Introduction Clostridium sporogenes

Introduction
Clostridium sporogenes is a Gram positive anaerobic sporeforming bacterium. It is a significant cause of food spoilage (McClure, 2006), and occasionally pathogenic (Inkster et al., 2011), and because of its physiological and genetic similarity to Clostridium botulinum Group I (proteolytic C. botulinum) (Bradbury et al., 2012; Carter et al., 2009; Collins et al., 1994; Peck et al., 2011) it is often used as a surrogate for this organism in demonstrating the effectiveness of food processes (Brown et al., 2012; Diao et al., 2014; Taylor et al., 2013). Clostridial spores persist in the environment. This highly resistant dormant state permits survival in hostile conditions (e.g. oxygen, absence of nutrients, heat treatment, desiccation, high pressure, toxic chemicals) that would be lethal to vegetative cells. The resistance properties of the spores of C. sporogenes and C. botulinum are a principal reason why these bacteria present a significant food spoilage and food safety problem (Brunt et al., 2014; Peck, 2009). The ultrastructure of clostridial and bacillus spores is generally conserved (Henriques and Moran, 2007; Paredes-Sabja et al., 2014), and comprises a spore coat, outer membrane, cortex, inner membrane and spore core (Leggett et al., 2012). In contrast, the outermost layers, in particular the exosporium, vary for individual species and strains (Driks, 1999; Henriques and Moran, 2007; Paredes-Sabja et al., 2014). Indeed, Bacillus subtilis may not have a recognised exosporium (Driks, 1999), although a point of much debate (Henriques and Moran, 2007). The exosporium and coat constituents are synthesised in the mother cell and assembled around the developing forespore (Henriques and Moran, 2007). Electron microscopy has shown the exosporium in several clostridia to be loosely fitted around the spore with an opening at one of the polar regions (Lund et al., 1978; Mackey and Morris, 1972a,b; Stevenson and Vaughn, 1972). However, in Clostridium difficile the exosporium often lacks the gap that separates the spore coat from the exosporium which is observed in Bacillus cereus and Bacillus anthracis spores (Paredes-Sabja et al., 2014). Although the exact role of the exosporium is not completely understood, previous studies with C. sporogenes suggest that the exosporium may have a role in germination, outgrowth and attachment (Panessa-Warren et al., 1994, 1997). While the proteinaceous spore coat provides protection for the spore, the exosporium is the first point of contact of the spore with its environment. When conditions in the environment become favourable, the dormancy of bacterial spores is * Corresponding author. broken, germination occurs and cell multiplication recommences. E-mail address: Jason.brunt@ifr.ac.uk (J. Brunt).
Food Microbiology 51 (2015) 45e50 Despite the fact that extensive investigations have been undertaken on spore germination, coat structure, and clostridial cell growth from spores (Henriques and Moran, 2007; Setlow, 2014; Stringer et al., 2011; Webb et al., 2012), there is a relative lack of information regarding the cell's exit from its protective coats. The purpose of the present study was to build on previous observations in C. sporogenes, Clostridium pasteurianum and B. anthracis that the spore exosporium may have a hole or “bottle cap” at its pole (Mackey and Morris, 1972b; Panessa-Warren et al., 1994, 1997; Steichen et al., 2007). In particular we show that the rupture of the C. sporogenes spore coat occurs adjacent to the pre-formed aperture in the exosporium, and that the germinated cell emerges through aligned openings in the spore coat and the exosporium.