Daniela Krajcikova

Searching for Protein-Protein Interactions within the Bacillus subtilis Spore Coat

The capability of endospores of Bacillus subtilis to withstand extreme environmental conditions is secured by several attributes. One of them, the protein shell that encases the spore and is known as the coat, provides the spore with its characteristic resistance to toxic chemicals, lytic enzymes, and predation by unicellular and multicellular eukaryotes. Despite most of the components of the spore coat having been identified, we have only a vague understanding of how such a complex structure is assembled. Using the yeast two-hybrid system, we attempted to identify direct contacts among the proteins allocated to the insoluble fraction of the spore coat: CotV, CotW, CotX, CotY, and CotZ. We also examined whether they could interact with CotE, one of the most crucial morphogenetic proteins governing outer coat formation and also present in the insoluble fraction. Out of all 21 possible interactions we tested, 4 were found to be positive. Among these interactions, we confirmed the previous observation that CotE forms homo-oligomers. In addition, we observed homotypic interactions of CotY, strong interactions between CotZ and CotY, and relatively weak, yet significant, interactions between CotV and CotW. The results of this yeast two-hybrid analysis were confirmed by size exclusion chromatography of recombinant coat proteins and a pull-down assay.

Interactions between Bacillus subtilis early spore coat morphogenetic proteins

When challenged by stresses such as starvation, the soil bacterium Bacillus subtilis produces an endospore surrounded by a proteinaceous coat composed of >70 proteins that are organized into three main layers: an amorphous undercoat, lightly staining lamellar inner coat and electron-dense outer coat. This coat protects the spore against a variety of chemicals or lysozyme. Mutual interactions of the coats building blocks are responsible for the formation of this structurally complex and extraordinarily resistant shell. However, the assembly process of spore coat proteins is still poorly understood. In the present work, the main focus is on the three spore coat morphogenetic proteins: SpoIVA, SpoVID and SafA. Direct interaction between SpoIVA and SpoVID proteins was observed using a yeast two-hybrid assay and verified by coexpression experiment followed by Western blot analysis. Coexpression experiments also confirmed previous findings that SpoVID and SafA directly interact, and revealed a novel interaction between SpoIVA and SafA. Moreover, gel filtration analysis revealed that both SpoIVA and SpoVID proteins form large oligomers.

Diverse supramolecular structures formed by self‐assembling proteins of the Bacillus subtilis spore coat

Bacterial spores (endospores), such as those of the pathogens Clostridium difficile and Bacillus anthracis, are uniquely stable cell forms, highly resistant to harsh environmental insults. Bacillus subtilis is the best studied spore‐former and we have used it to address the question of how the spore coat is assembled from multiple components to form a robust, protective superstructure. B. subtilis coat proteins (CotY, CotE, CotV and CotW) expressed in Escherichia coli can arrange intracellularly into highly stable macro‐structures through processes of self‐assembly. Using electron microscopy, we demonstrate the capacity of these proteins to generate ordered one‐dimensional fibres, two‐dimensional sheets and three‐dimensional stacks. In one case (CotY), the high degree of order favours strong, cooperative intracellular disulfide cross‐linking. Assemblies of this kind could form exquisitely adapted building blocks for higher‐order assembly across all spore‐formers. These physically robust arrayed units could also have novel applications in nano‐biotechnology processes.

Study of the interactions between the key spore coat morphogenetic proteins CotE and SpoVID.

The capability of Bacillus subtilis spores to withstand extreme environmental conditions is thought to be conferred especially by their outermost proteinaceous protective layer, called the spore coat. Of the over 70 proteins that form the spore coat, only a small subset of them affect its morphogenesis, they are referred to as morphogenetic proteins. In this study we investigated the interaction between two spore coat morphogenetic proteins SpoVID and CotE. SpoVID is involved in the process of spore surface encirclement by individual coat proteins, these include CotE, which controls the assembly of the outer coat layer. Both proteins were proposed to be recruited to a common protein scaffold, but their direct association has not been previously shown. Here we studied the interactions between CotE and SpoVID in vitro for the first time by using molecule recognition force spectroscopy, which allows the detection of piconewton forces between conjugated biological pairs and also facilitates the investigation of dynamic processes. The most probable CotE-CotE unbinding force was 49.4±0.1pN at a loading rate of 3.16×10³ pN/s while that of SpoVID-CotE was 26.5±0.6pN at a loading rate of 7.8×10² pN/s. We further analyzed the interactions with the bacterial two hybrid system and pull-down experiments, which also indicate that SpoVID interacts directly with CotE. In combination with the previously identified direct contacts among SpoIVA, SpoVID and SafA, our data imply that the physical association of key morphogenetic proteins forms a basic skeleton where other coat proteins could be attached.

The Interactions of Spore-Coat Morphogenetic Proteins Studied by Single-Molecule Recognition Force Spectroscopy

Bacillus subtilis can form a spore, which is a dormant type of cell, when its external environment becomes unsuitable for vegetative growth. The spore is surrounded by a multilayered proteinaceous shell called a spore coat, which plays a crucial role in dormancy and germination. Of the over 70 proteins that form the spore coat, only a small subset of them affect its morphogenesis; they are referred to as morphogenetic proteins. How these morphogenetic proteins interact, and furthermore, how they build the ordered, functional coat layers is not well understood. Elucidating the self-assembly mechanism of individual proteins into such a complex structure may contribute to its potential use in nano-biotechnology applications for preparing highly organized, robust, and resistant proteinaceous layers. Herein, direct, noncovalent, low-affinity interactions between the spore-coat morphogenetic proteins SpoIVA, SpoVID, and SafA were studied by using single-molecule recognition force spectroscopy in vitro for the first time. Based on the real-time examination of interactions between these three proteins, a series of dynamic kinetic data were obtained. It was also observed that the SafA-SpoVID interaction was stronger than that of SafA-SpoIVA.

Purification, crystallization and preliminary X-ray analysis of two crystal forms of ribonuclease Sa3.

RNase Sa3 produced by Streptomyces aureofaciens strain CCM 3239 belongs to the T1 family of microbial ribonucleases. It is closely related both to RNase Sa, studied in detail earlier, and to RNase Sa2 produced by the same microorganism. The most important property of RNase Sa3 is the relatively high cytotoxic activity, which was not observed for RNase Sa and Sa2. Recombinant RNase Sa3 was overexpressed in Escherichia coli and purified to high homogeneity. The hanging-drop vapour-diffusion method was used for crystallization. The two crystal forms are trigonal P3(1)21 and tetragonal P4(1)2(1)2, with unit-cell parameters a = b = 64.7, c = 69.6 A, gamma = 120 degrees and a = b = 34.0, c = 147.2 A, respectively. They diffract to 2.0 and to 1.7 A resolution, respectively, using synchrotron radiation. The asymmetric units of crystal forms I and II contain one molecule of the enzyme, which corresponds to V(M) = 3.8 A(3) Da(-1) with a solvent content of 68% and V(M) = 1.9 A(3) Da(-1) with a solvent content of 37%, respectively.

Physical interaction and assembly of Bacillus subtilis spore coat proteins CotE and CotZ studied by atomic force microscopy.

The spore of Bacillus subtilis, a dormant type of cell, is surrounded by a complex multilayered protein structure known as the coat. It is composed of over 70 proteins and essential for the spore to withstand extreme environmental conditions and allow germination under favorable conditions. However, understanding how the properties of the coat arise from the interactions among all these proteins is an important challenge. Moreover, many specific protein-protein interactions among the coat proteins are crucial for coat assembly. In this study, atomic force microscopy (AFM) based single molecule force spectroscopy (SMFS) was applied to investigate the interaction as a dynamic process between two morphogenetic coat proteins, CotE and CotZ. The unbinding force and kinetic parameters characterizing the interaction between CotE and CotZ were obtained. It is found that there is a strong affinity between CotE and CotZ. Furthermore, the assembly behaviors of CotE and CotZ, individually or in combination, were studied by AFM at solid-liquid interfaces. Our results revealed that CotE-CotZ assembly is dependent on their molar ratios and the interaction between CotE and CotZ involves in the CotE-CotZ assembly.

Forces and Kinetics of the Bacillus subtilis Spore Coat Proteins CotY and CotX Binding to CotE Inspected by Single Molecule Force Spectroscopy

Spores are uniquely stable cell types that are produced when bacteria encounter nutrient limitations. Spores are encased in a complex multilayered coat, which provides protection against environmental insults. The spore coat of Bacillus subtilis is composed of around 70 individual proteins that are organized into four distinct layers. Here we explored how morphogenetic protein CotE guides formation of the outermost layer of the coat, the crust, around the forespore by focusing on three proteins: CotE, CotY, and CotX. Single molecule force spectroscopy (SMFS) was used to investigate the interactions among CotE, CotY, and CotX at the single-molecule level. Direct interactions among these three proteins were observed. Additionally, the dissociation kinetics was also studied by measuring the unbinding forces of the complexes at different loading rates. A series of kinetic data of these complexes were acquired. It was found that the interaction of CotE and CotY was stronger than that of CotE and CotX.

Investigating interactions of the Bacillus subtilis spore coat proteins CotY and CotZ using single molecule force spectroscopy

Spores formed by Bacillus subtilis are surrounded by a protective and multilayered shell, termed the coat, which grants the spores resistance to various environmental stresses and facilitates spore germination. The spore coat consists of more than seventy different proteins, arranged into at least four distinct structural layers: the undercoat, inner coat, outer coat and crust. However, how these proteins, especially the morphogenetic proteins, interact to establish the organized, functional coat layers remains poorly understood. CotY and CotZ as the components of the crust, play a morphogenetic role in the crust assembly around the spore. In this study, the single molecule force spectroscopy was used to investigate the interaction and dynamics between CotY and CotZ at the single-molecule level. The results show that homotypic interactions of CotY and CotZ and the heterotypic interaction between CotY and CotZ exist. Furthermore, the dissociation kinetics of the complexes were studied by monitoring the relationship between the unbinding forces and the loading rates at different pulling velocities. In this way, a series of kinetic parameters regarding the three different complexes were obtained. It revealed the strong interactions between CotY and CotZ, CotY and CotY, and a relatively weak interaction of CotZ and CotZ.

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

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.