Development of bacterial bioformulations using response surface methodology.

Aim: Bacterial consortia exhibiting plant growth promoting properties have emerged as a sustainable approach for crop improvement. As the main challenge associated with them is loss of viability and performance under natural conditions, a robust approach for designing bioformulation is needed. In this study, an efficient bioformulation was developed using spontaneous mutants of three bacterial strains for growth promotion of Cajanus cajan.

Methods and results: Optimization of additives for solid [carboxymethylcellulose (CMC), and glycerol] and liquid [polysorbate, CMC, and polyvinyl pyrrolidone (PVP)] bioformulations was done by response surface methodology using central composite design. The stability of each bioinoculant in the formulation was assessed at 30°C and 4°C. The efficiency of the liquid bioformulation was checked in planta in sterile, and subsequently in non-sterile, soil. The maximum cell count was observed in solid bioformulation with 0.1 g l-1 CMC and 50% glycerol (8.10 × 108, 3.69 × 108, and 7.39 × 108 CFU g-1 for Priestia megaterium, Azotobacter chroococcum, and Pseudomonas sp. SK3, respectively) and in liquid bioformulation comprising 1% PVP, 0.1 g l-1 CMC, and 0.025% polysorbate (8 × 109, 3.8 × 109, and 6.82 × 109 CFU ml-1 for P. megaterium, A. chroococcum, and Pseudomonas sp. SK3, respectively). The bioinoculants showed a higher viability (6 months) at 4°C compared to 30°C. Triple culture consortium enhanced plant growth in comparison to the control. The strains could be detected in soil till 45 days after sowing.

Conclusions: The study established a systematic process for developing a potent bioformulation to promote agricultural sustainability. Using mutant strains, the bioinoculants could be tracked. In planta assays revealed that the triple culture consortium out-performed mono and dual cultures in terms of impact on plant growth.