The cryo-EM structure of African swine fever virus unravels a unique architecture comprising two icosahedral protein capsids and two lipoprotein membranes

Andrés, Germán; Charro, Diego; Matamoros, Tania; Dillard, Rebecca S.; Abrescia, Nicola G. A.

doi:10.1074/jbc.ac119.011196

Cited by 84 publications

(82 citation statements)

References 63 publications

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“…The disease is caused by African swine fever virus (ASFV), a large nucleocytoplasmic virus that contains a double-stranded 170-190 kb DNA genome, encoding 151-167 open reading frames (ORFs) [1]. The ASFV virion is a complex multi-enveloped and multi icosahedral particle containing at least 68 different structural viral polypeptides and 21 cellular proteins and possess a much more complex structure than previously believed [1][2][3]. ASFV replicates predominantly in mononuclear-phagocytic cells (monocytes and macrophages), which play a front-line role in activating and orchestrating the innate and adaptive host responses.…”

Section: Introductionmentioning

confidence: 99%

African swine fever vaccines: a promising work still in progress

2020

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African swine fever (ASF), a disease of obligatory declaration to the World Organization for Animal Health (OIE), has contributed to poverty and underdevelopment of affected areas. The presence of ASF has been historically neglected in Africa, contributing to its uncontrolled expansion and favouring its spread to continental Europe on at least three occasions, the last one in 2007 through the Republic of Georgia. Since then, African swine fever virus (ASFV) has spread to neighbouring countries, reaching the European Union in 2014, China in the summer of 2018 and spreading through Southeast Asia becoming a global problem. Lack of available vaccines against ASF makes its control even more difficult, representing today the number one threat for the swine industry worldwide and negatively affecting the global commerce equilibrium. Main body: In this review, we intend to put in perspective the reality of ASF vaccination today, taking into account that investment into ASF vaccine development has been traditionally unattractive, overall since ASF-free areas with large swine industries applied a non-vaccination policy for diseases listed by the OIE. The dramatic situation suffered in Asia and the increasing threat that ASF represents for wealthy countries with large swine industries, has dramatically changed the perspective that both private and public bodies have about ASF vaccinology, although this is controversial. The feasibility of modifying the ASFV genome has led to safe and efficacious experimental recombinant live attenuated viruses (LAVs). The main challenge today will be confirming the safety and efficacy of these technologies in the field, accelerating transfer to the industry for official registration and commercialization. The complexity of ASFV, together with the lack of knowledge about the mechanisms involved in protection and the specific antigens involved in it, requires further investment in research and development. Although far from the efficacy achieved by LAVs, subunit vaccines are the optimal choice for the future. If the world can wait for them or not is a contentious issue. Conclusion: Despite their inherent disadvantages, LAVs will be the first technology to reach the market, while subunit vaccines will need much further research to become a successful commercial reality.

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Section: Introductionmentioning

confidence: 99%

African swine fever vaccines: a promising work still in progress

2020

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“…This dimension ultimately recapitulates the relative packing and angular orientation of the individual β-barrels, V1 and V2, which is reflected in the angular aperture, of helices FG1-α and FG2-α (~69° as estimated for PRD1 P3 in CHIMERA [ 23 , 51 ]) and is mainly conserved across all the PRD1-adenovirus members ( Figure 2 B and Figure 3 ; <66.9° > ±7.3° as estimated across 26 MCP structures derived either through X-ray or cryo-EM). The structural invariance of this footprint allows the identification of the double β-barrel fold even at intermediate resolution, as occurred in the case of the African Swine Fever virus (ASFV) p72 MCP whose 8280 copies compose the virion outermost capsid shell ( Figure 3 , right) [ 52 ]. The ASFV p72 double β-barrel and the MCPs of the other large nucleocytoplasmic large DNA virus (NCLDV), PBCV-1 and Faustovirus cluster together [ 26 , 33 , 53 , 54 , 55 , 56 ] ( Figure 2 B).…”

Section: Major Capsid Proteins With a Double β-Barrel Fold: The Comentioning

confidence: 99%

“…The estimated angle between the two helices FG1-α and FG2-α is ~72° in line to that found across the corresponding helices in PRD1. Right, cryo-EM map of homotrimers of ASFV MCP p72 viewed along the 3-fold axis showing the pseudo-hexameric footprint generated by the p72 protein adopting the double jelly-roll fold (EMDBid 10325); this is displayed using the local resolution and mapped onto the density (color-coded resolution bar in Å) [ 52 ].…”

Section: Figurementioning

confidence: 99%

Superimposition of Viral Protein Structures: A Means to Decipher the Phylogenies of Viruses

Ravantti

Martínez-Castillo

Abrescia

2020

Viruses

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Superimposition of protein structures is key in unravelling structural homology across proteins whose sequence similarity is lost. Structural comparison provides insights into protein function and evolution. Here, we review some of the original findings and thoughts that have led to the current established structure-based phylogeny of viruses: starting from the original observation that the major capsid proteins of plant and animal viruses possess similar folds, to the idea that each virus has an innate “self”. This latter idea fueled the conceptualization of the PRD1-adenovirus lineage whose members possess a major capsid protein (innate “self”) with a double jelly roll fold. Based on this approach, long-range viral evolutionary relationships can be detected allowing the virosphere to be classified in four structure-based lineages. However, this process is not without its challenges or limitations. As an example of these hurdles, we finally touch on the difficulty of establishing structural “self” traits for enveloped viruses showcasing the coronaviruses but also the power of structure-based analysis in the understanding of emerging viruses

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“…In a brute-force effort to collect over 1,000 viral particles, in this issue Andrés et al (6) are able to report the structure of the complete, intact ASFV virion. Starting from the inside, the structure includes an inner nucleoid region containing the dsDNA genome (170 -190 kbp) enclosed by an inner capsid.…”

mentioning

confidence: 99%

“…Andrés et al employed additional approaches to overcome the degradation of resolution at the outer viral capsid, which contains antigenically important protein p72. To circumvent problems posed by imaging overly large particles by cryo-EM, they deconstructed the virus biochemically and then purified and resolved the structure of p72 as individual homotrimers free in solution (6). In a parallel effort, Wang et al (7) have recently reported the structure of ASFV, but they employ a different approach to resolve the outer capsid.…”

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confidence: 99%

Cryo-EM cools down swine fever

Gallagher

Harris

2020

Journal of Biological Chemistry

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Edited by Craig E. Cameron African swine fever virus (ASFV) is among the most complex DNA viruses known. Outbreaks have killed millions of swine around the world, and there is currently no vaccine. Three recent papers report the cryo-EM structure of the complete ASFV virion, comprising a viral particle of multiple layers, and resolve the major outer-capsid protein p72 to higher resolution. Progress in these reports provides a further understanding of the structure-function relationships of large viruses and should aid in ASFV vaccine development.

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The cryo-EM structure of African swine fever virus unravels a unique architecture comprising two icosahedral protein capsids and two lipoprotein membranes

Cited by 84 publications

References 63 publications

African swine fever vaccines: a promising work still in progress

African swine fever vaccines: a promising work still in progress

Superimposition of Viral Protein Structures: A Means to Decipher the Phylogenies of Viruses

Cryo-EM cools down swine fever

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