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Nodulation status of native woody legumes and phenotypic characteristics of associated rhizobia in soils of southern Ethiopia

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Abstract

The nodulation of provenances of Acacia seyal, Acacia tortilis and Faidherbia albida, and other indigenous multipurpose tree species were tested in 14 different soil samples collected from diverse agro-ecological zones in southern Ethiopia. Associated rhizobia were isolated from these and from excavated nodules of field standing mature trees, and phenotypically characterized. Indigenous rhizobia capable of eliciting nodules on at least one or more of the woody legume species tested were present in most of the soils. Tree species were markedly different in nodulation in the different site soils. Sesbania sesban and Acacia abyssinica showed higher nodulation ability across the different sites indicating widespread occurrence of compatible rhizobia in the soils. The nodulation patterns of the different provenances of Acacia spp. suggested the existence of intraspecific provenance variations in rhizobial affinity which can be exploited to improve N fixation through tree selection. Altogether, 241 isolates were recovered from the root nodules of trap host species and from excavated nodules. Isolates were differentiated by growth rate and colony morphology and there were very fast-, fast-, slow-, and very slow-growing rhizobia. The bulk of them (68.5%) were fast-growing acid-producing rhizobia while 25.3% were slow-growing alkali-producing types. Fast-growing alkali-producing (2.9%) and slow-growing acid-producing strains (3.3%) were isolated from trap host species and excavated nodules, respectively. All isolates fell into four colony types: watery translucent, white translucent, dull glistering and milky (curdled) type. The diversity of indigenous rhizobia in growth rate and colony morphology suggested that the collection probably includes several rhizobial genera.

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Acknowledgements

The authors gratefully acknowledge the financial support of the International Foundation for Science (IFS) for the seed collection, and the Norwegian Universities Committee for Development Research and Education (NUFU) for the research, the Lånekassen, Norway for the stipend for the PhD study of E. Wolde-meskel at the Agricultural University of Norway; and the Research and Extension Office and various departments at Awassa College of Agriculture, Ethiopia, for providing facilities for the research.

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Authors and Affiliations

  1. Department of Chemistry, Biotechnology and Food Science, Agricultural University of Norway, P.O. Box 5040, 1432, Askim, Norway

    Endalkachew Wolde-meskel & Åsa Frostegård

  2. Department of Plant Production and Dryland Farming, Awassa College of Agriculture, Debub University, P.O. Box 5, Awassa, Ethiopia

    Endalkachew Wolde-meskel

  3. Centre for International Environment and Development Studies (NORAGRIC), Agricultural University of Norway, P.O. Box 5001, 1432, Askim, Norway

    Trygve Berg

  4. National Institute of Health, National Institute of General Medical Sciences, 45 Centre Drive MSC 6200, Bethesda, MD 20892-6200, USA

    N. Kent Peters

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  1. Endalkachew Wolde-meskel
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  2. Trygve Berg
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  3. N. Kent Peters
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  4. Åsa Frostegård
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Correspondence to Endalkachew Wolde-meskel.

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Wolde-meskel, E., Berg, T., Kent Peters, N. et al. Nodulation status of native woody legumes and phenotypic characteristics of associated rhizobia in soils of southern Ethiopia. Biol Fertil Soils 40, 55–66 (2004). https://doi.org/10.1007/s00374-004-0743-5

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  • DOI: https://doi.org/10.1007/s00374-004-0743-5

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