Viral evolution in the cosmos

Nidia S. Trovao; Alexander G. Lucaci; Nikhil Pradeep; Meher Sethi; Lisa M. Bono; Ruth Subhash Singh; Kevin B. Clark; Victoria Zaksas; Marissa Burke; Andrés Caicedo; Verónica Castañeda; Kevin Zambrano; Rashid Karim; Corey A. Theriot; Guliz Otkiran; Dirk Neefs; Gaetano Isola; Gianluca Tartaglia; Michael Schotsaert; Sana Tamim; Saswati Das; Michael Fasullo; Nilufar Ali; Denis Fargette; Nicholas J.B. Brereton; Afshin Beheshti; Joseph W. Guarnieri; Eve Syrkin Wurtele

doi:10.1016/B978-0-443-32904-3.00009-1

Viral evolution in the cosmos

Nidia S. Trovao
, Alexander G. Lucaci
, Nikhil Pradeep
, Meher Sethi
, Lisa M. Bono
, Ruth Subhash Singh
, Kevin B. Clark
, Victoria Zaksas
, Marissa Burke
, Andrés Caicedo
, Verónica Castañeda
, Kevin Zambrano
, Rashid Karim
, Corey A. Theriot
, Guliz Otkiran
, Dirk Neefs
, Gaetano Isola
, Gianluca Tartaglia
, Michael Schotsaert
, Sana Tamim

Saswati Das, Michael Fasullo, Nilufar Ali, Denis Fargette, Nicholas J.B. Brereton, Afshin Beheshti, Joseph W. Guarnieri, Eve Syrkin Wurtele

Producción científica: Capítulo del libro/informe/acta de congreso › Capítulo › revisión exhaustiva

Resumen

Space travel exposes human beings to unique environmental stressors (e.g., radiation, microgravity) and induces significant physiological changes in hosts, profoundly impacting host-virus dynamics and creating conditions conducive to viral evolution. This chapter reviews current knowledge on viral behavior and evolution within the space environment, considering human, animal, plant, and spaceflight-associated viral sources. We discuss how spaceflight factors, coupled with host immune dysregulation, metabolic and hormonal shifts, altered cellular characteristics like membrane fluidity, and mitochondrial dysfunction, can influence viral replication, latency, transmission, and genetic variation. The well-documented reactivation of latent human herpesviruses (e.g., cytomegalovirus , Epstein-Barr virus, varicella-zoster virus, herpes simplex viruses) during space missions serves as a critical example of these effects, highlighting health risks within the confined built environment of spaceflight, which itself fosters unique viral transmission and coevolutionary scenarios. Methodologies for molecular diagnostics, genomic surveillance, data management and open data sharing, and advanced computational modeling, including phylodynamics, deep mutational scanning, and AI-based protein structure prediction, are explored as essential tools. Finally, strategies for mitigating viral risks during and after space missions are considered, alongside the broader implications of this research for long-duration space exploration, planetary protection, and terrestrial planetary health, emphasizing the critical need for continued investigation into viral adaptability in extraterrestrial settings.

Idioma original	Inglés
Título de la publicación alojada	Fundamentals of Space Medicine and Clinical Technology
Editorial	Elsevier
Páginas	67-96
Número de páginas	30
ISBN (versión digital)	9780443329043
ISBN (versión impresa)	9780443329050
DOI	https://doi.org/10.1016/B978-0-443-32904-3.00009-1
Estado	Publicada - 1 ene. 2025

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Trovao, N. S., Lucaci, A. G., Pradeep, N., Sethi, M., Bono, L. M., Singh, R. S., Clark, K. B., Zaksas, V., Burke, M., Caicedo, A., Castañeda, V., Zambrano, K., Karim, R., Theriot, C. A., Otkiran, G., Neefs, D., Isola, G., Tartaglia, G., Schotsaert, M., ... Wurtele, E. S. (2025). Viral evolution in the cosmos. En Fundamentals of Space Medicine and Clinical Technology (pp. 67-96). Elsevier. https://doi.org/10.1016/B978-0-443-32904-3.00009-1

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title = "Viral evolution in the cosmos",

abstract = "Space travel exposes human beings to unique environmental stressors (e.g., radiation, microgravity) and induces significant physiological changes in hosts, profoundly impacting host-virus dynamics and creating conditions conducive to viral evolution. This chapter reviews current knowledge on viral behavior and evolution within the space environment, considering human, animal, plant, and spaceflight-associated viral sources. We discuss how spaceflight factors, coupled with host immune dysregulation, metabolic and hormonal shifts, altered cellular characteristics like membrane fluidity, and mitochondrial dysfunction, can influence viral replication, latency, transmission, and genetic variation. The well-documented reactivation of latent human herpesviruses (e.g., cytomegalovirus , Epstein-Barr virus, varicella-zoster virus, herpes simplex viruses) during space missions serves as a critical example of these effects, highlighting health risks within the confined built environment of spaceflight, which itself fosters unique viral transmission and coevolutionary scenarios. Methodologies for molecular diagnostics, genomic surveillance, data management and open data sharing, and advanced computational modeling, including phylodynamics, deep mutational scanning, and AI-based protein structure prediction, are explored as essential tools. Finally, strategies for mitigating viral risks during and after space missions are considered, alongside the broader implications of this research for long-duration space exploration, planetary protection, and terrestrial planetary health, emphasizing the critical need for continued investigation into viral adaptability in extraterrestrial settings.",

keywords = "Evolutionary biology, astrovirology, biological sciences, evolutionary process, host-virus interactions, infectious disease, microgravity, space radiation, viral evolution, virology",

author = "Trovao, \{Nidia S.\} and Lucaci, \{Alexander G.\} and Nikhil Pradeep and Meher Sethi and Bono, \{Lisa M.\} and Singh, \{Ruth Subhash\} and Clark, \{Kevin B.\} and Victoria Zaksas and Marissa Burke and Andr{\'e}s Caicedo and Ver{\'o}nica Casta{\~n}eda and Kevin Zambrano and Rashid Karim and Theriot, \{Corey A.\} and Guliz Otkiran and Dirk Neefs and Gaetano Isola and Gianluca Tartaglia and Michael Schotsaert and Sana Tamim and Saswati Das and Michael Fasullo and Nilufar Ali and Denis Fargette and Brereton, \{Nicholas J.B.\} and Afshin Beheshti and Guarnieri, \{Joseph W.\} and Wurtele, \{Eve Syrkin\}",

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month = jan,

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doi = "10.1016/B978-0-443-32904-3.00009-1",

language = "English",

isbn = "9780443329050",

pages = "67--96",

booktitle = "Fundamentals of Space Medicine and Clinical Technology",

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Trovao, NS, Lucaci, AG, Pradeep, N, Sethi, M, Bono, LM, Singh, RS, Clark, KB, Zaksas, V, Burke, M, Caicedo, A, Castañeda, V, Zambrano, K, Karim, R, Theriot, CA, Otkiran, G, Neefs, D, Isola, G, Tartaglia, G, Schotsaert, M, Tamim, S, Das, S, Fasullo, M, Ali, N, Fargette, D, Brereton, NJB, Beheshti, A, Guarnieri, JW & Wurtele, ES 2025, Viral evolution in the cosmos. En Fundamentals of Space Medicine and Clinical Technology. Elsevier, pp. 67-96. https://doi.org/10.1016/B978-0-443-32904-3.00009-1

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AU - Trovao, Nidia S.

AU - Lucaci, Alexander G.

AU - Pradeep, Nikhil

AU - Sethi, Meher

AU - Bono, Lisa M.

AU - Singh, Ruth Subhash

AU - Clark, Kevin B.

AU - Zaksas, Victoria

AU - Burke, Marissa

AU - Caicedo, Andrés

AU - Castañeda, Verónica

AU - Zambrano, Kevin

AU - Karim, Rashid

AU - Theriot, Corey A.

AU - Otkiran, Guliz

AU - Neefs, Dirk

AU - Isola, Gaetano

AU - Tartaglia, Gianluca

AU - Schotsaert, Michael

AU - Tamim, Sana

AU - Das, Saswati

AU - Fasullo, Michael

AU - Ali, Nilufar

AU - Fargette, Denis

AU - Brereton, Nicholas J.B.

AU - Beheshti, Afshin

AU - Guarnieri, Joseph W.

AU - Wurtele, Eve Syrkin

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N2 - Space travel exposes human beings to unique environmental stressors (e.g., radiation, microgravity) and induces significant physiological changes in hosts, profoundly impacting host-virus dynamics and creating conditions conducive to viral evolution. This chapter reviews current knowledge on viral behavior and evolution within the space environment, considering human, animal, plant, and spaceflight-associated viral sources. We discuss how spaceflight factors, coupled with host immune dysregulation, metabolic and hormonal shifts, altered cellular characteristics like membrane fluidity, and mitochondrial dysfunction, can influence viral replication, latency, transmission, and genetic variation. The well-documented reactivation of latent human herpesviruses (e.g., cytomegalovirus , Epstein-Barr virus, varicella-zoster virus, herpes simplex viruses) during space missions serves as a critical example of these effects, highlighting health risks within the confined built environment of spaceflight, which itself fosters unique viral transmission and coevolutionary scenarios. Methodologies for molecular diagnostics, genomic surveillance, data management and open data sharing, and advanced computational modeling, including phylodynamics, deep mutational scanning, and AI-based protein structure prediction, are explored as essential tools. Finally, strategies for mitigating viral risks during and after space missions are considered, alongside the broader implications of this research for long-duration space exploration, planetary protection, and terrestrial planetary health, emphasizing the critical need for continued investigation into viral adaptability in extraterrestrial settings.

AB - Space travel exposes human beings to unique environmental stressors (e.g., radiation, microgravity) and induces significant physiological changes in hosts, profoundly impacting host-virus dynamics and creating conditions conducive to viral evolution. This chapter reviews current knowledge on viral behavior and evolution within the space environment, considering human, animal, plant, and spaceflight-associated viral sources. We discuss how spaceflight factors, coupled with host immune dysregulation, metabolic and hormonal shifts, altered cellular characteristics like membrane fluidity, and mitochondrial dysfunction, can influence viral replication, latency, transmission, and genetic variation. The well-documented reactivation of latent human herpesviruses (e.g., cytomegalovirus , Epstein-Barr virus, varicella-zoster virus, herpes simplex viruses) during space missions serves as a critical example of these effects, highlighting health risks within the confined built environment of spaceflight, which itself fosters unique viral transmission and coevolutionary scenarios. Methodologies for molecular diagnostics, genomic surveillance, data management and open data sharing, and advanced computational modeling, including phylodynamics, deep mutational scanning, and AI-based protein structure prediction, are explored as essential tools. Finally, strategies for mitigating viral risks during and after space missions are considered, alongside the broader implications of this research for long-duration space exploration, planetary protection, and terrestrial planetary health, emphasizing the critical need for continued investigation into viral adaptability in extraterrestrial settings.

KW - Evolutionary biology

KW - astrovirology

KW - biological sciences

KW - evolutionary process

KW - host-virus interactions

KW - infectious disease

KW - microgravity

KW - space radiation

KW - viral evolution

KW - virology

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DO - 10.1016/B978-0-443-32904-3.00009-1

M3 - Chapter

AN - SCOPUS:105029204479

SN - 9780443329050

SP - 67

EP - 96

BT - Fundamentals of Space Medicine and Clinical Technology

PB - Elsevier

ER -

Viral evolution in the cosmos

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