to ecological requirements. Insect Sociaux 49, 1–7.

Jouquet  P,  Mamou  L,  Lepage  M,  Velde  B. 2002b. Effect of termites on clay minerals in tropical soils: fungus-growing termites as weathering agents. European Journal of Soil Science 53, 521–527.

Jouquet  P, Mery T,  Rouland  C,  Lepage M. 2003. Modulated effect of the termite Ancistrotermes cavithorax (Isoptera, Macrotermitinae) on soil properties according to the structures built. Sociobiology 42, 403–412.

Jouquet P, Tessier D, Lepage M. 2004. The soil structural stability of termite nests: role of clays in Macrotermes bellicosus (Isoptera, Macrotermitinae) mound soils. European Journal of Soil Biolology 40, 23– 29.

Katoh H, Miura T, Maekawa K, Shinzato N, Matsumoto T. 2002. Genetic variation of symbiotic fungi cultivated by the macrotermitinae termite Odontotermes formosanus (Isoptera: Termitidae) in the Ryukyu Archipelago. Molecular Ecology 11, 1565– 1572.

Lavelle P, Bignell D, Lepage M, Wolters V, Roger P, Ineson P, Heal OW, Dhillion S. 1997. Soil function in a changing world: the role of invertebrate ecosystem engineers. European Journal of Soil Biology 33, 159–193.

Lavelle P, Dangefield C, Fragoso C, Eschenbrenner D, Lopez HD, Pashanasi B, Brussard L. 1994. The relationship between soil macro fauna and tropical soil fertility. In: Woomer PL, Swift MJ, ed. The biological management of tropical soil fertility. UK: John Wiley and sons. 137-169.

Lavelle PT, Decaëns M, Aubert S, Barot M, Blouin F, Bureau P, Margerie P, Mora, J-P Rossi. 2006. Soil invertebrates and ecosystem services. European Journal of Soil Biology 42, (Suppl. 1) S3eS15 ICSZ-Soil Animals and Ecosystems Services, Proceedings of the XIVth International Colloquium on Soil Biology.

Lopez-Hernandez D. 2001. Nutrient dynamics (C, N, P) in termite mounds of Nasutitermes ephratae from savannas of the Orinoco Lia nos (Venezuela). Siol Biollogy and Biochemistry 33, 747-753.

Makonde HM, Boga HI, Osiemo Z, Mwirichia R, Stielow JB, Göker M, Klenk H-P. 2013. Diversity of Termitomyces Associated with Fungus-Farming Termites Assessed by Cultural and Culture-Independent Methods. PLoS ONE 8(2), e56464. doi:10.1371/journal.pone.0056464.

Manuwa SI. 2009. Physico-chemical and dynamic properties of termite mound soil Relevant in sustainable food production. African Crop Science Society 9, 356-369.

Mora P, Seugé C, Chotte JL, Rouland C. 2003. Physico-chemical typology of the biogenic structures of termites and earthworms: a comparative analysis. Biology of Fertile Soil 37, 245–249.

Moriya S, Inoue T, Ohkuma M, Yaovapa T, Johjima T, Suwanarit P, Sangwani U, Vongkaluang C, Noparatnaraporn N, Kudo T. 2005. Fungal Community Analysis of Fungus gardens in termite nests. Microbes Environment 20, 243-252.

Noirot C. 1992. From wood- to humus-feeding: an important trend in termite evolution. In: Billen J, ed. Biology and Evolution of Social Insects. Leuven, Belgium: Leuven University Press. 107–119.

Okalebo JR, Githua WG, Wooma P. 2002. Laboratoty methods of soil and plant analysis: A working manual. 2nd edition. TSBF- CIAT and sacred Africa.

Roose-Amsaleg C, Brygoo Y, Harry M. 2004. Ascomycete diversity in soil-feeding termite nests and soils from a tropical rainforest. Environmental Microbiology 6, 462–469.

Tanaka U. 1986. Procedures for Soil Analysis. Technical cooperation project of JKUAT, Kenya. 19-57.

Walkley A, Black IA. 1934. An examination of the Degtjareff method for determining soil organic matter and proposed modification of the chromic acid titration method. Soil Science 37, 29–38.