Genetic Resistance to Smallpox: Lessons from Mousepox

Gunasegaran Karupiah; Vijay Panchanathan; Isaac G. Sakala; Geeta Chaudhri

doi:10.1002/9780470062128.ch11

Genetic Resistance to Smallpox: Lessons from Mousepox

Gunasegaran Karupiah^*, Vijay Panchanathan, Isaac G. Sakala, Geeta Chaudhri

^*Corresponding author for this work

Research output: Chapter in Book/Report/Conference proceeding › Chapter › peer-review

8 Citations (Scopus)

Abstract

There is increased interest in understanding protective immunity to smallpox for two principal reasons. First, it is the only disease that has been successfully eradicated using a live virus vaccine and, second, there exists a potential threat of intentional or unintentional release of variola virus, the causative agent of smallpox. Although mortality rates associated with smallpox were as high as 40%, a significant subset of those infected recovered. The basis of susceptibility or resistance, and the immune parameters associated with recovery, are still unknown. Animal models of poxvirus infections are being employed to understand what constitutes an effective host response. Ectromelia virus is closely related to variola virus and it causes a disease similar to smallpox in mice. This model is well established, resistant and susceptible strains of mice are defined and four genetic loci associated with resistance have been identified. Susceptibility to infection and disease severity is also influenced by virus immune evasion strategies. The outcome of infection is clearly dictated by several factors including host and viral genes, both of which influence the immune response. Here we present data on one virus-encoded immune modifier and its effect on the functions of two host genetic loci associated with resistance.

Original language	English
Title of host publication	Decoding the Genomic Control of Immune Reactions
Editors	Gregory Bock, Jamie Goode
Place of Publication	Chichester
Publisher	John Wiley & Sons Ltd.
Chapter	11
Pages	129-140
Number of pages	12
ISBN (Electronic)	9780470062128
ISBN (Print)	9780470027554
DOIs	https://doi.org/10.1002/9780470062128.ch11
Publication status	Published - 16 Mar 2007
Event	Novartis Foundation Symposium 281: Decoding the Genomic Control of Immune Reactions - University House, The Australian National University, Canberra, Australia Duration: 7 Mar 2006 → 9 Mar 2006 http://onlinelibrary.wiley.com/doi/book/10.1002/9780470062128

Publication series

Name	Novartis Foundation Symposium
Volume	281
ISSN (Electronic)	1935-4657

Conference

Conference	Novartis Foundation Symposium 281
Country/Territory	Australia
City	Canberra
Period	7/03/06 → 9/03/06
Internet address	http://onlinelibrary.wiley.com/doi/book/10.1002/9780470062128

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10.1002/9780470062128.ch11

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@inbook{3b0e2c0ee16b41d78fecb0b72f6989e0,

title = "Genetic Resistance to Smallpox: Lessons from Mousepox",

abstract = "There is increased interest in understanding protective immunity to smallpox for two principal reasons. First, it is the only disease that has been successfully eradicated using a live virus vaccine and, second, there exists a potential threat of intentional or unintentional release of variola virus, the causative agent of smallpox. Although mortality rates associated with smallpox were as high as 40%, a significant subset of those infected recovered. The basis of susceptibility or resistance, and the immune parameters associated with recovery, are still unknown. Animal models of poxvirus infections are being employed to understand what constitutes an effective host response. Ectromelia virus is closely related to variola virus and it causes a disease similar to smallpox in mice. This model is well established, resistant and susceptible strains of mice are defined and four genetic loci associated with resistance have been identified. Susceptibility to infection and disease severity is also influenced by virus immune evasion strategies. The outcome of infection is clearly dictated by several factors including host and viral genes, both of which influence the immune response. Here we present data on one virus-encoded immune modifier and its effect on the functions of two host genetic loci associated with resistance.",

keywords = "Host response to viral infection and disease outcome determinants, Infection susceptibility and disease severity by virus immune evasion strategies, Mousepox - model in virus-host interactions and smallpox, Smallpox, mousepox and genetic resistance, Understanding protective immunity to smallpox",

author = "Gunasegaran Karupiah and Vijay Panchanathan and Sakala, {Isaac G.} and Geeta Chaudhri",

note = "Publisher Copyright: {\textcopyright} Novartis Foundation 2007. All rights reserved.; Novartis Foundation Symposium 281 : Decoding the Genomic Control of Immune Reactions ; Conference date: 07-03-2006 Through 09-03-2006",

year = "2007",

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doi = "10.1002/9780470062128.ch11",

language = "English",

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series = "Novartis Foundation Symposium",

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editor = "Gregory Bock and Jamie Goode",

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Karupiah, G, Panchanathan, V, Sakala, IG & Chaudhri, G 2007, Genetic Resistance to Smallpox: Lessons from Mousepox. in G Bock & J Goode (eds), Decoding the Genomic Control of Immune Reactions. Novartis Foundation Symposium, vol. 281, John Wiley & Sons Ltd., Chichester, pp. 129-140, Novartis Foundation Symposium 281, Canberra, Australian Capital Territory, Australia, 7/03/06. https://doi.org/10.1002/9780470062128.ch11

Genetic Resistance to Smallpox: Lessons from Mousepox. / Karupiah, Gunasegaran; Panchanathan, Vijay; Sakala, Isaac G. et al.
Decoding the Genomic Control of Immune Reactions. ed. / Gregory Bock; Jamie Goode. Chichester: John Wiley & Sons Ltd., 2007. p. 129-140 (Novartis Foundation Symposium; Vol. 281).

Research output: Chapter in Book/Report/Conference proceeding › Chapter › peer-review

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AB - There is increased interest in understanding protective immunity to smallpox for two principal reasons. First, it is the only disease that has been successfully eradicated using a live virus vaccine and, second, there exists a potential threat of intentional or unintentional release of variola virus, the causative agent of smallpox. Although mortality rates associated with smallpox were as high as 40%, a significant subset of those infected recovered. The basis of susceptibility or resistance, and the immune parameters associated with recovery, are still unknown. Animal models of poxvirus infections are being employed to understand what constitutes an effective host response. Ectromelia virus is closely related to variola virus and it causes a disease similar to smallpox in mice. This model is well established, resistant and susceptible strains of mice are defined and four genetic loci associated with resistance have been identified. Susceptibility to infection and disease severity is also influenced by virus immune evasion strategies. The outcome of infection is clearly dictated by several factors including host and viral genes, both of which influence the immune response. Here we present data on one virus-encoded immune modifier and its effect on the functions of two host genetic loci associated with resistance.

KW - Host response to viral infection and disease outcome determinants

KW - Infection susceptibility and disease severity by virus immune evasion strategies

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DO - 10.1002/9780470062128.ch11

M3 - Chapter

SN - 9780470027554

T3 - Novartis Foundation Symposium

SP - 129

EP - 140

BT - Decoding the Genomic Control of Immune Reactions

A2 - Bock, Gregory

A2 - Goode, Jamie

PB - John Wiley & Sons Ltd.

CY - Chichester

Y2 - 7 March 2006 through 9 March 2006

ER -

Genetic Resistance to Smallpox: Lessons from Mousepox

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