Arthropod-borne viruses are transmitted among vertebrate hosts by insect vectors. Unusually, Rift Valley fever virus (RVFV) can also be transmitted by direct contacts of animals/humans with infectious tissues. What are the molecular mechanisms and evolutionary events leading to adopt one mode of transmission rather than the other? Viral replication is implied to be different in a vertebrate host and an invertebrate host. The alternating host cycle tends to limit virus evolution by adopting a compromise fitness level for replication in both hosts. To test this hypothesis, we used a cell culture model system to study the evolution of RVFV. We found that freeing RVFV from alternating replication in mammalian and mosquito cells led to large deletions in the NSs gene carrying the virulence factor. Resulting NSs-truncated viruses were able to protect mice from a challenge with a virulent RVFV. Thus, in nature, virulence is likely maintained by continuous alternating passages between vertebrates and insects. Thereby, depending on the mode of transmission adopted, the evolution of RVFV will be of major importance to predict the outcome of outbreaks

A Billecocq

A Lazcano

AA Sall

Anna-Bella Failloux

AT Ciota

Benjamin Roche

BH Bird

C Giorgi

D Ebert

DA Steinhauer

E Domingo

François Rougeon

GW Anderson

IP Greene

IS Novella

J Peleg

JC de Roode

Jean-Michel Thiberge

JF Saluzzo

JH Strauss

JM Meegan

JT Paweska

JW Drake

K Tamura

KPR Singh

LA Cooper

LL Coffey

M Bouloy

MJ Turell

N Le May

P Vialat

PE Turner

R Muller

Rebeca Rico-Hesse

RM Anderson

S Moutailler

Sara Moutailler

SC Weaver

Valérie Caro

WA Geering

WP Taylor

English

PubMed

BACKGROUND: Most arthropod-borne viruses (arboviruses) are RNA viruses, which are maintained in nature by replication cycles that alternate between arthropod and vertebrate hosts. Arboviruses appear to experience lower rates of evolution than RNA viruses that replicate in a single host. This genetic stability is assumed to result from a fitness trade-off imposed by host alternation, which constrains arbovirus genome evolution. To test this hypothesis, we used Rift Valley fever virus (RVFV), an arbovirus that can be transmitted either directly (between vertebrates during the manipulation of infected tissues, and between mosquitoes by vertical transmission) or indirectly (from one vertebrate to another by mosquito-borne transmission). METHODOLOGY/PRINCIPAL FINDINGS: RVFV was serially passaged in BHK21 (hamster) or Aag2 (Aedes aegypti) cells, or in alternation between the two cell types. After 30 passages, these single host-passaged viruses lost their virulence and induced protective effects against a challenge with a virulent virus. Large deletions in the NSs gene that encodes the virulence factor were detectable from the 15(th) serial passage onwards in BHK21 cells and from the 10(th) passage in Aag2 cells. The phosphoprotein NSs is not essential to viral replication allowing clones carrying deletions in NSs to predominate as they replicate slightly more rapidly. No genetic changes were found in viruses that were passaged alternately between arthropod and vertebrate cells. Furthermore, alternating passaged viruses presenting complete NSs gene remained virulent after 30 passages. CONCLUSIONS/SIGNIFICANCE: Our results strongly support the view that alternating replication is necessary to maintain the virulence factor carried by the NSs phosphoprotein

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PLoS Neglected Tropical Diseases

Host alternation is necessary to maintain the genome stability of rift valley fever virus.

Most arthropod-borne viruses (arboviruses) are RNA viruses, which are maintained in nature by replication cycles that alternate between arthropod and vertebrate hosts. Arboviruses appear to experience lower rates of evolution than RNA viruses that replicate in a single host. This genetic stability is assumed to result from a fitness trade-off imposed by host alternation, which constrains arbovirus genome evolution. To test this hypothesis, we used Rift Valley fever virus (RVFV), an arbovirus that can be transmitted either directly (between vertebrates during the manipulation of infected tissues, and between mosquitoes by vertical transmission) or indirectly (from one vertebrate to another by mosquito-borne transmission). gene remained virulent after 30 passages. phosphoprotein

Moutailler Sara

Roche Benjamin

Thiberge Jean-Michel

Caro Valérie

Rougeon François

Failloux Anna-Bella

Public Library of Science (PLOS)

Host Alternation Is Necessary to Maintain the Genome Stability of Rift Valley Fever Virus

Crossref

International audienceBackground: Most arthropod-borne viruses (arboviruses) are RNA viruses, which are maintained in nature by replication cycles that alternate between arthropod and vertebrate hosts. Arboviruses appear to experience lower rates of evolution than RNA viruses that replicate in a single host. This genetic stability is assumed to result from a fitness trade-off imposed by host alternation, which constrains arbovirus genome evolution. To test this hypothesis, we used Rift Valley fever virus (RVFV), an arbovirus that can be transmitted either directly (between vertebrates during the manipulation of infected tissues, and between mosquitoes by vertical transmission) or indirectly (from one vertebrate to another by mosquito-borne ransmission). Methodology/Principal Findings: RVFV was serially passaged in BHK21 (hamster) or Aag2 (Aedes aegypti) cells, or in alternation between the two cell types. After 30 passages, these single host-passaged viruses lost their virulence and induced protective effects against a challenge with a virulent virus. Large deletions in the NSs gene that encodes the virulence factor were detectable from the 15th serial passage onwards in BHK21 cells and from the 10th passage in Aag2 cells. The phosphoprotein NSs is not essential to viral replication allowing clones carrying deletions in NSs to predominate as they replicate slightly more rapidly. No genetic changes were found in viruses that were passaged alternately between arthropod and vertebrate cells. Furthermore, alternating passaged viruses presenting complete NSs gene remained virulent after 30 passages. Conclusions/Significance: Our results strongly support the view that alternating replication is necessary to maintain the virulence factor carried by the NSs phosphoprotein

Moutailler, Sara

Roche, Benjamin

Thiberge, Jean-Michel

Caro, Valérie

Rougeon, François

Failloux, Anna-Bella

HAL Descartes

Host alternation is necessary to maintain the genome stability of rift valley Fever virus.: Genome stability of RVFV

HAL: Hyper Article en Ligne

Hal-Diderot

HAL-Pasteur

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Host Alternation Is Necessary to Maintain the Genome Stability of Rift Valley Fever Virus

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Directory of Open Access Journals

Public Library of Science (PLOS)

Crossref

HAL Descartes

HAL: Hyper Article en Ligne

Hal-Diderot

Public Library of Science (PLOS)

HAL-Pasteur