Your search keyword '"James F. Conway"' showing total 58 results

1. Protofilament structure and supramolecular polymorphism of aggregated mutant huntingtin exon 1

Author

Alessia Lasorsa, Irina Matlahov, Talia Piretra, James F. Conway, Patrick C.A. van der Wel, Jennifer C. Boatz, and Solid-state nuclear magnetic resonance

Subjects

Huntingtin, Mutant, PROTEIN, ORGANIZATION, Fibril, Article, DISEASE, Supramolecular assembly, MECHANISMS, Protein Aggregates, 03 medical and health sciences, Exon, 0302 clinical medicine, Protein Domains, DOMAIN, Structural Biology, FIBRILS, Humans, Molecular Biology, supramolecular assembly, 030304 developmental biology, Huntingtin Protein, 0303 health sciences, DNA Repeat Expansion, Chemistry, AMYLOID POLYMORPHISM, amyloid, Biological activity, Huntington's disease, Exons, IN-VITRO, Fusion protein, In vitro, Microscopy, Electron, SOLID-STATE, Mutation, MAS ssNMR, Biophysics, TEM, 030217 neurology & neurosurgery, MOLECULAR-STRUCTURE

Abstract

Huntington's disease is a progressive neurodegenerative disease caused by expansion of the polyglutamine domain in the first exon of huntingtin (HttEx1). The extent of expansion correlates with disease progression and formation of amyloid-like protein deposits within the brain. The latter display polymorphism at the microscopic level, both in cerebral tissue and in vitro. Such polymorphism can dramatically influence cytotoxicity, leading to much interest in the conditions and mechanisms that dictate the formation of polymorphs. We examine conditions that govern HttEx1 polymorphism in vitro, including concentration and the role of the non-polyglutamine flanking domains. Using electron microscopy, we observe polymorphs that differ in width and tendency for higher-order bundling. Strikingly, aggregation yields different polymorphs at low and high concentrations. Narrow filaments dominate at low concentrations that may be more relevant in vivo. We dissect the role of N- and C-terminal flanking domains using protein with the former (httNT or N17) largely removed. The truncated protein is generated by trypsin cleavage of soluble HttEx1 fusion protein, which we analyze in some detail. Dye binding and solid-state NMR studies reveal changes in fibril surface characteristics and flanking domain mobility. Higher-order interactions appear facilitated by the C-terminal tail, while the polyglutamine forms an amyloid core resembling those of other polyglutamine deposits. Fibril-surface-mediated branching, previously attributed to secondary nucleation, is reduced in absence of httNT. A new model for the architecture of the HttEx1 filaments is presented and discussed in context of the assembly mechanism and biological activity.

Published

2020

2. Mobile Loops and Electrostatic Interactions Maintain the Flexible Tail Tube of Bacteriophage Lambda

Author

Alexis Huet, James F. Conway, Patricia L. Campbell, Robert L. Duda, and Jamie Nassur

Subjects

Models, Molecular, Fold (higher-order function), Viral protein, viruses, Static Electricity, Siphoviridae, medicine.disease_cause, Article, Bacteriophage, 03 medical and health sciences, chemistry.chemical_compound, Capsid, 0302 clinical medicine, Structural Biology, medicine, Tube (fluid conveyance), A-DNA, Amino Acid Sequence, Molecular Biology, 030304 developmental biology, Physics, 0303 health sciences, biology, Cryoelectron Microscopy, Virion, Viral Tail Proteins, biology.organism_classification, Bacteriophage lambda, chemistry, Biophysics, Capsid Proteins, 030217 neurology & neurosurgery, DNA

Abstract

The long flexible tail tube of bacteriophage lambda connects its capsid to the tail tip. On infection, a DNA ejection signal is passed from the tip, along the tube to the capsid that triggers passage of the DNA down the tube and into the host bacterium. The tail tube is built from repeating units of the major tail protein, gpV, which has two distinctive domains. Its N-terminal domain has the same fold as proteins that form the rigid inner tubes of contractile tail phages, such as T4, and its C-terminal domain adopt an Ig-like fold of unknown function. We determined structures of the lambda tail tube in free tails and in virions before and after DNA ejection using cryoelectron microscopy. Modeling of the density maps reveals how electrostatic interactions and a mobile loop participate in assembly and also impart flexibility to the tube while maintaining its integrity. We also demonstrate how a common protein fold produces rigid tubes in some phages but flexible tubes in others.

Published

2020

3. High-resolution asymmetric structure of a Fab–virus complex reveals overlap with the receptor binding site

Author

James F. Conway, Carol M. Bator, Daniel J. Goetschius, Susan Hafenstein, Robert E. Ashley, Alexander M. Makhov, Kai Huang, Lindsey J. Organtini, Samantha R. Hartmann, Colin R. Parrish, and Heather M. Callaway

Subjects

Parvovirus, Canine, Cryo-electron microscopy, medicine.drug_class, viruses, ISECC, Antibodies, Viral, Monoclonal antibody, Microbiology, Virus, Epitope, Epitopes, Immunoglobulin Fab Fragments, 03 medical and health sciences, Capsid, Dogs, Protein Domains, medicine, Animals, Antigens, 030304 developmental biology, epitope, 0303 health sciences, Binding Sites, Multidisciplinary, biology, 030306 microbiology, Parvovirus, Chemistry, parvovirus, Cryoelectron Microscopy, Canine parvovirus, Biological Sciences, biology.organism_classification, virus–fab complex, Mutation, Biophysics, cryo-EM, Protein Binding, Conformational epitope

Abstract

Significance Our study makes significant progress understanding asymmetry in icosahedral viruses that would be otherwise masked by forcing homogeneity through icosahedral averaging. Using an asymmetric approach revealed the atomic-resolution structure of a complex between canine parvovirus and a strain-specific neutralizing antibody. Since species jumping is a rare event in DNA viruses, the emergence of an antibody that binds more avidly to the canine-adapted virus (and not ancestral feline equivalent) is of special interest. The Fab-bound and -unbound epitopes were solved on the same virus capsid with an atomic-resolution asymmetric map. Fab 14 stabilizes a capsid loop within the same binding site used by the receptor, suggesting capsid conformational change or steric competition with the receptor contributes to the mechanism of antibody neutralization., Canine parvovirus is an important pathogen causing severe diseases in dogs, including acute hemorrhagic enteritis, myocarditis, and cerebellar disease. Overlap on the surface of parvovirus capsids between the antigenic epitope and the receptor binding site has contributed to cross-species transmission, giving rise to closely related variants. It has been shown that Mab 14 strongly binds and neutralizes canine but not feline parvovirus, suggesting this antigenic site also controls species-specific receptor binding. To visualize the conformational epitope at high resolution, we solved the cryogenic electron microscopy (cryo-EM) structure of the Fab–virus complex. We also created custom software, Icosahedral Subparticle Extraction and Correlated Classification, to solve a Fab–virus complex with only a few Fab bound per capsid and visualize local structures of the Fab-bound and -unbound antigenic sites extracted from the same complex map. Our results identified the antigenic epitope that had significant overlap with the receptor binding site, and the structures revealed that binding of Fab induced conformational changes to the virus. We were also able to assign the order and position of attached Fabs to allow assessment of complementarity between the Fabs bound to different positions. This approach therefore provides a method for using cryo-EM to investigate complementarity of antibody binding.

Published

2021

4. Role of the Herpes Simplex Virus CVSC Proteins at the Capsid Portal Vertex

Author

Fred L. Homa, Jamie B. Huffman, James F. Conway, and Alexis Huet

Subjects

Genes, Viral, viruses, Immunology, Genome, Viral, Herpesvirus 1, Human, Biology, medicine.disease_cause, Virus Replication, Microbiology, Genome, Virus, law.invention, Cell Line, 03 medical and health sciences, chemistry.chemical_compound, Viral Proteins, Capsid, law, Virology, Chlorocebus aethiops, DNA Packaging, medicine, Animals, Gene, Vero Cells, 030304 developmental biology, Helix bundle, Cell Nucleus, 0303 health sciences, Endodeoxyribonucleases, Structure and Assembly, Virus Assembly, 030302 biochemistry & molecular biology, Cryoelectron Microscopy, Herpes simplex virus, chemistry, Insect Science, DNA, Viral, Recombinant DNA, Capsid Proteins, DNA

Abstract

The packaging of DNA into preformed capsids is a critical step during herpesvirus infection. For herpes simplex virus, this process requires the products of seven viral genes: the terminase proteins pUL15, pUL28, and pUL33; the capsid vertex-specific component (CVSC) proteins pUL17 and pUL25; and the portal proteins pUL6 and pUL32. The pUL6 portal dodecamer is anchored at one vertex of the capsid by interactions with the adjacent triplexes as well as helical density attributed to the pUL17 and pUL25 subunits of the CVSC. To define the roles and structures of the CVSC proteins in virus assembly and DNA packaging, we isolated a number of recombinant viruses expressing pUL25, pUL17, and pUL36 fused with green or red fluorescent proteins as well as viruses with specific deletions in the CVSC genes. Biochemical and structural studies of these mutants demonstrated that (i) four of the helices in the CVSC helix bundle can be attributed to two copies each of pUL36 and pUL25, (ii) pUL17 and pUL6 are required for capsid binding of the terminase complex in the nucleus, (iii) pUL17 is important for determining the site of the first cleavage reaction generating replicated genomes with termini derived from the long-arm component of the herpes simplex virus 1 (HSV-1) genome, (iv) pUL36 serves no direct role in cleavage/packaging, (v) cleavage and stable packaging of the viral genome involve an ordered interaction of the terminase complex and pUL25 with pUL17 at the portal vertex, and (vi) packaging of the viral genome results in a dramatic displacement of the portal. IMPORTANCE Herpes simplex virus 1 (HSV-1) is the causative agent of several pathologies ranging in severity from the common cold sore to life-threatening encephalitic infection. A critical step during productive HSV-1 infection is the cleavage and packaging of replicated, concatemeric viral DNA into preformed capsids. A key knowledge gap is how the capsid engages the replicated viral genome and the subsequent packaging of a unit-length HSV genome. Here, biochemical and structural studies focused on the unique portal vertex of wild-type HSV and packaging mutants provide insights into the mechanism of HSV genome packaging. The significance of our research is in identifying the portal proteins pUL6 and pUL17 as key viral factors for engaging the terminase complex with the capsid and the subsequent cleavage, packaging, and stable incorporation of the viral genome in the HSV-1 capsid.

Published

2020

5. Cryo-EM maps reveal five-fold channel structures and their modification by gatekeeper mutations in the parvovirus minute virus of mice (MVM) capsid

Author

Suriyasri Subramanian, Alexander M. Makhov, Javier O. Cifuente, Peter Tattersall, Lindsey J. Organtini, Alec Grossman, Susan Hafenstein, James F. Conway, Susan F. Cotmore, Phillip P. Domeier, and Anthony D'Abramo

Subjects

0301 basic medicine, Virosomes, Cryo-electron microscopy, Parvovirus, viruses, Cryoelectron Microscopy, Mutant, Wild type, Biology, biology.organism_classification, Virology, Genome, Article, Cell biology, 03 medical and health sciences, chemistry.chemical_compound, Capsid, 030104 developmental biology, chemistry, Mutation, Minute Virus of Mice, Minute virus of mice, DNA

Abstract

In minute virus of mice (MVM) capsids, icosahedral five-fold channels serve as portals mediating genome packaging, genome release, and the phased extrusion of viral peptides. Previous studies suggest that residues L172 and V40 are essential for channel function. The structures of MVMi wildtype, and mutant L172T and V40A virus-like particles (VLPs) were solved from cryo-EM data. Two constriction points, termed the mid-gate and inner-gate, were observed in the channels of wildtype particles, involving residues L172 and V40 respectively. While the mid-gate of V40A VLPs appeared normal, in L172T adjacent channel walls were altered, and in both mutants there was major disruption of the inner-gate, demonstrating that direct L172:V40 bonding is essential for its structural integrity. In wildtype particles, residues from the N-termini of VP2 map into claw-like densities positioned below the channel opening, which become disordered in the mutants, implicating both L172 and V40 in the organization of VP2 N-termini.

Published

2017

6. Mitochondrial fatty acid oxidation and the electron transport chain comprise a multifunctional mitochondrial protein complex

Author

Claudette M. St. Croix, Simon C. Watkins, Stephen P. McCalley, Meicheng Wang, Shrabani Basu, Johan Palmfeldt, Niels Gregersen, Michael J. Calderon, Hana Alharbi, Yudong Wang, James F. Conway, Alexander M. Makhov, and Jerry Vockley

Subjects

0301 basic medicine, Substrate channeling, Citric Acid Cycle, Mitochondrial protein complex, Mitochondrion, Bioenergetics, Biochemistry, Mitochondria, Heart, Mitochondrial Proteins, 03 medical and health sciences, Electron Transport Complex III, Mice, Animals, Inner mitochondrial membrane, Molecular Biology, Electron Transport Complex I, 030102 biochemistry & molecular biology, Chemistry, Fatty Acids, Cell Biology, Electron transport chain, Electrophoreses, Rats, Citric acid cycle, 030104 developmental biology, Coenzyme Q – cytochrome c reductase, Oxidation-Reduction

Abstract

Three mitochondrial metabolic pathways are required for efficient energy production in eukaryotic cells: the electron transfer chain (ETC), fatty acid β-oxidation (FAO), and the tricarboxylic acid cycle. The ETC is organized into inner mitochondrial membrane supercomplexes that promote substrate channeling and catalytic efficiency. Although previous studies have suggested functional interaction between FAO and the ETC, their physical interaction has never been demonstrated. In this study, using blue native gel and two-dimensional electrophoreses, nano-LC-MS/MS, immunogold EM, and stimulated emission depletion microscopy, we show that FAO enzymes physically interact with ETC supercomplexes at two points. We found that the FAO trifunctional protein (TFP) interacts with the NADH-binding domain of complex I of the ETC, whereas the electron transfer enzyme flavoprotein dehydrogenase interacts with ETC complex III. Moreover, the FAO enzyme very-long-chain acyl-CoA dehydrogenase physically interacted with TFP, thereby creating a multifunctional energy protein complex. These findings provide a first view of an integrated molecular architecture for the major energy-generating pathways in mitochondria that ensures the safe transfer of unstable reducing equivalents from FAO to the ETC. They also offer insight into clinical ramifications for individuals with genetic defects in these pathways.

Published

2019

7. Mitochondrial ultrastructure, function, and calcium buffering by massive calcium loading observed using advanced cryo‐electron microscopy, high‐resolution respirometry and spectrofluorimetry

Author

Jason R. Schrad, Jasiel O. Strubbe, Jason N. Bazil, James F. Conway, and Kristin N. Parent

Subjects

High resolution respirometry, Chemistry, Cryo-electron microscopy, Calcium buffering, Genetics, Biophysics, Calcium loading, Molecular Biology, Biochemistry, Function (biology), Biotechnology, Mitochondrial ultrastructure

Published

2019

8. A Novel Packing for A-Form DNA in an Icosahedral Virus

Author

Zhangli Su, Stefan Schouten, Ying Liu, David Prangishvili, Fengbin Wang, Mart Krupovic, Edward H. Egelman, and James F. Conway

Subjects

Crystallography, Icosahedral symmetry, Chemistry, Biophysics, A-DNA, Virus

Published

2020

9. The apical region of the herpes simplex virus major capsid protein promotes capsid maturation

Author

Laura Lee Ruhge, Alexis Huet, James F. Conway, and Gregory A. Smith

Subjects

0301 basic medicine, Scaffold protein, medicine.medical_treatment, viruses, Immunology, Morphogenesis, Herpesvirus 1, Human, Biology, medicine.disease_cause, Cleavage (embryo), Microbiology, Epitope, Epitopes, Viral Proteins, 03 medical and health sciences, Capsid, Viral scaffold, Virology, Chlorocebus aethiops, medicine, Animals, Vero Cells, chemistry.chemical_classification, Protease, Structure and Assembly, Virus Assembly, Virion, biochemical phenomena, metabolism, and nutrition, Amino acid, Cell biology, medicine.anatomical_structure, 030104 developmental biology, Herpes simplex virus, chemistry, Insect Science, Mutation, Capsid Proteins, Nucleus

Abstract

The herpesvirus capsid assembles in the nucleus as an immature procapsid precursor built around viral scaffold proteins. The event that initiates procapsid maturation is unknown, but it is dependent upon activation of the VP24 internal protease. Scaffold cleavage triggers angularization of the shell and its decoration with the VP26 and pUL25 capsid-surface proteins. In both the procapsid and mature angularized capsid, the apical region of the major capsid protein (VP5) is surface exposed. We investigated whether the VP5 apical region contributes to intracellular transport dynamics following entry into primary sensory neurons and also tested the hypothesis that conserved negatively charged amino acids in the apical region contribute to VP26 acquisition. To our surprise, neither hypothesis proved true. Instead, mutation of glutamic acid residues in the apical region delayed viral propagation and induced focal capsid accumulations in nuclei. Examination of capsid morphogenesis based on epitope unmasking, capsid composition, and ultrastructural analysis indicated that these clusters consisted of procapsids. The results demonstrate that, in addition to established events that occur inside the capsid, the exterior capsid shell promotes capsid morphogenesis and maturation. IMPORTANCE Herpesviruses assemble capsids and encapsidate their genomes by a process that is unlike those of other mammalian viruses but is similar to those of some bacteriophage. Many important aspects of herpesvirus morphogenesis remain enigmatic, including how the capsid shell matures into a stable angularized configuration. Capsid maturation is triggered by activation of a protease that cleaves an internal protein scaffold. We report on the fortuitous discovery that a region of the major capsid protein that is exposed on the outer surface of the capsid also contributes to capsid maturation, demonstrating that the morphogenesis of the capsid shell from its procapsid precursor to the mature angularized form is dependent upon internal and external components of the megastructure.

Published

2018

10. Proteomic profiling of extracellular vesicles released from vascular smooth muscle cells during initiation of phosphate-induced mineralization

Author

Victoria Smethurst, Daisy Monier, James A. Mobley, Sandeep C. Chaudhary, Sana Khalid, James F. Conway, Dobrawa Napierala, and Alexis Huet

Subjects

0301 basic medicine, Proteomics, Vascular smooth muscle, Myocytes, Smooth Muscle, Biochemistry, Mineralization (biology), Extracellular vesicles, Article, Muscle, Smooth, Vascular, Phosphates, Elevated serum, 03 medical and health sciences, chemistry.chemical_compound, Extracellular Vesicles, Rheumatology, Humans, Orthopedics and Sports Medicine, Vascular Calcification, Molecular Biology, Vascular calcification, Proteomic Profiling, Gene Expression Profiling, Cell Biology, Phosphate, Cell biology, 030104 developmental biology, chemistry

Abstract

Purpose/Aim: Elevated serum phosphate is one of the major factors contributing to vascular calcification. Studies suggested that extracellular vesicles released from vascular smooth muscle cells significantly contribute to the initiation and progression of this pathology. Recently, we have demonstrated that elevated phosphate stimulates release of extracellular vesicles from osteogenic cells at the initiation of the mineralization process. Here, we used MOVAS cell line as an in vitro model of vascular calcification to examine whether vascular smooth muscle cells respond to high phosphate levels in a similar way and increase formation of extracellular vesicles. Materials and Methods: Vesicles residing in extracellular matrix as well as vesicles released to culture medium were evaluated by nanoparticle tracking analyses. In addition, using mass spectrometry and protein profiling, protein composition of extracellular vesicles released by MOVAS cells under standard growth conditions and upon exposure to high phosphate was compared. Results: Significant increase of the number of extracellular vesicles was detected after 72 h of exposure of cells to high phosphate. Elevated phosphate levels also affected protein composition of extracellular vesicles released from MOVAS cells. Finally, the comparative analyses of proteins in extracellular vesicles isolated from extracellular matrix and from conditioned medium identified significant differences in protein composition in these two groups of extracellular vesicles. Conclusions: Results of this study demonstrate that exposure of MOVAS cells to high phosphate levels stimulates the release of extracellular vesicles and changes their protein composition.

Published

2018

11. High-Resolution Structure Analysis of Antibody V5 and U4 Conformational Epitopes on Human Papillomavirus 16

Author

Robert E. Ashley, Neil D. Christensen, Susan Hafenstein, Sarah A. Brendle, Alexander M. Makhov, Jian Guan, Stephanie M. Bywaters, and James F. Conway

Subjects

0301 basic medicine, Models, Molecular, Protein Conformation, viruses, lcsh:QR1-502, Antibodies, Viral, Epitope, lcsh:Microbiology, Epitopes, 0302 clinical medicine, conformational epitope, Genotype, antibody neutralization, Receptor, human papillomavirus, Human papillomavirus 16, cryo-electron Microscopy (cryo-EM), U4 and V5, competition, steric clash, complex, virus, fab, biology, Chemistry, Antibodies, Monoclonal, 3. Good health, Infectious Diseases, Capsid, 030220 oncology & carcinogenesis, Antibody, Protein Binding, medicine.drug_class, Enzyme-Linked Immunosorbent Assay, Monoclonal antibody, Virus, Article, 03 medical and health sciences, Immunoglobulin Fab Fragments, Virology, medicine, Cryoelectron Microscopy, Virus Internalization, Antibodies, Neutralizing, 030104 developmental biology, biology.protein, Capsid Proteins, Conformational epitope

Abstract

Cancers attributable to human papillomavirus (HPV) place a huge burden on the health of both men and women. The current commercial vaccines are genotype specific and provide little therapeutic benefit to patients with existing HPV infections. Identifying the conformational epitopes on the virus capsid supports the development of improved recombinant vaccines to maximize long-term protection against multiple types of HPV. Fragments of antibody (Fab) digested from the neutralizing monoclonal antibodies H16.V5 (V5) and H16.U4 (U4) were bound to HPV16 capsids and the structures of the two virus-Fab complexes were solved to near atomic resolution using cryo-electron microscopy. The structures reveal virus conformational changes, the Fab-binding mode to the capsid, the residues comprising the epitope and indicate a potential interaction of U4 with the minor structural protein, L2. Competition enzyme-linked immunosorbent assay (ELISA) showed V5 outcompetes U4 when added sequentially, demonstrating a steric interference even though the footprints do not overlap. Combined with our previously reported immunological and structural results, we propose that the virus may initiate host entry through an interaction between the icosahedral five-fold vertex of the capsid and receptors on the host cell. The highly detailed epitopes identified for the two antibodies provide a framework for continuing biochemical, genetic and biophysical studies.

Published

2017

12. Capsids and Genomes of Jumbo-Sized Bacteriophages Reveal the Evolutionary Reach of the HK97 Fold

Author

Jianfei Hua, Alexis Huet, Carlos A. Lopez, Katerina Toropova, Welkin H. Pope, Robert L. Duda, Roger W. Hendrix, James F. Conway, and Vincent R. Racaniello

Subjects

0301 basic medicine, viruses, 030106 microbiology, Genome, Viral, Microbiology, Genome, Bacteriophage, 03 medical and health sciences, chemistry.chemical_compound, Paleontology, jumbophage, bacteriophage, Virology, evolution, phage, capsid, Bacteriophages, Electrophoresis, Gel, Two-Dimensional, HK97, genome, Gene, Genomic organization, Gel electrophoresis, Genetics, biology, Chromosome, biology.organism_classification, Biological Evolution, QR1-502, 030104 developmental biology, chemistry, Capsid, DNA, Viral, Mutation, cryo-EM, DNA, Research Article

Abstract

Large icosahedral viruses that infect bacteria represent an extreme of the coevolution of capsids and the genomes they accommodate. One subset of these large viruses is the jumbophages, tailed phages with double-stranded DNA genomes of at least 200,000 bp. We explored the mechanism leading to increased capsid and genome sizes by characterizing structures of several jumbophage capsids and the DNA packaged within them. Capsid structures determined for six jumbophages were consistent with the canonical phage HK97 fold, and three had capsid geometries with novel triangulation numbers (T=25, T=28, and T=52). Packaged DNA (chromosome) sizes were larger than the genome sizes, indicating that all jumbophages use a head-full DNA packaging mechanism. For two phages (PAU and G), the sizes appeared very much larger than their genome length. We used two-dimensional DNA gel electrophoresis to show that these two DNAs migrated abnormally due to base modifications and to allow us to calculate their actual chromosome sizes. Our results support a ratchet model of capsid and genome coevolution whereby mutations lead to increased capsid volume and allow the acquisition of additional genes. Once the added genes and larger capsid are established, mutations that restore the smaller size are disfavored., IMPORTANCE A large family of viruses share the same fold of the capsid protein as bacteriophage HK97, a virus that infects bacteria. Members of this family use different numbers of the capsid protein to build capsids of different sizes. Here, we examined the structures of extremely large capsids and measured their DNA content relative to the sequenced genome lengths, aiming to understand the process that increases size. We concluded that mutational changes leading to larger capsids become locked in by subsequent changes to the genome organization.

Published

2017

13. Inducible Polymerization and Two-Dimensional Assembly of the Repeats-in-Toxin (RTX) Domain from the Pseudomonas aeruginosa Alkaline Protease

Author

James F. Conway, Patrick H. Thibodeau, Liang Zhang, Jonathon Franks, and Donna B. Stolz

Subjects

Models, Molecular, Repetitive Sequences, Amino Acid, Amyloid, Protein Folding, Recombinant Fusion Proteins, Green Fluorescent Proteins, chemistry.chemical_element, Biology, Calcium, Protein aggregation, Protein Engineering, Biochemistry, Protein Aggregation, Pathological, Cofactor, Article, Polymerization, 03 medical and health sciences, Bacterial Proteins, Microscopy, Electron, Transmission, Protein Interaction Domains and Motifs, Metalloexopeptidases, 030304 developmental biology, chemistry.chemical_classification, 0303 health sciences, Circular Dichroism, 030302 biochemistry & molecular biology, Serine Endopeptidases, Protein engineering, Alkaline Phosphatase, Amino acid, Kinetics, Enzyme, chemistry, Pseudomonas aeruginosa, biology.protein, Microscopy, Electron, Scanning, Protein folding

Abstract

Self-assembling proteins represent potential scaffolds for the organization of enzymatic activities. The alkaline protease repeats-in-toxin (RTX) domain from Pseudomonas aeruginosa undergoes multiple structural transitions in the presence and absence of calcium, a native structural cofactor. In the absence of calcium, this domain is capable of spontaneous, ordered polymerization, producing amyloid-like fibrils and large two-dimensional protein sheets. This polymerization occurs under near-physiological conditions, is rapid, and can be controlled by regulating calcium in solution. Fusion of the RTX domain to a soluble protein results in the incorporation of engineered protein function into these macromolecular assemblies. Applications of this protein sequence in bacterial adherence and colonization and the generation of biomaterials are discussed.

Published

2014

14. Use of transmission electron microscopy to identify nanocrystals of challenging protein targets

Author

Monica Calero, Aina E. Cohen, Christopher O. Barnes, Irimpan I. Mathews, Guowu Lin, James F. Conway, Chaitan Khosla, Ted M. Ross, Hilary P. Stevenson, Alexander M. Makhov, Hugo Santamaria, Guillermo Calero, Andrea L. Edwards, Oliver B. Zeldin, S. Michael Soltis, and Veeranagu Nagarajan

Subjects

Multidisciplinary, Chemistry, Proteins, Reproducibility of Results, Nanotechnology, Biological Sciences, Crystallography, X-Ray, Recombinant Proteins, law.invention, Amorphous solid, Crystal, Microscopy, Electron, Transmission, Optical microscope, Nanocrystal, Transmission electron microscopy, law, Femtosecond, Escherichia coli, Sf9 Cells, Animals, Nanoparticles, Crystallization, Protein crystallization

Abstract

The current practice for identifying crystal hits for X-ray crystallography relies on optical microscopy techniques that are limited to detecting crystals no smaller than 5 μm. Because of these limitations, nanometer-sized protein crystals cannot be distinguished from common amorphous precipitates, and therefore go unnoticed during screening. These crystals would be ideal candidates for further optimization or for femtosecond X-ray protein nanocrystallography. The latter technique offers the possibility to solve high-resolution structures using submicron crystals. Transmission electron microscopy (TEM) was used to visualize nanocrystals (NCs) found in crystallization drops that would classically not be considered as "hits." We found that protein NCs were readily detected in all samples tested, including multiprotein complexes and membrane proteins. NC quality was evaluated by TEM visualization of lattices, and diffraction quality was validated by experiments in an X-ray free electron laser.

Published

2014

15. Cardiac Mitochondria Ultrastructural and Functional Changes Caused by Massive Calcium Loading Observed using Cryo-EM and High-Resolution Respirometry

Author

Jason R. Schrad, Kristin N. Parent, Jason N. Bazil, James F. Conway, and Jasiel O. Strubbe

Subjects

Cardiac mitochondria, High resolution respirometry, Chemistry, Cryo-electron microscopy, Biophysics, Ultrastructure, Calcium loading

Published

2019

16. CryoTEM study of effects of phosphorylation on the hierarchical assembly of porcine amelogenin and its regulation of mineralization in vitro

Author

Henry C. Margolis, Ping An Fang, James P. Simmer, James F. Conway, and Elia Beniash

Subjects

Swine, Mineralization (biology), Article, law.invention, Serine, Calcification, Physiologic, Dental Enamel Proteins, Microscopy, Electron, Transmission, stomatognathic system, Structural Biology, law, Extracellular, Animals, Phosphorylation, Tooth Crown, Viral matrix protein, Amelogenin, Enamel paint, Chemistry, Anatomy, Cell biology, visual_art, visual_art.visual_art_medium, Recombinant DNA

Abstract

Amelogenin, the major extracellular enamel matrix protein, plays a critical role in regulating the growth and organization of enamel. Assembly and mineralization of full-length native (P173) and recombinant (rP172) porcine amelogenins were studied by cryogenic Transmission Electron Microscopy (cryoTEM). The cryoTEM revealed that both native and recombinant porcine amelogenins undergo step-wise self-assembly. Although the overall structural organization of P173 and rP172 oligomers was similar and resembled oligomers of murine recombinant amelogenin rM179, there were subtle differences suggesting that a single phosphorylated serine present in P173 might affect amelogenin self-assembly. Our mineralization studies demonstrated that both P173 and rP172 oligomers stabilize initial mineral clusters. Importantly, however, rP172 regulated the organization of initial mineral clusters into linear chains and guided the formation of parallel arrays of elongated mineral particles, which are the hallmark of enamel structural organization. These results are similar to those obtained previously using full-length recombinant murine amelogenin (Fang et al., 2011a). In contrast to that seen with rP172, phosphorylated P173 strongly inhibits mineralization for extended periods of time. We propose that these differences might be due to the differences in the structural organization and charge distribution between P173 and rP172. Overall our studies indicate that self-assembly of amelogenin and the mechanisms of its control over mineralization might be universal across different mammalian species. Our data also provide new insight into the effect of phosphorylation on amelogenin self-assembly and its regulation of mineralization.

Published

2013

17. A Two-State Cooperative Expansion Converts the Procapsid Shell of Bacteriophage T5 into a Highly Stable Capsid Isomorphous to the Final Virion Head

Author

Didier Trevarin, Olivier Preux, Alexis Huet, Jeannine Drouin-Wahbi, Javier Pérez, James F. Conway, Dominique Durand, Claire Boulogne, Patrice Vachette, Aurélie Bertin, and Pascale Boulanger

Subjects

biology, Chemistry, Small-angle X-ray scattering, Cryo-electron microscopy, Virus Assembly, viruses, Protein subunit, Cryoelectron Microscopy, Osmolar Concentration, Virion, Prohead, Hydrogen-Ion Concentration, Siphoviridae, biology.organism_classification, Crystallography, chemistry.chemical_compound, Capsid, X-Ray Diffraction, Structural Biology, Ionic strength, Scattering, Small Angle, Molecular Biology, Bacteriophage T5, DNA

Abstract

Capsids of double-stranded DNA (dsDNA) bacteriophages initially assemble into compact procapsids, which undergo expansion upon the genome packaging. This shell remodeling results from a structural rearrangement of head protein subunits. It is a critical step in the capsid maturation pathway that yields final particles capable to withstand the huge internal pressure generated by the packed DNA. Here, we report on the expansion process of the large capsid ( T = 13) of bacteriophage T5. We purified the intermediate prohead II form, which is competent for packaging the 121-kbp dsDNA genome, and we investigated its morphology and dimensions using cryo-electron microscopy and small-angle X-ray scattering. Decreasing the pH or the ionic strength triggers expansion of prohead II, converting them into thinner and more faceted capsids isomorphous to the mature virion particles. At low pH, prohead II expansion is a highly cooperative process lacking any detectable intermediate. This two-state reorganization of the capsid lattice per se leads to a remarkable stabilization of the particle. The melting temperature of expanded T5 capsid is virtually identical with that of more complex shells that are reinforced by inter-subunit cross-linking (HK97) or by additional cementing proteins (T4). The T5 capsid with its “simple” two-state conversion thus appears to be a very attractive model for investigating the mechanism of the large-scale allosteric transition that takes place upon the genome packaging of dsDNA bacteriophages.

Published

2013

18. Hierarchical self-assembly of amelogenin and the regulation of biomineralization at the nanoscale

Author

Henry C. Margolis, Ping An Fang, James F. Conway, James P. Simmer, and Elia Beniash

Subjects

Calcium Phosphates, Multidisciplinary, Nanocomposite, Materials science, Amelogenin, Enamel paint, Cryoelectron Microscopy, Nanoparticle, Nanotechnology, Biological Sciences, Oligomer, Mice, chemistry.chemical_compound, Calcification, Physiologic, stomatognathic system, chemistry, visual_art, Image Processing, Computer-Assisted, visual_art.visual_art_medium, Animals, Nanoparticles, Crystallite, Self-assembly, Biomineralization

Abstract

Enamel is a highly organized hierarchical nanocomposite, which consists of parallel arrays of elongated apatitic crystallites forming an intricate three-dimensional microstructure. Amelogenin, the major extracellular matrix protein of dental enamel, regulates the formation of these crystalline arrays via cooperative interactions with forming mineral phase. Using cryoelectron microscopy, we demonstrate that amelogenin undergoes stepwise hierarchical self-assembly. Furthermore, our results indicate that interactions between amelogenin hydrophilic C-terminal telopeptides are essential for oligomer formation and for subsequent steps of hierarchical self-assembly. We further show that amelogenin assemblies stabilize mineral prenucleation clusters and guide their arrangement into linear chains that organize as parallel arrays. The prenucleation clusters subsequently fuse together to form needle-shaped mineral particles, leading to the formation of bundles of crystallites, the hallmark structural organization of the forming enamel at the nanoscale. These findings provide unique insight into the regulation of biological mineralization by specialized macromolecules and an inspiration for bottom-up strategies for the materials design.

Published

2011

19. Residues of the UL25 Protein of Herpes Simplex Virus That Are Required for Its Stable Interaction with Capsids

Author

Fred L. Homa, Katerina Toropova, James F. Conway, Jamie B. Huffman, and Shelley K. Cockrell

Subjects

Models, Molecular, viruses, Immunology, Herpesvirus 1, Human, Biology, medicine.disease_cause, Microbiology, Virus, Green fluorescent protein, Virology, Protein Interaction Mapping, medicine, Protein Structure, Quaternary, Sequence Deletion, chemistry.chemical_classification, Virus Assembly, Structure and Assembly, Cryoelectron Microscopy, Capsomere, Virion, Molecular biology, Amino acid, N-terminus, Herpes simplex virus, Amino Acid Substitution, Biochemistry, Capsid, chemistry, Insect Science, Capsid Proteins, Binding domain

Abstract

The herpes simplex virus 1 (HSV-1) UL25 gene product is a minor capsid component that is required for encapsidation, but not cleavage, of replicated viral DNA. UL25 is located on the capsid surface in a proposed heterodimer with UL17, where five copies of the heterodimer are found at each of the capsid vertices. Previously, we demonstrated that amino acids 1 to 50 of UL25 are essential for its stable interaction with capsids. To further define the UL25 capsid binding domain, we generated recombinant viruses with either small truncations or amino acid substitutions in the UL25 N terminus. Studies of these mutants demonstrated that there are two important regions within the capsid binding domain. The first 27 amino acids are essential for capsid binding of UL25, while residues 26 to 39, which are highly conserved in the UL25 homologues of other alphaherpesviruses, were found to be critical for stable capsid binding. Cryo-electron microscopy reconstructions of capsids containing either a small tag on the N terminus of UL25 or the green fluorescent protein (GFP) fused between amino acids 50 and 51 of UL25 demonstrate that residues 1 to 27 of UL25 contact the hexon adjacent to the penton. A second region, most likely centered on amino acids 26 to 39, contacts the triplex that is one removed from the penton. Importantly, both of these UL25 capsid binding regions are essential for the stable packaging of full-length viral genomes.

Published

2011

20. Sar1 assembly regulates membrane constriction and ER export

Author

Carolyn B. Coyne, Adam L. Baker, Meir Aridor, Simon C. Watkins, Yasunori Yamamoto, Kimberly R. Long, and James F. Conway

Subjects

Guanosine, Biology, Endoplasmic Reticulum, Article, Protein Structure, Secondary, 03 medical and health sciences, chemistry.chemical_compound, 0302 clinical medicine, Dogs, Animals, Humans, COPII, Research Articles, 030304 developmental biology, Dynamin, Monomeric GTP-Binding Proteins, 0303 health sciences, Endoplasmic reticulum, Vesicle, Cell Membrane, Biological Transport, Cell Biology, Cell biology, body regions, Enzyme Activation, Membrane, chemistry, Mutation, Triphosphatase, COP-Coated Vesicles, Caco-2 Cells, Protein Multimerization, Bacterial outer membrane, 030217 neurology & neurosurgery, hormones, hormone substitutes, and hormone antagonists

Abstract

While dynamin pinches vesicles from the plasma membrane, the Sar1 GTPase specializes in cinching ER membrane tubules., The guanosine triphosphatase Sar1 controls the assembly and fission of COPII vesicles. Sar1 utilizes an amphipathic N-terminal helix as a wedge that inserts into outer membrane leaflets to induce vesicle neck constriction and control fission. We hypothesize that Sar1 organizes on membranes to control constriction as observed with fission proteins like dynamin. Sar1 activation led to membrane-dependent oligomerization that transformed giant unilamellar vesicles into small vesicles connected through highly constricted necks. In contrast, membrane tension provided through membrane attachment led to organization of Sar1 in ordered scaffolds that formed rigid, uniformly nonconstricted lipid tubules to suggest that Sar1 organization regulates membrane constriction. Sar1 organization required conserved residues located on a unique C-terminal loop. Mutations in this loop did not affect Sar1 activation or COPII recruitment and enhanced membrane constriction, yet inhibited Sar1 organization and procollagen transport from the endoplasmic reticulum (ER). Sar1 activity was directed to liquid-disordered lipid phases. Thus, lipid-directed and tether-assisted Sar1 organization controls membrane constriction to regulate ER export.

Published

2010

21. Structure and Energetics of Encapsidated DNA in Bacteriophage HK97 Studied by Scanning Calorimetry and Cryo-electron Microscopy

Author

Brian Firek, Philip D. Ross, Roger W. Hendrix, Robert L. Duda, Naiqian Cheng, James F. Conway, and Alasdair C. Steven

Subjects

Calorimetry, Differential Scanning, Protein Conformation, Cryo-electron microscopy, Chemistry, viruses, Cryoelectron Microscopy, Calorimetry, DNA condensation, Article, Nucleic acid thermodynamics, Crystallography, chemistry.chemical_compound, Capsid, Structural Biology, Ionic strength, DNA, Viral, Nucleic Acid Conformation, Thermodynamics, Bacteriophages, Capsid Proteins, Denaturation (biochemistry), Molecular Biology, DNA

Abstract

Encapsidation of duplex DNA by bacteriophages represents an extreme case of genome condensation, reaching near-crystalline concentrations of DNA. The HK97 system is well suited to study this phenomenon in view of the detailed knowledge of its capsid structure. To characterize the interactions involved, we combined calorimetry with cryo-electron microscopy and native gel electrophoresis. We found that, as in other phages, HK97 DNA is organized in coaxially wound nested shells. When DNA-filled capsids (heads) are scanned in buffer containing 1 mM Mg(2+), DNA melting and capsid denaturation both contribute to the complex thermal profile between 82 degrees C and 96 degrees C. In other conditions (absence of Mg(2+) and lower ionic strength), DNA melting shifts to lower temperatures and the two events are resolved. Heads release their DNA at temperatures well below the onset of DNA melting or capsid denaturation. We suggest that, on heating, the internal pressure increases, causing the DNA to exit-probably via the portal vertex-while the capsid, although largely intact, sustains local damage that leads to an earlier onset of thermal denaturation. Heads differ structurally from empty capsids in the curvature of their protein shell, a change attributable to outwards pressure exerted by the DNA. We propose that this transition is sensed by the portal that is embedded in the capsid wall, whereupon the structure of the portal and its interactions with terminase, the packaging enzyme, are altered, thus signaling that packaging is at or approaching completion.

Published

2009

22. Polyglutamine disruption of the huntingtin exon 1 N terminus triggers a complex aggregation mechanism

Author

Ravindra Kodali, Veronique M. Chellgren, Trevor P. Creamer, Rakesh Mishra, James F. Conway, Ashwani Kumar Thakur, Dalaver H. Anjum, Ronald Wetzel, In-Ja L. Byeon, Monika Thakur, Murali Jayaraman, and Angela M. Gronenborn

Subjects

Magnetic Resonance Spectroscopy, Huntingtin, Macromolecular Substances, Protein Conformation, Nerve Tissue Proteins, Peptide, Plasma protein binding, Models, Biological, Article, 03 medical and health sciences, Exon, 0302 clinical medicine, Protein structure, Microscopy, Electron, Transmission, Structural Biology, Huntingtin Protein, Humans, Molecular Biology, 030304 developmental biology, chemistry.chemical_classification, 0303 health sciences, Chemistry, Circular Dichroism, Nuclear Proteins, Amino acid, N-terminus, Kinetics, Biochemistry, Biophysics, Protein Multimerization, Peptides, 030217 neurology & neurosurgery, Protein Binding

Abstract

Simple polyglutamine (polyQ) peptides aggregate in vitro via a nucleated growth pathway directly yielding amyloid-like aggregates. We show here that the 17-amino-acid flanking sequence (HTT(NT)) N-terminal to the polyQ in the toxic huntingtin exon 1 fragment imparts onto this peptide a complex alternative aggregation mechanism. In isolation, the HTT(NT) peptide is a compact coil that resists aggregation. When polyQ is fused to this sequence, it induces in HTT(NT), in a repeat-length dependent fashion, a more extended conformation that greatly enhances its aggregation into globular oligomers with HTT(NT) cores and exposed polyQ. In a second step, a new, amyloid-like aggregate is formed with a core composed of both HTT(NT) and polyQ. The results indicate unprecedented complexity in how primary sequence controls aggregation within a substantially disordered peptide and have implications for the molecular mechanism of Huntington's disease.

Published

2009

23. A Free Energy Cascade with Locks Drives Assembly and Maturation of Bacteriophage HK97 Capsid

Author

Naiqian Cheng, Alasdair C. Steven, James F. Conway, Philip D. Ross, Brian Firek, Lindsay Dierkes, Roger W. Hendrix, and Robert L. Duda

Subjects

Models, Molecular, Steric effects, Conformational change, Calorimetry, Differential Scanning, medicine.diagnostic_test, Chemistry, Cryo-electron microscopy, Proteolysis, Protein subunit, Cryoelectron Microscopy, Capsomere, Article, Protein Structure, Tertiary, Crystallography, Capsid, Structural Biology, Covalent bond, Mutation, medicine, Thermodynamics, Bacteriophages, Capsid Proteins, Molecular Biology

Abstract

We investigated the thermodynamic basis of HK97 assembly by scanning calorimetry and cryo-electron microscopy. This pathway involves self-assembly of hexamers and pentamers of the precursor capsid protein gp5 into procapsids; proteolysis of their N-terminal Delta-domains; expansion, a major conformational change; and covalent crosslinking. The thermal denaturation parameters convey the changes in stability at successive steps in assembly, and afford estimates of the corresponding changes in free energy. The procapsid represents a kinetically accessible local minimum of free energy. In maturation, it progresses to lower minima in a cascade punctuated by irreversible processes ("locks"), i.e. proteolysis and crosslinking, that lower kinetic barriers and prevent regression. We infer that Delta-domains not only guide assembly but also restrain the procapsid from premature expansion; their removal by proteolysis is conducive to initiating expansion and to its proceeding to completion. We also analyzed the mutant E219K, whose capsomers reassemble in vitro into procapsids with vacant vertices called "whiffleballs". E219K assemblies all have markedly reduced stability compared to wild-type gp5 (DeltaT(p) approximately -7 degrees C to -10 degrees C; where T(p) is the denaturation temperature). As the mutated residue is buried in the core of gp5, we attribute the observed reduction in stability to steric and electrostatic perturbations of the packing of side-chains in the subunit interior. To explain the whiffleball phenotype, we suggest that these effects propagate to the capsomer periphery in such a way as to differentially affect the stability or solubility of dissociated pentamers, leaving only hexamers to reassemble.

Published

2006

24. Structure of the Dodecahedral Penton Particle from Human Adenovirus Type 3

Author

Patrizia Fuschiotti, Celine Fabry, Guy Schoehn, James F. Conway, Pascal Fender, Jadwiga Chroboczek, Elizabeth A. Hewat, and Rob W.H. Ruigrok

Subjects

Models, Molecular, chemistry.chemical_classification, Protein Conformation, Pentamer, Cryo-electron microscopy, Internal cavity, Adenoviruses, Human, viruses, Molecular Sequence Data, Peptide, Microscopy, Electron, Dodecahedron, Crystallography, Capsid, Dodecameric protein, chemistry, Structural Biology, Humans, Capsid Proteins, Amino Acid Sequence, Sequence Alignment, Molecular Biology, Peptide sequence, Adenovirus serotype

Abstract

The sub-viral dodecahedral particle of human adenovirus type 3, composed of the viral penton base and fiber proteins, shares an important characteristic of the entire virus: it can attach to cells and penetrate them. Structure determination of the fiberless dodecahedron by cryo-electron microscopy to 9 Angstroms resolution reveals tightly bound pentamer subunits, with only minimal interfaces between penton bases stabilizing the fragile dodecahedron. The internal cavity of the dodecahedron is approximately 80 Angstroms in diameter, and the interior surface is accessible to solvent through perforations of approximately 20 Angstroms diameter between the pentamer towers. We observe weak density beneath pentamers that we attribute to a penton base peptide including residues 38-48. The intact amino-terminal domain appears to interfere with pentamer-pentamer interactions and its absence by mutation or proteolysis is essential for dodecamer assembly. Differences between the 9 Angstroms dodecahedron structure and the adenovirus serotype 2 (Ad2) crystallographic model correlate closely with differences in sequence. The 3D structure of the dodecahedron including fibers at 16 Angstroms resolution reveals extra density on the top of the penton base that can be attributed to the fiber N terminus. The fiber itself exhibits striations that correlate with features of the atomic structure of the partial Ad2 fiber and that represent a repeat motif present in the amino acid sequence. These new observations offer important insights into particle assembly and stability, as well as the practicality of using the dodecahedron in targeted drug delivery. The structural work provides a sound basis for manipulating the properties of this particle and thereby enhancing its value for such therapeutic use.

Published

2006

25. Metastable Intermediates as Stepping Stones on the Maturation Pathways of Viral Capsids

Author

Alasdair C. Steven, James F. Conway, Giovanni Cardone, Naiqian Cheng, Lili You, Roger W. Hendrix, and Robert L. Duda

Subjects

0303 health sciences, Chemistry, Protein subunit, Virus Assembly, 030302 biochemistry & molecular biology, Capsomere, Mutant, Cryoelectron Microscopy, Energy landscape, Random hexamer, Calorimetry, Virology, Microbiology, QR1-502, Folding (chemistry), 03 medical and health sciences, Capsid, Biophysics, Virus maturation, Bacteriophages, 030304 developmental biology, Research Article

Abstract

As they mature, many capsids undergo massive conformational changes that transform their stability, reactivity, and capacity for DNA. In some cases, maturation proceeds via one or more intermediate states. These structures represent local minima in a rich energy landscape that combines contributions from subunit folding, association of subunits into capsomers, and intercapsomer interactions. We have used scanning calorimetry and cryo-electron microscopy to explore the range of capsid conformations accessible to bacteriophage HK97. To separate conformational effects from those associated with covalent cross-linking (a stabilization mechanism of HK97), a cross-link-incompetent mutant was used. The mature capsid Head I undergoes an endothermic phase transition at 60°C in which it shrinks by 7%, primarily through changes in its hexamer conformation. The transition is reversible, with a half-life of ~3 min; however, >50% of reverted capsids are severely distorted or ruptured. This observation implies that such damage is a potential hazard of large-scale structural changes such as those involved in maturation. Assuming that the risk is lower for smaller changes, this suggests a rationalization for the existence of metastable intermediates: that they serve as stepping stones that preserve capsid integrity as it switches between the radically different conformations of its precursor and mature states., IMPORTANCE Large-scale conformational changes are widespread in virus maturation and infection processes. These changes are accompanied by the release of conformational free energy as the virion (or fusogenic glycoprotein) switches from a precursor state to its mature state. Each state corresponds to a local minimum in an energy landscape. The conformational changes in capsid maturation are so radical that the question arises of how maturing capsids avoid being torn apart. Offering proof of principle, severe damage is inflicted when a bacteriophage HK97 capsid reverts from the (nonphysiological) state that it enters when heated past 60°C. We suggest that capsid proteins have been selected in part by the criterion of being able to avoid sustaining collateral damage as they mature. One way of achieving this—as with the HK97 capsid—involves breaking the overall transition down into several smaller steps in which the risk of damage is reduced.

Published

2014

26. Molecular dynamics of protein complexes from four-dimensional cryo-electron microscopy

Author

J. Bernard Heymann, James F. Conway, and Alasdair C. Steven

Subjects

Models, Molecular, Conformational change, Chemistry, Cryo-electron microscopy, Cryoelectron Microscopy, Molecular Conformation, Single particle analysis, Herpesvirus 1, Human, Transition state, Molecular dynamics, Structural Biology, Microscopy, Virus maturation, Biophysics, Bacteriophages, Capsid Proteins, Protein Precursors, Biological system, Conformational isomerism

Abstract

Cryo-electron microscopy of single particles offers a unique opportunity to detect and quantify conformational variation of protein complexes. Different conformers may, in principle, be distinguished by classification of individual projections in which image differences arising from viewing geometry are disentangled from variability in the underlying structures by “multiple particle analysis”—MPA. If the various conformers represent dynamically related states of the same complex, MPA has the potential to visualize transition states, and eventually to yield movies of the dynamic process. Ordering the various conformers into a time series is facilitated if cryo-EM data are taken at successive times from a system that is known to be developing in time. Virus maturation represents a relatively tractable dynamic process because the changes are large and irreversible and the rate of the natural process may be conveniently slowed in vitro by adjusting the environmental conditions. We describe the strategy employed in a recent analysis of herpes simplex virus procapsid maturation (Nat. Struct. Biol. 10 (2003) 334–341), compare it with previous work on the maturation of bacteriophage HK97 procapsid, and discuss various factors that impinge on the feasibility of performing similar experimental analyses of molecular dynamics in the general case.

Published

2004

27. The morphogenic linker peptide of HBV capsid protein forms a mobile array on the interior surface

Author

James F. Conway, Naiqian Cheng, Stephen J. Stahl, David M. Belnap, Paul T. Wingfield, Norman R. Watts, and Alasdair C. Steven

Subjects

Models, Molecular, Hepatitis B virus, Protein Folding, Cellobiose dehydrogenase, Protein Conformation, Recombinant Fusion Proteins, viruses, Sequence (biology), Peptide, Biology, Article, General Biochemistry, Genetics and Molecular Biology, Structure-Activity Relationship, Capsid, Protein structure, Escherichia coli, Image Processing, Computer-Assisted, Morphogenesis, Hepatitis B e Antigens, Molecular Biology, chemistry.chemical_classification, General Immunology and Microbiology, Circular Dichroism, General Neuroscience, Cryoelectron Microscopy, Hepatitis B Core Antigens, Molecular biology, Peptide Fragments, Protein Structure, Tertiary, Amino Acid Substitution, chemistry, Subtraction Technique, Chromatography, Gel, Nucleic acid, Biophysics, Carbohydrate Dehydrogenases, Protein folding, Crystallization, Linker

Abstract

Many capsid proteins have peptides that influence their assembly. In hepatitis B virus capsid protein, the peptide STLPETTVV, linking the shell-forming ‘core’ domain and the nucleic acid-binding ‘protamine’ domain, has such a role. We have studied its morphogenic properties by permuting its sequence, substituting it with an extraneous peptide, deleting it to directly fuse the core and protamine domains and assembling core domain dimers with added linker peptides. The peptide was found to be necessary for the assembly of protamine domain-containing capsids, although its size-determining effect tolerates some modifications. Although largely invisible in a capsid crystal structure, we could visualize linker peptides by cryo-EM difference imaging: they emerge on the inner surface and extend from the capsid protein dimer interface towards the adjacent symmetry axis. A closely sequence-similar peptide in cellobiose dehydrogenase, which has an extended conformation, offers a plausible prototype. We propose that linker peptides are attached to the capsid inner surface as hinged struts, forming a mobile array, an arrangement with implications for morphogenesis and the management of encapsidated nucleic acid.

Published

2002

28. [Untitled]

Author

Andreas Plückthun, Alexander Wlodawer, James F. Conway, Alasdair C. Steven, Fan Yang, Zbigniew Dauter, Mario E. Cerritelli, Patrik Forrer, and Naiqian Cheng

Subjects

Viral protein, Chemistry, Trimer, medicine.disease_cause, Biochemistry, Crystallography, Protein structure, Capsid, Structural Biology, Icosahedral viral capsid, Genetics, medicine, Protein folding, Peptide sequence, Protein secondary structure

Abstract

The crystal structure of gpD, the capsid-stabilizing protein of bacteriophage lambda, was solved at 1.1 A resolution. Data were obtained from twinned crystals in space group P21 and refined with anisotropic temperature factors to an R-factor of 0.098 (Rfree = 0. 132). GpD (109 residues) has a novel fold with an unusually low content of regular secondary structure. Noncrystallographic trimers with substantial intersubunit interfaces were observed. The C-termini are well ordered and located on one side of the trimer, relatively far from its three-fold axis. The N-termini are disordered up to Ser 15, which is close to the three-fold axis and on the same side as the C-termini. A density map of the icosahedral viral capsid at 15 A resolution, obtained by cryo-electron microscopy and image reconstruction, reveals gpD trimers, seemingly indistinguishable from the ones seen in the crystals, at all three-fold sites. The map further reveals that the side of the trimer that binds to the capsid is the side on which both termini reside. Despite this orientation of the gpD trimer, fusion proteins connected by linker peptides to either terminus bind to the capsid, allowing protein and peptide display.

Published

2000

29. Maturation Dynamics of a Viral Capsid

Author

James F. Conway, Roger W. Hendrix, John E. Johnson, Hiro Tsuruta, Alasdair C. Steven, Robert L. Duda, Naiqian Cheng, William R. Wikoff, and Ramani Lata

Subjects

education.field_of_study, medicine.diagnostic_test, Biochemistry, Genetics and Molecular Biology(all), Proteolysis, Dynamics (mechanics), Population, Biology, Two stages, Virology, General Biochemistry, Genetics and Molecular Biology, chemistry.chemical_compound, chemistry, Polymerization, Capsid, Biophysics, medicine, Protein folding, education, DNA

Abstract

Typical of DNA bacteriophages and herpesviruses, HK97 assembles in two stages: polymerization and maturation. First, capsid protein polymerizes into closed shells; then, these precursors mature into larger, stabler particles. Maturation is initiated by proteolysis, producing a metastable particle primed for expansion—the major structural transition. We induced expansion in vitro by acidic pH and monitored the resulting changes by time-resolved X-ray diffraction and cryo–electron microscopy. The transition, which is not synchronized over the population, proceeds in a series of stochastically triggered subtransitions. Three distinct intermediates were identified, which are comparable to transitional states in protein folding. The intermediates' structures reveal the molecular events occurring during expansion. Integrated into a movie (see Dynamic Visualization below), they show capsid maturation as a dynamic process.

Published

2000

30. Localization of the C terminus of the assembly domain of hepatitis B virus capsid protein: Implications for morphogenesis and organization of encapsidated RNA

Author

Naiqian Cheng, Paul T. Wingfield, Adam Zlotnick, James F. Conway, Stephen J. Stahl, and A.C. Steven

Subjects

chemistry.chemical_classification, Hepatitis B virus, Gold cluster, Multidisciplinary, Molecular Structure, viruses, C-terminus, Dimer, Mutant, RNA, Peptide, Biological Sciences, Biology, chemistry.chemical_compound, Crystallography, Capsid, chemistry, Escherichia coli, Biophysics, Humans, RNA, Viral, Cysteine

Abstract

The capsid protein of hepatitis B virus, consisting of an “assembly” domain (residues 1–149) and an RNA-binding “protamine” domain (residues 150–183), assembles from dimers into icosahedral capsids of two different sizes. The C terminus of the assembly domain (residues 140–149) functions as a morphogenetic switch, longer C termini favoring a higher proportion of the larger capsids, it also connects the protamine domain to the capsid shell. We now have defined the location of this peptide in capsids assembled in vitro by engineering a mutant assembly domain with a single cysteine at its C terminus (residue 150), labeling it with a gold cluster and visualizing the cluster by cryo-electron microscopy. The labeled protein is unimpaired in its ability to form capsids. Our density map reveals a single undecagold cluster under each fivefold and quasi-sixfold vertex, connected to sites at either end of the undersides of the dimers. Considering the geometry of the vertices, the C termini must be more crowded at the fivefolds. Thus, a bulky C terminus would be expected to favor formation of the larger (T = 4) capsids, which have a greater proportion of quasi-sixfolds. Capsids assembled by expressing the full-length protein in Escherichia coli package bacterial RNAs in amounts equivalent to the viral pregenome. Our density map of these capsids reveals a distinct inner shell of density—the RNA. The RNA is connected to the protein shell via the C-terminal linkers and also makes contact around the dimer axes.

Published

1997

31. Finding a needle in a haystack: detection of a small protein (the 12-kDa VP26) in a large complex (the 200-MDa capsid of herpes simplex virus)

Author

Jay C. Brown, Frank P. Booy, Benes L. Trus, A.C. Steven, James F. Conway, and William W. Newcomb

Subjects

Multidisciplinary, Macromolecular Substances, Viral protein, viruses, Capsomere, Herpesvirus 1, Human, Viral tegument, Biology, medicine.disease_cause, Molecular biology, In vitro, Molecular Weight, Microscopy, Electron, chemistry.chemical_compound, Capsid, Herpes simplex virus, chemistry, Image Processing, Computer-Assisted, medicine, Biophysics, Capsid Proteins, Guanidine, Research Article

Abstract

Macromolecular complexes that consist of homopolymeric protein frameworks with additional proteins attached at strategic sites for a variety of structural and functional purposes are widespread in subcellular biology. One such complex is the capsid of herpes simplex virus type 1 whose basic framework consists of 960 copies of the viral protein, VP5 (149 kDa), arranged in an icosahedrally symmetric shell. This shell also contains major amounts of three other proteins, including VP26 (12 kDa), a small protein that is approximately equimolar with VP5 and accounts for approximately 6% of the capsid mass. With a view to inferring the role of VP26 in capsid assembly, we have localized it by quantitative difference imaging based on three-dimensional reconstructions calculated from cryo-electron micrographs. Purified capsids from which VP26 had been removed in vitro by treatment with guanidine hydrochloride were compared with preparations of the same depleted capsids to which purified VP26 had been rebound and with native (undepleted) capsids. The resulting three-dimensional density maps indicate that six VP26 subunits are distributed symmetrically around the outer tip of each hexon protrusion on VP26-containing capsids. Because VP26 may be readily dissociated from and reattached to the capsid, it does not appear to contribute significantly to structural stabilization. Rather, its exposed location suggests that VP26 may be involved in linking the capsid to the surrounding tegument and envelope at a later stage of viral assembly.

Published

1994

32. Disulfide bond formation contributes to herpes simplex virus capsid stability and retention of pentons

Author

Athena Kosinski, Jacob Nellissery, Renata Szczepaniak, Joshua A. Jadwin, Alexander M. Makhov, James F. Conway, and Sandra K. Weller

Subjects

Models, Molecular, viruses, Immunology, Herpesvirus 1, Human, Biology, medicine.disease_cause, Microbiology, Virus, Dithiothreitol, chemistry.chemical_compound, Virology, Chlorocebus aethiops, Extracellular, medicine, Animals, Disulfides, Vero Cells, Structure and Assembly, Virion, biochemical phenomena, metabolism, and nutrition, Herpes simplex virus, chemistry, Capsid, Biochemistry, Covalent bond, Ethylmaleimide, Reducing Agents, Insect Science, Biophysics, Capsid Proteins, Intracellular, DNA

Abstract

Disulfide bonds reportedly stabilize the capsids of several viruses, including papillomavirus, polyomavirus, and simian virus 40, and have been detected in herpes simplex virus (HSV) capsids. In this study, we show that in mature HSV-1 virions, capsid proteins VP5, VP23, VP19C, UL17, and UL25 participate in covalent cross-links, and that these are susceptible to dithiothreitol (DTT). In addition, several tegument proteins were found in high-molecular-weight complexes, including VP22, UL36, and UL37. Cross-linked capsid complexes can be detected in virions isolated in the presence and absence of N -ethylmaleimide (NEM), a chemical that reacts irreversibly with free cysteines to block disulfide formation. Intracellular capsids isolated in the absence of NEM contain disulfide cross-linked species; however, intracellular capsids isolated from cells pretreated with NEM did not. Thus, the free cysteines in intracellular capsids appear to be positioned such that disulfide bond formation can occur readily if they are exposed to an oxidizing environment. These results indicate that disulfide cross-links are normally present in extracellular virions but not in intracellular capsids. Interestingly, intracellular capsids isolated in the presence of NEM are unstable; B and C capsids are converted to a novel form that resembles A capsids, indicating that scaffold and DNA are lost. Furthermore, these capsids also have lost pentons and peripentonal triplexes as visualized by cryoelectron microscopy. These data indicate that capsid stability, and especially the retention of pentons, is regulated by the formation of disulfide bonds in the capsid.

Published

2011

33. Role of the Propeptide in Controlling Conformation and Assembly State of Hepatitis B virus e-antigen

Author

Alasdair C. Steven, Paul T. Wingfield, James F. Conway, Stephen J. Stahl, Naiqian Cheng, and Norman R. Watts

Subjects

Models, Molecular, Circular dichroism, Chemistry, Stereochemistry, Protein Conformation, viruses, Dimer, Circular Dichroism, Cryoelectron Microscopy, Article, Peptide Fragments, Crystallography, chemistry.chemical_compound, HBcAg, Protein structure, HBeAg, Capsid, Structural Biology, Intramolecular force, Mutation, Disulfides, Hepatitis B e Antigens, Protein precursor, Molecular Biology

Abstract

Hepatitis B virus "e-antigen" (HBeAg) is thought to be a soluble dimeric protein that is associated with chronic infection. It shares 149 residues with the viral capsid protein "core-antigen" (HBcAg), but has an additional 10-residue, hydrophobic, cysteine-containing amino-terminal propeptide whose presence correlates with physical, serological, and immunological differences between the two proteins. In HBcAg dimers, the subunits pair by forming a four-helix bundle stabilized by an intermolecular disulfide bond. The structure of HBeAg is probably similar but, instead, has two intramolecular disulfide bonds involving the propeptide. To compare the proteins directly and thereby clarify the role of the propeptide, we identified mutations and solution conditions that render both proteins as either soluble dimers or assembled capsids. Thermally induced unfolding monitored by circular dichroism, and electrophoresis of oxidized and reduced dimers, showed that the propeptide has a destabilizing effect and that the intramolecular disulfide bond forms preferentially and blocks the formation of the intermolecular disulfide bond that otherwise stabilizes the dimer. The HBeAg capsids are less regular than the HBcAg capsids; nevertheless, cryo-electron microscopy reconstructions confirm that they are constructed of dimers resembling those of HBcAg capsids. In them, a portion of the propeptide is visible near the dimer interface, suggesting that it intercalates there, consistent with the known formation of a disulfide bond between C(-7) in the propeptide and C61 in the dimer interface. However, this intercalation distorts the dimer into an assembly-reluctant conformation.

Published

2011

34. Structural features in the heptad substructure and longer range repeats of two-stranded α-fibrous proteins

Author

James F. Conway and David A.D. Parry

Subjects

Muscle Proteins, Tropomyosin, Myosins, Biology, Biochemistry, Molecular aggregation, Data sequences, Intermediate Filament Proteins, Structural Biology, Myosin, Animals, Humans, Connectin, Amino Acids, Intermediate filament, Molecular Biology, chemistry.chemical_classification, Desmoplakin, General Medicine, Amino acid, Cytoskeletal Proteins, Desmoplakins, chemistry, biology.protein, Biophysics, Substructure

Abstract

Considerable sequence data have been collected from the intermediate filament proteins and other α-fibrous proteins including myosin, tropomyosin, paramyosin, desmoplakin and M-protein. The data show that there is a clear preference for some amino acids to occur in specific positions within the heptad substructure that characterizes the sequences which form the coiled-coil rod domain in this class of proteins. The results also indicate that although there are major similarities between the various proteins there are also key differences. In all cases, however, significant regularities in the linear disposition of the acidic and the basic residues in the coiled-coil segments can be related to modes of chain and molecular aggregation. In particular a clear trend has been observed which relates the mode of molecular aggregation to the number of interchain ionic interactions per heptad pair.

Published

1990

35. A thermally induced phase transition in a viral capsid transforms the hexamers, leaving the pentamers unchanged

Author

Philip D. Ross, Robert L. Duda, Roger W. Hendrix, James F. Conway, Naiqian Cheng, and Alasdair C. Steven

Subjects

Phase transition, Hot Temperature, Calorimetry, Differential Scanning, Icosahedral symmetry, Cryo-electron microscopy, Cryoelectron Microscopy, Prohead, Calorimetry, Random hexamer, Phase Transition, Article, chemistry.chemical_compound, Crystallography, Differential scanning calorimetry, Monomer, Capsid, chemistry, Structural Biology, Bacteriophages, Capsid Proteins

Abstract

Scanning calorimetry combined with cryo-electron microscopy affords a powerful approach to investigating hierarchical interactions in multi-protein complexes. Calorimetry can detect the temperatures at which certain interactions are disrupted and cryo-EM can reveal the accompanying structural changes. The procapsid of bacteriophage HK97 (Prohead I) is a 450A-diameter shell composed of 60 hexamers and 12 pentamers of gp5, organized with icosahedral symmetry. Gp5 consists of the N-terminal Delta-domain (11kDa) and gp5* (31 kDa): gp5* forms the contiguous shell from which clusters of Delta-domains extend inwards. At neutral pH, Prohead I exhibits an endothermic transition at 53 degrees C with an enthalpy change of 14 kcal/mole (of gp5 monomer). We show that this transition is reversible. To capture its structural expression, we incubated Prohead I at 60 degrees C followed by rapid freezing and, by cryo-EM, observed a capsid species 10% larger than Prohead I. At 11A resolution, visible changes are confined to the gp5 hexamers. Their Delta-domain clusters have disappeared and are presumably disordered, either by unfolding or dispersal. The gp5* hexamer rings are thinned and flattened as they assume the conformation observed in Expansion Intermediate I, a transition state of the normal, proteolysis-induced, maturation pathway. We infer that, at ambient temperatures, the hexamer Delta-domains restrain their gp5* rings from switching to a lower free energy, EI-I-like, state; above 53 degrees, this restraint is overcome. Pentamers, on the other hand, are more stably anchored and resist this thermal perturbation.

Published

2006

36. Time-resolved molecular dynamics of bacteriophage HK97 capsid maturation interpreted by electron cryo-microscopy and X-ray crystallography

Author

Naiqian Cheng, Alasdair C. Steven, Kelly K. Lee, John E. Johnson, Robert L. Duda, Lu Gan, Jinghua Tang, William R. Wikoff, James F. Conway, and Roger W. Hendrix

Subjects

Conformational change, Chemistry, Cryo-electron microscopy, Protein subunit, Cryoelectron Microscopy, Prohead, Crystallography, X-Ray, Coliphages, Molecular machine, In vitro maturation, Crystallography, Molecular dynamics, Capsid, Structural Biology

Abstract

The bacteriophage HK97 capsid is a molecular machine that exhibits large-scale conformational rearrangements of its 420 identical protein subunits during capsid maturation. Immature empty capsids, termed Prohead II, assemble in vivo in an Escherichia coli expression system. Maturation of these particles may be induced in vitro, converting them into Head II capsids that are indistinguishable in conformation from the capsid of an infectious phage particle. One method of in vitro maturation requires acidification to drive the reaction through two expansion intermediates (EI-I, EI-II) to its penultimate particle state (EI-III), which has 86% more internal volume than Prohead II. Neutralization of EI-III produces the fully mature capsid, Head II. The three expansion intermediates and the acid expansion pathway were characterized by cryo-EM analysis and 3D reconstruction. We now report that, although large-scale structural changes are involved, the electron density maps for these intermediate states are readily interpreted in terms of quasi-atomic models based on subunit structures determined by prior crystallographic analysis of Head II. Progression through the expansion intermediate states primarily represents rigid-body rotations and translations of the subunits, accompanied by refolding of two small regions, the N-terminal arm and a beta-hairpin called the E-loop. Movies made with these pseudo-atomic coordinates and the Head II X-ray coordinates illuminate various aspects of the maturation pathway in the course of which the pattern of inter-subunit interactions is sequentially transformed while the integrity of the capsid is maintained.

Published

2005

37. Structure of an insect parvovirus (Junonia coenia Densovirus) determined by cryo-electron microscopy

Author

Miguel López-Ferber, Elizabeth A. Hewat, James F. Conway, Fabien Scholari, and Anneke Bruemmer

Subjects

Models, Molecular, Cryo-electron microscopy, Viral protein, viruses, medicine.disease_cause, Crystallography, X-Ray, chemistry.chemical_compound, Viral Proteins, Capsid, Structural Biology, medicine, Animals, Densovirus, Molecular Biology, Parvoviridae, biology, Parvovirus, C-terminus, Cryoelectron Microscopy, virus diseases, biochemical phenomena, metabolism, and nutrition, biology.organism_classification, Virology, Molecular biology, Protein Structure, Tertiary, chemistry, DNA, Viral, Butterflies, DNA

Abstract

Junonia coenia densovirus (JcDNV) belongs to the densovirus genus of the Parvoviridae family and infects the larvae of the Common Buckeye butterfly. Its capsid is icosahedral and consists of viral proteins VP1 (88 kDa), VP2 (58 kDa), VP3 (52 kDa) and VP4 (47 kDa). Each viral protein has the same C terminus but differs in the length of its N-terminal extension. Virus-like-particles (VLPs) assemble spontaneously when the individual viral proteins are expressed by a recombinant baculovirus. We present here the structure of native JcDNV at 8.7 A resolution and of the two VLPs formed essentially from VP2 and VP4 at 17 A resolution, as determined by cryo-electron microscopy. The capsid displays a remarkably smooth surface, with only two very small spikes that define a pentagonal plateau on the 5-fold axes. JcDNV is very closely related to Galleria mellonella densovirus (GmDNV), whose structure is known (94% sequence identity with VP4 and 96% similarity). We compare these structures in order to locate the structural changes and mutations that may be involved in the species shift of these densoviruses. A single mutation at the tip of one of the two small spikes is a strong candidate as a species shift determinant. Difference imaging reveals that the 21 disordered amino acid residues at the N terminus of the capsid protein VP4 are located inside the capsid at the 5-fold axis, but the additional 94 amino acid residue extension of VP2 is not visible, suggesting that it is highly disordered. There is strong evidence of DNA ordering associated with the 3-fold axes of the capsid.

Published

2004

38. Diversity of core antigen epitopes of hepatitis B virus

Author

David M. Belnap, S. J. Stahl, A.C. Steven, Naiqian Cheng, Paul T. Wingfield, James F. Conway, and Norman R. Watts

Subjects

Hepatitis B virus, chemistry.chemical_classification, Models, Molecular, Antigenicity, Multidisciplinary, Cryoelectron Microscopy, Peptide, Biology, Biological Sciences, medicine.disease_cause, Virology, Hepatitis B Core Antigens, Epitope, Epitopes, Epitope mapping, Antigen, chemistry, Capsid, medicine, biology.protein, Antibody, Epitope Mapping

Abstract

Core antigen (cAg), the viral capsid, is one of the three major clinical antigens of hepatitis B virus. cAg has been described as presenting either one or two conformational epitopes involving the “immunodominant loop.” We have investigated cAg antigenicity by cryo-electron microscopy at ≈11-Å resolution of capsids labeled with monoclonal Fabs, combined with molecular modeling, and describe here two conformational epitopes. Both Fabs bind to the dimeric external spikes, and each epitope has contributions from the loops on both subunits, explaining their discontinuous nature: however, their binding aspects and epitopes differ markedly. To date, four cAg epitopes have been characterized: all are distinct. Although only two regions of the capsid surface are accessible to antibodies, local clustering of the limited number of exposed peptide loops generates a potentially extensive set of discontinuous epitopes. This diversity has not been evident from competition experiments because of steric interference effects. These observations suggest an explanation for the distinction between cAg and e-antigen (an unassembled form of capsid protein) and an approach to immunodiagnosis, exploiting the diversity of cAg epitopes.

Published

2003

39. Molecular Mechanisms In Bacteriophage T7 Procapsid Assembly, Maturation, And Dna Containment

Author

James F. Conway, Mario E. Cerritelli, Benes L. Trus, Alasdair C. Steven, and Naiqian Cheng

Subjects

Scaffold protein, Phage display, Expression vector, biology, Icosahedral symmetry, viruses, biology.organism_classification, Molecular biology, Bacteriophage, chemistry.chemical_compound, chemistry, Capsid, Vertex (curve), Biophysics, DNA

Abstract

Bacteriophage T7 is a double-stranded DNA bacteriophage that has attracted particular interest in studies of gene expression and regulation and of morphogenesis, as well as in biotechnological applications of expression vectors and phage display. We report here studies of T7 capsid assembly by cryoelectron microscopy and image analysis. T7 follows the canonical pathway of first forming a procapsid that converts into the mature capsid, but with some novel variations. The procapsid is a round particle with an icosahedral triangulation number of 7 levo, composed of regular pentamers and elongated hexamers. A singular vertex in the procapsid is occupied by the connector/portal protein, which forms 12-fold and 13-fold rings when overexpressed, of which the 12-mer appears to be the assembly-competent form. This vertex is the site of two symmetry mismatches: between the connector and the surrounding five gp 10 hexamers; and between the connector and the 8-fold cylindrical core mounted on its inner surface. The scaffolding protein, gp9, which is required for assembly, forms nubbin-like protrusions underlying the hexamers but not the pentamers, with no contacts between neighboring gp9 monomers. We propose that gp9 facilitates assembly by binding to gp10 hexamers, locking them into a morphogenically correct conformation. gp9 is expelled as the procapsid matures into the larger, thinner walled, polyhedral capsid. Several lines of evidence implicate the connector vertex as the site at which the maturation transformation is initiated: in vivo, maturation appears to be triggered by DNA packaging whereby the signal may involve interaction of the connector with DNA. In the mature T7 head, the DNA is organized as a tightly wound coaxial spool, with the DNA coiled around the core in at least four and perhaps as many as six concentric shells.

Published

2003

40. Methods for reconstructing density maps of 'single' particles from cryoelectron micrographs to subnanometer resolution

Author

James F. Conway and Alasdair C. Steven

Subjects

Models, Molecular, Hepatitis B virus, Contrast transfer function, Micrograph, Chemistry, Macromolecular Substances, Resolution (electron density), Cryoelectron Microscopy, Nanotechnology, Image processing, Computational physics, Visualization, law.invention, Capsid, Structural Biology, law, Image Processing, Computer-Assisted, Symmetry (geometry), Electron microscope, Level of detail

Abstract

Recently the resolution attainable in density maps calculated from cryo-electron micrographs of free-standing virus capsids has advanced to resolutions below 1 nm. This represents a significant milestone in that resolutions of this order potentially allow direct visualization of individual elements of protein secondary structure (i.e., alpha-helices), in addition to the shapes and connectivity of subdomains. We describe here a computational strategy for structural analyses at this level of detail: its principal innovation is a procedure for correcting the contrast transfer function of the electron microscope. Also important is the practice of combining data from pairs of differently defocused micrographs to improve the signal-to-noise ratio of the images, thereby allowing more precise determinations of the particles' orientations and origins and contributing to higher resolution reconstructions. These procedures proved instrumental in our analysis of the capsid of hepatitis B virus at 9-A resolution (Conway et al., 1997, Nature 386, 91-94). Finally, we discuss the prospects for achieving comparable resolutions for isolated macromolecular complexes with lower symmetry or no symmetry and for further extension of the resolution.

Published

1999

41. Tetrairidium, a four-atom cluster, is readily visible as a density label in three-dimensional cryo-EM maps of proteins at 10-25 A resolution

Author

James F. Hainfeld, Naiqian Cheng, A.C. Steven, P.E. Wingfield, Vishwas N. Joshi, Stephen J. Stahl, James F. Conway, Richard D. Powell, and Norman R. Watts

Subjects

Hepatitis B virus, Cryo-electron microscopy, Chemistry, Resolution (electron density), Cryoelectron Microscopy, Context (language use), Iridium, Crystallography, chemistry.chemical_compound, Viral Proteins, Capsid, Structural Biology, Molecular Probes, Atom, Cluster (physics), Image Processing, Computer-Assisted, Organometallic Compounds, Maleimide, Organogold Compounds, Metal clusters

Abstract

Heavy metal clusters derivatized to bind to designated chemical groups on proteins have great potential as density labels for cryo-electron microscopy. Smaller clusters offer higher resolution and penetrate more easily into sterically restricted sites, but are more difficult to detect. In this context, we have explored the potential of tetrairidium (Ir4 )a s a density label by attaching it via maleimide linkage to the C-terminus of the hepatitis B virus (HBV) capsid protein. Although the clusters are not visible in unprocessed cryo-electron micrographs, they are distinctly visible in three-dimensional density maps calculated from them, even at only partial occupancy. The Ir4 label was clearly visualized in our maps at 11‐14 A resolution of both size variants of the HBV capsid, thus confirming our previous localization of this site with undecagold (Zlotnick, A., Cheng, N., Stahl, S. J., Conway, J. F., Steven, A. C., and Wingfield, P. T., Proc. Natl. Acad. Sci. USA 94, 9556‐9561, 1997). Ir4 penetrated to the interior of intact capsids to label this site on their inner surface, unlike undecagold for which labelling was achieved only with dissociated dimers that were then reassembled into capsids. The Ir4 cluster remained visible as the resolution of the maps was lowered progressively to ,25 A. r 1999 Academic Press

Published

1999

42. Linkage Between Proteolysis and Conformational Change in Virus Assembly: Insights from Cryo-Electron Microscopy

Author

L Dierkas, Naiqian Cheng, James F. Conway, Brian Firek, PD Ross, Robert L. Duda, A.C. Steven, and Roger W. Hendrix

Subjects

Crystallography, Conformational change, medicine.diagnostic_test, Cryo-electron microscopy, Chemistry, law, Proteolysis, medicine, Linkage (mechanical), Instrumentation, Virus, law.invention

Abstract

Extended abstract of a paper presented at Microscopy and Microanalysis 2006 in Chicago, Illinois, USA, July 30 – August 3, 2005

Published

2006

43. The effects of radiation damage on the structure of frozen hydrated HSV-1 capsids

Author

Benes L. Trus, Jay C. Brown, Frank P. Booy, William W. Newcomb, James F. Conway, and A.C. Steven

Subjects

Chemistry, Water, Model system, Electrons, Herpesvirus 1, Human, law.invention, Frozen hydrated, Biological specimen, Crystallography, Microscopy, Electron, Nuclear magnetic resonance, Capsid, Structural Biology, law, Electron micrographs, Freezing, Electron dose, Radiation damage, Image Processing, Computer-Assisted, Electron microscope

Abstract

Radiation damage imposes stringent limits on the information content of electron micrographs of biological specimens. In this study, we have investigated its effects on frozen, hydrated specimens and three-dimensional reconstructions calculated from cryomicrographs using capsids of herpes simplex virus as a model system. Multiple-exposure series of micrographs of both B-capsids (which contain no DNA) and C-capsids (which are fully packaged) were recorded and reconstructions were calculated from the first exposures, corresponding to a cumulative electron dose of 6-7 e-/A2, and from later exposures (25-40 e-/A2). Experimental procedures were standardized to ensure that perceived changes in the micrographs and reconstructions would be attributable to radiation damage alone. The effects of the higher doses in both the micrographs and the reconstructions were expressed as a progressive blurring of the finer details, corresponding to a delocalization of structure in the ice-embedded specimens. The resolutions of the reconstructions were quantified according to a form of the Fourier ring correlation coefficient criterion, according to which the first-exposure reconstructions had resolutions of 30-36 A. The fifth-exposure B-capsid reconstruction had comparable nominal resolution, although it exhibited progressively lower correlations at higher spatial frequencies. Qualitatively similar changes in the series of C-capsid reconstructions were observed although they were more pronounced, presumably because these micrographs had lower contrast and signal-to-noise ratios. We infer that the observed changes in the images and reconstructions and the concomitant loss in contrast in the immediate vicinity of the capsid surface may reflect radiation-induced perturbation of molecular structure and/or the release of peptide fragments. Nevertheless, the observed changes are relatively subtle, at least at the operational resolution of this study; overall, our results support earlier indications (M. F. Schmid et al. J. Struct. Biol. 108, 62-68, 1992) that prospects are quite good for tilt-series reconstructions from cryoelectron micrographs, including six to eight views of the same specimen.

Published

1993

44. The short tail-fiber of bacteriophage T4: molecular structure and a mechanism for its conformational transition

Author

A.C. Steven, James F. Conway, T.G. Zurabishvili, Martha N. Simon, Vadim V. Mesyanzhinov, A.M. Makhov, and Benes L. Trus

Subjects

Microscopy, Electron, Scanning Transmission, Protein Conformation, Molecular Sequence Data, Trimer, Biology, Oligomer, Models, Biological, Negative Staining, law.invention, chemistry.chemical_compound, Protein structure, law, Virology, Scanning transmission electron microscopy, Image Processing, Computer-Assisted, Molecule, Bacteriophage T4, Amino Acid Sequence, Mathematical Computing, Viral Structural Proteins, Molecular mass, Sequence Homology, Amino Acid, Negative stain, Crystallography, chemistry, Electron microscope, Sequence Analysis

Abstract

Electron microscopy, image processing and computational sequence analysis were used to investigate the structure of the short tail-fiber of bacteriophage T4. This molecule, an oligomer of gp12, is an adhesin that binds the virion irreversibly to the bacterial surface. Short tail-fibers were isolated from mutant-infected cells in which gp12 is synthesized and assembled correctly, but not incorporated into virions. Visualized in negative stain, these filamentous molecules are approximately 38 nm in total length, with an arrowhead-shaped head (approximately 10 nm long by 6 nm wide), a 24-nm shaft of uniform width (approximately 3.8 nm), and a small, seemingly flexible, tail. The primary sequence contains a domain consisting of tandem quasi-repeats, each about 40 residues long, extending from approximately residue 50 to residue 320. Molecular mass analyses by scanning transmission electron microscopy confirm that the molecule is a trimer. The masses of the head, shaft, and tail domains are consistent with (trimers of) the carboxy-terminus, the repeat region, and the amino-terminus, respectively. When short tail-fibers are visualized extending from baseplates, their heads are distal, i.e., detached, implying that it is the tail that remains in contact with the baseplate. Analysis of the molecules' curvature properties detects three hinge-sites: these suggest how the short tail-fiber may be initially accommodated in a compact conformation in the "hexagon" state of the baseplate, from which it converts to the extended conformation when the baseplate switches into its "star" state.

Published

1993

45. Cysteine Mapping of Cytoplasmic Dynein Motor Domain

Author

James F. Conway, Hikmat N. Daghestani, and Billy W. Day

Subjects

Biochemistry, Microtubule, Chemistry, Vesicle, Organelle, Biophysics, Native state, Immunoglobulin light chain, Cytoskeleton, Fluorescence spectroscopy, Cysteine

Abstract

Cytoplasmic dynein is a large cytoskeletal protein complex comprised of a heterodimer of heavy chains, intermediate chains, light intermediate chains and light chains. Cytoplasmic dynein is responsible for transporting cargo, other proteins, vesicles and organelles, throughout the cell by movement along microtubules in a retrograde fashion. This activity is mediated by a series of conformational changes to the motor domain induced by ATP binding, hydrolysis and the release of ADP to give a power-stroke motion. There are, however, many unknowns regarding the conformational changes and structure of the motor domain. The extremely large size of the motor domain (380 kDa) makes structural characterization a challenging task. As an initial step towards this goal, cysteine mapping of the motor domain was performed. Preliminary results from fluorescence spectroscopy indicate that 6 out of the 47 cysteines react with ThioGlo(r)1 (methyl 10-(2,5-dioxo-2,5-dihydro-1H-pyrrol-1-yl)-9-methoxy-3-oxo-3H-benzo[f]chromene-2-carboxylate) in the motor domain's native state. Under denaturing conditions, an additional 15 cysteines are revealed. The non-reactivity of the remaining 26 cysteines suggests the presence of 13 disulfide bonds in the motor domain. These results are being analyzed with mass spectrometry to confirm and identify the accessible, buried and oxidized cysteines. This information will be instrumental in mapping the location of residues within cytoplasmic dynein's motor domain. In addition to characterizing the structure of the motor domain, gold particle-bearing labels reactive with surface-accessible cysteines are being explored to provide cryoelectron microscopy data on the motor domain.

Published

2010

46. Vive La Différence! Mapping Macromolecular Complexes by Generalized Difference Imaging

Author

Naiqian Cheng, James F. Conway, Norman R. Watts, Alasdair C. Steven, and Paul T. Wingfield

Subjects

010302 applied physics, Crystallography, Chemistry, 0103 physical sciences, Macromolecular Complexes, 02 engineering and technology, 021001 nanoscience & nanotechnology, 0210 nano-technology, 01 natural sciences, Instrumentation

Abstract

Overview. Three-dimensional cryo-electron microscopy holds great potential for the investigation of macromolecular complexes, including viruses, the cytoskeleton, and the nanomachines that carry out many vital cellular functions. Such complexes often contain protein subunits of different kinds, with cumulative molecular weights running well into the megadalton range. To rationalize their functional assignments in structural terms, the first order of business is to map the locations of the component subunits of a given complex. A more detailed objective then becomes to understand the organization of their domains and the overall layout of the polypeptide chains. With current methodology, resolutions below 20Å are often achievable in cryo-EM, extending below 10 Å in favorable cases. Although resolutions of this order yield valuable morphological information, they do not usually suffice to identify individual subunits within a complex.Generalized difference imagingoffers a solution to this problem of molecular mapping.

Published

2000

47. Proteolytic Control of Bacteriophage HK97 Capsid Maturation

Author

Naiqian Cheng, Robert L. Duda, James F. Conway, Roger W. Hendrix, and Alasdair C. Steven

Subjects

Chemistry, Bacteriophage HK97, Capsid maturation, Instrumentation, Cell biology

Abstract

HK97 is a tailed temperate bacteriophage of E. coli that builds an icosahedral capsid using steps that include regulated assembly, proteolysis, radical conformational changes and the formation of novel covalent bonds (Fig. 1). This pathway is being exploited as a model system to explore how the formation of multiprotein complexes can be regulated by each of these mechanisms. We have identified and purified at least four intermediates (Prohead I, Prohead II, Head I and Head II) and examined them by cryo-electron microscopy and three dimensional reconstruction procedures (Fig. 2). Comparison of particle reconstructions at resolution of about 25 - 30 A have lead to major insights into the causes and purposes of the regulated changes that we have also characterized biochemically and genetically.Prohead I consists of 420 copies of the 42 kDa gp5 capsid protein arranged as 72 blister-shaped morphological capsomers in a thick walled hollow T=7 icosahedral particle with a diameter of -470 Å.

Published

1998

48. Prohead Perestroika: Bacteriophage T7 Capsid Before and After Maturation

Author

Naiqian Cheng, James F. Conway, Alasdair C. Steven, and Mario E. Cerritelli

Subjects

Bacteriophage, biology, Capsid, Chemistry, Prohead, biology.organism_classification, Instrumentation, Virology

Abstract

Bacteriophage T7 provides a well defined system to study the assembly of a moderately complex virus. The mature virion consists of a 60 nm icosahedral capsid containing the linear 40 kb genome and an internal protein “core”, and a short tail. The capsid originates as a DNA-free prohead, whose assembly requires both the major capsid protein (gpl0, ∼ 420 copies) and the scaffolding protein (gp9, ∼180 copies). Native proheads incorporate an oligomeric ring of the connector/portal protein at one vertex and the inner core, but prohead-like particles assemble when gp10 and gp9 alone are expressed. In maturation -as with other dsDNA phages - the T7 prohead undergoes a major conformational change, in which the shell structure alters dramatically, and the scaffolding protein is expelled. We have used cryo-EM in combination with other techniques to study this transition and to investigate the interactions between scaffold and surface shell in the T7 prohead.Highly purified preparations of proheads were generated from the co-expression of head and scaffolding proteins from the cloned gene in E. coli. Tail-less mature capsids as well as DNA-filled heads were prepared from infection of a T7 strain that completely lacks the tail genes.

Published

1997

49. Visualization and analysis of capsid dimorphism in hepatitis B virus to 17 Å resolution by cryo-electron microscopy

Author

James F. Conway, Stephen J. Stahl, Adam Zlotnick, A.C. Steven, Naiqian Cheng, F.P. Booy, and Paul T. Wingfield

Subjects

Hepatitis B virus, Capsid, Cryo-electron microscopy, Chemistry, viruses, Resolution (electron density), Biophysics, medicine, General Medicine, medicine.disease_cause

Abstract

Hepatitis B virus (HBV) is an enveloped virus with an icosahedral capsid. Its homodimeric capsid protein assembles into particles of two sizes - one with T=3 icosahedral symmetry (90 dimers), the other with T=4 symmetry (120 dimers). Both sizes of particle are found in vivo as well as in expression systems. We have developed an in vitro assembly system using purified, bacterially expressed, capsid proteins. Capsids assembled from different protein constructs were studied by cryo-electron microscopy using a Philips CM20 microscope equipped with a field emission gun operating at 120 keV.Capsids assembled from the different protein constructs were assayed by cryo-electron microscopy and sucrose gradient fractionation. Cryo-electron microscopy was required to identify the two different sizes of capsids and the small population of misshapen particles, and also to ascertain the quality of the gradient fractionation (Figure 1, 2). The protein constructs lacked the predominantly basic C-terminal 34 amino acids of the full-length capsid protein (183 amino acids), and were further truncated between residues 138 and 149. Constructs terminating between residue 140 and 149 assembled into mixtures of T=3 and T=4 particles; the smallest construct (138 residues) did not form capsids.

Published

1996

50. Bacteriophage HK97: Structural transitions along the capsid assembly pathway

Author

James F. Conway, Naiqian Cheng, Robert L. Duda, A.C. Steven, and Roger W. Hendrix

Subjects

Capsid, Chemistry, Biophysics, Bacteriophage HK97, General Medicine

Abstract

The assembly pathway of the HK97 capsid passes through four stages, starting with the first complete precursor and ending with the mature head. The earliest particle, Prohead I, contains 415-420 copies of the major capsid protein (42kDa) arrayed in a T=7 icosahedral lattice. Proteolytic cleavage (42kDa → 31kDa) converts Prohead I into Prohead II. Expansion of Prohead II into Head I involves a major conformational change that is thought to be triggered in vivo by DNA packaging. The final transition to Head II involves the formation of covalent crosslinks between capsid protein subunits that confer additional stability. We have been examining the structural basis of these transitionsand describe here the Prohead II and Head II states.Highly purified preparations of capsids were prepared either from expression vectors of capsid proteins or from growing phage mutants in E. coli cells. Samples were prepared for electron microscopy in the frozen, hydrated, state, and imaged in a Philips EM400T operating at 100kV, using a Gatan 626 cryo-holder. Micrographs were digitized and three-dimensional density maps were calculated as described.

Published

1994