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20. Modulation of the lytic apparatus by the FtsEX complex within the bacterial division machinery.

Author

Alcorlo M, Martínez-Caballero S, Li J, Sham LT, Luo M, and Hermoso JA

Abstract

The FtsEX membrane complex constitutes an essential component of the ABC transporter superfamily, widely distributed among bacterial species. It governs peptidoglycan degradation for cell division, acting as a signal transmitter rather than a substrate transporter. Through the ATPase activity of FtsE, it facilitates signal transmission from the cytosol across the membrane to the periplasm, activating associated peptidoglycan hydrolases. This review concentrates on the latest structural advancements elucidating the architecture of the FtsEX complex and its interplay with lytic enzymes or regulatory counterparts. The revealed three-dimensional structures unveil a landscape wherein a precise array of intermolecular interactions, preserved across diverse bacterial species, afford meticulous spatial and temporal control over the cell division process., (© 2024 The Author(s). FEBS Letters published by John Wiley & Sons Ltd on behalf of Federation of European Biochemical Societies.)

Published
2024
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21. Molecular and structural basis of oligopeptide recognition by the Ami transporter system in pneumococci.

Author

Alcorlo M, Abdullah MR, Steil L, Sotomayor F, López-de Oro L, de Castro S, Velázquez S, Kohler TP, Jiménez E, Medina A, Usón I, Keller LE, Bradshaw JL, McDaniel LS, Camarasa MJ, Völker U, Hammerschmidt S, and Hermoso JA

Subjects
Crystallography, X-Ray, Models, Molecular, Lipoproteins, Streptococcus pneumoniae metabolism, Bacterial Proteins metabolism, Bacterial Proteins chemistry, Bacterial Proteins genetics, Oligopeptides metabolism, ATP-Binding Cassette Transporters metabolism, ATP-Binding Cassette Transporters chemistry
Abstract

ATP-binding cassette (ABC) transport systems are crucial for bacteria to ensure sufficient uptake of nutrients that are not produced de novo or improve the energy balance. The cell surface of the pathobiont Streptococcus pneumoniae (pneumococcus) is decorated with a substantial array of ABC transporters, critically influencing nasopharyngeal colonization and invasive infections. Given the auxotrophic nature of pneumococci for certain amino acids, the Ami ABC transporter system, orchestrating oligopeptide uptake, becomes indispensable in host compartments lacking amino acids. The system comprises five exposed Oligopeptide Binding Proteins (OBPs) and four proteins building the ABC transporter channel. Here, we present a structural analysis of all the OBPs in this system. Multiple crystallographic structures, capturing both open and closed conformations along with complexes involving chemically synthesized peptides, have been solved at high resolution providing insights into the molecular basis of their diverse peptide specificities. Mass spectrometry analysis of oligopeptides demonstrates the unexpected remarkable promiscuity of some of these proteins when expressed in Escherichia coli, displaying affinity for a wide range of peptides. Finally, a model is proposed for the complete Ami transport system in complex with its various OBPs. We further disclosed, through in silico modelling, some essential structural changes facilitating oligopeptide transport into the cellular cytoplasm. Thus, the structural analysis of the Ami system provides valuable insights into the mechanism and specificity of oligopeptide binding by the different OBPs, shedding light on the intricacies of the uptake mechanism and the in vivo implications for this human pathogen., Competing Interests: The authors have declared that no competing interests exist., (Copyright: © 2024 Alcorlo et al. This is an open access article distributed under the terms of the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original author and source are credited.)

Published
2024
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22. Flexible structural arrangement and DNA-binding properties of protein p6 from Bacillus subtillis phage φ29.

Author

Alcorlo M, Luque-Ortega JR, Gago F, Ortega A, Castellanos M, Chacón P, de Vega M, Blanco L, Hermoso JM, Serrano M, Rivas G, and Hermoso JA

Subjects
DNA Replication, DNA, Viral genetics, Nucleoproteins metabolism, Viral Proteins metabolism, Bacillus Phages genetics, Bacillus Phages chemistry, Bacillus subtilis virology
Abstract

The genome-organizing protein p6 of Bacillus subtilis bacteriophage φ29 plays an essential role in viral development by activating the initiation of DNA replication and participating in the early-to-late transcriptional switch. These activities require the formation of a nucleoprotein complex in which the DNA adopts a right-handed superhelix wrapping around a multimeric p6 scaffold, restraining positive supercoiling and compacting the viral genome. Due to the absence of homologous structures, prior attempts to unveil p6's structural architecture failed. Here, we employed AlphaFold2 to engineer rational p6 constructs yielding crystals for three-dimensional structure determination. Our findings reveal a novel fold adopted by p6 that sheds light on its self-association mechanism and its interaction with DNA. By means of protein-DNA docking and molecular dynamic simulations, we have generated a comprehensive structural model for the nucleoprotein complex that consistently aligns with its established biochemical and thermodynamic parameters. Besides, through analytical ultracentrifugation, we have confirmed the hydrodynamic properties of the nucleocomplex, further validating in solution our proposed model. Importantly, the disclosed structure not only provides a highly accurate explanation for previously experimental data accumulated over decades, but also enhances our holistic understanding of the structural and functional attributes of protein p6 during φ29 infection., (© The Author(s) 2024. Published by Oxford University Press on behalf of Nucleic Acids Research.)

Published
2024
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23. Verification: model-free phasing with enhanced predicted models in ARCIMBOLDO_SHREDDER.

Author

Medina A, Jiménez E, Caballero I, Castellví A, Triviño Valls J, Alcorlo M, Molina R, Hermoso JA, Sammito MD, Borges R, and Usón I

Subjects
Crystallography, X-Ray, Models, Molecular, Peptides
Abstract

Structure predictions have matched the accuracy of experimental structures from close homologues, providing suitable models for molecular replacement phasing. Even in predictions that present large differences due to the relative movement of domains or poorly predicted areas, very accurate regions tend to be present. These are suitable for successful fragment-based phasing as implemented in ARCIMBOLDO. The particularities of predicted models are inherently addressed in the new predicted_model mode, rendering preliminary treatment superfluous but also harmless. B-value conversion from predicted LDDT or error estimates, the removal of unstructured polypeptide, hierarchical decomposition of structural units from domains to local folds and systematically probing the model against the experimental data will ensure the optimal use of the model in phasing. Concomitantly, the exhaustive use of models and stereochemistry in phasing, refinement and validation raises the concern of crystallographic model bias and the need to critically establish the information contributed by the experiment. Therefore, in its predicted_model mode ARCIMBOLDO_SHREDDER will first determine whether the input model already constitutes a solution or provides a straightforward solution with Phaser. If not, extracted fragments will be located. If the landscape of solutions reveals numerous, clearly discriminated and consistent probes or if the input model already constitutes a solution, model-free verification will be activated. Expansions with SHELXE will omit the partial solution seeding phases and all traces outside their respective masks will be combined in ALIXE, as far as consistent. This procedure completely eliminates the molecular replacement search model in favour of the inferences derived from this model. In the case of fragments, an incorrect starting hypothesis impedes expansion. The predicted_model mode has been tested in different scenarios., (open access.)

Published
2022
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24. Regulation of Lytic Machineries by the FtsEX Complex in the Bacterial Divisome.

Author

Alcorlo M, Martínez-Caballero S, Molina R, and Hermoso JA

Subjects
ATP-Binding Cassette Transporters chemistry, ATP-Binding Cassette Transporters metabolism, Adenosine Triphosphatases metabolism, Bacteria metabolism, Cell Cycle Proteins metabolism, Protein Binding, Bacterial Proteins metabolism, Escherichia coli Proteins metabolism
Abstract

The essential membrane complex FtsE/FtsX (FtsEX), belonging to the ABC transporter superfamily and widespread among bacteria, plays a relevant function in some crucial cell wall remodeling processes such as cell division, elongation, or sporulation. FtsEX plays a double role by recruiting proteins to the divisome apparatus and by regulating lytic activity of the cell wall hydrolases required for daughter cell separation. Interestingly, FtsEX does not act as a transporter but uses the ATPase activity of FtsE to mechanically transmit a signal from the cytosol, through the membrane, to the periplasm that activates the attached hydrolases. While the complete molecular details of such mechanism are not yet known, evidence has been recently reported that clarify essential aspects of this complex system. In this chapter we will present recent structural advances on this topic. The three-dimensional structure of FtsE, FtsX, and some of the lytic enzymes or their cognate regulators revealed an unexpected scenario in which a delicate set of intermolecular interactions, conserved among different bacterial genera, could be at the core of this regulatory mechanism providing exquisite control in both space and time of this central process to assist bacterial survival., (© 2022. The Author(s), under exclusive license to Springer Nature Switzerland AG.)

Published
2022
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25. Structural Characterization of the Essential Cell Division Protein FtsE and Its Interaction with FtsX in Streptococcus pneumoniae.

Author

Alcorlo M, Straume D, Lutkenhaus J, Håvarstein LS, and Hermoso JA

Subjects
ATP-Binding Cassette Transporters chemistry, ATP-Binding Cassette Transporters genetics, Bacterial Proteins genetics, Cell Cycle Proteins genetics, Cell Division genetics, Protein Binding, Streptococcus pneumoniae genetics, Bacterial Proteins chemistry, Cell Cycle Proteins chemistry, Streptococcus pneumoniae chemistry
Abstract

FtsEX is a membrane complex widely conserved across diverse bacterial genera and involved in critical processes such as recruitment of division proteins and in spatial and temporal regulation of muralytic activity during cell division or sporulation. FtsEX is a member of the ABC transporter superfamily. The component FtsX is an integral membrane protein, whereas FtsE is an ATPase and is required for the transmission of a conformational signal from the cytosol through the membrane to regulate the activity of cell wall hydrolases in the periplasm. Both proteins are essential in the major human respiratory pathogenic bacterium Streptococcus pneumoniae , and FtsX interacts with the modular peptidoglycan hydrolase PcsB at the septum. Here, we report high-resolution structures of pneumococcal FtsE bound to different nucleotides. Structural analysis revealed that FtsE contains all the conserved structural motifs associated with ATPase activity and afforded interpretation of the in vivo dimeric arrangement in both the ADP and ATP states. Interestingly, three specific FtsE regions with high structural plasticity were identified that shape the cavity in which the cytosolic region of FtsX would be inserted. The residues corresponding to the FtsX coupling helix, responsible for contacting FtsE, were identified and validated by in vivo mutagenesis studies showing that this interaction is essential for cell growth and proper morphology. IMPORTANCE Bacterial cell division is a central process that requires exquisite orchestration of both the cell wall biosynthetic and lytic machineries. The essential membrane complex FtsEX, widely conserved across bacteria, plays a central role by recruiting proteins to the divisome apparatus and by regulating periplasmic muralytic activity from the cytosol. FtsEX is a member of the type VII family of the ABC-superfamily, but instead of being a transporter, it couples the ATP hydrolysis catalyzed by FtsE to mechanically transduce a conformational signal that provokes the activation of peptidoglycan (PG) hydrolases. So far, no structural information is available for FtsE. Here, we provide the structural characterization of FtsE, confirming its ATPase nature and revealing regions with high structural plasticity which are key for FtsE binding to FtsX. The complementary binding region in FtsX has also been identified and validated in vivo Our results provide evidence on how the difference between the ATP/ADP-bound states in FtsE would dramatically alter the interaction of FtsEX with the PG hydrolase PcsB in pneumococcal division., (Copyright © 2020 Alcorlo et al.)

Published
2020
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26. Class A PBPs have a distinct and unique role in the construction of the pneumococcal cell wall.

Author

Straume D, Piechowiak KW, Olsen S, Stamsås GA, Berg KH, Kjos M, Heggenhougen MV, Alcorlo M, Hermoso JA, and Håvarstein LS

Subjects
Amidohydrolases isolation & purification, Bacterial Proteins isolation & purification, Cell Division, Membrane Proteins metabolism, Uridine Diphosphate N-Acetylmuramic Acid analogs & derivatives, Uridine Diphosphate N-Acetylmuramic Acid metabolism, Amidohydrolases metabolism, Bacterial Proteins metabolism, Cell Wall metabolism, Penicillin-Binding Proteins metabolism, Peptidoglycan metabolism, Streptococcus pneumoniae physiology
Abstract

In oval-shaped Streptococcus pneumoniae , septal and longitudinal peptidoglycan syntheses are performed by independent functional complexes: the divisome and the elongasome. Penicillin-binding proteins (PBPs) were long considered the key peptidoglycan-synthesizing enzymes in these complexes. Among these were the bifunctional class A PBPs, which are both glycosyltransferases and transpeptidases, and monofunctional class B PBPs with only transpeptidase activity. Recently, however, it was established that the monofunctional class B PBPs work together with transmembrane glycosyltransferases (FtsW and RodA) from the shape, elongation, division, and sporulation (SEDS) family to make up the core peptidoglycan-synthesizing machineries within the pneumococcal divisome (FtsW/PBP2x) and elongasome (RodA/PBP2b). The function of class A PBPs is therefore now an open question. Here we utilize the peptidoglycan hydrolase CbpD that targets the septum of S. pneumoniae cells to show that class A PBPs have an autonomous role during pneumococcal cell wall synthesis. Using assays to specifically inhibit the function of PBP2x and FtsW, we demonstrate that CbpD attacks nascent peptidoglycan synthesized by the divisome. Notably, class A PBPs could process this nascent peptidoglycan from a CbpD-sensitive to a CbpD-resistant form. The class A PBP-mediated processing was independent of divisome and elongasome activities. Class A PBPs thus constitute an autonomous functional entity which processes recently formed peptidoglycan synthesized by FtsW/PBP2×. Our results support a model in which mature pneumococcal peptidoglycan is synthesized by three functional entities, the divisome, the elongasome, and bifunctional PBPs. The latter modify existing peptidoglycan but are probably not involved in primary peptidoglycan synthesis., Competing Interests: The authors declare no competing interest., (Copyright © 2020 the Author(s). Published by PNAS.)

Published
2020
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27. SEQUENCE SLIDER: expanding polyalanine fragments for phasing with multiple side-chain hypotheses.

Author

Borges RJ, Meindl K, Triviño J, Sammito M, Medina A, Millán C, Alcorlo M, Hermoso JA, Fontes MRM, and Usón I

Subjects
Algorithms, Glycosyltransferases chemistry, Lipoproteins chemistry, Protein Folding, Protein Structure, Secondary, Crystallography, X-Ray methods, Peptide Fragments chemistry, Peptides chemistry, Software
Abstract

Fragment-based molecular-replacement methods can solve a macromolecular structure quasi-ab initio. ARCIMBOLDO, using a common secondary-structure or tertiary-structure template or a library of folds, locates these with Phaser and reveals the rest of the structure by density modification and autotracing in SHELXE. The latter stage is challenging when dealing with diffraction data at lower resolution, low solvent content, high β-sheet composition or situations in which the initial fragments represent a low fraction of the total scattering or where their accuracy is low. SEQUENCE SLIDER aims to overcome these complications by extending the initial polyalanine fragment with side chains in a multisolution framework. Its use is illustrated on test cases and previously unknown structures. The selection and order of fragments to be extended follows the decrease in log-likelihood gain (LLG) calculated with Phaser upon the omission of each single fragment. When the starting substructure is derived from a remote homolog, sequence assignment to fragments is restricted by the original alignment. Otherwise, the secondary-structure prediction is matched to that found in fragments and traces. Sequence hypotheses are trialled in a brute-force approach through side-chain building and refinement. Scoring the refined models through their LLG in Phaser may allow discrimination of the correct sequence or filter the best partial structures for further density modification and autotracing. The default limits for the number of models to pursue are hardware dependent. In its most economic implementation, suitable for a single laptop, the main-chain trace is extended as polyserine rather than trialling models with different sequence assignments, which requires a grid or multicore machine. SEQUENCE SLIDER has been instrumental in solving two novel structures: that of MltC from 2.7 Å resolution data and that of a pneumococcal lipoprotein with 638 residues and 35% solvent content., (open access.)

Published
2020
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28. Structural basis of denuded glycan recognition by SPOR domains in bacterial cell division.

Author

Alcorlo M, Dik DA, De Benedetti S, Mahasenan KV, Lee M, Domínguez-Gil T, Hesek D, Lastochkin E, López D, Boggess B, Mobashery S, and Hermoso JA

Subjects
Bacillus subtilis chemistry, Bacillus subtilis metabolism, Carbohydrate Sequence, Cell Wall metabolism, Crystallography, X-Ray, Escherichia coli metabolism, Escherichia coli Proteins metabolism, Lipoproteins chemistry, Lipoproteins metabolism, Molecular Dynamics Simulation, Peptidoglycan metabolism, Protein Binding, Pseudomonas aeruginosa chemistry, Pseudomonas aeruginosa metabolism, Cell Wall chemistry, Escherichia coli chemistry, Escherichia coli Proteins chemistry, Peptidoglycan chemistry, Protein Domains
Abstract

SPOR domains are widely present in bacterial proteins that recognize cell-wall peptidoglycan strands stripped of the peptide stems. This type of peptidoglycan is enriched in the septal ring as a product of catalysis by cell-wall amidases that participate in the separation of daughter cells during cell division. Here, we document binding of synthetic denuded glycan ligands to the SPOR domain of the lytic transglycosylase RlpA from Pseudomonas aeruginosa (SPOR-RlpA) by mass spectrometry and structural analyses, and demonstrate that indeed the presence of peptide stems in the peptidoglycan abrogates binding. The crystal structures of the SPOR domain, in the apo state and in complex with different synthetic glycan ligands, provide insights into the molecular basis for recognition and delineate a conserved pattern in other SPOR domains. The biological and structural observations presented here are followed up by molecular-dynamics simulations and by exploration of the effect on binding of distinct peptidoglycan modifications.

Published
2019
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29. Structure of the Large Extracellular Loop of FtsX and Its Interaction with the Essential Peptidoglycan Hydrolase PcsB in Streptococcus pneumoniae.

Author

Rued BE, Alcorlo M, Edmonds KA, Martínez-Caballero S, Straume D, Fu Y, Bruce KE, Wu H, Håvarstein LS, Hermoso JA, Winkler ME, and Giedroc DP

Subjects
Bacterial Proteins genetics, Cell Cycle Proteins genetics, Crystallography, X-Ray, DNA Mutational Analysis, Genes, Essential, Magnetic Resonance Spectroscopy, Microbial Viability, Models, Molecular, Protein Binding, Protein Conformation, Streptococcus pneumoniae genetics, Streptococcus pneumoniae physiology, Bacterial Proteins chemistry, Bacterial Proteins metabolism, Cell Cycle Proteins chemistry, Cell Cycle Proteins metabolism, N-Acetylmuramoyl-L-alanine Amidase chemistry, N-Acetylmuramoyl-L-alanine Amidase metabolism, Streptococcus pneumoniae enzymology
Abstract

Streptococcus pneumoniae is a leading killer of infants and immunocompromised adults and has become increasingly resistant to major antibiotics. Therefore, the development of new antibiotic strategies is desperately needed. Targeting bacterial cell division is one such strategy, specifically by targeting proteins that are essential for the synthesis and breakdown of peptidoglycan. One complex important to this process is FtsEX. FtsEX comprises a cell division-regulating integral membrane protein (FtsX) and a cytoplasmic ATPase (FtsE) that resembles an ATP-binding cassette (ABC) transporter. Here, we present nuclear magnetic resonance (NMR) solution structural and crystallographic models of the large extracellular domain of FtsX, denoted extracellular loop 1 (ECL1). The structure of ECL1 reveals an upper extended β-hairpin and a lower α-helical lobe, each extending from a mixed α-β core. The helical lobe mediates a physical interaction with the peptidoglycan hydrolase PcsB via the coiled-coil domain of PcsB (PscB CC ). Characterization of S. pneumoniae strain D39-derived strains harboring mutations in the α-helical lobe shows that this subdomain is essential for cell viability and required for proper cell division of S. pneumoniae IMPORTANCE FtsX is a ubiquitous bacterial integral membrane protein involved in cell division that regulates the activity of peptidoglycan (PG) hydrolases. FtsX is representative of a large group of ABC3 superfamily proteins that function as "mechanotransmitters," proteins that relay signals from the inside to the outside of the cell. Here, we present a structural characterization of the large extracellular loop, ECL1, of FtsX from the opportunistic human pathogen S. pneumoniae We show the molecular nature of the direct interaction between the peptidoglycan hydrolase PcsB and FtsX and demonstrate that this interaction is essential for cell viability. As such, FtsX represents an attractive, conserved target for the development of new classes of antibiotics., (Copyright © 2019 Rued et al.)

Published
2019
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30. Three-dimensional structures of Lipoproteins from Streptococcus pneumoniae and Staphylococcus aureus.

Author

Bartual SG, Alcorlo M, Martínez-Caballero S, Molina R, and Hermoso JA

Subjects
Host-Pathogen Interactions, Membrane Proteins chemistry, Protein Structure, Tertiary, Virulence, Bacterial Proteins chemistry, Lipoproteins chemistry, Staphylococcus aureus chemistry, Staphylococcus aureus pathogenicity, Streptococcus pneumoniae chemistry, Streptococcus pneumoniae pathogenicity
Abstract

Bacterial lipoproteins (Lpp) compose a large family of surface-exposed proteins that are involved in diverse, but critical, cellular functions spanning from fitness to virulence. All of them present a common signature, a sequence motif, known as LipoBox, containing an invariant Cys residue that allows the protein to be covalently bound to the membrane through a thioether linkage. Despite the abundance and relevance of Lpp, there is a scarcity of structural and functional information for this family of proteins. In this review, the updated structural and functional data for Lpp from two Gram-positive pathogenic model organisms, Staphylococcus aureus and Streptococcus pneumoniae is presented. The available structural information offers a glimpse over the Lpp functional mechanisms. Their relevance in bacterial fitness, and also in virulence and host-pathogen interactions, reveals lipoproteins as very attractive targets for designing of novel antimicrobials, and interesting candidates as novel vaccine antigens., (Copyright © 2017 Elsevier GmbH. All rights reserved.)

Published
2018
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31. A single amino acid polymorphism in the glycosyltransferase CpsK defines four Streptococcus suis serotypes.

Author

Roy D, Athey TBT, Auger JP, Goyette-Desjardins G, Van Calsteren MR, Takamatsu D, Okura M, Teatero S, Alcorlo M, Hermoso JA, Segura M, Gottschalk M, and Fittipaldi N

Subjects
Alleles, Glycosyltransferases chemistry, Glycosyltransferases metabolism, Magnetic Resonance Spectroscopy, Models, Molecular, Mutation, Polymorphism, Single Nucleotide, Protein Conformation, Serogroup, Virulence, Amino Acid Substitution, Glycosyltransferases genetics, Polymorphism, Genetic, Streptococcus suis classification, Streptococcus suis genetics
Abstract

The capsular polysaccharide (CPS) is the major virulence factor of the emerging zoonotic pathogen Streptococcus suis. CPS differences are also the basis for serological differentiation of the species into 29 serotypes. Serotypes 2 and 1/2, which possess identical gene content in their cps loci, express CPSs that differ only by substitution of galactose (Gal) by N-acetylgalactosamine (GalNAc) in the CPS side chain. The same sugar substitution differentiates the CPS of serotypes 14 and 1, whose cps loci are also identical in gene content. Here, using mutagenesis, CPS structural analysis, and protein structure modeling, we report that a single amino acid polymorphism in the glycosyltransferase CpsK defines the enzyme substrate predilection for Gal or GalNAc and therefore determines CPS composition, structure, and strain serotype. We also show that the different CPS structures have similar antiphagocytic properties and that serotype switching has limited impact on the virulence of S. suis.

Published
2017
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32. Carbohydrate recognition and lysis by bacterial peptidoglycan hydrolases.

Author

Alcorlo M, Martínez-Caballero S, Molina R, and Hermoso JA

Subjects
Animals, Bacteria enzymology, Databases, Protein, Humans, N-Acetylmuramoyl-L-alanine Amidase chemistry, Protein Binding, Carbohydrate Metabolism, N-Acetylmuramoyl-L-alanine Amidase metabolism
Abstract

The major component of bacterial cell wall is peptidoglycan (PG), a complex polymer formed by long glycan chains cross-linked by peptide stems. PG is in constant equilibrium requiring well-orchestrated coordination between synthesis and degradation. The resulting cell-wall fragments can be recycled, act as messengers for bacterial communication, as effector molecules in immune response or as signaling molecules triggering antibiotics resistance. Tailoring and recycling of PG requires the cleavage of different covalent bonds of the PG sacculi by a diverse set of specific enzymes whose activities are strictly regulated. Here, we review the molecular mechanisms that govern PG remodeling focusing on the structural information available for the bacterial lytic enzymes and the mechanisms by which they recognize their substrates., (Copyright © 2017 Elsevier Ltd. All rights reserved.)

Published
2017
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33. Ionic tethering contributes to the conformational stability and function of complement C3b.

Author

López-Perrote A, Harrison RE, Subías M, Alcorlo M, Rodríguez de Córdoba S, Morikis D, and Llorca O

Subjects
Animals, Complement C3b genetics, Genetic Predisposition to Disease, Humans, Microscopy, Electron, Polymorphism, Single Nucleotide, Protein Conformation, Protein Domains physiology, Protein Stability, Thermodynamics, Complement C3b chemistry, Complement C3b metabolism, Macular Degeneration genetics, Models, Molecular
Abstract

C3b, the central component of the alternative pathway (AP) of the complement system, coexists as a mixture of conformations in solution. These conformational changes can affect interactions with other proteins and complement regulators. Here we combine a computational model for electrostatic interactions within C3b with molecular imaging to study the conformation of C3b. The computational analysis shows that the TED domain in C3b is tethered ionically to the macroglobulin (MG) ring. Monovalent counterion concentration affects the magnitude of electrostatic forces anchoring the TED domain to the rest of the C3b molecule in a thermodynamic model. This is confirmed by observing NaCl concentration dependent conformational changes using single molecule electron microscopy (EM). We show that the displacement of the TED domain is compatible with C3b binding to Factor B (FB), suggesting that the regulation of the C3bBb convertase could be affected by conditions that promote movement in the TED domain. Our molecular model also predicts mutations that could alter the positioning of the TED domain, including the common R102G polymorphism, a risk variant for developing age-related macular degeneration. The common C3b isoform, C3bS, and the risk isoform, C3bF, show distinct energetic barriers to displacement in the TED that are related to a network of electrostatic interactions at the interface of the TED and MG-ring domains of C3b. These computational predictions agree with experimental evidence that shows differences in conformation observed in C3b isoforms purified from homozygous donors. Altogether, we reveal an ionic, reversible attachment of the TED domain to the MG ring that may influence complement regulation in some mutations and polymorphisms of C3b., (Copyright © 2016 Elsevier Ltd. All rights reserved.)

Published
2017
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34. Modular Architecture and Unique Teichoic Acid Recognition Features of Choline-Binding Protein L (CbpL) Contributing to Pneumococcal Pathogenesis.

Author

Gutiérrez-Fernández J, Saleh M, Alcorlo M, Gómez-Mejía A, Pantoja-Uceda D, Treviño MA, Voß F, Abdullah MR, Galán-Bartual S, Seinen J, Sánchez-Murcia PA, Gago F, Bruix M, Hammerschmidt S, and Hermoso JA

Subjects
Animals, Binding Sites physiology, Calcium metabolism, Cell Wall metabolism, Cell Wall microbiology, Crystallography, X-Ray methods, Female, Immune Evasion physiology, Mice, Models, Molecular, Nasopharynx metabolism, Nasopharynx microbiology, Phagocytes metabolism, Phagocytes microbiology, Phosphorylcholine metabolism, Pneumococcal Infections microbiology, Respiratory Tract Infections metabolism, Respiratory Tract Infections microbiology, Virulence physiology, Carrier Proteins metabolism, Choline metabolism, Pneumococcal Infections metabolism, Streptococcus pneumoniae metabolism, Streptococcus pneumoniae pathogenicity, Teichoic Acids metabolism
Abstract

The human pathogen Streptococcus pneumoniae is decorated with a special class of surface-proteins known as choline-binding proteins (CBPs) attached to phosphorylcholine (PCho) moieties from cell-wall teichoic acids. By a combination of X-ray crystallography, NMR, molecular dynamics techniques and in vivo virulence and phagocytosis studies, we provide structural information of choline-binding protein L (CbpL) and demonstrate its impact on pneumococcal pathogenesis and immune evasion. CbpL is a very elongated three-module protein composed of (i) an Excalibur Ca 2+ -binding domain -reported in this work for the very first time-, (ii) an unprecedented anchorage module showing alternate disposition of canonical and non-canonical choline-binding sites that allows vine-like binding of fully-PCho-substituted teichoic acids (with two choline moieties per unit), and (iii) a Ltp_Lipoprotein domain. Our structural and infection assays indicate an important role of the whole multimodular protein allowing both to locate CbpL at specific places on the cell wall and to interact with host components in order to facilitate pneumococcal lung infection and transmigration from nasopharynx to the lungs and blood. CbpL implication in both resistance against killing by phagocytes and pneumococcal pathogenesis further postulate this surface-protein as relevant among the pathogenic arsenal of the pneumococcus.

Published
2016
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35. Renew or die: The molecular mechanisms of peptidoglycan recycling and antibiotic resistance in Gram-negative pathogens.

Author

Domínguez-Gil T, Molina R, Alcorlo M, and Hermoso JA

Subjects
Biological Transport, Cell Wall chemistry, Cell Wall metabolism, Gram-Negative Bacteria enzymology, Gram-Negative Bacteria genetics, Gram-Negative Bacterial Infections drug therapy, Gram-Negative Bacterial Infections microbiology, Hexosaminidases genetics, Hexosaminidases metabolism, Humans, Models, Molecular, Peptidoglycan Glycosyltransferase chemistry, Peptidoglycan Glycosyltransferase classification, Peptidoglycan Glycosyltransferase genetics, Peptidoglycan Glycosyltransferase metabolism, Protein Domains, Protein Structure, Secondary, beta-Lactamases genetics, beta-Lactamases metabolism, Anti-Bacterial Agents pharmacology, Cell Wall drug effects, Drug Resistance, Multiple, Bacterial genetics, Gene Expression Regulation, Bacterial, Gram-Negative Bacteria drug effects, Peptidoglycan metabolism
Abstract

Antimicrobial resistance is one of the most serious health threats. Cell-wall remodeling processes are tightly regulated to warrant bacterial survival and in some cases are directly linked to antibiotic resistance. Remodeling produces cell-wall fragments that are recycled but can also act as messengers for bacterial communication, as effector molecules in immune response and as signaling molecules triggering antibiotic resistance. This review is intended to provide state-of-the-art information about the molecular mechanisms governing this process and gather structural information of the different macromolecular machineries involved in peptidoglycan recycling in Gram-negative bacteria. The growing body of literature on the 3D structures of the corresponding macromolecules reveals an extraordinary complexity. Considering the increasing incidence and widespread emergence of Gram-negative multidrug-resistant pathogens in clinics, structural information on the main actors of the recycling process paves the way for designing novel antibiotics disrupting cellular communication in the recycling-resistance pathway., (Copyright © 2016. Published by Elsevier Ltd.)

Published
2016
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36. Structural insights on complement activation.

Author

Alcorlo M, López-Perrote A, Delgado S, Yébenes H, Subías M, Rodríguez-Gallego C, Rodríguez de Córdoba S, and Llorca O

Subjects
Complement C3 chemistry, Complement C3b chemistry, Humans, Protein Conformation, Protein Interaction Domains and Motifs, Protein Stability, Proteolysis, Complement Activation, Complement C3 metabolism, Complement C3b metabolism, Models, Molecular
Abstract

The proteolytic cleavage of C3 to generate C3b is the central and most important step in the activation of complement, a major component of innate immunity. The comparison of the crystal structures of C3 and C3b illustrates large conformational changes during the transition from C3 to C3b. Exposure of a reactive thio-ester group allows C3b to bind covalently to surfaces such as pathogens or apoptotic cellular debris. The displacement of the thio-ester-containing domain (TED) exposes hidden surfaces that mediate the interaction with complement factor B to assemble the C3-convertase of the alternative pathway (AP). In addition, the displacement of the TED and its interaction with the macroglobulin 1 (MG1) domain generates an extended surface in C3b where the complement regulators factor H (FH), decay accelerating factor (DAF), membrane cofactor protein (MCP) and complement receptor 1 (CR1) can bind, mediating accelerated decay of the AP C3-convertase and proteolytic inactivation of C3b. In the last few years, evidence has accumulated revealing that the structure of C3b in solution is significantly more flexible than anticipated. We review our current knowledge on C3b structural flexibility to propose a general model where the TED can display a collection of conformations around the MG ring, as well as a few specialized positions where the TED is held in one of several fixed locations. Importantly, this conformational heterogeneity in C3b impacts complement regulation by affecting the interaction with regulators., (© 2015 FEBS.)

Published
2015
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37. Structural basis for the stabilization of the complement alternative pathway C3 convertase by properdin.

Author

Alcorlo M, Tortajada A, Rodríguez de Córdoba S, and Llorca O

Subjects
Animals, Blotting, Western, CHO Cells, Cricetinae, Cricetulus, Microscopy, Electron, Transmission, Properdin immunology, Complement C3-C5 Convertases immunology, Complement C3b immunology, Complement Factor B immunology, Complement Pathway, Alternative immunology, Immunity, Innate immunology, Models, Immunological, Properdin pharmacology
Abstract

Complement is an essential component of innate immunity. Its activation results in the assembly of unstable protease complexes, denominated C3/C5 convertases, leading to inflammation and lysis. Regulatory proteins inactivate C3/C5 convertases on host surfaces to avoid collateral tissue damage. On pathogen surfaces, properdin stabilizes C3/C5 convertases to efficiently fight infection. How properdin performs this function is, however, unclear. Using electron microscopy we show that the N- and C-terminal ends of adjacent monomers in properdin oligomers conform a curly vertex that holds together the AP convertase, interacting with both the C345C and vWA domains of C3b and Bb, respectively. Properdin also promotes a large displacement of the TED (thioester-containing domain) and CUB (complement protein subcomponents C1r/C1s, urchin embryonic growth factor and bone morphogenetic protein 1) domains of C3b, which likely impairs C3-convertase inactivation by regulatory proteins. The combined effect of molecular cross-linking and structural reorganization increases stability of the C3 convertase and facilitates recruitment of fluid-phase C3 convertase to the cell surfaces. Our model explains how properdin mediates the assembly of stabilized C3/C5-convertase clusters, which helps to localize complement amplification to pathogen surfaces.

Published
2013
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38. Unique structure of iC3b resolved at a resolution of 24 Å by 3D-electron microscopy.

Author

Alcorlo M, Martínez-Barricarte R, Fernández FJ, Rodríguez-Gallego C, Round A, Vega MC, Harris CL, de Cordoba SR, and Llorca O

Subjects
Complement C3b isolation & purification, Humans, Models, Molecular, Protein Structure, Tertiary, Receptors, Complement 3b chemistry, Scattering, Small Angle, Solutions, X-Ray Diffraction, Complement C3b chemistry, Complement C3b ultrastructure, Microscopy, Electron
Abstract

Activation of C3, deposition of C3b on the target surface, and subsequent amplification by formation of a C3-cleaving enzyme (C3-convertase; C3bBb) triggers the effector functions of complement that result in inflammation and cell lysis. Concurrently, surface-bound C3b is proteolyzed to iC3b by factor I and appropriate cofactors. iC3b then interacts with the complement receptors (CR) of the Ig superfamily, CR2 (CD21), CR3 (CD11b/CD18), and CR4 (CD11c/CD18) on leukocytes, down-modulating inflammation, enhancing B cell-mediated immunity, and targeting pathogens for clearance by phagocytosis. Using EM and small-angle X-ray scattering, we now present a medium-resolution structure of iC3b (24 Å). iC3b displays a unique conformation with structural features distinct from any other C3 fragment. The macroglobulin ring in iC3b is similar to that in C3b, whereas the TED (thioester-containing domain) domain and the remnants of the CUB (complement protein subcomponents C1r/C1s, urchin embryonic growth factor and bone morphogenetic protein 1) domain have moved to locations more similar to where they were in native C3. A consequence of this large conformational change is the disruption of the factor B binding site, which renders iC3b unable to assemble a C3-convertase. This structural model also justifies the decreased interaction between iC3b and complement regulators and the recognition of iC3b by the CR of the Ig superfamily, CR2, CR3, and CR4. These data further illustrate the extraordinary conformational versatility of C3 to accommodate a great diversity of functional activities.

Published
2011
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39. Characterization of Bacillus subtilis uracil-DNA glycosylase and its inhibition by phage φ29 protein p56.

Author

Pérez-Lago L, Serrano-Heras G, Baños B, Lázaro JM, Alcorlo M, Villar L, and Salas M

Subjects
Amino Acid Motifs, Amino Acid Sequence, Bacillus Phages chemistry, Bacillus Phages genetics, Bacillus subtilis chemistry, Bacillus subtilis genetics, Bacterial Proteins antagonists & inhibitors, Bacterial Proteins chemistry, Bacterial Proteins genetics, Enzyme Inhibitors chemistry, Gene Expression Regulation, Enzymologic, Molecular Sequence Data, Protein Binding, Sequence Alignment, Uracil-DNA Glycosidase antagonists & inhibitors, Uracil-DNA Glycosidase chemistry, Uracil-DNA Glycosidase genetics, Viral Proteins chemistry, Viral Proteins genetics, Bacillus Phages metabolism, Bacillus subtilis enzymology, Bacterial Proteins metabolism, Down-Regulation, Enzyme Inhibitors metabolism, Uracil-DNA Glycosidase metabolism, Viral Proteins metabolism
Abstract

Uracil-DNA glycosylase (UDG) is a conserved DNA repair enzyme involved in uracil excision from DNA. Here, we report the biochemical characterization of UDG encoded by Bacillus subtilis, a model low G+C Gram-positive organism. The purified enzyme removes uracil preferentially from single-stranded DNA over double-stranded DNA, exhibiting higher preference for U:G than U:A mismatches. Furthermore, we have identified key amino acids necessary for B. subtilis UDG activity. Our results showed that Asp-65 and His-187 are catalytic residues involved in glycosidic bond cleavage, whereas Phe-78 would participate in DNA recognition. Recently, it has been reported that B. subtilis phage φ29 encodes an inhibitor of the UDG enzyme, named protein p56, whose role has been proposed to ensure an efficient viral DNA replication, preventing the deleterious effect caused by UDG when it eliminates uracils present in the φ29 genome. In this work, we also show that a φ29-related phage, GA-1, encodes a p56-like protein with UDG inhibition activity. In addition, mutagenesis analysis revealed that residue Phe-191 of B. subtilis UDG is critical for the interaction with φ29 and GA-1 p56 proteins, suggesting that both proteins have similar mechanism of inhibition., (© 2011 Blackwell Publishing Ltd.)

Published
2011
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40. Analytical ultracentrifugation studies of phage phi29 protein p6 binding to DNA.

Author

Alcorlo M, Jiménez M, Ortega A, Hermoso JM, Salas M, Minton AP, and Rivas G

Subjects
Magnesium chemistry, Ultracentrifugation, Viral Proteins chemistry, Bacillus Phages metabolism, DNA, Viral chemistry, Viral Proteins metabolism
Abstract

Protein p6 from Bacillus subtilis phage phi29 binds double-stranded DNA, forming a large nucleoprotein complex all along the viral genome, and has been proposed to be an architectural protein with a global role in genome organization. Here, we have characterized quantitatively the DNA binding properties of protein p6 by means of sedimentation velocity and sedimentation equilibrium experiments permitting determination of the strength and stoichiometry of complex formation. The composition dependence of protein binding to DNA is quantitatively consistent with a model in which the protein undergoes a reversible monomer-dimer self-association, and the dimeric species binds noncooperatively to the DNA. We also have found that when the anisotropic bendability periodicity of the nucleotide sequence preferred by p6 is modified, nucleocomplex formation is impaired. In addition, suppression of complex formation at high ionic strength is reversed by the addition of high concentrations of an inert polymer, mimicking the crowded intracellular environment. The results obtained in this work illustrate how macromolecular crowding could act as a metabolic buffer that can significantly extend the range of intracellular conditions under which a specific reaction may occur.

Published
2009
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41. In vivo DNA binding of bacteriophage GA-1 protein p6.

Author

Alcorlo M, Salas M, and Hermoso JM

Subjects
Bacillus genetics, Bacillus virology, DNA Replication, DNA, Superhelical, DNA, Viral genetics, DNA-Binding Proteins genetics, Gene Expression Regulation, Viral, Nalidixic Acid, Novobiocin, Protein Binding, Viral Proteins genetics, Bacillus Phages genetics, Bacillus Phages metabolism, DNA, Viral metabolism, DNA-Binding Proteins metabolism, Genome, Viral, Viral Proteins metabolism
Abstract

Bacteriophage GA-1 infects Bacillus sp. strain G1R and has a linear double-stranded DNA genome with a terminal protein covalently linked to its 5' ends. GA-1 protein p6 is very abundant in infected cells and binds DNA with no sequence specificity. We show here that it binds in vivo to the whole viral genome, as detected by cross-linking, chromatin immunoprecipitation, and real-time PCR analyses, and has the characteristics of a histone-like protein. Binding to DNA of GA-1 protein p6 shows little supercoiling dependency, in contrast to the ortholog protein of the evolutionary related Bacillus subtilis phage phi29. This feature is a property of the protein rather than the DNA or the cellular background, since phi29 protein p6 shows supercoiling-dependent binding to GA-1 DNA in Bacillus sp. strain G1R. GA-1 DNA replication is impaired in the presence of the gyrase inhibitors novobiocin and nalidixic acid, which indicates that, although noncovalently closed, the viral genome is topologically constrained in vivo. GA-1 protein p6 is also able to bind phi29 DNA in B. subtilis cells; however, as expected, the binding is less supercoiling dependent than the one observed with the phi29 protein p6. In addition, the nucleoprotein complex formed is not functional, since it is not able to transcomplement the DNA replication deficiency of a phi29 sus6 mutant. Furthermore, we took advantage of phi29 protein p6 binding to GA-1 DNA to find that the viral DNA ejection mechanism seems to take place, as in the case of phi29, with a right to left polarity in a two-step, push-pull process.

Published
2007
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42. The phage phi29 membrane protein p16.7, involved in DNA replication, is required for efficient ejection of the viral genome.

Author

Alcorlo M, González-Huici V, Hermoso JM, Meijer WJ, and Salas M

Subjects
Bacillus Phages genetics, Bacillus subtilis virology, DNA Replication physiology, Promoter Regions, Genetic, Bacillus Phages physiology, DNA, Viral metabolism, Membrane Proteins physiology, Viral Proteins physiology
Abstract

It is becoming clear that in vivo phage DNA ejection is not a mere passive process. In most cases, both phage and host proteins seem to be involved in pulling at least part of the viral DNA inside the cell. The DNA ejection mechanism of Bacillus subtilis bacteriophage phi29 is a two-step process where the linear DNA penetrates the cell with a right-left polarity. In the first step approximately 65% of the DNA is pushed into the cell. In the second step, the remaining DNA is actively pulled into the cytoplasm. This step requires protein p17, which is encoded by the right-side early operon that is ejected during the first push step. The membrane protein p16.7, also encoded by the right-side early operon, is known to play an important role in membrane-associated phage DNA replication. In this work we show that, in addition, p16.7 is required for efficient execution of the second pull step of DNA ejection.

Published
2007
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43. Phage phi29 proteins p1 and p17 are required for efficient binding of architectural protein p6 to viral DNA in vivo.

Author

González-Huici V, Alcorlo M, Salas M, and Hermoso JM

Subjects
Bacillus Phages genetics, Chromatin Immunoprecipitation, DNA Replication, Gene Expression Regulation, Viral, Mutation, Polymerase Chain Reaction, Viral Proteins genetics, Bacillus Phages metabolism, Bacillus subtilis virology, DNA, Viral metabolism, Viral Proteins metabolism
Abstract

Bacteriophage phi29 protein p6 is a viral architectural protein, which binds along the whole linear phi29 DNA in vivo and is involved in initiation of DNA replication and transcription control. Protein p1 is a membrane-associated viral protein, proposed to attach the viral genome to the cell membrane. Protein p17 is involved in pulling phi29 DNA into the cell during the injection process. We have used chromatin immunoprecipitation and real-time PCR to analyze in vivo p6 binding to DNA in cells infected with phi29 sus1 or sus17 mutants; in both cases p6 binding is significantly decreased all along phi29 DNA. phi29 DNA is topologically constrained in vivo, and p6 binding is highly increased in the presence of novobiocin, a gyrase inhibitor that produces a loss of DNA negative superhelicity. Here we show that, in cells infected with phi29 sus1 or sus17 mutants, the increase of p6 binding by novobiocin is even higher than in cells containing p1 and p17, alleviating the p6 binding deficiency. Therefore, proteins p1 and p17 could be required to restrain the proper topology of phi29 DNA, which would explain the impaired DNA replication observed in cells infected with sus1 or sus17 mutants.

Published
2004
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44. Bacteriophage Ø29 protein p6: an architectural protein involved in genome organization, replication and control of transcription.

Author

González-Huici V, Alcorlo M, Salas M, and Hermoso JM

Subjects
Bacillus Phages metabolism, Bacillus Phages physiology, DNA-Binding Proteins metabolism, DNA-Binding Proteins physiology, Genome, Viral, Viral Regulatory and Accessory Proteins metabolism, Viral Regulatory and Accessory Proteins physiology, Bacillus Phages genetics, DNA Replication, Transcription, Genetic, Viral Proteins physiology, Virus Replication
Abstract

Protein p6 of B. subtilis bacteriophage Ø29 binds to DNA forming a nucleoprotein complex in which the DNA wraps a protein core forming a right-handed superhelix, therefore restraining positive supercoiling and compacting the DNA. The protein does not specifically recognize a nucleotide sequence but rather a structural feature and it binds as a dimer through the minor groove. Protein p6 is in a monomer-dimer equilibrium that shifts to higher-order structures at a concentration of about 1 mM. These structures are probably present in vivo as the intracellular concentration of p6 is estimated to be in this range, and in fact the effective concentration should be still higher due to the macromolecular crowding. The p6 oligomers show an elongated shape compatible with a helical structure reminiscent of the superhelical DNA of the nucleoprotein complex, therefore it was proposed that protein p6 forms a scaffold on which the DNA folds. Since protein p6 is very abundant in infected cells, enough to bind the entire viral progeny, it was proposed to have an architectural role organizing and compacting the viral genome. It has been demonstrated that protein p6 binds in vivo to most, if not all, the Ø29 genome, although with different affinity, the highest one corresponding to the genome ends. Binding to plasmidic DNA was much lower, although it increased dramatically when the negative superhelicity was decreased. Hence, protein p6 binding specificity for Ø29 DNA is based on supercoiling, providing that the Ø29 genome, although topologically constrained, has a negative superhelicity lower than that of plasmid DNA. The formation of the nucleoprotein complex has functional implications in DNA replication and the control of transcription. It activates the initiation of replication that occurs at the genome ends for which the binding affinity is highest. It represses early transcription from promoter C2, and, together with protein p4, it represses transcription from promoters A2b and A2c and activates late transcription from promoter A3; therefore, protein p6 is involved in the early to late transcription switch.

Published
2004
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45. Binding of phage Phi29 architectural protein p6 to the viral genome: evidence for topological restriction of the phage linear DNA.

Author

González-Huici V, Alcorlo M, Salas M, and Hermoso JM

Subjects
Bacillus Phages metabolism, Bacillus Phages physiology, Base Sequence, Cloning, Molecular, DNA, Viral metabolism, Escherichia coli genetics, Genome, Viral, Nucleic Acid Conformation, Protein Binding, Virus Replication, Bacillus Phages genetics, DNA, Viral chemistry, Viral Proteins metabolism
Abstract

Bacillus subtilis phage Phi29 protein p6 is required for DNA replication and promotes the switch from early to late transcription. In vivo it binds all along the viral linear DNA, which suggests a global role as an architectural protein; in contrast, binding to bacterial DNA is negligible. This specificity could be due to the p6 binding preference for less negatively supercoiled DNA, as is presumably the case with viral (with respect to bacterial) DNA. Here we demonstrate that p6 binding to Phi29 DNA is greatly increased when negative supercoiling is decreased by novobiocin; in addition, gyrase is required for DNA replication. This indicates that, although non-covalently closed, the viral genome is topologically constrained in vivo. We also show that the p6 binding to different Phi29 DNA regions is modulated by the structural properties of their nucleotide sequences. The higher affinity for DNA ends is possibly related to the presence of sequences in which their bendability properties favor the formation of the p6-DNA complex, whereas the lower affinity for the transcription control region is most probably due to the presence of a rigid intrinsic DNA curvature.

Published
2004
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