Abstract
The naturally occurring Δ40p53 isoform heterotetramerizes with wild-type p53 (WTp53) to regulate development, aging, and stress responses. How Δ40p53 alters WTp53 function remains enigmatic because their co-expression causes tetramer heterogeneity. We circumvented this issue with a well-tested strategy that expressed Δ40p53:WTp53 as a single transcript, ensuring a 2:2 tetramer stoichiometry. Human MCF10A cell lines expressing Δ40p53:WTp53, WTp53, or WTp53:WTp53 (as controls) from the native TP53 locus were examined with transcriptomics (precision nuclear run-on sequencing [PRO-seq] and RNA sequencing [RNA-seq]), metabolomics, and other methods. Δ40p53:WTp53 was transcriptionally active, and, although phenotypically similar to WTp53 under normal conditions, it failed to induce growth arrest upon Nutlin-induced p53 activation. This occurred via Δ40p53:WTp53-dependent inhibition of enhancer RNA (eRNA) transcription and subsequent failure to induce mRNA biogenesis, despite similar genomic occupancy to WTp53. A different stimulus (5-fluorouracil [5FU]) also showed Δ40p53:WTp53-specific changes in mRNA induction; however, other transcription factors (TFs; e.g., E2F2) could then drive the response, yielding similar outcomes vs. WTp53. Our results establish that Δ40p53 tempers WTp53 function to enable compensatory responses by other stimulus-specific TFs. Such modulation of WTp53 activity may be an essential physiological function for Δ40p53. Moreover, Δ40p53:WTp53 functional distinctions uncovered herein suggest an eRNA requirement for mRNA biogenesis and that human p53 evolved as a tetramer to support eRNA transcription.
Highlights
Transcription factors (TFs) are the primary drivers of cell state and cell physiology [1]
Δ40p53:wild-type p53 (WTp53) functional distinctions uncovered suggest an enhancer RNA (eRNA) requirement for mRNA biogenesis and that human p53 evolved as a tetramer to support eRNA transcription
Because Δ40p53:WTp53 was expressed as a single transcript, a fixed 2:2 tetramer stoichiometry was assured, avoiding tetramer heterogeneity that results from Δ40p53 + WTp53 co-expression
Summary
Transcription factors (TFs) are the primary drivers of cell state and cell physiology [1]. As a testament to their biological importance, an entire population of fibroblasts will form myotubes upon had no role in study design, data collection and analysis, decision to publish, or preparation of the manuscript. Expression of a single TF, MyoD [2]. As a TF, p53 coordinates cellular stress responses and plays key roles in cancer, aging, and stem cell biology [3,4,5]. Regulation of p53 function across these diverse biological circumstances involves an array of mechanisms, with well-studied exam-
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