Your search keyword '"Teschke CM"' showing total 78 results

1. Structural Model of Bacteriophage P22 Scaffolding Protein in a Procapsid by Magic-Angle Spinning NMR.

Author

Guo C, Whitehead RD, Struppe J, Porat-Dahlerbruch G, Hassan A, Gronenborn AM, Alexandrescu AT, Teschke CM, and Polenova T

Abstract

Icosahedral dsDNA viruses such as the tailed bacteriophages and herpesviruses have a conserved pathway to virion assembly that is initiated from a scaffolding protein driven procapsid formation. The dsDNA is actively packaged into procapsids, which undergo complex maturation reactions to form infectious virions. In bacteriophage P22, scaffolding protein (SP) directs the assembly of coat proteins into procapsids that have a T=7 icosahedral arrangement, en route to the formation of the mature P22 capsid. Other than the C-terminal helix-turn-helix involved in interaction with coat protein, the structure of the P22 303 amino acid scaffolding protein within the procapsid is not understood. Here, we present a structural model of P22 scaffolding protein encapsulated within the 23 MDa procapsid determined by magic angle spinning NMR spectroscopy. We took advantage of the 10-fold sensitivity gains afforded by the novel CPMAS CryoProbe to establish the secondary structure of P22 scaffolding protein and employed 19 F MAS NMR experiments to probe its oligomeric state in the procapsid. Our results indicate that the scaffolding protein has both α-helical and disordered segments and forms a trimer of dimers when bound to the procapsid lattice. This work provides the first structural information for P22 SP beyond the C-terminal helix-turn-helix and demonstrates the power of MAS NMR to understand higher-order viral protein assemblies involving structural components that are inaccessible to other structural biology techniques.

Published

2024

2. Templated trimerization of the phage L decoration protein on capsids.

Author

Woodbury BM, Newcomer RL, Alexandrescu AT, and Teschke CM

Abstract

The 134-residue phage L decoration protein (Dec) forms a capsid-stabilizing homotrimer that has an asymmetric tripod-like structure when bound to phage L capsids. The N-termini of the trimer subunits consist of spatially separated globular OB-fold domains that interact with the virions of phage L or the related phage P22. The C-termini of the trimer form a three-stranded intertwined spike structure that accounts for nearly all the interactions that stabilize the trimer. A Dec mutant with the spike residues 99-134 deleted (Dec 1-98 ) was used to demonstrate that the stable globular OB-fold domain folds independently of the C-terminal residues. However, Dec 1-98 was unable to bind phage P22 virions, indicating the C-terminal spike is essential for stable capsid interaction. The full-length Dec trimer is disassembled into monomers by acidification to pH <2. These monomers retain the folded globular OB-fold domain structure, but the spike is unfolded. Increasing the pH of the Dec monomer solution to pH 6 allowed for slow trimer formation in vitro over the course of days. The infectious cycle of phage L is only around an hour, however, implying Dec trimer assembly in vivo is templated by the phage capsid. The Thermodynamic Hypothesis holds that protein folding is determined by the amino acid sequence. Dec serves as an unusual example of an oligomeric folding step that is kinetically accelerated by a viral capsid template. The capsid templating mechanism could satisfy the flexibility needed for Dec to adapt to the unusual quasi-symmetric binding site on the mature phage L capsid., Competing Interests: CONFLICT OF INTEREST The authors declare no potential conflict of interest.

Published

2024

3. Bacteriophage P22 SieA-mediated superinfection exclusion.

Author

Leavitt JC, Woodbury BM, Gilcrease EB, Bridges CM, Teschke CM, and Casjens SR

Subjects

Humans, Prophages genetics, Prophages metabolism, Membrane Proteins metabolism, DNA metabolism, Amino Acids metabolism, Bacteriophage P22 genetics, Superinfection, Bacteriophages genetics

Abstract

Many temperate phages encode prophage-expressed functions that interfere with superinfection of the host bacterium by external phages. Salmonella phage P22 has four such systems that are expressed from the prophage in a lysogen that are encoded by the c2 (repressor), gtrABC , sieA , and sieB genes. Here we report that the P22-encoded SieA protein is necessary and sufficient for exclusion by the SieA system and that it is an inner membrane protein that blocks DNA injection by P22 and its relatives, but has no effect on infection by other tailed phage types. The P22 virion injects its DNA through the host cell membranes and periplasm via a conduit assembled from three "ejection proteins" after their release from the virion. Phage P22 mutants that overcome the SieA block were isolated, and they have amino acid changes in the C-terminal regions of the gene 16 and 20 encoded ejection proteins. Three different single-amino acid changes in these proteins are required to obtain nearly full resistance to SieA. Hybrid P22 phages that have phage HK620 ejection protein genes are also partially resistant to SieA. There are three sequence types of extant phage-encoded SieA proteins that are less than 30% identical to one another, yet comparison of two of these types found no differences in phage target specificity. Our data strongly suggest a model in which the inner membrane protein SieA interferes with the assembly or function of the periplasmic gp20 and membrane-bound gp16 DNA delivery conduit.IMPORTANCEThe ongoing evolutionary battle between bacteria and the viruses that infect them is a critical feature of bacterial ecology on Earth. Viruses can kill bacteria by infecting them. However, when their chromosomes are integrated into a bacterial genome as a prophage, viruses can also protect the host bacterium by expressing genes whose products defend against infection by other viruses. This defense property is called "superinfection exclusion." A significant fraction of bacteria harbor prophages that encode such protective systems, and there are many different molecular strategies by which superinfection exclusion is mediated. This report is the first to describe the mechanism by which bacteriophage P22 SieA superinfection exclusion protein protects its host bacterium from infection by other P22-like phages. The P22 prophage-encoded inner membrane SieA protein prevents infection by blocking transport of superinfecting phage DNA across the inner membrane during injection., Competing Interests: The authors declare no conflict of interest.

Published

2024

4. Molecular Architecture of Salmonella Typhimurium Virus P22 Genome Ejection Machinery.

Author

Iglesias SM, Lokareddy RK, Yang R, Li F, Yeggoni DP, David Hou CF, Leroux MN, Cortines JR, Leavitt JC, Bird M, Casjens SR, White S, Teschke CM, and Cingolani G

Subjects

Capsid Proteins chemistry, Viral Tail Proteins genetics, Bacteriophage P22 genetics, Bacteriophage P22 chemistry, Bacteriophage P22 metabolism, Salmonella typhimurium virology

Abstract

Bacteriophage P22 is a prototypical member of the Podoviridae superfamily. Since its discovery in 1952, P22 has become a paradigm for phage transduction and a model for icosahedral viral capsid assembly. Here, we describe the complete architecture of the P22 tail apparatus (gp1, gp4, gp10, gp9, and gp26) and the potential location and organization of P22 ejection proteins (gp7, gp20, and gp16), determined using cryo-EM localized reconstruction, genetic knockouts, and biochemical analysis. We found that the tail apparatus exists in two equivalent conformations, rotated by ∼6° relative to the capsid. Portal protomers make unique contacts with coat subunits in both conformations, explaining the 12:5 symmetry mismatch. The tail assembles around the hexameric tail hub (gp10), which folds into an interrupted β-propeller characterized by an apical insertion domain. The tail hub connects proximally to the dodecameric portal protein and head-to-tail adapter (gp4), distally to the trimeric tail needle (gp26), and laterally to six trimeric tailspikes (gp9) that attach asymmetrically to gp10 insertion domain. Cryo-EM analysis of P22 mutants lacking the ejection proteins gp7 or gp20 and biochemical analysis of purified recombinant proteins suggest that gp7 and gp20 form a molecular complex associated with the tail apparatus via the portal protein barrel. We identified a putative signal transduction pathway from the tailspike to the tail needle, mediated by three flexible loops in the tail hub, that explains how lipopolysaccharide (LPS) is sufficient to trigger the ejection of the P22 DNA in vitro., Competing Interests: Declaration of Competing Interest The authors declare that they have no known competing financial interests or personal relationships that could have appeared to influence the work reported in this paper., (Copyright © 2023 Elsevier Ltd. All rights reserved.)

Published

2023

5. Bacteriophage P22 SieA mediated superinfection exclusion.

Author

Leavitt JC, Woodbury BM, Gilcrease EB, Bridges CM, Teschke CM, and Casjens SR

Abstract

Many temperate phages encode prophage-expressed functions that interfere with superinfection of the host bacterium by external phages. Salmonella phage P22 has four such systems that are expressed from the prophage in a lysogen that are encoded by the c2 (repressor), gtrABC , sieA , and sieB genes. Here we report that the P22-encoded SieA protein is the only phage protein required for exclusion by the SieA system, and that it is an inner membrane protein that blocks DNA injection by P22 and its relatives, but has no effect on infection by other tailed phage types. The P22 virion injects its DNA through the host cell membranes and periplasm via a conduit assembled from three "ejection proteins" after their release from the virion. Phage P22 mutants were isolated that overcome the SieA block, and they have amino acid changes in the C-terminal regions of the gene 16 and 20 encoded ejection proteins. Three different single amino acid changes in these proteins are required to obtain nearly full resistance to SieA. Hybrid P22 phages that have phage HK620 ejection protein genes are also partially resistant to SieA. There are three sequence types of extant phage-encoded SieA proteins that are less than 30% identical to one another, yet comparison of two of these types found no differences in target specificity. Our data are consistent with a model in which the inner membrane protein SieA interferes with the assembly or function of the periplasmic gp20 and membrane-bound gp16 DNA delivery conduit.

Published

2023

6. NMR detection and conformational dependence of two, three, and four-bond isotope shifts due to deuteration of backbone amides.

Author

Alexandrescu AT, Dregni AJ, and Teschke CM

Subjects

Deuterium chemistry, Nuclear Magnetic Resonance, Biomolecular methods, Hydrogen chemistry, Protein Conformation, Hydrogen Bonding, Amides chemistry, Proteins chemistry

Abstract

NMR isotope shifts occur due to small differences in nuclear shielding when nearby atoms are different isotopes. For molecules dissolved in 1:1 H 2 O:D 2 O, the resulting mixture of N-H and N-D isotopes leads to a small splitting of resonances from adjacent nuclei. We used multidimensional NMR to measure isotope shifts for the proteins CUS-3iD and CspA. We observed four-bond 4 ∆N(ND) isotope shifts in high-resolution 2D 15 N-TROSY experiments of the perdeuterated proteins that correlate with the torsional angle psi. Three-bond 3 ∆C'(ND) isotope shifts detected in H(N)CO spectra correlate with the intraresidue H-O distance, and to a lesser extent with the dihedral angle phi. The conformational dependence of the isotope shifts agree with those previously reported in the literature. Both the 4 ∆N(ND) and 3 ∆C'(ND) isotope shifts are sensitive to distances between the atoms giving rise to the isotope shifts and the atoms experiencing the splitting, however, these distances are strongly correlated with backbone dihedral angles making it difficult to resolve distance from stereochemical contributions to the isotope shift. H(NCA)CO spectra were used to measure two-bond 2 ∆C'(ND) isotope shifts and [D]/[H] fractionation factors. Neither parameter showed significant differences for hydrogen-bonded sites, or changes over a 25° temperature range, suggesting they are not sensitive to hydrogen bonding. Finally, the quartet that arises from the combination of 2 ∆C'(ND) and 3 ∆C'(ND) isotope shifts in H(CA)CO spectra was used to measure synchronized hydrogen exchange for the sequence neighbors A315-S316 in the protein CUS-3iD. In many of our experiments we observed minor resonances due to the 10% D 2 O used for the sample deuterium lock, indicating isotope shifts can be a source of spectral heterogeneity in standard NMR experiments. We suggest that applications of isotope shifts such as conformational analysis and correlated hydrogen exchange could benefit from the larger magnetic fields becoming available., (© 2023. The Author(s), under exclusive licence to Springer Nature B.V.)

Published

2023

7. High-resolution cryo-EM structure of the Shigella virus Sf6 genome delivery tail machine.

Author

Li F, Hou CD, Yang R, Whitehead R 3rd, Teschke CM, and Cingolani G

Abstract

Sf6 is a bacterial virus that infects the human pathogen Shigella flexneri. Here, we describe the cryo-electron microscopy structure of the Sf6 tail machine before DNA ejection, which we determined at a 2.7-angstrom resolution. We built de novo structures of all tail components and resolved four symmetry-mismatched interfaces. Unexpectedly, we found that the tail exists in two conformations, rotated by ~6° with respect to the capsid. The two tail conformers are identical in structure but differ solely in how the portal and head-to-tail adaptor carboxyl termini bond with the capsid at the fivefold vertex, similar to a diamond held over a five-pronged ring in two nonidentical states. Thus, in the mature Sf6 tail, the portal structure does not morph locally to accommodate the symmetry mismatch but exists in two energetic minima rotated by a discrete angle. We propose that the design principles of the Sf6 tail are conserved across P22-like Podoviridae.

Published

2022

8. Tryptophan Residues Are Critical for Portal Protein Assembly and Incorporation in Bacteriophage P22.

Author

Woodbury BM, Motwani T, Leroux MN, Barnes LF, Lyktey NA, Banerjee S, Dedeo CL, Jarrold MF, and Teschke CM

Subjects

Capsid metabolism, Capsid Proteins genetics, Tryptophan analysis, Tryptophan metabolism, Virus Assembly, Bacteriophage P22 genetics, Herpesvirus 1, Human metabolism

Abstract

The oligomerization and incorporation of the bacteriophage P22 portal protein complex into procapsids (PCs) depends upon an interaction with scaffolding protein, but the region of the portal protein that interacts with scaffolding protein has not been defined. In herpes simplex virus 1 (HSV-1), conserved tryptophan residues located in the wing domain are required for portal-scaffolding protein interactions. In this study, tryptophan residues (W) present at positions 41, 44, 207 and 211 within the wing domain of the bacteriophage P22 portal protein were mutated to both conserved and non-conserved amino acids. Substitutions at each of these positions were shown to impair portal function in vivo, resulting in a lethal phenotype by complementation. The alanine substitutions caused the most severe defects and were thus further characterized. An analysis of infected cell lysates for the W to A mutants revealed that all the portal protein variants except W211A, which has a temperature-sensitive incorporation defect, were successfully recruited into procapsids. By charge detection mass spectrometry, all W to A mutant portal proteins were shown to form stable dodecameric rings except the variant W41A, which dissociated readily to monomers. Together, these results suggest that for P22 conserved tryptophan, residues in the wing domain of the portal protein play key roles in portal protein oligomerization and incorporation into procapsids, ultimately affecting the functionality of the portal protein at specific stages of virus assembly.

Published

2022

9. Pulse-field gradient nuclear magnetic resonance of protein translational diffusion from native to non-native states.

Author

Whitehead RD 3rd, Teschke CM, and Alexandrescu AT

Subjects

Diffusion, Magnetic Resonance Spectroscopy, Proteins, Urea, Dimethyl Sulfoxide, Protein Biosynthesis

Abstract

Hydrodynamic radii (R h -values) calculated from diffusion coefficients measured by pulse-field-gradient nuclear magnetic resonance are compared for folded and unfolded proteins. For native globular proteins, the R h -values increase as a power of 0.35 with molecular size, close to the scaling factor of 0.33 predicted from polymer theory. Unfolded proteins were studied under four sets of conditions: in the absence of denaturants, in the presence of 6 M urea, in 95% dimethyl sulfoxide (DMSO), and in 40% hexafluoroisopropanol (HFIP). Scaling factors under all four unfolding conditions are similar (0.49-0.53) approaching the theoretical value of 0.60 for a fully unfolded random coil. Persistence lengths are also similar, except smaller in 95% DMSO, suggesting that the polypeptides are more disordered on a local scale with this solvent. Three of the proteins in our unfolded set have an asymmetric sequence-distribution of charged residues. While these proteins behave normally in water and 6 M urea, they give atypically low R h -values in 40% HFIP and 95% DMSO suggesting they are forming electrostatic hairpins, favored by their asymmetric sequence charge distribution and the low dielectric constants of DMSO and HFIP. While diffusion-ordered NMR spectroscopy can separate small molecules, we show a number of factors combine to make protein-sized molecules much more difficult to resolve in mixtures. Finally, we look at the temperature dependence of apparent diffusion coefficients. Small molecules show a linear temperature response, while large proteins show abnormally large apparent diffusion coefficients at high temperatures due to convection, suggesting diffusion reference standards are only useful near 25°C., (© 2022 The Protein Society.)

Published

2022

10. Intravirion DNA Can Access the Space Occupied by the Bacteriophage P22 Ejection Proteins.

Author

Leavitt JC, Gilcrease EB, Woodbury BM, Teschke CM, and Casjens SR

Subjects

Bacteriophage P22 chemistry, Capsid Proteins genetics, Cryoelectron Microscopy, DNA Packaging, DNA, Viral metabolism, Genetic Techniques, Viral Proteins metabolism, Bacteriophage P22 genetics, DNA, Viral genetics, Viral Proteins genetics, Virion genetics

Abstract

Tailed double-stranded DNA bacteriophages inject some proteins with their dsDNA during infection. Phage P22 injects about 12, 12, and 30 molecules of the proteins encoded by genes 7 , 16 and 20 , respectively. After their ejection from the virion, they assemble into a trans-periplasmic conduit through which the DNA passes to enter the cytoplasm. The location of these proteins in the virion before injection is not well understood, although we recently showed they reside near the portal protein barrel in DNA-filled heads. In this report we show that when these proteins are missing from the virion, a longer than normal DNA molecule is encapsidated by the P22 headful DNA packaging machinery. Thus, the ejection proteins occupy positions within the virion that can be occupied by packaged DNA when they are absent.

Published

2021

11. Keeping It Together: Structures, Functions, and Applications of Viral Decoration Proteins.

Author

Dedeo CL, Teschke CM, and Alexandrescu AT

Subjects

Animals, Capsid chemistry, Capsid Proteins chemistry, Capsid Proteins genetics, DNA Packaging, DNA, Viral, Gene Transfer, Horizontal, Host-Pathogen Interactions, Mice, Models, Molecular, Protein Folding, Structure-Activity Relationship, Virion, Virus Assembly, DNA Viruses genetics, Viral Proteins chemistry, Viral Proteins genetics

Abstract

Decoration proteins are viral accessory gene products that adorn the surfaces of some phages and viral capsids, particularly tailed dsDNA phages. These proteins often play a "cementing" role, reinforcing capsids against accumulating internal pressure due to genome packaging, or environmental insults such as extremes of temperature or pH. Many decoration proteins serve alternative functions, including target cell recognition, participation in viral assembly, capsid size determination, or modulation of host gene expression. Examples that currently have structures characterized to high-resolution fall into five main folding motifs: β-tulip, β-tadpole, OB-fold, Ig-like, and a rare knotted α-helical fold. Most of these folding motifs have structure homologs in virus and target cell proteins, suggesting horizontal gene transfer was important in their evolution. Oligomerization states of decoration proteins range from monomers to trimers, with the latter most typical. Decoration proteins bind to a variety of loci on capsids that include icosahedral 2-, 3-, and 5-fold symmetry axes, as well as pseudo-symmetry sites. These binding sites often correspond to "weak points" on the capsid lattice. Because of their unique abilities to bind virus surfaces noncovalently, decoration proteins are increasingly exploited for technology, with uses including phage display, viral functionalization, vaccination, and improved nanoparticle design for imaging and drug delivery. These applications will undoubtedly benefit from further advances in our understanding of these versatile augmenters of viral functions.

Published

2020

12. NMR Mapping of Disordered Segments from a Viral Scaffolding Protein Enclosed in a 23 MDa Procapsid.

Author

Whitehead RD 3rd, Teschke CM, and Alexandrescu AT

Subjects

Bacteriophage P22 metabolism, Capsid metabolism, Intrinsically Disordered Proteins chemistry, Magnetic Resonance Spectroscopy methods, Protein Binding, Protein Domains, Viral Structural Proteins metabolism, Bacteriophage P22 chemistry, Capsid chemistry, Protein Folding, Viral Structural Proteins chemistry

Abstract

Scaffolding proteins (SPs) are required for the capsid shell assembly of many tailed double-stranded DNA bacteriophages, some archaeal viruses, herpesviruses, and adenoviruses. Despite their importance, only one high-resolution structure is available for SPs within procapsids. Here, we use the inherent size limit of NMR to identify mobile segments of the 303-residue phage P22 SP free in solution and when incorporated into a ∼23 MDa procapsid complex. Free SP gives NMR signals from its acidic N-terminus (residues 1-40) and basic C-terminus (residues 264-303), whereas NMR signals from the middle segment (residues 41-263) are missing because of intermediate conformational exchange on the NMR chemical shift timescale. When SP is incorporated into P22 procapsids, NMR signals from the C-terminal helix-turn-helix domain disappear because of binding to the procapsid interior. Signals from the N-terminal domain persist, indicating that this segment retains flexibility when bound to procapsids. The unstructured character of the N-terminus, coupled with its high content of negative charges, is likely important for dissociation and release of SP during the double-stranded DNA genome packaging step accompanying phage maturation., (Copyright © 2019 Biophysical Society. Published by Elsevier Inc. All rights reserved.)

Published

2019

13. Portal Protein: The Orchestrator of Capsid Assembly for the dsDNA Tailed Bacteriophages and Herpesviruses.

Author

Dedeo CL, Cingolani G, and Teschke CM

Subjects

DNA, Viral genetics, Herpesviridae chemistry, Models, Molecular, Protein Conformation, Bacteriophages genetics, Capsid physiology, Capsid Proteins genetics, DNA, Herpesviridae genetics, Virus Assembly

Abstract

Tailed, double-stranded DNA bacteriophages provide a well-characterized model system for the study of viral assembly, especially for herpesviruses and adenoviruses. A wealth of genetic, structural, and biochemical work has allowed for the development of assembly models and an understanding of the DNA packaging process. The portal complex is an essential player in all aspects of bacteriophage and herpesvirus assembly. Despite having low sequence similarity, portal structures across bacteriophages share the portal fold and maintain a conserved function. Due to their dynamic role, portal proteins are surprisingly plastic, and their conformations change for each stage of assembly. Because the maturation process is dependent on the portal protein, researchers have been working to validate this protein as a potential antiviral drug target. Here we review recent work on the role of portal complexes in capsid assembly, including DNA packaging, as well as portal ring assembly and incorporation and analysis of portal structures.

Published

2019

14. Of capsid structure and stability: The partnership between charged residues of E-loop and P-domain of the bacteriophage P22 coat protein.

Author

Asija K and Teschke CM

Subjects

Bacteriophage P22 chemistry, Bacteriophage P22 genetics, Bacteriophage P22 ultrastructure, Capsid metabolism, Capsid Proteins genetics, Capsid Proteins metabolism, Models, Molecular, Protein Domains, Protein Stability, Virion chemistry, Virion genetics, Virion metabolism, Bacteriophage P22 metabolism, Capsid chemistry, Capsid Proteins chemistry

Abstract

Tailed dsDNA bacteriophages and herpesviruses form capsids using coat proteins that have the HK97 fold. In these viruses, the coat proteins first assemble into procapsids, which subsequently mature during DNA packaging. Generally interactions between the coat protein E-loop of one subunit and the P-domain of an adjacent subunit help stabilize both capsomers and capsids. Based on a recent 3.3 Å cryo-EM structure of the bacteriophage P22 virion, E-loop amino acids E52, E59 and E72 were suggested to stabilize the capsid through intra-capsomer salt bridges with the P-domain residues R102, R109 and K118. The glutamic acid residues were each mutated to alanine to test this hypothesis. The substitutions resulted in a WT phenotype and did not destabilize capsids; rather, the alanine substituted coat proteins increased the stability of procapsids and virions. These results indicate that different types of interactions must be used between the E-loop and P-domain to stabilize phage P22 procapsids and virions., (Copyright © 2019 Elsevier Inc. All rights reserved.)

Published

2019

15. A Hydrophobic Network: Intersubunit and Intercapsomer Interactions Stabilizing the Bacteriophage P22 Capsid.

Author

Asija K and Teschke CM

Subjects

Bacteriophage P22 genetics, Hydrophobic and Hydrophilic Interactions, Protein Domains, Protein Structure, Secondary, Viral Proteins genetics, Bacteriophage P22 chemistry, Protein Folding, Viral Proteins chemistry

Abstract

Double-stranded DNA (dsDNA) tailed phages and herpesviruses assemble their capsids using coat proteins that have the ubiquitous HK97 fold. Though this fold is common, we do not have a thorough understanding of the different ways viruses adapt it to maintain stability in various environments. The HK97-fold E-loop, which connects adjacent subunits at the outer periphery of capsomers, has been implicated in capsid stability. Here, we show that in bacteriophage P22, residue W61 at the tip of the E-loop plays a role in stabilizing procapsids and in maturation. We hypothesize that a hydrophobic pocket is formed by residues I366 and W410 in the P domain of a neighboring subunit within a capsomer, into which W61 fits like a peg. In addition, W61 likely bridges to residues A91 and L401 in P-domain loops of an adjacent capsomer, thereby linking the entire capsid together with a network of hydrophobic interactions. There is conservation of this hydrophobic network in the distantly related P22-like phages, indicating that this structural feature is likely important for stabilizing this family of phages. Thus, our data shed light on one of the varied elegant mechanisms used in nature to consistently build stable viral genome containers through subtle adaptation of the HK97 fold. IMPORTANCE Similarities in assembly reactions and coat protein structures of the dsDNA tailed phages and herpesviruses make phages ideal models to understand capsid assembly and identify potential targets for antiviral drug discovery. The coat protein E-loops of these viruses are involved in both intra- and intercapsomer interactions. In phage P22, hydrophobic interactions peg the coat protein subunits together within a capsomer, where the E-loop hydrophobic residue W61 of one subunit packs into a pocket of hydrophobic residues I366 and W410 of the adjacent subunit. W61 also makes hydrophobic interactions with A91 and L401 of a subunit in an adjacent capsomer. We show these intra- and intercapsomer hydrophobic interactions form a network crucial to capsid stability and proper assembly., (Copyright © 2019 American Society for Microbiology.)

Published

2019

16. The amazing HK97 fold: versatile results of modest differences.

Author

Duda RL and Teschke CM

Subjects

Models, Molecular, Protein Folding, Archaeal Viruses chemistry, Bacteriophages chemistry, Capsid chemistry, Capsid Proteins chemistry, Herpesviridae chemistry

Abstract

dsDNA Bacteriophages, some dsDNA archaeal viruses and the Herpesviruses share many features including a common capsid assembly pathway and coat protein fold. The coat proteins of these viruses, which have the HK97 fold, co-assemble with a free or attached scaffolding protein and other capsid proteins into a precursor capsid, known as a procapsid or prohead. The procapsid is a metastable state that increases in stability as a result of morphological changes that occur during the dsDNA packaging reaction. We review evidence from several systems indicating that proper contacts acquired in the assembly of the procapsid are critical to forming the correct morphology in the mature capsid., (Copyright © 2019 Elsevier B.V. All rights reserved.)

Published

2019

17. Architect of Virus Assembly: the Portal Protein Nucleates Procapsid Assembly in Bacteriophage P22.

Author

Motwani T and Teschke CM

Subjects

Bacteriophage P22 metabolism, Capsid metabolism, Bacteriophage P22 chemistry, Capsid chemistry, Virus Assembly

Abstract

Tailed double-stranded DNA (dsDNA) bacteriophages, herpesviruses, and adenoviruses package their genetic material into a precursor capsid through a dodecameric ring complex called the portal protein, which is located at a unique 5-fold vertex. In several phages and viruses, including T4, Φ29, and herpes simplex virus 1 (HSV-1), the portal forms a nucleation complex with scaffolding proteins (SPs) to initiate procapsid (PC) assembly, thereby ensuring incorporation of only one portal ring per capsid. However, for bacteriophage P22, the role of its portal protein in initiation of procapsid assembly is unclear. We have developed an in vitro P22 assembly assay where portal protein is coassembled into procapsid-like particles (PLPs). Scaffolding protein also catalyzes oligomerization of monomeric portal protein into dodecameric rings, possibly forming a scaffolding protein-portal protein nucleation complex that results in one portal ring per P22 procapsid. Here, we present evidence substantiating that the P22 portal protein, similarly to those of other dsDNA viruses, can act as an assembly nucleator. The presence of the P22 portal protein is shown to increase the rate of particle assembly and contribute to proper morphology of the assembled particles. Our results highlight a key function of portal protein as an assembly initiator, a feature that is likely conserved among these classes of dsDNA viruses. IMPORTANCE The existence of a single portal ring is essential to the formation of infectious virions in the tailed double-stranded DNA (dsDNA) phages, herpesviruses, and adenoviruses and, as such, is a viable antiviral therapeutic target. How only one portal is selectively incorporated at a unique vertex is unclear. In many dsDNA viruses and phages, the portal protein acts as an assembly nucleator. However, early work on phage P22 assembly in vivo indicated that the portal protein did not function as a nucleator for procapsid (PC) assembly, leading to the suggestion that P22 uses a unique mechanism for portal incorporation. Here, we show that portal protein nucleates assembly of P22 procapsid-like particles (PLPs). Addition of portal rings to an assembly reaction increases the rate of formation and yield of particles and corrects improper particle morphology. Our data suggest that procapsid assembly may universally initiate with a nucleation complex composed minimally of portal and scaffolding proteins (SPs)., (Copyright © 2019 American Society for Microbiology.)

Published

2019

18. Conservation and Divergence of the I-Domain Inserted into the Ubiquitous HK97 Coat Protein Fold in P22-Like Bacteriophages.

Author

Tripler TN, Kaplan AR, Alexandrescu AT, and Teschke CM

Subjects

Nuclear Magnetic Resonance, Biomolecular, Protein Domains, Protein Structure, Secondary, Bacteriophage P22 chemistry, Capsid chemistry, Protein Folding, Viral Envelope Proteins chemistry

Abstract

Despite very low sequence homology, the major capsid proteins of double-stranded DNA (dsDNA) bacteriophages, some archaeal viruses, and the herpesviruses share a structural motif, the HK97 fold. Bacteriophage P22, a paradigm for this class of viruses, belongs to a phage gene cluster that contains three homology groups: P22-like, CUS-3-like, and Sf6-like. The coat protein of each phage has an inserted domain (I-domain) that is more conserved than the rest of the coat protein. In P22, loops in the I-domain are critical for stabilizing intra- and intersubunit contacts that guide proper capsid assembly. The nuclear magnetic resonance (NMR) structures of the P22, CUS-3, and Sf6 I-domains reveal that they are all six-stranded, anti-parallel β-barrels. Nevertheless, significant structural differences occur in loops connecting the β-strands, in surface electrostatics used to dock the I-domains with their respective coat protein core partners, and in sequence motifs displayed on the capsid surfaces. Our data highlight the structural diversity of I-domains that could lead to variations in capsid assembly mechanisms and capsid surfaces adapted for specific phage functions. IMPORTANCE Comparative studies of protein structures often provide insights into their evolution. The HK97 fold is a structural motif used to form the coat protein shells that encapsidate the genomes of many dsDNA phages and viruses. The structure and function of coat proteins based on the HK97 fold are often embellished by the incorporation of I-domains. In the present work we compare I-domains from three phages representative of highly divergent P22-like homology groups. While the three I-domains share a six-stranded β-barrel skeleton, there are differences (i) in structure elements at the periphery of the conserved fold, (ii) in the locations of disordered loops important in capsid assembly and conformational transitions, (iii) in surfaces charges, and (iv) in sequence motifs that are potential ligand-binding sites. These structural modifications on the rudimentary I-domain fold suggest that considerable structural adaptability was needed to fulfill the versatile range of functional requirements for distinct phages., (Copyright © 2019 American Society for Microbiology.)

Published

2019

19. The phage L capsid decoration protein has a novel OB-fold and an unusual capsid binding strategy.

Author

Newcomer RL, Schrad JR, Gilcrease EB, Casjens SR, Feig M, Teschke CM, Alexandrescu AT, and Parent KN

Subjects

Capsid ultrastructure, Caudovirales ultrastructure, Cryoelectron Microscopy, DNA, Viral metabolism, Imaging, Three-Dimensional, Magnetic Resonance Spectroscopy, Protein Binding, Protein Multimerization, Capsid metabolism, Capsid Proteins chemistry, Capsid Proteins metabolism, Caudovirales physiology, Virus Assembly

Abstract

The major coat proteins of dsDNA tailed phages (order Caudovirales ) and herpesviruses form capsids by a mechanism that includes active packaging of the dsDNA genome into a precursor procapsid, followed by expansion and stabilization of the capsid. These viruses have evolved diverse strategies to fortify their capsids, such as non-covalent binding of auxiliary 'decoration' (Dec) proteins. The Dec protein from the P22-like phage L has a highly unusual binding strategy that distinguishes between nearly identical three-fold and quasi-three-fold sites of the icosahedral capsid. Cryo-electron microscopy and three-dimensional image reconstruction were employed to determine the structure of native phage L particles. NMR was used to determine the structure/dynamics of Dec in solution. The NMR structure and the cryo-EM density envelope were combined to build a model of the capsid-bound Dec trimer. Key regions that modulate the binding interface were verified by site-directed mutagenesis., Competing Interests: RN, JS, EG, SC, MF, CT, AA, KP No competing interests declared, (© 2019, Newcomer et al.)

Published

2019

20. NMR assignments for monomeric phage L decoration protein.

Author

Newcomer RL, Belato HB, Teschke CM, and Alexandrescu AT

Subjects

Amino Acid Sequence, Hydrogen-Ion Concentration, Bacteriophage lambda, Nuclear Magnetic Resonance, Biomolecular, Viral Proteins chemistry

Abstract

Phage L encodes a trimeric 43 kDa decoration protein (Dec) that noncovalently binds and stabilizes the capsids of the homologous phages L and P22 in vitro. At physiological pH Dec was unsuitable for NMR. We were able to obtain samples amenable for NMR spectroscopy by unfolding Dec to pH 2 and refolding it to pH 4. Our unfolding/refolding protocol converted trimeric Dec to a folded 14.4 kDa monomer. We verified that the acid-unfolding protocol did not perturb the secondary structure, or the capsid-binding function of refolded Dec. We were able to obtain complete 1 H, 15 N, and 13 C assignments for the Dec monomer, as well as information on its secondary structure and dynamics based on chemical shift assignments. The assigned NMR spectrum is being used to determine the three-dimensional structure of Dec, which is important for understanding how the trimer binds phage capsids and for the use of the protein as a platform for phage-display nanotechnology.

Published

2018

21. Lessons from bacteriophages part 1: Deriving utility from protein structure, function, and evolution.

Author

Asija K and Teschke CM

Subjects

Animals, Bacteriophages immunology, Capsid Proteins chemistry, Capsid Proteins genetics, Capsid Proteins physiology, Evolution, Molecular, Genome, Viral, Humans, Models, Molecular, Protein Conformation, Vaccines, Virus-Like Particle chemistry, Vaccines, Virus-Like Particle genetics, Vaccines, Virus-Like Particle immunology, Virus Assembly genetics, Virus Assembly physiology, Bacteriophages genetics, Bacteriophages physiology

Abstract

Competing Interests: The authors have declared that no competing interests exist.

Published

2018

22. Lessons from bacteriophages part 2: A saga of scientific breakthroughs and prospects for their use in human health.

Author

Asija K and Teschke CM

Subjects

Bacterial Infections drug therapy, Bacterial Infections microbiology, Bacteriophages genetics, Evolution, Molecular, Host Specificity, Host-Pathogen Interactions genetics, Host-Pathogen Interactions physiology, Humans, Phage Therapy trends, Precision Medicine methods, Precision Medicine trends, Bacterial Infections therapy, Bacteriophages physiology, Phage Therapy methods

Abstract

Competing Interests: The authors have declared that no competing interests exist.

Published

2018

23. A viral scaffolding protein triggers portal ring oligomerization and incorporation during procapsid assembly.

Author

Motwani T, Lokareddy RK, Dunbar CA, Cortines JR, Jarrold MF, Cingolani G, and Teschke CM

Subjects

Capsid Proteins chemistry, Models, Molecular, Protein Conformation, Spectrum Analysis, Viral Proteins chemistry, Viral Proteins metabolism, Bacteriophage P22 physiology, Capsid Proteins metabolism, Protein Multimerization, Virus Assembly

Abstract

Most double-stranded DNA viruses package genetic material into empty precursor capsids (or procapsids) through a dodecameric portal protein complex that occupies 1 of the 12 vertices of the icosahedral lattice. Inhibiting incorporation of the portal complex prevents the formation of infectious virions, making this step an excellent target for antiviral drugs. The mechanism by which a sole portal assembly is selectively incorporated at the special vertex is unclear. We recently showed that, as part of the DNA packaging process for bacteriophage P22, the dodecameric procapsid portal changes conformation to a mature virion state. We report that preformed dodecameric rings of P22 portal protein, as opposed to portal monomers, incorporate into nascent procapsids, with preference for the procapsid portal conformation. Finally, a novel role for P22 scaffolding protein in triggering portal ring formation from portal monomers is elucidated and validated by incorporating de novo assembled portal rings into procapsids.

Published

2017

24. NMR assignments for the insertion domain of bacteriophage Sf6 coat protein.

Author

Tripler TN, Teschke CM, and Alexandrescu AT

Subjects

Amino Acid Sequence, Protein Domains, Bacteriophage P22 physiology, Capsid Proteins chemistry, Capsid Proteins metabolism, Nuclear Magnetic Resonance, Biomolecular

Abstract

The P22 bacteriophage group is a subgroup of the λ phage supercluster, comprised of the three major sequence types Sf6, P22, and CUS-3, based on their capsid proteins. Our goal is to investigate the extent to which structure-function relationships are conserved for the viral coat proteins and I-domains in this subgroup. Sf6 is a phage that infects the human pathogen Shigella flexneri. The coat protein of Sf6 assembles into a procapsid, which further undergoes maturation during DNA packaging into an infectious virion. The Sf6 coat protein contains a genetically inserted domain, termed the I-domain, similar to the ones present in the P22 and CUS-3 coat proteins. Based on the P22 example, I-domains play important functional roles in capsid assembly, stability, viability, and size-determination. Here we report the 1 H, 15 N, and 13 C chemical shift assignments for the I-domain of the Sf6 phage coat protein. Chemical shift-based secondary structure prediction and hydrogen-bond patterns from a long-range HNCO experiment indicate that the Sf6 I-domain adopts a 6-stranded β-barrel fold like those of P22 and CUS-3 but with important differences, including the absence of the D-loop that is critical for capsid assembly and the addition of a novel disordered loop region.

Published

2017

25. Portal protein functions akin to a DNA-sensor that couples genome-packaging to icosahedral capsid maturation.

Author

Lokareddy RK, Sankhala RS, Roy A, Afonine PV, Motwani T, Teschke CM, Parent KN, and Cingolani G

Subjects

Bacteriophage P22 ultrastructure, Capsid ultrastructure, Capsid Proteins physiology, Capsid Proteins ultrastructure, Crystallography, X-Ray, DNA Packaging physiology, DNA, Viral ultrastructure, Endodeoxyribonucleases metabolism, Genome, Viral physiology, Microscopy, Electron, Molecular Docking Simulation, Protein Multimerization physiology, Protein Structure, Quaternary physiology, Bacteriophage P22 physiology, Capsid physiology, Capsid Proteins chemistry, DNA, Viral physiology, Virus Assembly physiology

Abstract

Tailed bacteriophages and herpesviruses assemble infectious particles via an empty precursor capsid (or 'procapsid') built by multiple copies of coat and scaffolding protein and by one dodecameric portal protein. Genome packaging triggers rearrangement of the coat protein and release of scaffolding protein, resulting in dramatic procapsid lattice expansion. Here, we provide structural evidence that the portal protein of the bacteriophage P22 exists in two distinct dodecameric conformations: an asymmetric assembly in the procapsid (PC-portal) that is competent for high affinity binding to the large terminase packaging protein, and a symmetric ring in the mature virion (MV-portal) that has negligible affinity for the packaging motor. Modelling studies indicate the structure of PC-portal is incompatible with DNA coaxially spooled around the portal vertex, suggesting that newly packaged DNA triggers the switch from PC- to MV-conformation. Thus, we propose the signal for termination of 'Headful Packaging' is a DNA-dependent symmetrization of portal protein., Competing Interests: The authors declare no competing financial interests.

Published

2017

26. Measurement of the accurate mass of a 50 MDa infectious virus.

Author

Keifer DZ, Motwani T, Teschke CM, and Jarrold MF

Subjects

DNA, Viral analysis, DNA, Viral chemistry, Molecular Weight, Salmonella enterica virology, Viral Proteins analysis, Viral Proteins chemistry, Virus Cultivation, Bacteriophage P22 chemistry, Bacteriophage P22 isolation & purification, Spectrometry, Mass, Electrospray Ionization methods, Virion chemistry, Virion isolation & purification, Virology methods

Abstract

Rationale: Bacteriophage P22 is believed to contain a total of 521 copies of 9 different proteins and a 41,724 base pair genome. Despite its enormous size and complexity, phage P22 can be electrosprayed, and it remains intact in ultra-high vacuum where its molar mass distribution has been measured., Methods: Phage P22 virions were generated by complementation in Salmonella enterica and purified. They were transferred into 100 mM ammonium acetate and then electrosprayed. The masses of individual virions were determined using charge detection mass spectrometry., Results: The stoichiometry of the protein components of phage P22 is sufficiently well known that the theoretical molar mass can be determined to within a narrow range. The measured average molar mass of phage P22, 52,180 ± 59 kDa, is consistent with the theoretical molar mass and supports the proposed stoichiometry of the components. The intrinsic width of the phage P22 mass distribution can be accounted for by the distribution of DNA packaged by the headful mechanism., Conclusions: At over 50 MDa, phage P22 is the largest object with a well-defined molar mass to be analyzed by mass spectrometry. The narrow measured mass distribution indicates that the virions survive the transition into the gas phase intact. Copyright © 2016 John Wiley & Sons, Ltd., (Copyright © 2016 John Wiley & Sons, Ltd.)

Published

2016

27. Localization of the Houdinisome (Ejection Proteins) inside the Bacteriophage P22 Virion by Bubblegram Imaging.

Author

Wu W, Leavitt JC, Cheng N, Gilcrease EB, Motwani T, Teschke CM, Casjens SR, and Steven AC

Subjects

Bacteriophage P22 ultrastructure, Models, Biological, Virion ultrastructure, Bacteriophage P22 chemistry, Cryoelectron Microscopy, Viral Proteins analysis, Virion chemistry

Abstract

Unlabelled: The P22 capsid is a T=7 icosahedrally symmetric protein shell with a portal protein dodecamer at one 5-fold vertex. Extending outwards from that vertex is a short tail, and putatively extending inwards is a 15-nm-long α-helical barrel formed by the C-terminal domains of portal protein subunits. In addition to the densely packed genome, the capsid contains three "ejection proteins" (E-proteins [gp7, gp16, and gp20]) destined to exit from the tightly sealed capsid during the process of DNA delivery into target cells. We estimated their copy numbers by quantitative SDS-PAGE as approximately 12 molecules per virion of gp16 and gp7 and 30 copies of gp20. To localize them, we used bubblegram imaging, an adaptation of cryo-electron microscopy in which gaseous bubbles induced in proteins by prolonged irradiation are used to map the proteins' locations. We applied this technique to wild-type P22, a triple mutant lacking all three E-proteins, and three mutants each lacking one E-protein. We conclude that all three E-proteins are loosely clustered around the portal axis, in the region displaced radially inwards from the portal crown. The bubblegram data imply that approximately half of the α-helical barrel seen in the portal crystal structure is disordered in the mature virion, and parts of the disordered region present binding sites for E-proteins. Thus positioned, the E-proteins are strategically placed to pass down the shortened barrel and through the portal ring and the tail, as they exit from the capsid during an infection., Importance: While it has long been appreciated that capsids serve as delivery vehicles for viral genomes, there is now growing awareness that viruses also deliver proteins into their host cells. P22 has three such proteins (ejection proteins [E-proteins]), whose initial locations in the virion have remained unknown despite their copious amounts (total of 2.5 MDa). This study succeeded in localizing them by the novel technique of bubblegram imaging. The P22 E-proteins are seen to be distributed around the orifice of the portal barrel. Interestingly, this barrel, 15 nm long in a crystal structure, is only about half as long in situ: the remaining, disordered, portion appears to present binding sites for E-proteins. These observations document a spectacular example of a regulatory order-disorder transition in a supramolecular system and demonstrate the potential of bubblegram imaging to map the components of other viruses as well as cellular complexes., (Copyright © 2016 Wu et al.)

Published

2016

28. Acquiring Structural Information on Virus Particles with Charge Detection Mass Spectrometry.

Author

Keifer DZ, Motwani T, Teschke CM, and Jarrold MF

Subjects

Capsid, Virus Assembly, Capsid Proteins chemistry, Mass Spectrometry, Virion chemistry

Abstract

Charge detection mass spectrometry (CDMS) is a single-molecule technique particularly well-suited to measuring the mass and charge distributions of heterogeneous, MDa-sized ions. In this work, CDMS has been used to analyze the assembly products of two coat protein variants of bacteriophage P22. The assembly products show broad mass distributions extending from 5 to 15 MDa for A285Y and 5 to 25 MDa for A285T coat protein variants. Because the charge of large ions generated by electrospray ionization depends on their size, the charge can be used to distinguish hollow shells from more compact structures. A285T was found to form T = 4 and T = 7 procapsids, and A285Y makes a small number of T = 3 and T = 4 procapsids. Owing to the decreased stability of the A285Y and A285T particles, chemical cross-linking was required to stabilize them for electrospray CDMS.Graphical Abstract.

Published

2016

29. Contextual Role of a Salt Bridge in the Phage P22 Coat Protein I-Domain.

Author

Harprecht C, Okifo O, Robbins KJ, Motwani T, Alexandrescu AT, and Teschke CM

Subjects

Amino Acid Substitution, Bacteriophage P22 genetics, Capsid Proteins genetics, Hydrogen-Ion Concentration, Models, Molecular, Mutagenesis, Site-Directed, Protein Domains, Protein Folding, Protein Multimerization, Protein Stability, Recombinant Proteins chemistry, Recombinant Proteins genetics, Recombinant Proteins metabolism, Sodium Chloride metabolism, Thermodynamics, Bacteriophage P22 metabolism, Capsid Proteins chemistry, Capsid Proteins metabolism

Abstract

The I-domain is a genetic insertion in the phage P22 coat protein that chaperones its folding and stability. Of 11 acidic residues in the I-domain, seven participate in stabilizing electrostatic interactions with basic residues across elements of secondary structure, fastening the β-barrel fold. A hydrogen-bonded salt bridge between Asp-302 and His-305 is particularly interesting as Asp-302 is the site of a temperature-sensitive-folding mutation. The pKa of His-305 is raised to 9.0, indicating the salt bridge stabilizes the I-domain by ∼4 kcal/mol. Consistently, urea denaturation experiments indicate the stability of the WT I-domain decreases by 4 kcal/mol between neutral and basic pH. The mutants D302A and H305A remove the pH dependence of stability. The D302A substitution destabilizes the I-domain by 4 kcal/mol, whereas H305A had smaller effects, on the order of 1-2 kcal/mol. The destabilizing effects of D302A are perpetuated in the full-length coat protein as shown by a higher sensitivity to protease digestion, decreased procapsid assembly rates, and impaired phage production in vivo By contrast, the mutants have only minor effects on capsid expansion or stability in vitro The effects of the Asp-302-His-305 salt bridge are thus complex and context-dependent. Substitutions that abolish the salt bridge destabilize coat protein monomers and impair capsid self-assembly, but once capsids are formed the effects of the substitutions are overcome by new quaternary interactions between subunits., (© 2016 by The American Society for Biochemistry and Molecular Biology, Inc.)

Published

2016

30. Mechanism of Protein Denaturation: Partial Unfolding of the P22 Coat Protein I-Domain by Urea Binding.

Author

Newcomer RL, Fraser LCR, Teschke CM, and Alexandrescu AT

Subjects

Hydrogen Bonding, Models, Molecular, Protein Stability, Protein Structure, Secondary, Protein Structure, Tertiary, Solvents chemistry, Temperature, Bacteriophage P22, Capsid Proteins chemistry, Capsid Proteins metabolism, Protein Denaturation drug effects, Urea metabolism, Urea pharmacology

Abstract

The I-domain is an insertion domain of the bacteriophage P22 coat protein that drives rapid folding and accounts for over half of the stability of the full-length protein. We sought to determine the role of hydrogen bonds (H-bonds) in the unfolding of the I-domain by examining (3)JNC' couplings transmitted through H-bonds, the temperature and urea-concentration dependence of (1)HN and (15)N chemical shifts, and native-state hydrogen exchange at urea concentrations where the domain is predominantly folded. The native-state hydrogen-exchange data suggest that the six-stranded β-barrel core of the I-domain is more stable against unfolding than a smaller subdomain comprised of a short α-helix and three-stranded β-sheet. H-bonds, separately determined from solvent protection and (3)JNC' H-bond couplings, are identified with an accuracy of 90% by (1)HN temperature coefficients. The accuracy is improved to 95% when (15)N temperature coefficients are also included. In contrast, the urea dependence of (1)HN and (15)N chemical shifts is unrelated to H-bonding. The protein segments with the largest chemical-shift changes in the presence of urea show curved or sigmoidal titration curves suggestive of direct urea binding. Nuclear Overhauser effects to urea for these segments are also consistent with specific urea-binding sites in the I-domain. Taken together, the results support a mechanism of urea unfolding in which denaturant binds to distinct sites in the I-domain. Disordered segments bind urea more readily than regions in stable secondary structure. The locations of the putative urea-binding sites correlate with the lower stability of the structure against solvent exchange, suggesting that partial unfolding of the structure is related to urea accessibility., (Copyright © 2015 Biophysical Society. Published by Elsevier Inc. All rights reserved.)

Published

2015

31. A Molecular Staple: D-Loops in the I Domain of Bacteriophage P22 Coat Protein Make Important Intercapsomer Contacts Required for Procapsid Assembly.

Author

D'Lima NG and Teschke CM

Subjects

Bacteriophage P22 genetics, Bacteriophage P22 metabolism, Capsid metabolism, Capsid Proteins genetics, Capsid Proteins metabolism, Cross-Linking Reagents chemistry, DNA chemistry, DNA metabolism, DNA Packaging physiology, DNA, Viral metabolism, Gene Expression, Models, Molecular, Phenanthrolines chemistry, Protein Folding, Protein Structure, Secondary, Protein Structure, Tertiary, Salmonella typhimurium virology, Virion genetics, Virion metabolism, Bacteriophage P22 chemistry, Capsid chemistry, Capsid Proteins chemistry, DNA, Viral chemistry, Virion chemistry, Virus Assembly physiology

Abstract

Unlabelled: Bacteriophage P22, a double-stranded DNA (dsDNA) virus, has a nonconserved 124-amino-acid accessory domain inserted into its coat protein, which has the canonical HK97 protein fold. This I domain is involved in virus capsid size determination and stability, as well as protein folding. The nuclear magnetic resonance (NMR) solution structure of the I domain revealed the presence of a D-loop, which was hypothesized to make important intersubunit contacts between coat proteins in adjacent capsomers. Here we show that amino acid substitutions of residues near the tip of the D-loop result in aberrant assembly products, including tubes and broken particles, highlighting the significance of the D-loops in proper procapsid assembly. Using disulfide cross-linking, we showed that the tips of the D-loops are positioned directly across from each other both in the procapsid and the mature virion, suggesting their importance in both states. Our results indicate that D-loop interactions act as "molecular staples" at the icosahedral 2-fold symmetry axis and significantly contribute to stabilizing the P22 capsid for DNA packaging., Importance: Many dsDNA viruses have morphogenic pathways utilizing an intermediate capsid, known as a procapsid. These procapsids are assembled from a coat protein having the HK97 fold in a reaction driven by scaffolding proteins or delta domains. Maturation of the capsid occurs during DNA packaging. Bacteriophage HK97 uniquely stabilizes its capsid during maturation by intercapsomer cross-linking, but most virus capsids are stabilized by alternate means. Here we show that the I domain that is inserted into the coat protein of bacteriophage P22 is important in the process of proper procapsid assembly. Specifically, the I domain allows for stabilizing interactions across the capsid 2-fold axis of symmetry via a D-loop. When amino acid residues at the tip of the D-loop are mutated, aberrant assembly products, including tubes, are formed instead of procapsids, consequently phage production is affected, indicating the importance of stabilizing interactions during the assembly and maturation reactions., (Copyright © 2015, American Society for Microbiology. All Rights Reserved.)

Published

2015

32. NMR assignments for the insertion domain of bacteriophage CUS-3 coat protein.

Author

Tripler TN, Maciejewski MW, Teschke CM, and Alexandrescu AT

Subjects

Amino Acid Sequence, Molecular Sequence Data, Protein Structure, Secondary, Protein Structure, Tertiary, Bacteriophage P22 chemistry, Capsid Proteins chemistry, Nuclear Magnetic Resonance, Biomolecular

Abstract

CUS-3 is a P22-like tailed dsDNA bacteriophage that infects Escherichia coli serotype K1. The CUS-3 coat protein, which forms the icosahedral capsid, has a conserved HK97-fold but with a non-conserved accessory domain known as the insertion domain (I-domain). Sequence alignment of the coat proteins from CUS-3 and P22 shows higher sequence similarity for the I-domains (35 %) than for the HK97-cores, suggesting the I-domains play important functional roles. The I-domain of the P22 coat protein, which has an NMR structure comprised of a six-stranded β-barrel, has been shown to govern the assembly, stability and size of the resulting capsid particles. Here, we report the (1)H, (15)N, and (13)C assignments for the I-domain from the coat protein of bacteriophage CUS-3. The secondary structure and dynamics of the CUS-3 I-domain, predicted from the assigned NMR chemical shifts, agree with those of the P22 I-domain, suggesting the CUS-3 and P22 I-domains may have similar structures and functions in capsid assembly.

Published

2015

33. A method to investigate protein association with intact sealed mycobacterial membrane vesicles.

Author

D'Lima NG and Teschke CM

Subjects

Adenosine Triphosphatases metabolism, Bacterial Proteins metabolism, Cell Membrane metabolism, Membrane Transport Proteins metabolism, Mycobacterium tuberculosis metabolism, Adenosine Triphosphatases chemistry, Bacterial Proteins chemistry, Cell Membrane chemistry, Membrane Transport Proteins chemistry, Mycobacterium tuberculosis chemistry

Abstract

In mycobacteria, probing the association of cytoplasmic proteins with the membrane itself, as well as with integral or peripheral membrane proteins, is limited by the difficulty in extracting intact sealed membrane vesicles due to the complex cell wall structure. Here we tested the association of Mycobacterium tuberculosis SecA1 and SecA2 proteins with intact membrane vesicles by a flotation assay using iodixanol density gradients. These protocols have wide applications for studying the association of other mycobacterial cytoplasmic proteins with the membrane and membrane-associated proteins., (Copyright © 2015 Elsevier Inc. All rights reserved.)

Published

2015

34. Nature's favorite building block: Deciphering folding and capsid assembly of proteins with the HK97-fold.

Author

Suhanovsky MM and Teschke CM

Subjects

Capsid Proteins chemistry, Protein Folding, Protein Multimerization, Archaeal Viruses physiology, Bacteriophages physiology, Capsid Proteins metabolism, Herpesviridae physiology, Virus Assembly

Abstract

For many (if not all) bacterial and archaeal tailed viruses and eukaryotic Herpesvirdae the HK97-fold serves as the major architectural element in icosahedral capsid formation while still enabling the conformational flexibility required during assembly and maturation. Auxiliary proteins or Δ-domains strictly control assembly of multiple, identical, HK97-like subunits into procapsids with specific icosahedral symmetries, rather than aberrant non-icosahedral structures. Procapsids are precursor structures that mature into capsids in a process involving release of auxiliary proteins (or cleavage of Δ-domains), dsDNA packaging, and conformational rearrangement of the HK97-like subunits. Some coat proteins built on the ubiquitous HK97-fold also have accessory domains or loops that impart specific functions, such as increased monomer, procapsid, or capsid stability. In this review, we analyze the numerous HK97-like coat protein structures that are emerging in the literature (over 40 at time of writing) by comparing their topology, additional domains, and their assembly and misassembly reactions., (Copyright © 2015 Elsevier Inc. All rights reserved.)

Published

2015

35. Multiple functional roles of the accessory I-domain of bacteriophage P22 coat protein revealed by NMR structure and CryoEM modeling.

Author

Rizzo AA, Suhanovsky MM, Baker ML, Fraser LC, Jones LM, Rempel DL, Gross ML, Chiu W, Alexandrescu AT, and Teschke CM

Subjects

Cryoelectron Microscopy, Models, Molecular, Molecular Dynamics Simulation, Nuclear Magnetic Resonance, Biomolecular, Protein Structure, Quaternary, Protein Structure, Tertiary, Protein Subunits, Static Electricity, Bacteriophage P22 chemistry, Bacteriophage P22 ultrastructure, Capsid Proteins chemistry, Capsid Proteins ultrastructure

Abstract

Some capsid proteins built on the ubiquitous HK97-fold have accessory domains imparting specific functions. Bacteriophage P22 coat protein has a unique insertion domain (I-domain). Two prior I-domain models from subnanometer cryoelectron microscopy (cryoEM) reconstructions differed substantially. Therefore, the I-domain's nuclear magnetic resonance structure was determined and also used to improve cryoEM models of coat protein. The I-domain has an antiparallel six-stranded β-barrel fold, not previously observed in HK97-fold accessory domains. The D-loop, which is dynamic in the isolated I-domain and intact monomeric coat protein, forms stabilizing salt bridges between adjacent capsomers in procapsids. The S-loop is important for capsid size determination, likely through intrasubunit interactions. Ten of 18 coat protein temperature-sensitive-folding substitutions are in the I-domain, indicating its importance in folding and stability. Several are found on a positively charged face of the β-barrel that anchors the I-domain to a negatively charged surface of the coat protein HK97-core., (Copyright © 2014 Elsevier Ltd. All rights reserved.)

Published

2014

36. Highly specific salt bridges govern bacteriophage P22 icosahedral capsid assembly: identification of the site in coat protein responsible for interaction with scaffolding protein.

Author

Cortines JR, Motwani T, Vyas AA, and Teschke CM

Subjects

Bacteriophage P22 genetics, Capsid Proteins genetics, DNA Mutational Analysis, Models, Molecular, Mutagenesis, Site-Directed, Protein Conformation, Protein Interaction Domains and Motifs, Static Electricity, Viral Structural Proteins genetics, Bacteriophage P22 chemistry, Bacteriophage P22 physiology, Capsid metabolism, Capsid Proteins metabolism, Protein Interaction Mapping, Viral Structural Proteins metabolism, Virus Assembly

Abstract

Unlabelled: Icosahedral virus assembly requires a series of concerted and highly specific protein-protein interactions to produce a proper capsid. In bacteriophage P22, only coat protein (gp5) and scaffolding protein (gp8) are needed to assemble a procapsid-like particle, both in vivo and in vitro. In scaffolding protein's coat binding domain, residue R293 is required for procapsid assembly, while residue K296 is important but not essential. Here, we investigate the interaction of scaffolding protein with acidic residues in the N-arm of coat protein, since this interaction has been shown to be electrostatic. Through site-directed mutagenesis of genes 5 and 8, we show that changing coat protein N-arm residue 14 from aspartic acid to alanine causes a lethal phenotype. Coat protein residue D14 is shown by cross-linking to interact with scaffolding protein residue R293 and, thus, is intimately involved in proper procapsid assembly. To a lesser extent, coat protein N-arm residue E18 is also implicated in the interaction with scaffolding protein and is involved in capsid size determination, since a cysteine mutation at this site generated petite capsids. The final acidic residue in the N-arm that was tested, E15, is shown to only weakly interact with scaffolding protein's coat binding domain. This work supports growing evidence that surface charge density may be the driving force of virus capsid protein interactions., Importance: Bacteriophage P22 infects Salmonella enterica serovar Typhimurium and is a model for icosahedral viral capsid assembly. In this system, coat protein interacts with an internal scaffolding protein, triggering the assembly of an intermediate called a procapsid. Previously, we determined that there is a single amino acid in scaffolding protein required for P22 procapsid assembly, although others modulate affinity. Here, we identify partners in coat protein. We show experimentally that relatively weak interactions between coat and scaffolding proteins are capable of driving correctly shaped and sized procapsids and that the lack of these proper protein-protein interfaces leads to aberrant structures. The present work represents an important contribution supporting the hypothesis that virus capsid assembly is governed by seemingly simple interactions. The highly specific nature of the subunit interfaces suggests that these could be good targets for antivirals.

Published

2014

37. ADP-dependent conformational changes distinguish Mycobacterium tuberculosis SecA2 from SecA1.

Author

D'Lima NG and Teschke CM

Subjects

Adenosine Diphosphate genetics, Adenosine Diphosphate metabolism, Adenosine Triphosphatases genetics, Adenosine Triphosphatases metabolism, Animals, Bacterial Proteins genetics, Bacterial Proteins metabolism, Humans, Macrophages microbiology, Membrane Transport Proteins genetics, Membrane Transport Proteins metabolism, Mycobacterium tuberculosis genetics, Mycobacterium tuberculosis pathogenicity, Protein Binding, Protein Structure, Tertiary, Protein Transport, Adenosine Diphosphate chemistry, Adenosine Triphosphatases chemistry, Bacterial Proteins chemistry, Membrane Transport Proteins chemistry, Mycobacterium tuberculosis enzymology

Abstract

In bacteria, most secreted proteins are exported through the SecYEG translocon by the SecA ATPase motor via the general secretion or "Sec" pathway. The identification of an additional SecA protein, particularly in Gram-positive pathogens, has raised important questions about the role of SecA2 in both protein export and establishment of virulence. We previously showed in Mycobacterium tuberculosis, the causative agent of tuberculosis, the accessory SecA2 protein possesses ATPase activity that is required for bacterial survival in host macrophages, highlighting its importance in virulence. Here, we show that SecA2 binds ADP with much higher affinity than SecA1 and releases the nucleotide more slowly. Nucleotide binding also regulates movement of the precursor-binding domain in SecA2, unlike in SecA1 or conventional SecA proteins. This conformational change involving closure of the clamp in SecA2 may provide a mechanism for the cell to direct protein export through the conventional SecA1 pathway under normal growth conditions while preventing ordinary precursor proteins from interacting with the specialized SecA2 ATPase.

Published

2014

38. An intramolecular chaperone inserted in bacteriophage P22 coat protein mediates its chaperonin-independent folding.

Author

Suhanovsky MM and Teschke CM

Subjects

Bacteriophage P22 genetics, Capsid Proteins chemistry, Capsid Proteins genetics, Kinetics, Molecular Chaperones chemistry, Molecular Chaperones genetics, Peptidylprolyl Isomerase chemistry, Protein Stability, Protein Structure, Tertiary, Salmonella typhimurium genetics, Salmonella typhimurium metabolism, Salmonella typhimurium virology, Bacteriophage P22 metabolism, Capsid Proteins biosynthesis, Molecular Chaperones biosynthesis, Protein Folding

Abstract

The bacteriophage P22 coat protein has the common HK97-like fold but with a genetically inserted domain (I-domain). The role of the I-domain, positioned at the outermost surface of the capsid, is unknown. We hypothesize that the I-domain may act as an intramolecular chaperone because the coat protein folds independently, and many folding mutants are localized to the I-domain. The function of the I-domain was investigated by generating the coat protein core without its I-domain and the isolated I-domain. The core coat protein shows a pronounced folding defect. The isolated I-domain folds autonomously and has a high thermodynamic stability and fast folding kinetics in the presence of a peptidyl prolyl isomerase. Thus, the I-domain provides thermodynamic stability to the full-length coat protein so that it can fold reasonably efficiently while still allowing the HK97-like core to retain the flexibility required for conformational switching during procapsid assembly and maturation.

Published

2013

39. NMR assignments for the telokin-like domain of bacteriophage P22 coat protein.

Author

Rizzo AA, Fraser LC, Sheftic SR, Suhanovsky MM, Teschke CM, and Alexandrescu AT

Subjects

Amino Acid Sequence, Molecular Sequence Data, Protein Structure, Secondary, Protein Structure, Tertiary, Bacteriophage P22 metabolism, Capsid Proteins chemistry, Myosin-Light-Chain Kinase chemistry, Nuclear Magnetic Resonance, Biomolecular, Peptide Fragments chemistry

Abstract

The bacteriophage P22 virion is assembled from identical coat protein monomers in a complex reaction that is generally conserved among tailed, double-stranded DNA bacteriophages and viruses. Many coat proteins of dsDNA viruses have structures based on the HK97 fold, but in some viruses and phages there are additional domains. In the P22 coat protein, a "telokin-like" domain was recently identified, whose structure has not yet been characterized at high-resolution. Two recently published low-resolution cryo-EM reconstructions suggest markedly different folds for the telokin-like domain that lead to alternative conclusions about its function in capsid assembly and stability. Here we report (1)H, (15)N, and (13)C NMR resonance assignments for the telokin-like domain. The secondary structure predicted from the chemical shift values obtained in this work shows significant discrepancies from both cryo-EM models but agrees better with one of the models. In particular, the functionally important "D-loop" in one model shows chemical shifts and solvent exchange protection more consistent with β-sheet structure. Our work will set the basis for a high-resolution NMR structure determination of the telokin-like domain that will help improve the cryo-EM models, and in turn lead to a better understanding of how coat protein monomers assemble into the icosahedral capsids required for virulence.

Published

2013

40. Unraveling the role of the C-terminal helix turn helix of the coat-binding domain of bacteriophage P22 scaffolding protein.

Author

Padilla-Meier GP, Gilcrease EB, Weigele PR, Cortines JR, Siegel M, Leavitt JC, Teschke CM, and Casjens SR

Subjects

Amino Acid Sequence, Capsid Proteins chemistry, Circular Dichroism, Escherichia coli virology, Models, Molecular, Molecular Conformation, Molecular Sequence Data, Mutagenesis, Site-Directed, Mutation, Oligonucleotides genetics, Prophages genetics, Protein Binding, Protein Structure, Secondary, Protein Structure, Tertiary, Static Electricity, Virus Assembly, Bacteriophage P22 metabolism

Abstract

Many viruses encode scaffolding and coat proteins that co-assemble to form procapsids, which are transient precursor structures leading to progeny virions. In bacteriophage P22, the association of scaffolding and coat proteins is mediated mainly by ionic interactions. The coat protein-binding domain of scaffolding protein is a helix turn helix structure near the C terminus with a high number of charged surface residues. Residues Arg-293 and Lys-296 are particularly important for coat protein binding. The two helices contact each other through hydrophobic side chains. In this study, substitution of the residues of the interface between the helices, and the residues in the β-turn, by aspartic acid was used examine the importance of the conformation of the domain in coat binding. These replacements strongly affected the ability of the scaffolding protein to interact with coat protein. The severity of the defect in the association of scaffolding protein to coat protein was dependent on location, with substitutions at residues in the turn and helix 2 causing the most significant effects. Substituting aspartic acid for hydrophobic interface residues dramatically perturbs the stability of the structure, but similar substitutions in the turn had much less effect on the integrity of this domain, as determined by circular dichroism. We propose that the binding of scaffolding protein to coat protein is dependent on angle of the β-turn and the orientation of the charged surface on helix 2. Surprisingly, formation of the highly complex procapsid structure depends on a relatively simple interaction.

Published

2012

41. Themes and variations of viral small terminase proteins.

Author

Teschke CM

Published

2012

42. Stepwise molecular display utilizing icosahedral and helical complexes of phage coat and decoration proteins in the development of robust nanoscale display vehicles.

Author

Parent KN, Deedas CT, Egelman EH, Casjens SR, Baker TS, and Teschke CM

Subjects

Materials Testing, Nanocapsules ultrastructure, Nanotubes ultrastructure, Bacteriophage P22 chemistry, Nanocapsules chemistry, Nanotubes chemistry, Peptide Library, Pharmaceutical Vehicles chemical synthesis, Viral Proteins chemistry

Abstract

A stepwise addition protocol was developed to display cargo using bacteriophage P22 capsids and the phage decoration (Dec) protein. Three-dimensional image reconstructions of frozen-hydrated samples of P22 particles with nanogold-labeled Dec bound to them revealed the locations of the N- and C-termini of Dec. Each terminus is readily accessible for molecular display through affinity tags such as nickel-nitrilotriacetic acid, providing a total of 240 cargo-binding sites. Dec was shown by circular dichroism to be a β-sheet rich protein, and fluorescence anisotropy binding experiments demonstrated that Dec binds to P22 heads with high (~110 nm) affinity. Dec also binds to P22 nanotubes, which are helically symmetric assemblies that form when the P22 coat protein contains the F170A amino acid substitution. Several classes of tubes with Dec bound to them were visualized by cryo-electron microscopy and their three-dimensional structures were determined by helical reconstruction methods. In all instances, Dec trimers bound to P22 capsids and nanotubes at positions where three neighboring capsomers (oligomers of six coat protein subunits) lie in close proximity to one another. Stable interactions between Dec and P22 allow for the development of robust, nanoscale size, display vehicles., (Copyright © 2012 Elsevier Ltd. All rights reserved.)

Published

2012

43. The energetic contributions of scaffolding and coat proteins to the assembly of bacteriophage procapsids.

Author

Zlotnick A, Suhanovsky MM, and Teschke CM

Subjects

Bacteriophage P22 chemistry, Bacteriophage P22 genetics, Binding Sites, Capsid chemistry, Capsid Proteins chemistry, Capsid Proteins genetics, Kinetics, Viral Structural Proteins chemistry, Viral Structural Proteins genetics, Bacteriophage P22 physiology, Capsid metabolism, Capsid Proteins metabolism, Viral Structural Proteins metabolism, Virus Assembly

Abstract

In vitro assembly of bacteriophage P22 procapsids requires coat protein and sub-stoichiometric concentrations of the internal scaffolding protein. If there is no scaffolding protein, coat protein assembles aberrantly, but only at higher concentrations. Too much scaffolding protein results in partial procapsids. By treating the procapsid as a lattice that can bind and be stabilized by scaffolding protein we dissect procapsid assembly as a function of protein concentration and scaffolding/coat protein ratio. We observe that (i) the coat-coat association is weaker for procapsids than for aberrant polymer formation, (ii) scaffolding protein makes a small but sufficient contribution to stability to favor the procapsid form, and (iii) there are multiple classes of scaffolding protein binding sites. This approach should be applicable to other heterogeneous virus assembly reactions and will facilitate our ability to manipulate such in vitro reactions to probe assembly, and for development of nanoparticles., (Copyright © 2012 Elsevier Inc. All rights reserved.)

Published

2012

44. Decoding bacteriophage P22 assembly: identification of two charged residues in scaffolding protein responsible for coat protein interaction.

Author

Cortines JR, Weigele PR, Gilcrease EB, Casjens SR, and Teschke CM

Subjects

Amino Acid Sequence, Bacteriophage P22 chemistry, Bacteriophage P22 genetics, Capsid Proteins chemistry, Helix-Turn-Helix Motifs, Models, Molecular, Molecular Sequence Data, Protein Binding, Protein Structure, Tertiary, Sequence Alignment, Viral Structural Proteins genetics, Bacteriophage P22 physiology, Capsid Proteins metabolism, Viral Structural Proteins chemistry, Viral Structural Proteins metabolism, Virus Assembly

Abstract

Proper assembly of viruses must occur through specific interactions between capsid proteins. Many double-stranded DNA viruses and bacteriophages require internal scaffolding proteins to assemble their coat proteins into icosahedral capsids. The 303 amino acid bacteriophage P22 scaffolding protein is mostly helical, and its C-terminal helix-turn-helix (HTH) domain binds to the coat protein during virion assembly, directing the formation of an intermediate structure called the procapsid. The interaction between coat and scaffolding protein HTH domain is electrostatic, but the amino acids that form the protein-protein interface have yet to be described. In the present study, we used alanine scanning mutagenesis of charged surface residues of the C-terminal HTH domain of scaffolding protein. We have determined that P22 scaffolding protein residues R293 and K296 are crucial for binding to coat protein and that the neighboring charges are not essential but do modulate the affinity between the two proteins., (Copyright © 2011 Elsevier Inc. All rights reserved.)

Published

2011

45. Bacteriophage P22 capsid size determination: roles for the coat protein telokin-like domain and the scaffolding protein amino-terminus.

Author

Suhanovsky MM and Teschke CM

Subjects

Amino Acid Substitution genetics, Bacteriophage P22 metabolism, Bacteriophage P22 ultrastructure, Capsid metabolism, Capsid ultrastructure, Capsid Proteins genetics, Microscopy, Electron, Models, Molecular, Mutation, Missense, Myosin-Light-Chain Kinase genetics, Peptide Fragments genetics, Protein Structure, Tertiary, Suppression, Genetic, Bacteriophage P22 physiology, Capsid physiology, Capsid Proteins metabolism, Viral Structural Proteins metabolism, Virus Assembly

Abstract

Assembly of icosahedral capsids of proper size and symmetry is not understood. Residue F170 in bacteriophage P22 coat protein is critical for conformational switching during assembly. Substitutions at this site cause assembly of tubes of hexamerically arranged coat protein. Intragenic suppressors of the ts phenotype of F170A and F170K coat protein mutants were isolated. Suppressors were repeatedly found in the coat protein telokin-like domain at position 285, which caused coat protein to assemble into petite procapsids and capsids. Petite capsid assembly strongly correlated to the side chain volume of the substituted amino acid. We hypothesize that larger side chains at position 285 torque the telokin-like domain, changing flexibility of the subunit and intercapsomer contacts. Thus, a single amino acid substitution in coat protein is sufficient to change capsid size. In addition, the products of assembly of the variant coat proteins were affected by the size of the internal scaffolding protein., (Copyright © 2011 Elsevier Inc. All rights reserved.)

Published

2011

46. Conformational changes in bacteriophage P22 scaffolding protein induced by interaction with coat protein.

Author

Padilla-Meier GP and Teschke CM

Subjects

Bacteriophage P22 metabolism, Benzofurans chemistry, Benzofurans metabolism, Capsid Proteins metabolism, Cross-Linking Reagents chemistry, Cross-Linking Reagents metabolism, Fluorescence Resonance Energy Transfer, Viral Proteins metabolism, Virus Assembly, Bacteriophage P22 chemistry, Capsid Proteins chemistry, Protein Conformation, Viral Proteins chemistry

Abstract

Many prokaryotic and eukaryotic double-stranded DNA viruses use a scaffolding protein to assemble their capsid. Assembly of the double-stranded DNA bacteriophage P22 procapsids requires the interaction of 415 molecules of coat protein and 60-300 molecules of scaffolding protein. Although the 303-amino-acid scaffolding protein is essential for proper assembly of procapsids, little is known about its structure beyond an NMR structure of the extreme C-terminus, which is known to interact with coat protein. Deletion mutagenesis indicates that other regions of scaffolding protein are involved in interactions with coat protein and other capsid proteins. Single-cysteine and double-cysteine variants of scaffolding protein were generated for use in fluorescence resonance energy transfer and cross-linking experiments designed to probe the conformation of scaffolding protein in solution and within procapsids. We showed that the N-terminus and the C-terminus are proximate in solution, and that the middle of the protein is near the N-terminus but not accessible to the C-terminus. In procapsids, the N-terminus was no longer accessible to the C-terminus, indicating that there is a conformational change in scaffolding protein upon assembly. In addition, our data are consistent with a model where scaffolding protein dimers are positioned parallel with one another with the associated C-termini., (Copyright © 2011 Elsevier Ltd. All rights reserved.)

Published

2011

47. Cryo-reconstructions of P22 polyheads suggest that phage assembly is nucleated by trimeric interactions among coat proteins.

Author

Parent KN, Sinkovits RS, Suhanovsky MM, Teschke CM, Egelman EH, and Baker TS

Subjects

Bacteriophage P22 metabolism, Bacteriophage P22 ultrastructure, Capsid, Capsid Proteins chemistry, Microscopy, Electron, Transmission, Models, Molecular, Protein Binding, Bacteriophage P22 physiology, Capsid Proteins metabolism, Virus Assembly

Abstract

Bacteriophage P22 forms an isometric capsid during normal assembly, yet when the coat protein (CP) is altered at a single site, helical structures (polyheads) also form. The structures of three distinct polyheads obtained from F170L and F170A variants were determined by cryo-reconstruction methods. An understanding of the structures of aberrant assemblies such as polyheads helps to explain how amino acid substitutions affect the CP, and these results can now be put into the context of CP pseudo-atomic models. F170L CP forms two types of polyhead and each has the CP organized as hexons (oligomers of six CPs). These hexons have a skewed structure similar to that in procapsids (precursor capsids formed prior to dsDNA packaging), yet their organization differs completely in polyheads and procapsids. F170A CP forms only one type of polyhead, and though this has hexons organized similarly to hexons in F170L polyheads, the hexons are isometric structures like those found in mature virions. The hexon organization in all three polyheads suggests that nucleation of procapsid assembly occurs via a trimer of CP monomers, and this drives formation of a T = 7, isometric particle. These variants also form procapsids, but they mature quite differently: F170A expands spontaneously at room temperature, whereas F170L requires more energy. The P22 CP structure along with scaffolding protein interactions appear to dictate curvature and geometry in assembled structures and residue 170 significantly influences both assembly and maturation.

Published

2010

48. Determinants of bacteriophage P22 polyhead formation: the role of coat protein flexibility in conformational switching.

Author

Suhanovsky MM, Parent KN, Dunn SE, Baker TS, and Teschke CM

Subjects

Amino Acid Substitution, Bacteriophage P22 genetics, Bacteriophage P22 physiology, Capsid Proteins genetics, Capsid Proteins ultrastructure, Imaging, Three-Dimensional, Microscopy, Electron, Transmission, Mutagenesis, Site-Directed, Protein Structure, Tertiary, Bacteriophage P22 chemistry, Capsid Proteins chemistry, Virus Assembly

Abstract

We have investigated determinants of polyhead formation in bacteriophage P22 in order to understand the molecular mechanism by which coat protein assembly goes astray. Polyhead assembly is caused by amino acid substitutions in coat protein at position 170, which is located in the β-hinge. In vivo scaffolding protein does not correct polyhead assembly by F170A or F170K coat proteins, but does for F170L. All F170 variants bind scaffolding protein more weakly than wild-type as observed by affinity chromatography with scaffolding protein-agarose and scaffolding protein shell re-entry experiments. Electron cryo-microscopy and three-dimensional image reconstructions of F170A and F170K empty procapsid shells showed that there is a decreased flexibility of the coat subunits relative to wild-type. This was confirmed by limited proteolysis and protein sequencing, which showed increased protection of the A-domain. Our data support the conclusion that the decrease in flexibility of the A-domain leads to crowding of the subunits at the centre of the pentons, thereby favouring the hexon configuration during assembly. Thus, correct coat protein interactions with scaffolding protein and maintenance of sufficient coat protein flexibility are crucial for proper P22 assembly. The coat protein β-hinge region is the major determinant for both features., (© 2010 Blackwell Publishing Ltd.)

Published

2010

49. 'Let the phage do the work': using the phage P22 coat protein structures as a framework to understand its folding and assembly mutants.

Author

Teschke CM and Parent KN

Subjects

Bacteriophage P22 genetics, Capsid Proteins genetics, Capsid Proteins metabolism, Models, Biological, Mutant Proteins genetics, Mutant Proteins metabolism, Virus Assembly, Bacteriophage P22 chemistry, Capsid Proteins chemistry, Mutant Proteins chemistry, Protein Folding, Protein Multimerization

Abstract

The amino acid sequence of viral capsid proteins contains information about their folding, structure and self-assembly processes. While some viruses assemble from small preformed oligomers of coat proteins, other viruses such as phage P22 and herpesvirus assemble from monomeric proteins (Fuller and King, 1980; Newcomb et al., 1999). The subunit assembly process is strictly controlled through protein:protein interactions such that icosahedral structures are formed with specific symmetries, rather than aberrant structures. dsDNA viruses commonly assemble by first forming a precursor capsid that serves as a DNA packaging machine (Earnshaw, Hendrix, and King, 1980; Heymann et al., 2003). DNA packaging is accompanied by a conformational transition of the small precursor procapsid into a larger capsid for isometric viruses. Here we highlight the pseudo-atomic structures of phage P22 coat protein and rationalize several decades of data about P22 coat protein folding, assembly and maturation generated from a combination of genetics and biochemistry., (2010 Elsevier Inc. All rights reserved.)

Published

2010

50. P22 coat protein structures reveal a novel mechanism for capsid maturation: stability without auxiliary proteins or chemical crosslinks.

Author

Parent KN, Khayat R, Tu LH, Suhanovsky MM, Cortines JR, Teschke CM, Johnson JE, and Baker TS

Subjects

Amino Acid Sequence, Cryoelectron Microscopy, Models, Molecular, Molecular Sequence Data, Protein Conformation, Virus Assembly, Bacteriophage P22 metabolism, Capsid metabolism, Capsid Proteins chemistry

Abstract

Viral capsid assembly and stability in tailed, dsDNA phage and Herpesviridae are achieved by various means including chemical crosslinks (unique to HK97), or auxiliary proteins (lambda, T4, phi29, and herpesviruses). All these viruses have coat proteins (CP) with a conserved, HK97-like core structure. We used a combination of trypsin digestion, gold labeling, cryo-electron microscopy, 3D image reconstruction, and comparative modeling to derive two independent, pseudoatomic models of bacteriophage P22 CP: before and after maturation. P22 capsid stabilization results from intersubunit interactions among N-terminal helices and an extensive "P loop," which obviate the need for crosslinks or auxiliary proteins. P22 CP also has a telokin-like Ig domain that likely stabilizes the monomer fold so that assembly may proceed via individual subunit addition rather than via preformed capsomers as occurs in HK97. Hence, the P22 CP structure may be a paradigm for understanding how monomers assemble in viruses like phi29 and HSV-1.

Published

2010