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RESEARCH ARTICLE

Root and root hair mechanisms that confer symbiotic competence for nodulation in acidic soils within Medicago species: a holistic model

Y. Cheng A , E. L. J. Waktin B , J. G. Howieson A C and G. W. O’Hara A
+ Author Affiliations
- Author Affiliations

A Centre for Rhizobium Studies, Murdoch University, Murdoch, WA 6150, Australia.

B School of Biomedical Sciences, Curtin University of Technology, GPO Box U1987, Perth, WA 6845, Australia.

C Author for correspondence. Email: jhowieso@murdoch.edu.au

Australian Journal of Experimental Agriculture 45(3) 231-240 https://doi.org/10.1071/EA03150
Submitted: 29 July 2003  Accepted: 1 June 2004   Published: 14 April 2005

Abstract

Three experiments were undertaken to investigate the mechanisms used by the annual medic species, Medicago murex (Murex medic) to achieve nodulation more rapidly in acidic soils than the perennial species Medicago sativa (lucerne). In experiment 1, numbers and locations of root hairs on the primary roots of medic and lucerne were determined from plants grown in soil of pH 4.3 and 7.0. Experiment 2 enumerated the numbers of Sinorhizobium medicae (rhizobia) associated with the roots of medic and lucerne when grown in an acidic soil. Experiment 3 used a GFP-marked strain of rhizobia to determine the localised distribution of rhizobia along various zones of the primary roots of medic and lucerne in soil of pH 4.3 and 7.0. When grown in an acidic soil, medic produced 60% more root hairs/mm root along the primary root axis compared with lucerne, from 7 days after sowing. In soil of low pH, medic also had higher numbers of rhizobia associated with its entire root system than lucerne, with about 103 cfu/cm root throughout the 24-day period of the experiment, compared with lucerne for which rhizobial numbers decreased from 102 to 11 cfu/cm root over the same time period. When the intensity of fluorescence emitted by a GFP-marked transconjugant of rhizobia was measured at localised zones along the primary root of medic and lucerne grown in the acidic soil, it was 1.8-fold higher from the roots of medic than lucerne at 7 days after sowing, indicating higher numbers of rhizobia along medic roots. Hence, the numbers of rhizobia associated with the entire root system, and those colonised on localised zones of the primary root of medic were both higher than that of lucerne. These fundamental differences between the 2 species, combined with the earlier finding that lucerne tends to acidify its rhizosphere more than medic, allowed us to construct conceptual models that attempt to explain the increased symbiotic competency of medic compared with lucerne, and the different nodulation responses between medic and lucerne at low pH.


Acknowledgements

We thank R. Carr for help with soil preparation; Dr R. Tiwari for advice in constructing the green fluorescent protein-marked transconjugant of Sinorhizobium medicae; and G. Thomson (School of Biology and Biotechnology, Murdoch University) and J. Murphy (Centre for Microscopy and Microanalysis, University of Western Australia) for their assistance with microscopy. This research was funded by the Australian Research Council and forms part of a PhD thesis by Y. Cheng.


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