Development of a single-cell atlas for woodland strawberry (<i>Fragaria vesca</i>) leaves during early <i>Botrytis cinerea</i> infection using single-cell RNA-seq

Bai, Yibo; Liu, Hui; Lyu, Hai-Meng; Su, Liyao; Xiong, Jinsong; Cheng, Zong‐Ming

doi:10.1093/hr/uhab055

Cited by 32 publications

(37 citation statements)

References 53 publications

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“…Based on the specific unique molecular identification of single‐cell, scRNA‐seq enable monitoring of intracellular transcriptional activity at the single‐cell level (Seyfferth et al ., 2021 ). Currently, scRNA‐seq of several plant species, such as Arabidopsis, strawberry, rice and maize, peanuts, and one woody plant populus were reported (Bai et al ., 2022 ; Chen et al ., 2021 ; Kim et al ., 2021 ; Li et al ., 2021 ; Liu et al ., 2020 , 2021 ; Marand et al ., 2021 ; Xie et al ., 2021 ; Zhang et al ., 2021a , b ). Through these studies, a database of cell‐specific markers and a single‐cell atlas of various tissues and organs from different species has been established, providing new insights into organ development, cell differentiation and cell division (Jin et al ., 2021 ).…”

Section: Introductionmentioning

confidence: 99%

Single‐cell transcriptome atlas reveals developmental trajectories and a novel metabolic pathway of catechin esters in tea leaves

Wang

Peng

et al. 2022

Plant Biotechnology Journal

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The tea plant is an economically important woody beverage crop. The unique taste of tea is evoked by certain metabolites, especially catechin esters, whereas their precise formation mechanism in different cell types remains unclear. Here, a fast protoplast isolation method was established and the transcriptional profiles of 16 977 single cells from 1st and 3rd leaves were investigated. We first identified 79 marker genes based on six isolated tissues and constructed a transcriptome atlas, mapped developmental trajectories and further delineated the distribution of different cell types during leaf differentiation and genes associated with cell fate transformation. Interestingly, eight differently expressed genes were found to co-exist at four branch points. Genes involved in the biosynthesis of certain metabolites showed cell-and development-specific characteristics. An unexpected catechin ester glycosyltransferase was characterized for the first time in plants by a gene co-expression network in mesophyll cells. Thus, the first single-cell transcriptional landscape in woody crop leave was reported and a novel metabolism pathway of catechin esters in plants was discovered.

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Section: Introductionmentioning

confidence: 99%

Single‐cell transcriptome atlas reveals developmental trajectories and a novel metabolic pathway of catechin esters in tea leaves

Wang

Peng

et al. 2022

Plant Biotechnology Journal

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“…All powdery mildew pathogens are strictly obligate biotrophic pathogens that adhere to the surface of plant tissues. Conventional omics mainly aim to characterize the plant response to pathogens at the whole‐tissue level, obscuring the characteristics of different cell populations (Bai et al, 2022). Botany applications of single‐cell transcriptomics enable the resolution of plant disease resistance processes at the level of individual cell types.…”

Section: Discussionmentioning

confidence: 99%

“…Conventional omics mainly aim to characterize the plant response to pathogens at the whole-tissue level, obscuring the characteristics of different cell populations (Bai et al, 2022). Botany applications of single-cell transcriptomics enable the resolution of plant disease In this study, we characterized the distinct gene expression patterns of rubber leaf cells during powdery mildew infection and successfully screened a gene for resistance to powdery mildew in rubber trees.…”

Section: Discussionmentioning

confidence: 99%

Single‐cell transcriptomic analyses reveal cellular and molecular patterns of rubber tree response to early powdery mildew infection

Liang

et al. 2023

Plant Cell & Environment

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As a perennial woody plant, the rubber tree (Hevea brasiliensis) must adapt to various environmental challenges through gene expression in multiple cell types. It is still unclear how genes in this species are expressed at the cellular level and the precise mechanisms by which cells respond transcriptionally to environmental stimuli, especially in the case of pathogen infection. Here, we characterized the transcriptomes in Hevea leaves during early powdery mildew infection using single‐cell RNA sequencing. We identified 10 cell types and constructed the first single‐cell atlas of Hevea leaves. Distinct gene expression patterns of the cell clusters were observed under powdery mildew infection, which was especially significant in the epidermal cells. Most of the genes involved in host–pathogen interactions in epidermal cells exhibited a pattern of dramatically increased expression with increasing pseudotime. Interestingly, we found that the HbCNL2 gene, encoding a nucleotide‐binding leucine‐rich repeat protein, positively modulated the defence of rubber leaves against powdery mildew. Overexpression of the HbCNL2 gene triggered a typical cell death phenotype in tobacco leaves and a higher level of reactive oxygen species in the protoplasts of Hevea leaves. The HbCNL2 protein was located in the cytomembrane and nucleus, and its leucine‐rich repeat domain interacted with the histidine kinase‐like ATPase domain of the molecular chaperone HbHSP90 in the nucleus. Collectively, our results provide the first observation of the cellular and molecular responses of Hevea leaves to biotrophic pathogen infection and can guide the identification of disease‐resistance genes in this important tree species.

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“…Bai et al. (2022) using scRNA‐seq obtained a pseudotime trajectory revealing mechanisms underlying the transition from normal functioning to the defense response in epidermal and mesophyll cells upon Botrytis cinerea infection.…”

Section: Single‐cell Transcriptomicsmentioning

confidence: 99%

Going broad and deep: sequencing‐driven insights into plant physiology, evolution, and crop domestication

et al. 2023

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SUMMARY Deep sequencing is a term that has become embedded in the plant genomic literature in recent years and with good reason. A torrent of (largely) high‐quality genomic and transcriptomic data has been collected and most of this has been publicly released. Indeed, almost 1000 plant genomes have been reported (http://www.plabipd.de) and the 2000 Plant Transcriptomes Project has long been completed. The EarthBioGenome project will dwarf even these milestones. That said, massive progress in understanding plant physiology, evolution, and crop domestication has been made by sequencing broadly (across a species) as well as deeply (within a single individual). We will outline the current state of the art in genome and transcriptome sequencing before we briefly review the most visible of these broad approaches, namely genome‐wide association and transcriptome‐wide association studies, as well as the compilation of pangenomes. This will include both (i) the most commonly used methods reliant on single nucleotide polymorphisms and short InDels and (ii) more recent examples which consider structural variants. We will subsequently present case studies exemplifying how their application has brought insight into either plant physiology or evolution and crop domestication. Finally, we will provide conclusions and an outlook as to the perspective for the extension of such approaches to different species, tissues, and biological processes.

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Development of a single-cell atlas for woodland strawberry (Fragaria vesca) leaves during early Botrytis cinerea infection using single-cell RNA-seq

Cited by 32 publications

References 53 publications

Single‐cell transcriptome atlas reveals developmental trajectories and a novel metabolic pathway of catechin esters in tea leaves

Single‐cell transcriptome atlas reveals developmental trajectories and a novel metabolic pathway of catechin esters in tea leaves

Single‐cell transcriptomic analyses reveal cellular and molecular patterns of rubber tree response to early powdery mildew infection

Going broad and deep: sequencing‐driven insights into plant physiology, evolution, and crop domestication

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