A Possible Overwintering Mechanism for Bluetongue Virus in the Absence of the Insect Vector

Overview

Journal J Gen Virol

Specialty Microbiology

Date 2003 Jan 21

PMID 12533719

Citations 35

Authors

H Takamatsu

P S Mellor

P P C Mertens

P A Kirkham

J N Burroughs

R M E Parkhouse

Affiliations

Soon will be listed here.

Abstract

Bluetongue virus (BTV) and several other Orbivirus species are transmitted between mammalian hosts via bites from adults of certain species of Culicoides midges. However, BTV can survive for 9-12 months (typically during the winter), in the absence of adult vectors, with no detectable cases of viraemia, disease or seroconversion in the host. The survival of the virus from one 'vector season' to the next is called 'overwintering' but the mechanism involved is not fully understood. It is demonstrated that BTV can persistently infect ovine gammadelta T-cells in vitro, a process that may also occur during infection and viraemia in mammalian hosts, thus providing a mechanism for virus persistence. Interaction of persistently BTV-infected gammadelta T-cells with antibody to the gammadelta T-cell-specific surface molecule WC-1 resulted in conversion to a lytic infection and increased virus release. Skin fibroblasts induce a similar conversion, indicating that they express a counter ligand for WC-1. Feeding of Culicoides midges induces skin inflammation, which is accompanied by recruitment of large numbers of activated gammadelta T-cells. The interaction of persistently infected gammadelta T-cells with skin fibroblasts would result in increased virus production at 'biting sites', favouring transmission to the insect vector. This suggested mechanism might also involve up-regulation of the WC-1 ligand at inflamed sites. It has been shown previously that cleavage of virus surface proteins by protease enzymes (which may also be associated with inflammation) generates infectious subvirus particles that have enhanced infectivity (100 times) for the insect vector.

Citing Articles

Culicoides and midge-associated arboviruses on cattle farms in Yunnan Province, China.

Duan Y, Li Z, Bellis G, Li L, Liu B, Wang J Parasite. 2024; 31:72.

PMID: 39565151 PMC: 11578047. DOI: 10.1051/parasite/2024072.

Increased Virulence of Midge Cell-Derived Bluetongue Virus in IFNAR Mice.

Drolet B, Reister-Hendricks L, Mayo C, Rodgers C, Molik D, McVey D Viruses. 2024; 16(9).

PMID: 39339950 PMC: 11437402. DOI: 10.3390/v16091474.

Longitudinal seroepidemiological survey and risk factors for bluetongue virus infection in sheep in the state of Parana, Brazil, from 2014 to 2017.

Sbizera M, Barreto J, Pertile S, de Almeida Rego F, Lisboa J, da Cunha Filho L Braz J Microbiol. 2024; 55(4):4191-4198.

PMID: 39177730 PMC: 11711410. DOI: 10.1007/s42770-024-01486-9.

Arthropod-Borne Viruses of Human and Animal Importance: Overwintering in Temperate Regions of Europe during an Era of Climate Change.

Mansfield K, Schilling M, Sanders C, Holding M, Johnson N Microorganisms. 2024; 12(7).

PMID: 39065076 PMC: 11278640. DOI: 10.3390/microorganisms12071307.

Specific T-cell subsets have a role in anti-viral immunity and pathogenesis but not viral dynamics or onwards vector transmission of an important livestock arbovirus.

Newbrook K, Khan N, Fisher A, Chong K, Gubbins S, Davies W Front Immunol. 2024; 15:1328820.

PMID: 38357545 PMC: 10864546. DOI: 10.3389/fimmu.2024.1328820.