Monitoring of Spore-forming Dynamics Through Flow Cytometry

Overview

Journal Front Microbiol

Specialty Microbiology

Date 2024 Nov 13

PMID 39534508

Authors

Zhili Chen

Yuanyuan Lu

Jiazhen Cui

Yuzhong Feng

Haolong Dong

Xuan Huang

Chen Zhu

Xianghua Xiong

Huipeng Chen

Qingyang Wang

Gang Liu

Affiliations

Soon will be listed here.

Abstract

The plate counting method is a traditional and widely accepted technique for live cell counting, often employed for enumeration and spore forming rate calculations. However, this method requires at least 12 h to generate results, making it unsuitable for real-time monitoring of bacterial growth status and spore transformation rate. crystals, produced during sporulation, are widely used as microbial pesticides, with high demand for industrial scale production. Variations in cultivation conditions and harvest timing during large-scale pore production of significantly affect spore forming rate, impacting crystallization yield. Nevertheless, there is a lack of real-time monitoring methods for spore conversion rate. Flow cytometry (FCM), a well-established technique for single-cell analysis in eukaryotic cells, has been successfully applied in bacterial detection in environmental and food samples. In this study, we introduced a rapid flow cytometry-based method for determining spore forming rate of , with two nucleic acid dyes, SYTO24 and LDS751. The method enables dynamic monitoring of spore, vegetative cell, and viable but non-culturable/dead cell proportions during the whole cultivation process, and spore forming rate could be gained within 30 min. Data of spore forming rate by FCM method is consistent with that by plate counting method, offering a faster and more efficient approach for assessing sporulation status in industrial microbial pesticide production.

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