Single-nucleus RNA and ATAC sequencing reveals the impact of chromatin accessibility on gene expression in Arabidopsis roots at the singlecell level

Similar to other complex organisms,plants consist of diverse and specialized cell types.The gain of unique biological functions of these different cell types is the consequence of the establishment of cell-typespecific transcriptional programs.As a necessary step in gaining a deeper understanding of the regulatory mechanisms controlling plant gene expression,we report the use of single-nucleus RNA sequencing(sNucRNA-seq)and single-nucleus assay for transposase accessible chromatin sequencing(sNucATACseq)technologies on Arabidopsis roots.The comparison of our single-nucleus transcriptomes to the published protoplast transcriptomes validated the use of nuclei as biological entities to establish plant cell-type-specific transcriptomes.Furthermore,our sNucRNA-seq results uncovered the transcriptomes of additional cell subtypes not identified by single-cell RNA-seq.Similar to our transcriptomic approach,the sNucATAC-seq approach led to the distribution of the Arabidopsis nuclei into distinct clusters,suggesting the differential accessibility of chromatin between groups of cells according to their identity.To reveal the impact of chromatin accessibility on gene expression,we integrated sNucRNA-seq and sNucATAC-seq data and demonstrated that cell-type-specific marker genes display cell-type-specific patterns of chromatin accessibility.Our data suggest that the differential chromatin accessibility is a critical mechanism to regulate gene activity at the cell-type level.

Involvement of C2H2 zinc finger proteins in the regulation of epidermal cell fate determination in Arabidopsis

Cell fate determination is a basic developmental process during the growth of multicellular organisms.Trichomes and root hairs of Arabidopsis are both readily accessible structures originating from the epidermal cells of the aerial tissues and roots respectively, and they serve as excellent models for understanding the molecular mechanisms controlling cell fate determination and cell morphogenesis. The regulation of trichome and root hair formationis a complex program that consists of the integration of hormonal signals with a large number of transcriptional factors, including MYB and b HLH transcriptional factors.Studies during recent years have uncovered an important role of C2H2 type zinc finger proteins in the regulation of epidermal cell fate determination. Here in this minireview we briefly summarize the involvement of C2H2 zinc finger proteins in the control of trichome and root hair formation in Arabidopsis.