Characterization of a newly discovered putative DNA replication initiator from Paenibacillus polymyxa phage phiBP.

The bacteriophage phiBP contains a newly discovered putative replisome organizer, a helicase loader, and a beta clamp, which together may serve to replicate its DNA. Bioinformatics analysis of the phiBP replisome organizer sequence showed that it belongs to a recently identified family of putative initiator proteins. We prepared and isolated a wild type-like recombinant protein, gpRO-HC, and a mutant protein gpRO-HCK8A, containing a lysine to alanine substitution at position 8.

spores displaying RBD domain of SARS-CoV-2 spike protein.

spores are considered to be efficient and useful vehicles for the surface display and delivery of heterologous proteins. In this study, we prepared recombinant spores with the receptor binding domain (RBD) of the SARS-CoV-2 spike glycoprotein displayed on their surface in fusion with the CotZ or CotY spore coat proteins as a possible tool for the development of an oral vaccine against the SARS-CoV-2 virus. The RBD was attached to the N-terminus or C-terminus of the coat proteins.

The helicase core accessory regions of the phage BFK20 DnaB-like helicase gp43 significantly affect its activity, oligomeric state and DNA binding properties.

The multifunctional phage replication protein gp43 is composed of an N-terminal prim-pol domain and a C-terminal domain similar to the SF4-type replicative helicases. We prepared four mutants all missing the prim-pol domain with the helicase core flanked by accessory N- and C-terminal regions truncated to varying extents. The shortest fragment still possessing strong ssDNA-dependent ATPase activity and helicase activity was gp43HEL519-983.

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

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.

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.

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.

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.

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.

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.

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 coat's building blocks are responsible for the formation of this structurally complex and extraordinarily resistant shell.

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.

Atomic force microscopy imaging and single molecule recognition force spectroscopy of coat proteins on the surface of Bacillus subtilis spore.

Coat assembly in Bacillus subtilis serves as a tractable model for the study of the self-assembly process of biological structures and has a significant potential for use in nano-biotechnological applications. In the present study, the morphology of B. subtilis spores was investigated by magnetically driven dynamic force microscopy (MAC mode atomic force microscopy) under physiological conditions.

A new member of the bacterial ribonuclease inhibitor family from Saccharopolyspora erythraea.

We have identified Sti, the gene of a ribonuclease inhibitor from Saccharopolyspora erythraea, by using a T7 phage display system. A specific phage has been isolated from a genome library by a biopanning procedure, using RNase Sa3, a ribonuclease from Streptomyces aureofaciens, as bait. Sti, a protein of 121 amino acid residues, with molecular mass 13059 Da, is a homolog of barstar and other microbial ribonuclease inhibitors.

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.

Conformational stability and thermodynamics of folding of ribonucleases Sa, Sa2 and Sa3.

Ribonucleases Sa, Sa2, and Sa3 are three small, extracellular enzymes produced by different strains of Streptomyces aureofaciens with amino acid sequences that are 50% identical. We have studied the unfolding of these enzymes by heat and urea to determine the conformational stability and its dependence on temperature, pH, NaCl, and the disulfide bond. All three of the Sa ribonucleases unfold reversibly by a two-state mechanism with melting temperatures, Tm, at pH 7 of 48.

Isolation and purification of two novel streptomycete RNase inhibitors, SaI14 and SaI20, and cloning, sequencing, and expression in Escherichia coli of the gene coding for SaI14.

Two new RNase inhibitors, SaI14 (Mr, approximately 14,000) and SaI20 (Mr, approximately 20,000), were isolated and purified from a Streptomyces aureofaciens strain. The gene sai14, coding for SaI14 protein, was cloned and expressed in Escherichia coli. The alignment of the deduced amino acid sequence of SaI14 with that of barstar, the RNase inhibitor from Bacillus amyloliquefaciens, showed significant similarity between them, especially in the region which contains most of the residues involved in barnase-barstar complex formation.