Your search keyword '"Spore coat"' showing total 8 results

1. A “spore-like” oral nanodrug delivery platform for precision targeted therapy of inflammatory bowel disease

Author

Yang, Junfei, Wang, Ke, Sun, Shuxin, Pei, Tianqi, Li, Junxiu, Gong, Xunwei, Zheng, Cuixia, Zhang, Yun, Song, Qingling, and Wang, Lei

Published

2025

2. Mechanistic insights into the adaptive evolvability of spore heat resistance in Bacillus cereus sensu lato.

Author

Khanal, Sadhana, Kim, Tom Dongmin, Begyn, Katrien, Duverger, Wouter, Kramer, Gertjan, Brul, Stanley, Rajkovic, Andreja, Devlieghere, Frank, Heyndrickx, Marc, Schymkowitz, Joost, Rousseau, Frederic, Broussolle, Véronique, Michiels, Chris, and Aertsen, Abram

Subjects

*BACILLUS cereus, *MICROBIAL inactivation, *BIOLOGICAL evolution, *SPORES, *WHOLE genome sequencing, *BACTERIAL spores, *SPOREFORMING bacteria

Abstract

Wet heat treatment is a commonly applied method in the food and medical industries for the inactivation of microorganisms, and bacterial spores in particular. While many studies have delved into the mechanisms underlying wet heat killing and spore resistance, little attention has so far been dedicated to the capacity of spore-forming bacteria to tune their resistance through adaptive evolution. Nevertheless, a recent study from our group revealed that a psychrotrophic strain of the Bacillus cereus sensu lato group (i.e. Bacillus weihenstephanensis LMG 18989) could readily and reproducibly evolve to acquire enhanced spore wet heat resistance without compromising its vegetative cell growth ability at low temperatures. In the current study, we demonstrate that another B. cereus strain (i.e. the mesophilic B. cereus sensu stricto ATCC 14579) can acquire significantly increased spore wet heat resistance as well, and we subjected both the previously and currently obtained mutants to whole genome sequencing. This revealed that five out of six mutants were affected in genes encoding regulators of the spore coat and exosporium pathway (i.e. spoIVFB , sigK and gerE), with three of them being affected in gerE. A synthetically constructed ATCC 14579 ΔgerE mutant likewise yielded spores with increased wet heat resistance, and incurred a compromised spore coat and exosporium. Further investigation revealed significantly increased spore DPA levels and core dehydration as the likely causes for the observed enhanced spore wet heat resistance. Interestingly, deletion of gerE in Bacillus subtilis 168 did not impose increased spore wet heat resistance, underscoring potentially different adaptive evolutionary paths in B. cereus and B. subtilis. • B. cereus can readily evolve endospore heat resistance. • Resistance was caused by mutations in the SpoIVFB-SigK-GerE regulatory cascade. • Spore heat resistance coincided with elevated DPA levels and spore density. [ABSTRACT FROM AUTHOR]

Published

2024

3. Display of the peroxiredoxin Bcp1 of Sulfolobus solfataricus on probiotic spores of Bacillus megaterium.

Author

Lanzilli, Mariamichela, Donadio, Giuliana, Fusco, Francesca Anna, Sarcinelli, Carmen, Limauro, Danila, Ricca, Ezio, and Isticato, Rachele

Subjects

*PEROXIREDOXINS, *SULFOLOBUS solfataricus, *BACILLUS megaterium, *FLUORESCEIN isothiocyanate, *DITHIOTHREITOL

Abstract

Bacterial spores displaying heterologous proteins have been proposed as a safe and efficient method for delivery of antigens and enzymes to animal mucosal surfaces. Initial studies have been performed using Bacillus subtilis spores, but other spore forming organisms have also been considered. B. megaterium spores have been shown capable of displaying large amounts of a model heterologous protein ( Discosoma red fluorescent protein mRFP) that in part crossed the exosporium to localize in the space between the outer coat layer and the exosporium. Here, B. megaterium spores have been used to adsorb Bcp1 (bacterioferritin comigratory protein 1), a peroxiredoxin of the archaeon Sulfolobus solfataricus, known to have an antioxidant activity. The spores were highly efficient in adsorbing the heterologous enzyme which, once adsorbed, retained its activity. The adsorbed Bcp1 localized beneath the exosporium, filling the space between the outer coat and the exosporium. This unusual localization contributed to the stability of the enzyme-spore interaction and to the protection of the adsorbed enzyme in simulated intestinal or gastric conditions. [ABSTRACT FROM AUTHOR]

Published

2018

4. Exploring the interaction network of the Bacillus subtilis outer coat and crust proteins.

Author

Krajčíková, Daniela, Forgáč, Vladimír, Szabo, Adam, and Barák, Imrich

Subjects

*BACILLUS subtilis, *BACTERIAL proteins, *BACTERIAL spores, *BACTERIAL cells, *CYTOPLASM

Abstract

Bacillus subtilis spores, representatives of an exceptionally resistant dormant cell type, are encircled by a thick proteinaceous layer called the spore coat. More than 80 proteins assemble into four distinct coat layers: a basement layer, an inner coat, an outer coat and a crust. As the spore develops inside the mother cell, spore coat proteins synthesized in the cytoplasm are gradually deposited onto the prespore surface. A small set of morphogenetic proteins necessary for spore coat morphogenesis are thought to form a scaffold to which the rest of the coat proteins are attached. Extensive localization and proteomic studies using wild type and mutant spores have revealed the arrangement of individual proteins within the spore coat layers. In this study we examined the interactions between the proteins localized to the outer coat and crust using a bacterial two hybrid system. These two layers are composed of at least 25 components. Self-interactions were observed for most proteins and numerous novel interactions were identified. The most interesting contacts are those made with the morphogenetic proteins CotE, CotY and CotZ; these could serve as a basis for understanding the specific roles of particular proteins in spore coat morphogenesis. [ABSTRACT FROM AUTHOR]

Published

2017

5. Clostridium difficile spore biology: sporulation, germination, and spore structural proteins.

Author

Paredes-Sabja, Daniel, Shen, Aimee, and Sorg, Joseph A.

Subjects

*BACTERIAL spore germination, *BACTERIAL sporulation, *CLOSTRIDIOIDES difficile, *CYTOSKELETAL proteins, *NOSOCOMIAL infections, *GRAM-positive bacterial infections, *BACTERIAL morphogenesis

Abstract

Clostridium difficile is a Gram-positive, spore-forming obligate anaerobe and a major nosocomial pathogen of worldwide concern. Owing to its strict anaerobic requirements, the infectious and transmissible morphotype is the dormant spore. In susceptible patients, C. difficile spores germinate in the colon to form the vegetative cells that initiate Clostridium difficile infections (CDI). During CDI, C. difficile induces a sporulation pathway that produces more spores; these spores are responsible for the persistence of C. difficile in patients and horizontal transmission between hospitalized patients. Although important to the C. difficile lifecycle, the C. difficile spore proteome is poorly conserved when compared to members of the Bacillus genus. Further, recent studies have revealed significant differences between C. difficile and Bacillus subtilis at the level of sporulation, germination, and spore coat and exosporium morphogenesis. In this review, the regulation of the sporulation and germination pathways and the morphogenesis of the spore coat and exosporium will be discussed. [ABSTRACT FROM AUTHOR]

Published

2014

6. The MADS-box transcription factor SrfA is required for actin cytoskeleton organization and spore coat stability during Dictyostelium sporulation

Author

Escalante, Ricardo, Yamada, Yohko, Cotter, David, Sastre, Leandro, and Sameshima, Masazumi

Subjects

*TRANSCRIPTION factors, *SERUM, *DICTYOSTELIUM, *GENETIC mutation

Abstract

The MADS-box transcription factor SrfA is involved in spore differentiation in Dictyostelium [Development 125 (1998) 3801]. Mutant spores show an altered morphology and loss of viability. A detailed structural analysis of mutant spores has been performed to gain insight into the specific aspects of spore differentiation in which SrfA is involved. Two main structural defects have been observed. One is the formation of high order actin structures, the so-called actin rods. SrfA mutant spores showed the initial stages of rod formation but no mature rods were found in older spores either in the nucleus or the cytoplasm. Moreover, phosphorylation of actin, that is believed to stabilize the actin rods, is strongly reduced in the mutant. The other defect observed was the formation of the spore coat. Young srfA− spores show basically normal trilaminar coat structures suggesting that release of prespore vesicles and basic assembly of the coat takes place in the absence of SrfA. However, the outer layer gets wavier as the spore ages and suffers a progressive degradation suggesting a late defect in the stability of the spore coat. Taken together, these results suggest that SrfA is involved in late events of spore maturation necessary for spore stability. [Copyright &y& Elsevier]

Published

2004

7. Spore coat formation and timely sporulation depend on cellulose in Dictyostelium.

Author

Zhang, P., McGlynn, A. C., West, C. M., Loomis, W. F., and Blanton, R. L.

Subjects

DICTYOSTELIUM, CELLULOSE, PHYSIOLOGY

Abstract

Abstract Cellulose is a major component of the extracellular coat that surrounds the terminally-differentiated spore of Dictyostelium. It is sandwiched between two layers of proteins that derive from prespore vesicles by exocytosis. Strains unable to synthesize cellulose due to null mutations in the gene encoding the catalytic subunit of cellulose synthase (dcsA) failed to make detergent-resistant spores but produced small, highly refractile, round spore-like cells up to a day late. Although these cells resembled spores in appearance, they were unstable, only transiently ellipsoid in shape, and sensitive to hypo-osmotic shock, drying, or detergents. Differentiation of these pseudo-spores was induced in the normal time frame by activation of the cAMP-dependent protein kinase or co-development with wild type cells, and coat proteins were secreted by the dcsA-null cells at the same time as wild type cells. A substantial fraction of secreted coat proteins was loosely associated with the surface of the mutant cells, resembling the precoat posited to form early during normal sporulation. Transmission electron microscopy revealed that the precoat had little ultrastructural organization in the absence of cellulose. Thus, cellulose in the coat appears to be required for the organization of the precoat precursors as well as the stability, dormancy, and shape of the spore. [ABSTRACT FROM AUTHOR]

Published

2001

8. Diffraction pattern of Bacillus subtilis CotY spore coat protein 2D crystals.

Author

Bodík, Michal, Krajčíková, Daniela, Hagara, Jakub, Majkova, Eva, Barák, Imrich, and Šiffalovič, Peter

Subjects

*CRYSTALLOIDS (Botany), *DIFFRACTION patterns, *BACILLUS subtilis, *BACILLUS thuringiensis, *SPORES, *X-ray scattering, *PROTEIN structure, *BACTERIAL inactivation

Abstract

• Preparation of Bacillus subtilis CotY spore coat protein Langmuir films. • Employing the Grazing-Incidence Wide-Angle X-ray Scattering on the Langmuir films of CotY spore coat protein. • Identification of the ordering inside the protein. Bacillus subtilis spore coat is a bacterial proteinaceous structure with amazing characteristics of self-organization, unique resiliency, toughness and flexibility in the same time. The spore coat represents a complex multilayered protein structure which is composed of over 80 coat proteins. Some of these proteins form two dimensional crystal structures who's low resolution ternary structure as was determined by electron microscopy. However, there are no 3D structure of these proteins known, due to a problem of preparing 3D crystals which could be analyzed by synchrotron X-ray sources. In the present study, Grazing-Incidence Wide-Angle X-ray Scattering (GIWAXS) was applied to investigate a diffraction pattern of CotY 2D crystals formed on Langmuir monolayer films. We observed two distinct diffraction rings and their position corresponds to a structure with the lattice spacing of 10.6 Å and 5.0 Å, respectively. Obtaining diffractions of 2D crystals pave the way to determination of 3D structure of coat proteins by using strong X-ray sources. [ABSTRACT FROM AUTHOR]

Published

2021