Abstract
Temperature profoundly affects the kinetics of biochemical reactions, yet how large molecular complexes such as the transcription machinery accommodate changing temperatures to maintain cellular function is poorly understood. Here, we developed plant native elongating transcripts sequencing (plaNET-seq) to profile genome-wide nascent RNA polymerase II (RNAPII) transcription during the cold-response of Arabidopsis thaliana with single-nucleotide resolution. Combined with temporal resolution, these data revealed transient genome-wide reprogramming of nascent RNAPII transcription during cold, including characteristics of RNAPII elongation and thousands of non-coding transcripts connected to gene expression. Our results suggest a role for promoter–proximal RNAPII stalling in predisposing genes for transcriptional activation during plant–environment interactions. At gene 3′-ends, cold initially facilitated transcriptional termination by limiting the distance of read-through transcription. Within gene bodies, cold reduced the kinetics of co-transcriptional splicing leading to increased intragenic stalling. Our data resolved multiple distinct mechanisms by which temperature transiently altered the dynamics of nascent RNAPII transcription and associated RNA processing, illustrating potential biotechnological solutions and future focus areas to promote food security in the context of a changing climate.
Highlights
Changes to ambient temperatures challenge the development and growth of living organisms
Our analysis identified small nuclear RNAs involved in splicing, confirming co-purification of the spliceosome with RNA polymerase II (RNAPII) complexes (Supplementary fig. 4b), consistent with earlier reports[15,21]
Highly expressed genes in Arabidopsis exist without evidence for divergent non-coding transcripts (DNC) originating from their promoter NDR
Summary
Changes to ambient temperatures challenge the development and growth of living organisms. While mammals retain a stable body temperature, sessile organisms such as plants continually sense their environment and rely on molecular mechanisms that compensate for temperature changes[1]. Alterations to the ambient temperature frequently lead to re-programming of the transcriptional output by RNA polymerase II (RNAPII) that reflects steady-state levels of messenger RNAs and noncoding RNAs in the cell[2,3]. Sequence-specific transcription factors controlling the initiation of transcription often shape these responses. The significance of mechanisms regulating eukaryotic gene expression after initiation, for example through control of elongation of the nascent. RNA chain is increasingly appreciated[4].
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