Influence of the Chad-Cameroon pipeline on termite assemblages

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Research Paper 01/06/2014
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Influence of the Chad-Cameroon pipeline on termite assemblages

Pierre Dieudonné n, Guy Josens
J. Bio. Env. Sci.4( 6), 153-166, June 2014.
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Abstract

The study of Chad-Cameroon pipeline disturbances on termite assemblages was conducted in 9 sites in the savannah and forest ecosystems, five years following the completion of the works. In each site an experimental design was made up of four transect belts, 100 m long by 2 m wide, two in the disturbed zone and two in the undisturbed zone . Soil samples were taken in the fifth, ninth and fifteenth sections of each of the transect belt to measure the impact of the work on soil texture and chemical properties. Furthermore, termites were inventoried in the whole transect belt. The pipeline construction disrupted significantly the soil textural parameters, bulk density, water properties and soil organic matter. In all 36 transects, 99 termite species were collected. The overall species richness decreased in the disturbed zone but the overall density was not changed. However, the abundance of wood feeding termites significantly increased whereas the species richness and abundance of soil feeding termites decreased. The relatively small difference in termite assemblages between disturbed and undisturbed areas is greatly explained by the fact that ecosystems crossed by the pipeline were already noticeably degraded before the pipeline installation.

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Bengtsson J. 2002. Disturbance and resilience in soil animal communities. European Journal of Soil Biology 38 (2), 119 – 125.

Bengtsson G and Rundgren S. 1988. The Gusum case: a brass mill and the distribution of soil Collembola. Canadian Journal of Zoology 66, 1518-1526.

Birang M. 2004. Soil Macrofauna community structure along a gradient of land use intensification in the humid forest zone of Southern Cameroon. Tropical Resource Management Papers 197.

Colwell, RK. 2005. EstimateS: statistical estimation of species richness and shared species from samples. Version 7.5. Persistent URL <purl.oclc.org/estimates>.

Dames and Moore. 1999. Chad export project supplemental collection program Fishery survey of pipeline route Cameroon portion. 44.

Davies RG and Maryati, M. 1999. Termite assemblages, forest disturbance and greenhouse gas fluxes in Sabah, East Malaysia. Philosophical Transactions of the Royal Society B 354, 1791 – 1802.

Deblauwe I, Dibog L, Missoup, AD, Dupain J, Van Elsacker L, Dekoninck W, Bonte, D and Hendrickx F. 2007. Spatial scales affecting termite diversity in tropical lowland rainforest: a case study in southeast Cameroon. African Journal Ecology 46, 5–18.

DeSouza O. and Brown VK. 1994. Effect of habitat fragmentation on Amazonian termite communities. Journal of Tropical Ecology 10, 197–206.

Dibog L, Eggleton P, Norgrove L, Bignell, DE and Hauser S. 1999. Impacts of canopy cover on soil termite assemblages in an agrisilvicultural system in Southern Cameroon. Bulletin of entomological Research 89, 125-132.

Donovan SE, Eggleton P and Bignell DE. 2001. Gut content analysis and a new feeding group classification of termites (Isoptera). Ecological Entomology 26, 356–366.

Doucet R. 1994. La Science Agricole. Climat, sols et productions végétales du Québec Eds Berger 569.

Eggleton P, Bignell DE, Sands WA, Mawdsley NA, Lawton JH, Wood, TG and Bignell, NC. 1996. The diversity, abundance and biomass of termites under different levels of disturbance in the Mbalmayo Forest Reserve, southern Cameroon. Philosophical Transactions of the Royal Society B 351, 51–68.

Eggleton P, Homathevi R, Jeeva D, Jones DT, Davies RG and Maryati M.1997. The species richness and composition of termite (Isoptera) in primary and regenerating lowland Dipterocarp Forest in Sabah East Malaysia. Ecotropica 3, 119-128.

Eggleton P, Bignell DE, Hauser S, Dibog L, Norgrove L and Birang M. 2002. Termite diversity across an anthropogenic disturbance gradient in the humid forest zone of West Africa. Agriculture, Ecosystems and Environment 90, 189-202.

Franzluebbers AJ. 2002. Water infiltration and soil structure related to organic matter and its stratification with depth. Soil and Tillage Research 66, 197–205.

Jones TD and Eggleton P. 2000. Sampling termite assemblages in tropical forest: testing a rapid biodiversity assessment protocol. J. appl. Ecol. 37, 191-203.

Jones TD, Susilo F X, Bignell DE, Hardiwinoto S, Gillison AN and Eggleton P. 2003. Termite assemblage collapses along a land-use intensification gradient in lowland Central Sumatra, Indonesia. Journal of apply Ecology 40, 380391.

Lavelle P and Pashanasi B. 1989. Soil fauna and land management in Peruvian Amazonia (Yurimaguas, Loreto). Pedobiologia. 33, 283-291.

Lavelle P, Bignell DE, Lepage M, Wolters V, Roger P, Ineson P., Heal OW and Dhillion S. 1997. Soil function in a changing world: the role of invertebrate ecosystem engineers. European Journal of Soil Biology 33(4), 159–193.

Lepage M, Abbadie L, Josens G and Lavelle P. 2006a. Role of Soil Fauna in Nitrogen Cycling. Lamto Structure Functionning and Dynamics of a savannah Ecosystem (Abbadie, L., Gignoux, J., Le Roux, X. and Lepage, M. Eds) pp. 299-312.

Lepage M, Abbadie L, Josens G, Souleymane K and Lavelle P. 2006b. Perturbations of Soil Carbon Dynamics by Soil Fauna. Lamto Structure Functionning and Dynamics of a savannah Ecosystem (Abbadie, L., Gignoux, J., Le Roux, X. and Lepage, M. Eds): 235-250.

Letouzey R. 1985. Notice de la carte phytogéographique du Cameroun 1 :500000. 102.

Paine RT, Tegner, MJ and Johnson, EA. 1998. Compounded perturbations yield ecological surprises. Ecosystems 1, 535–545.

Pfeiffer A. 2010. Effects of soil disturbance on aggregation and mineral-associated carbon and nitrogen storage. Senior Integrative Exercise. 41.

Pickett STA, Kolosa J, Armeso JJ and Collins, SL. 1989. The ecological concept of disturbance and its expression at various hierarchical levels. Oikos 54,129 – 136.

Romme W, Everham E, Frelich L, Moritz M and Sparks R. 1998. Are large, infrequent disturbances qualitatively different from small, frequent disturbances? Ecosystems. 1, 524–534.