Heat Activation and Inactivation of Bacterial Spores: Is There an Overlap?

Heat activation at a sublethal temperature is widely applied to promote species spore germination. This treatment also has the potential to be employed in food processing to eliminate undesired bacterial spores by enhancing their germination and then inactivating the less-heat-resistant germinated s...

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Bibliographic Details
Published in:Applied and environmental microbiology 2022-03, Vol.88 (5), p.e0232421-e0232421
Main Authors: Wen, Juan, Smelt, Jan P P M, Vischer, Norbert O E, de Vos, Arend L, Setlow, Peter, Brul, Stanley
Format: Article
Language:English
Subjects:
Applied and Industrial Microbiology
Asparagine
Bacillus
Bacillus subtilis - physiology
Bacteria
Bacterial Proteins - pharmacology
Damage
Deactivation
Food
Food Microbiology
Food preservation
Food processing
Food spoilage
Germination
Heat
Heat inactivation
Heat treatment
Heat treatments
Heterogeneity
Hot Temperature
Inactivation
Intoxication
Potassium
Spoilage
Spore germination
Spores
Spores, Bacterial
Thermal resistance
Valine
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Summary:Heat activation at a sublethal temperature is widely applied to promote species spore germination. This treatment also has the potential to be employed in food processing to eliminate undesired bacterial spores by enhancing their germination and then inactivating the less-heat-resistant germinated spores at a milder temperature. However, incorrect heat treatment could also generate heat damage in spores and lead to more heterogeneous spore germination. Here, the heat activation and heat damage profile of Bacillus subtilis spores was determined by testing spore germination and outgrowth at both population and single-spore levels. The heat treatments used were 40 to 80°C and for 0 to 300 min. The results were as follows. (i) Heat activation at 40 to 70°C promoted l-valine- and l-asparagine-glucose-fructose-potassium (AGFK)-induced germination in a time-dependent manner. (ii) The optimal heat activation temperatures for AGFK and l-valine germination via the GerB plus GerK or GerA germinant receptors were 65°C and 50 to 65°C, respectively. (iii) Heat inactivation of dormant spores appeared at 70°C, and the heat damage of molecules essential for germination and growth began at 70 and 65°C, respectively. (iv) Heat treatment at 75°C resulted in both activation of germination and damage to the germination apparatus, and 80°C treatment caused more pronounced heat damage. (v) For the spores that should withstand adverse environmental temperatures in nature, heat activation seemed functional for a subsequent optimal germination process, while heat damage affected both germination and outgrowth. Bacterial spores are thermal-stress-resistant structures that can thus survive food preservation strategies and revive through the process of spore germination. The more heat resistant spores are, the more heterogeneous their germination upon the addition of germinants. Upon germination, spores can cause food spoilage and food intoxication. Here, we provide new information on both heat activation and inactivation regimes and their effects on the (heterogeneity of) spore germination.
ISSN:0099-2240
1098-5336
DOI:10.1128/aem.02324-21