Abstract
Bacillus thuringiensis is the major bioinsecticide worldwide produced due to the Cry protein activity. Several studies have been done to improve the cost–productivity relation. The neutral protease A (NprA) is the major extracellular protein massively produced during the stationary phase by this bacterium, contributing to the Cry proteins' degradation. Also, the deletion of aprA and nprA genes enhanced the yield of Cry protein, stabilizing it. Therefore, to increase Cry production, one possibility is to degrade the NprA protease in the culture media. In the present study, proteinase K was used to hydrolyze the NprA to increase Cry production. Proteinase K was added during the exponential growth of B. thuringiensis culture. The bacilli and endospores were measured along all culture, while the Cry protein was measured at the end of the culture. The addition of PK affects the bacilli and spore kinetics positively but negatively to the Cry protein (there is no Cry protein detection). Therefore, the gene expression of the cry1Ac, nprX, nprA, and spo0A was measured. The expression of each gene was followed along all culture. Results demonstrated that PK alters both the transcriptional levels and the expression order of the genes.
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Acknowledgements
HRB-D acknowledges the scholarship granted by Project 2008-105057/CONACyT.
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This study was funded by CONACyT (CB-2008–105057 and CB-2015/258587).
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AKN-M conceived and designed the research. MAP-R wrote the manuscript. HRB-D and CR-S conducted the experiments. MAP-R, KVC-C, AH-H, and AKN-M analyzed the obtained data. All authors read and approved the manuscript.
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Peña-Rico, M.A., Bravo-D, H.R., Roldan-Sabino, C. et al. Addition of proteinase K during the culture alter the physiology of Bacillus thuringiensis culture and the cry1Ac, nprX, nprA, and spo0A gene transcription. Antonie van Leeuwenhoek 115, 89–102 (2022). https://doi.org/10.1007/s10482-021-01683-8
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DOI: https://doi.org/10.1007/s10482-021-01683-8