Mycobiology.  2005 Mar;33(1):51-60. 10.4489/MYCO.2005.33.1.051.

Increased Salinity Tolerance of Cowpea Plants by Dual Inoculation of an Arbuscular Mycorrhizal Fungus Glomus clarum and a Nitrogen-fixer Azospirillum brasilense

Affiliations
  • 1Botany Department, Faculty of Science, Zagazig Univ., Zagazig, Sharkia Gov. 44519, Egypt. rabiegam@hotmail.com
  • 2Botany Department, Faculty of Science, South Valley University, Sohag, Egypt.
  • 3Science Department, Taief Teacher's College, Saudi Arabia.

Abstract

Pot greenhouse experiments were carried out to attempt to increase the salinity tolerance of one of the most popular legume of the world; cowpea; by using dual inoculation of an Am fungus Glomus clarum and a nitrogen-fixer Azospirillum brasilense. The effect of these beneficial microbes, as single- or dual inoculation-treatments, was assessed in sterilized loamy sand soil at five NaCl levels (0.0~7.2 ds/m) in irrigating water. The results of this study revealed that percentage of mycorrhizal infection, plant height, dry weight, nodule number, protein content, nitrogenase and phosphatase activities, as well as nutrient elements N, P, K, Ca, Mg were significantly decreased by increasing salinity level in non-mycorrhized plants in absence of NFB. Plants inoculated with NFB showed higher nodule numbers, protein content, nitrogen concentration and nitrogenase activities than those of non-inoculated at all salinity levels. Mycorrhized plants exhibited better improvement in all measurements than that of non-mycorrhized ones at all salinity levels, especially, in the presence of NFB. The concentration of Na+ was significantly accumulated in cowpea plants by rising salinity except in shoots of mycorrhizal plants which had K+/Na+ ratios higher than other treatments. This study indicated that dual inoculation with Am fungi and N-fixer Azospirillum can support both needs for N and P, excess of NaCl and will be useful in terms of soil recovery in saline area.

Keyword

Glomus; Growth; Fixation; Legumes; Nitrogen; Nodule; Nutrients; Symbiosis

MeSH Terms

Azospirillum brasilense*
Azospirillum*
Fabaceae
Fungi*
Nitrogen
Nitrogenase
Plants
Salinity*
Silicon Dioxide
Soil
Symbiosis
Water
Nitrogen
Nitrogenase
Silicon Dioxide
Soil
Water
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