Isolation of polysaccharide producer and heavy metal tolerant local rhizobial isolates

Mohammed Hamid Jasim, Raad Hassani Sultan

Abstract


Background: Rhizobial bacteria is an important species among the soil bacteria that inter a relationship with leguminous plant and fix nitrogen symbiotically. Importance of this relation not only for soil as soil fertilizer but also to keep our environment without pollution.  

Methods: Survey was conducted to collect different strains of rhizobial from different area in Nineveh Governate in Iraq. Isolation and biochemical tests were done under laboratory conditions. Determination of exopolysaccharide and tolerance of heavy metal was conducted also. Data obtained was recorded after cultivation and incubation of rhizobial strains.

Results: The rhizobial bacteria were isolated from the following leguminous plants: Vigna unguiculata L., Trifolium alexandrinum, Trigonella foenum-graecum L., Leucaena leucocephala L., Medicago sativa L., Phaseolus vulgaris L., Tribulus terrestris L. and Vicia faba L. Maximum exopolysaccharide production were reached to 3.70 gm/L by the isolate R. leguminosarum bv. Viciae  RM25,after two days of incubation. The maximum cell dry weight was 2.90 gm/L. by the isolate E. meliloti RM14, after two days of incubation. Maximum reduction in pH were 4.30 by strain E. meliloti RM5, after two days incubation. All the local isolated rhizobia were tolerated to nickel chloride for the studied concentrations: 100, 500, 1000 and 5000 µg/ ml. Also were tolerance to 100 and 500 µg/ ml of zinc sulfate and copper sulfate. 1000 µg/ ml concentration of zinc sulfate were also tolerated by all rhizobial isolates.

Conclusion: Rhizobium bacteria possess several mechanisms that allow them to tolerate heavy metal exposure. These mechanisms include the expression of efflux pumps, the presence of metal-resistance plasmids, the production of EPS, and the ability to adapt to environmental factors. Further research is needed to fully understand the mechanisms behind the heavy metal tolerance in Rhizobium and to explore the potential applications of these bacteria in bioremediation of heavy metal polluted soils.


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References


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DOI: http://dx.doi.org/10.62940/als.v10i4.2314

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