Fuente: PubMed "meat" Arch Microbiol. 2026 Feb 16;208(4):195. doi: 10.1007/s00203-026-04760-6.ABSTRACTFoodborne Clostridium spores represent a significant group of pathogens that threaten food safety, posing a unique control challenge due to their extreme resistance to conventional processing and high pathogenicity upon germination. The spore inner membrane (SIM), a critical structure enveloping the spore core, serves as the central functional interface governing resistance, dormancy maintenance, and germination regulation. Notably, the composition and organization of the Clostridial SIM exhibit distinct features compared to the well-studied Bacillus model, though some mechanistic understandings are extrapolated from the latter. Critically, the SIM lipids in dormant spores exist in a tightly packed gel phase, which drastically reduces membrane fluidity and constitutes the fundamental physical basis for its exceptional low-permeability barrier. Current debates center on whether key germination receptors are individually embedded within the SIM or assemble into a higher-order "germinosome" complex that may span or sit atop the membrane to coordinate signal perception. This article systematically reviews the research progress on the composition, structure, and functional characteristics of the SIM in foodborne Clostridial spores. It elaborates on the low-permeability barrier and signaling hub formed by its unique phospholipids (e.g., cardiolipin, phosphatidylglycerol) and functional proteins (e.g., Ger family receptors, SpoVA channels). The core roles of the SIM in resisting heat and chemical stress, maintaining core homeostasis, and responding to germination signals are analyzed. Furthermore, key research techniques in this field (e.g., electron microscopy, solid-state NMR, lipidomics / proteomics, gene editing) and their applications are summarized. Finally, current challenges and bottlenecks are outlined, including difficulties in dynamic analysis of the SIM, understanding interspecies mechanistic differences, and developing targeted control applications. This review aims to deepen the understanding of the resistance and germination mechanisms of Clostridial spores and to provide a insight and a potential theoretical basis for developing more targeted spore-control strategies targeting the SIM.PMID:41697364 | DOI:10.1007/s00203-026-04760-6