Zika Virus Infection Results in Biochemical Changes Associated With RNA Editing, Inflammatory and Antiviral Responses in Aedes albopictus.

Maria G Onyango,Erin Taylor Kelly,Geoffrey M Attardo,Elyse Banker,Laura D Kramer,Alexander T Ciota,Jessica Stout,Sean M Bialosuknia,Lili Kuo

doi:10.3389/fmicb.2020.559035

Abstract

Rapid and significant range expansion of both the Zika virus (ZIKV) and its Aedes vector species has resulted in the declaration of ZIKV as a global health threat. Successful transmission of ZIKV by its vector requires a complex series of interactions between these entities including the establishment, replication and dissemination of the virus within the mosquito. The metabolic conditions within the mosquito tissues play a critical role in mediating the crucial processes of viral infection and replication and represent targets for prevention of virus transmission. In this study, we carried out a comprehensive metabolomic phenotyping of ZIKV infected and uninfected Ae. albopictus by untargeted analysis of primary metabolites, lipids and biogenic amines. We performed a comparative metabolomic study of infection state with the aim of understanding the biochemical changes resulting from the interaction between the ZIKV and its vector. We have demonstrated that ZIKV infection results in changes to the cellular metabolic environment including a significant enrichment of inosine and pseudo-uridine (Ψ) levels which may be associated with RNA editing activity. In addition, infected mosquitoes demonstrate a hypoglycemic phenotype and show significant increases in the abundance of metabolites such as prostaglandin H2, leukotriene D4 and protoporphyrinogen IX which are associated with antiviral activity. These provide a basis for understanding the biochemical response to ZIKV infection and pathology in the vector. Future mechanistic studies targeting these ZIKV infection responsive metabolites and their associated biosynthetic pathways can provide inroads to identification of mosquito antiviral responses with infection blocking potential.

Highlights

Zika virus (ZIKV) was first isolated in Zika forest, Uganda from a sentinel rhesus monkey in 1947 as well as from Aedes (Stegomyia) africana (Dick, 1952; Dick et al, 1952; Hayes, 2009; Petersen et al, 2016) and is a member of the family Flaviviridae, genus Flavivirus with a 10,794 base positive-sense single stranded RNA genome (Faye et al, 2014), classified as a member of the Spondweni group (Cook and Holmes, 2006)
The goal of this study is to provide a comprehensive analysis of dynamic changes in the global metabolic profile in whole Ae. albopictus mosquitoes infected with ZIKV
RNA-editing enzymes, Adenosine deaminases that act on RNA (ADARs) deaminates double stranded RNA converting adenosine (A) to inosine (I) in pre-mRNA hairpins (Bass and Weintraub, 1988)

Summary

Introduction

Zika virus (ZIKV) was first isolated in Zika forest, Uganda from a sentinel rhesus monkey in 1947 as well as from Aedes (Stegomyia) africana (Dick, 1952; Dick et al, 1952; Hayes, 2009; Petersen et al, 2016) and is a member of the family Flaviviridae, genus Flavivirus with a 10,794 base positive-sense single stranded RNA genome (Faye et al, 2014), classified as a member of the Spondweni group (Cook and Holmes, 2006). ZIKV has become a focus of intense research due to its rapid geographic spread in the Americas as well as its association with birth defects in offspring from infected mothers (e.g., microcephaly) and neurological syndromes (Ventura et al, 2016; de Oliveira et al, 2017; World Health Organization [WHO], 2019). This has resulted in a concerted effort to understand the biology of ZIKV and the interactions it has with its vector host. Despite the progress made in understanding Zika etiology and its transmission, there exists a significant knowledge gap in the understanding of interactions between ZIKV and its vector

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