The cap-snatching frequency of a plant bunyavirus from nonsense mRNAs is low but is increased by silencing of UPF1 or SMG7

Identification of maize genes that condition early systemic infection of sugarcane mosaic virus through single-cell transcriptomics

During the early systemic infection of plant pathogens, individual cells can harbor pathogens at various stages of infection, ranging from absent to abundant. Consequently, gene expression levels within these cells in response to the pathogens exhibit significant variability. These variations are pivotal in determining pathogenicity or susceptibility, yet they remain largely unexplored and poorly understood. Sugarcane mosaic virus (SCMV) is a representative member of the monocot-infecting potyviruses with a polyadenylated RNA genome, which can be captured by single-cell RNA sequencing (scRNA-seq). Here, we performed scRNA-seq on SCMV-infected maize leaves during early systemic infection (prior to symptom manifestation) to investigate the co-variation patterns between viral accumulation and intracellular gene expression alterations. We identified five cell types and found that mesophyll-4 (MS4) cells exhibited the highest levels of viral accumulation in most cells. Early systemic infection of SCMV resulted in a greater upregulation of differentially expressed genes, which were mainly enriched in biological processes related to translation, peptide biosynthesis, and metabolism. Co-variation analysis of the altered maize gene expression and viral accumulation levels in MS1, 2, and 4 revealed several patterns, and the co-expression relationships between them were mainly positive. Furthermore, functional studies identified several potential anti- or pro-viral factors that may play crucial roles during the early stage of SCMV systemic infection. These results not only provide new insights into plant gene regulation during viral infection but also offer a foundation for future investigations of host-virus interactions across molecular, cellular, and physiological scales.

Transcription start site mapping of geminiviruses using the in vitro cap-snatching of a tenuivirus

Geminiviruses are a family of single-stranded DNA viruses that cause significant yield losses in crop production worldwide. Transcription start site (TSS) mapping is crucial in understanding the gene expression mechanisms of geminiviruses. However, this often requires costly and laborious experiments. Rice stripe virus (RSV) has a mechanism called cap-snatching, whereby it cleaves cellular mRNAs and uses the 5' cleavage product, a capped-RNA leader (CRL), as primers for transcription. Our previous work demonstrated that RSV snatches CRLs from geminiviral mRNAs in co-infected plants, providing a convenient and powerful approach to map the TSSs of geminiviruses. However, co-infections are not always feasible for all geminiviruses. In this study, we evaluated the use of in vitro cap-snatching of RSV for the same purpose, using tomato yellow leaf curl virus (TYLCV) as an example. We incubated RNA extracted from TYLCV-infected plants with purified RSV ribonucleoproteins in a reaction mixture that supports in vitro cap-snatching of RSV. The RSV mRNAs produced in the reaction were deep sequenced. The CRLs snatched by RSV allowed us to locate 28 TSSs in TYLCV. These results provide support for using RSV's in vitro cap-snatching to map geminiviral TSSs.

The biological functions of nonsense-mediated mRNA decay in plants: RNA quality control and beyond

Nonsense-mediated mRNA decay (NMD) is an evolutionarily conserved quality control pathway that inhibits the expression of transcripts containing premature termination codon. Transcriptome and phenotypic studies across a range of organisms indicate roles of NMD beyond RNA quality control and imply its involvement in regulating gene expression in a wide range of physiological processes. Studies in moss Physcomitrella patens and Arabidopsis thaliana have shown that NMD is also important in plants where it contributes to the regulation of pathogen defence, hormonal signalling, circadian clock, reproduction and gene evolution. Here, we provide up to date overview of the biological functions of NMD in plants. In addition, we discuss several biological processes where NMD factors implement their function through NMD-independent mechanisms.