Research & Reviews: A Journal of Biotechnology

Cyanobacteria are microalgae which are freely distributed in aquatic environment. They are photosynthetic organisms and can fix atmospheric nitrogen under anerobic condition. Such cyanobacteria have been applied as a nitrogen fertilizer in agriculture to improve the crop yield. Since the application of chemical fertilizers in crop fields created heavy metal pollution which could be neutralized by microalgae under aquatic environment. They have ability to tolerate the heavy metal concentrations under polluted environment. The present investigation analyzed the impact of mercuric iodide concentrations on the growth of Phormidium spp. which were initially isolated from the paddy field of Selugai, Sivagangai district, Tamil Nadu. They were mass cultured and treated with various concentrations of mercuric iodide (0.1–1 ppm) under laboratory condition. The present strategy enhanced the cyanobacterial populations under different heavy metal concentrations. Phormidium growth was measured and estimated the chlorophyll and phycobillins contents, nitrogen, protein contents and quantity of excreted ammonia. The present investigation has concluded that the selective cyanobacteria Phormidium spp. was well grown at the low concentrations of heavy metals, but higher concentrations affected the growth Phormidium when compared to control. This work confirmed that the mass distribution of cyanobacteria in paddy field preciously fixed atmospheric nitrogen and at the same time they were tolerated against multiple application of agrochemicals with heavy metals normally in crop field. Such organisms could neutralize the heavy metals at minimum level in crop field and improve the crop growth.

Malik, Farhat R., Soaliha Ahmed, and Yazdana M. Rizki. Utilization of lignocellulosic waste for the preparation of nitrogenous biofertilizer. Pakistan Journal of Biological Sciences 4.10 (2001):1217-1220.

Song, Tieying, et al. Biodiversity and seasonal variation of the cyanobacterial assemblage in a rice paddy field in Fujian, China. FEMS Microbiology Ecology 54.1 (2005): 131-140.

Subramanian, G., and L. Uma. Cyanobacteria in pollution control. Journal of Scientific and Industrial Research 55 (1996): 685-692.

Mackinney, Gr. Absorption of light by chlorophyll solutions. Journal of biological chemistry 140.2 (1941): 315-322.

Bennett, Allen, and Lawrence Bogorad. Complementary chromatic adaptation in a filamentous blue-green alga. The Journal of cell biology 58.2 (1973): 419-435.

Umbreitt WW, Buris RH, Stauffer JF. Method for nitrogen in: Manometric and Bio-chemical technique. 15th Ed. Burgees publishing company, Minnesota, 1972; 259-260p.

Solorzano, Lucia. DETERMINATION OF AMMONIA IN NATURAL WATERS BY THE PHENOLHYPOCHLORITE METHOD 1 1 This research was fully supported by US Atomic Energy Commission Contract No. ATS (11‐1) GEN 10, PA 20. Limnology and oceanography 14.5 (1969): 799-801.

Lowry, Oliver H. Protein measurement with the Folin phenol reagent. J biol Chem 193 (1951):265-275.

Das, Nilanjana, R. Vimala, and P. Karthika. Biosorption of heavy metals–an overview. (2008).

De Philippis, Roberto, and Ernesto Micheletti. Heavy metal removal with exopolysaccharide-producing cyanobacteria. Handbook of Advanced Industrial and Hazardous Wastes Management. CRC Press, 2017. 931-964.

Naja, Ghinwa, and Bohumil Volesky. The mechanism of metal cation and anion biosorption. Microbial biosorption of metals. Springer, Dordrecht, 2011. 19-58.

Surosz, Waldemar, and K. A. Palinska. Effects of heavy-metal stress on cyanobacterium Anabaena flos-aquae. Archives of environmental contamination and toxicology 48.1 (2004): 40-48.

Khalil, Zeinab. Toxicological response of a cyanobacterium, Phormidium fragile, to mercury. Water, air, and soil pollution 98.1 (1997): 179-185.