Examination of Impact of Arsenic Stress on Soil Microbes

Rashida Sultana; Maleeha Umber; Fareeha Iffat; Shanzah Kiran; Ayesha Khalid; Mirza Naseer Ahmad

doi:10.21743/pjaec/2020.12.36

Authors

Rashida Sultana Department of Botany, Abdus Salaam Research Forum, Nusrat Jahan College Rabwah, Chenab Nagar, Pakistan Author
Maleeha Umber Department of Botany, Abdus Salaam Research Forum, Nusrat Jahan College Rabwah, Chenab Nagar, Pakistan Author
Fareeha Iffat Department of Botany, Abdus Salaam Research Forum, Nusrat Jahan College Rabwah, Chenab Nagar, Pakistan Author
Shanzah Kiran Department of Botany, Abdus Salaam Research Forum, Nusrat Jahan College Rabwah, Chenab Nagar, Pakistan Author
Ayesha Khalid Department of Botany, Abdus Salaam Research Forum, Nusrat Jahan College Rabwah, Chenab Nagar, Pakistan Author
Mirza Naseer Ahmad Department of Geography, Faculty of Earth Sciences, Abdus Salaam Research Forum, Nusrat Jahan College Rabwah, Chenab Nagar, Pakistan Author

DOI:

https://doi.org/10.21743/pjaec/2020.12.36

Keywords:

Pseudomonas, Penicillium, Arsenic, CLED, Soil microbes, Well method, Spread method, Disk method

Abstract

The research was performed at Botany department, Nusrat Jahan College Rabwah Pakistan to screen stress tolerance level of soil microbes (pseudomonas and penicillium) taken from NARC (National Agricultural Research Centre) Pakistan against different levels of sodium arsenite
stress (1 mg/L to 10 mg/L). The research was based on completely randomized design. Three drops were applied to microbes grown on CLED (cysteine-, lactose-, and electrolyte-deficient) media to determine zone of inhibition through disk, well and spread method, while control group was without sodium arsenite application. After application of various levels of arsenic stress organisms were incubated for 24 h at 37°C. After incubation, zones of inhibition were measured. Our study has shown that both micobes cannot overcome higher levels of arsenic stress because in higher stress petriplates, increased inhibitory zones were observed.