Abstract

Simple SummaryPlants often harbor persistent plant virus infection transmitted only vertically through seeds, resulting in no obvious symptoms (cryptic infections). Several studies have shown that such cryptic infections provide resilience against abiotic (and biotic) stress. We have recently discovered a new group of cryptic plant viruses infecting mitochondria (plant mitovirus). Mitochondria are cellular organelles displaying a pivotal role in protecting cells from the stress of nature . Here, we look at the proteomic alterations caused by the mitovirus cryptic infection of Chenopodium quinoa by Systems Biology approaches allowing one to evaluate data at holistic level. Quinoa is a domesticated plant species with many exciting features of abiotic stress resistance, and it is distinguished by its exceptional nutritional characteristics, such as the content and quality of proteins, minerals, lipids, and tocopherols. These features determined the growing interest for the quinoa crop by the scientific community and international organizations since they provide opportunities to produce high-value grains in arid, high-salt and high-UV agroecological environments. We discovered that quinoa lines hosting mitovirus activate some metabolic processes that might help them face drought. These findings present a new perspective for breeding crop plants through the augmented genome provided by accessory cryptic viruses to be investigated in the future.Plant mitoviruses belong to Mitoviridae family and consist of positive single-stranded RNA genomes replicating exclusively in host mitochondria. We previously reported the biological characterization of a replicating plant mitovirus, designated Chenopodium quinoa mitovirus 1 (CqMV1), in some Chenopodium quinoa accessions. In this study, we analyzed the mitochondrial proteome from leaves of quinoa, infected and not infected by CqMV1. Furthermore, by protein–protein interaction and co-expression network models, we provided a system perspective of how CqMV1 affects mitochondrial functionality. We found that CqMV1 is associated with changes in mitochondrial protein expression in a mild but well-defined way. In quinoa-infected plants, we observed up-regulation of functional modules involved in amino acid catabolism, mitochondrial respiratory chain, proteolysis, folding/stress response and redox homeostasis. In this context, some proteins, including BCE2 (lipoamide acyltransferase component of branched-chain alpha-keto acid dehydrogenase complex), DELTA-OAT (ornithine aminotransferase) and GR-RBP2 (glycine-rich RNA-binding protein 2) were interesting because all up-regulated and network hubs in infected plants; together with other hubs, including CAT (catalase) and APX3 (L-ascorbate peroxidase 3), they play a role in stress response and redox homeostasis. These proteins could be related to the higher tolerance degree to drought we observed in CqMV1-infected plants. Although a specific causative link could not be established by our experimental approach at this stage, the results suggest a new mechanistic hypothesis that demands further in-depth functional studies.

Highlights

  • Mitoviruses belong to Mitoviridae family inside the Lenarviricota phylum and consist of positive single-stranded RNA genomes

  • We analyzed the mitochondrial proteome from leaves of quinoa lines, not infected (BO25, BO78) and infected (IPSP, REG), after confirming presence/absence of Chenopodium quinoa mitovirus 1 (CqMV1) by a specific qRT-PCR assay [7] (Figure 1A)

  • To identify differentially expressed proteins (DEPs) between not infected and infected phenotypes, data were evaluated at functional level by systems biology approaches based on graph theory, and in particular based on protein–protein interaction (PPI) and Co-Exp network models

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Summary

Introduction

Mitoviruses belong to Mitoviridae family inside the Lenarviricota phylum and consist of positive single-stranded RNA (ssRNA) genomes. Bruenn et al demonstrated the presence of mitoviral sequences in many plant nuclear and mitochondrial genomes [5], which was the first indirect evidence that plants, at some point, could become infected by mitoviruses; more recently, further indirect evidence of replicating plant mitoviruses has been provided by mining the transcriptome of a number of plant species [6] In this scenario, we have previously reported the complete genome sequence and the biological characterization of a replicating plant mitovirus, designated Chenopodium quinoa mitovirus 1 (CqMV1), in some Chenopodium quinoa accessions [7]. Mitoviruses were first discovered and characterized in fungi, but recently, in addition to their occurrence in some plant mitochondria, evidence of mitoviruses infecting insects was provided [8]

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