Your search keyword '"HK97"' showing total 6 results

1. Point mutation in a virus-like capsid drives symmetry reduction to form tetrahedral cages.

Author

Szyszka TN, Andreas MP, Lie F, Miller LM, Adamson LSR, Fatehi F, Twarock R, Draper BE, Jarrold MF, Giessen TW, and Lau YH

Subjects

Myxococcus xanthus genetics, Myxococcus xanthus metabolism, Models, Molecular, Point Mutation, Capsid metabolism, Capsid chemistry, Capsid ultrastructure, Capsid Proteins genetics, Capsid Proteins chemistry, Capsid Proteins metabolism, Cryoelectron Microscopy

Abstract

Protein capsids are a widespread form of compartmentalization in nature. Icosahedral symmetry is ubiquitous in capsids derived from spherical viruses, as this geometry maximizes the internal volume that can be enclosed within. Despite the strong preference for icosahedral symmetry, we show that simple point mutations in a virus-like capsid can drive the assembly of unique symmetry-reduced structures. Starting with the encapsulin from Myxococcus xanthus , a 180-mer bacterial capsid that adopts the well-studied viral HK97 fold, we use mass photometry and native charge detection mass spectrometry to identify a triple histidine point mutant that forms smaller dimorphic assemblies. Using cryoelectron microscopy, we determine the structures of a precedented 60-mer icosahedral assembly and an unexpected 36-mer tetrahedron that features significant geometric rearrangements around a new interaction surface between capsid protomers. We subsequently find that the tetrahedral assembly can be generated by triple-point mutation to various amino acids and that even a single histidine point mutation is sufficient to form tetrahedra. These findings represent a unique example of tetrahedral geometry when surveying all characterized encapsulins, HK97-like capsids, or indeed any virus-derived capsids reported in the Protein Data Bank, revealing the surprising plasticity of capsid self-assembly that can be accessed through minimal changes in the protein sequence., Competing Interests: Competing interests statement:Two of the authors (B.E.D. and M.F.J.) are shareholders in Megadalton Solutions, a company that is engaged in commercializing CDMS. B.E.D. is an employee of Megadalton Solutions and M.F.J. is a consultant for Waters.

Published

2024

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

Author

Hua J, Huet A, Lopez CA, Toropova K, Pope WH, Duda RL, Hendrix RW, and Conway JF

Subjects

DNA, Viral genetics, Electrophoresis, Gel, Two-Dimensional, Mutation, Bacteriophages genetics, Bacteriophages ultrastructure, Biological Evolution, Capsid ultrastructure, Genome, Viral

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., (Copyright © 2017 Hua et al.)

Published

2017

3. 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, and James F. Conway

Subjects

bacteriophage, capsid, cryo-EM, evolution, genome, HK97, Microbiology, QR1-502

Abstract

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

4. The tripartite capsid gene of Salmonella phage Gifsy-2 yields a capsid assembly pathway engaging features from HK97 and λ

Author

Effantin, Grégory, Figueroa-Bossi, Nara, Schoehn, Guy, Bossi, Lionello, and Conway, James F.

Subjects

*VIRAL genetics, *SALMONELLA, *BACTERIOPHAGES, *MOLECULAR virology, *CRYOMICROSCOPY, *ELECTRON microscopy, *PROTEIN structure, *VIRAL proteins

Abstract

Abstract: Phage Gifsy-2, a lambdoid phage infecting Salmonella, has an unusually large composite gene coding for its major capsid protein (mcp) at the C-terminal end, a ClpP-like protease at the N-terminus, and a ∼200 residue central domain of unknown function but which may have a scaffolding role. This combination of functions on a single coding region is more extensive than those observed in other phages such as HK97 (scaffold–capsid fusion) and λ (protease–scaffold fusion). To study the structural phenotype of the unique Gifsy-2 capsid gene, we have purified Gifsy-2 particles and visualized capsids and procapsids by cryoelectron microscopy, determining structures to resolutions up to 12Å. The capsids have lambdoid T=7 geometry and are well modeled with the atomic structures of HK97 mcp and phage λ gpD decoration protein. Thus, the unique Gifsy-2 capsid protein gene yields a capsid maturation pathway engaging features from both phages HK97 and λ. [Copyright &y& Elsevier]

Published

2010

5. Fossil record of an archaeal HK97-like provirus

Author

Narahari Akkaladevi, Vamseedhar Rayaprolu, Brian Bothner, Mark J. Young, Walid S. Maaty, Joshua Heinemann, George H. Gauss, C. Martin Lawrence, and Susan K. Brumfield

Subjects

Archaeal Viruses, Models, Molecular, Virosomes, Archaeal Proteins, viruses, ved/biology.organism_classification_rank.species, Encapsulin, Particle, Virus, Bacteriophage, 03 medical and health sciences, Proviruses, Virology, HK97, Linocin, 030304 developmental biology, Genetics, 0303 health sciences, Sequence Homology, Amino Acid, biology, 030306 microbiology, ved/biology, Sulfolobus solfataricus, Herpesvirus, Provirus, biology.organism_classification, Archaea, Recombinant Proteins, Hyperthermophile, 3. Good health, Pyrococcus furiosus, Microscopy, Electron, Capsid, Proteome

Abstract

One of the outstanding questions in biology today is the origin of viruses. We have discovered a protein in the hyperthermophile Sulfolobus solfataricus while following proteome regulation during viral infection that led to the discovery of a fossil provirus. Characterization of the wild type and recombinant protein revealed that it assembled into virus-like particles with a diameter of ~32nm. Sequence and structural analyses showed that the likely proviral capsid protein, Sso2749, is homologous to a protein from Pyrococcus furiosus that forms virus-like particles using the HK-97 major capsid protein fold. The SsP2-provirus appears mosaic and contains proteins with similarity to, among others, eukaryotic herpesviruses and tailed dsDNA bacteriophage families, reinforcing the hypothesis of a common ancestral gene pool across all three domains of life. This is the first description of the HK-97 fold in a crenarchaeal virus and the first direct genomic connection of linocin-like protein cages to a virus.

6. The tripartite capsid gene of Salmonella phage Gifsy-2 yields a capsid assembly pathway engaging features from HK97 and λ

Author

Lionello Bossi, Guy Schoehn, Nara Figueroa-Bossi, James F. Conway, and Grégory Effantin

Subjects

Genes, Viral, medicine.medical_treatment, viruses, Assembly, Lambda, Bacteriophage, Capsid, Cryoelectron microscopy, Virology, medicine, Electron microscopy, Coding region, HK97, Gene, Protease, biology, Virus Assembly, Structure, Gifsy-2, biochemical phenomena, metabolism, and nutrition, biology.organism_classification, Phenotype, Molecular biology, Cell biology, Phage, Capsid Proteins, Domain of unknown function, Salmonella Phages

Abstract

Phage Gifsy-2, a lambdoid phage infecting Salmonella, has an unusually large composite gene coding for its major capsid protein (mcp) at the C-terminal end, a ClpP-like protease at the N-terminus, and a {approx} 200 residue central domain of unknown function but which may have a scaffolding role. This combination of functions on a single coding region is more extensive than those observed in other phages such as HK97 (scaffold-capsid fusion) and {lambda} (protease-scaffold fusion). To study the structural phenotype of the unique Gifsy-2 capsid gene, we have purified Gifsy-2 particles and visualized capsids and procapsids by cryoelectron microscopy, determining structures to resolutions up to 12 A. The capsids have lambdoid T = 7 geometry and are well modeled with the atomic structures of HK97 mcp and phage {lambda} gpD decoration protein. Thus, the unique Gifsy-2 capsid protein gene yields a capsid maturation pathway engaging features from both phages HK97 and {lambda}.