Abstract

To investigate the best carbon source for mixotrophic growth of Cyanothece sp. This cyanobacterium is also used as a source of biogenic silver nanoparticles. The study also investigates the antimicrobial activity of nanoparticles (both gold and silver) biosynthesized by this cyanobacterium. Those particles are tested solely and in combination as antimicrobial agents against two farm bacteria commonly found in Al Ahsa. Soil extract was prepared from pesticide-free soil whereas dextrose was prepared in 6 mM concentration and the cyanobacterial culture cell density was determined after two weeks. Cultures of Cyanothece sp. were incubated with silver nitrate until turning brown. The external solution of culture was analyzed using chemical analyses including UV- visible and FTIR to confirm nano silver formation. Previously-biosynthesized nano gold particles by Cyanothece sp. were used solely and in combination with newly biosynthesized nano silver particles for antimicrobial bioassay against the two farm bacterial pathogens. The best mixotrophic cyanobacterial growth was obtained for soil extract followed by dextrose which were significantly different from control. The synthesis of nanoparticles using this cyanobacterium was confirmed using UV-visible light spectrophotometry which detected the characteristic surface plasmon resonance peak in the range of 410-450 nm and the FTIR spectroscopy which showed the characteristic silver nanoparticles peak at 3.297 cm^-1 which overlaps with -OH- in addition to the other functional groups associated with nano silver particles detected at 2,927, 1,631 and 1,383 cm⁻¹. Silver nanoparticles showed the strong antimicrobial effect against both pathogens Staphylococcus aureus (MRSA) and Staphylococcus warneri with inhibition zone diameter 1.3 cm for both followed by the combination of silver and gold nanoparticles. Soil extract is a natural medium rich in all types of organic and inorganic nutrients which enhance algal mixotrophic growth. Biosynthesized silver nanoparticles showed the strongest antibacterial action against both pathogens most likely due to its ease of penetration, interaction with cellular components, generation of reactive oxygen species and induction of oxidative stress leading to bacterial death.

Conclusion

, Mass culturing of cyanobacteria by using soil extract is both economic and eco-friendly. In addition, the green biosynthesis of silver nanoparticles and their use in biocontrol of farm pathogens serve the purposes of environmental sustainability and food security.

Keywords:
antimicrobial; biocontrol; cyanobacteria; Cyanothece sp.; environmental sustainability; food security; mixotrophy; silver nanoparticles