Plant and Soil

, Volume 184, Issue 1, pp 123–130 | Cite as

Soil moisture and potassium affect the performance of symbiotic nitrogen fixation in faba bean and common bean

  • U. Ravi Sangakkara
  • Ueli A. Hartwig
  • Josef Nösberger


Potassium (K) is reported to improve plant's resistance against environmental stress. A frequently experienced stress for plants in the tropics is water shortage. It is not known if sufficient K supply would help plants to partially overcome the effects of water stress, especially that of symbiotic nitrogen fixation which is often rather low in the tropics when compared to that of temperate regions. Thus, the impact of three levels of fertilizer potassium (0.1, 0.8 and 3.0 mM K) on symbiotic nitrogen fixation was evaluated with two legumes under high (field capacity to 25% depletion) and low (less than 50% of field capacity) water regimes. Plants were grown in single pots in silica sand under controlled conditions with 1.5 mM N (15N enriched NH4NO3). The species were faba bean (Vicia faba L.), a temperate, amide producing legume and common bean (Phaseolus vulgaris L.), a tropical, ureide producing species. In both species, 0.1 mM K was insufficient for nodulation at both moisture regimes, although plant growth was observed. The supply of 0.8 or 3.0 mM K allowed nodulation and subsequent nitrogen fixation which appeared to be adequate for respective plant growth. High potassium supply had a positive effect on nitrogen fixation, on shoot and root growth and on water potential in both water regimes. Where nodulation occurred, variations caused by either K or water supply had no consequences on the percentage of nitrogen derived from the symbiosis. The present data indicate that K can apparently alleviate water shortage to a certain extent. Moreover it is shown that the symbiotic system in both faba bean and common bean is less tolerant to limiting K supply than plants themselves. However, as long as nodulation occurs, N assimilation from the symbiotic source is not selectively affected by K as opposed to N assimilation from fertilizer.

Key words

common bean faba bean nodulation potassium fertilization symbiotic nitrogen fixation water stress 


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Copyright information

© Kluwer Academic Publishers 1996

Authors and Affiliations

  • U. Ravi Sangakkara
    • 1
  • Ueli A. Hartwig
    • 2
  • Josef Nösberger
    • 2
  1. 1.Faculty of AgricultureUniversity of PeradeniyaSri Lanka
  2. 2.Institute of Plant SciencesETH-ZentrumZürichSwitzerland

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