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The nucleolus, a dynamic nuclear compartment long regarded as the cell ribosome factory, is emerging as an important player in the regulation of cell survival and recovery from stress. In larger eukaryotes, the stress-induced transcriptional response is mediated by a family of heat-shock transcription factors. Among these, HSF1, considered the master regulator of stress-induced transcriptional responses, controls the expression of cytoprotective heat shock proteins (HSPs), molecular chaperones/cochaperones constituting a major component of the cell protein quality control machinery essential to circumvent stress-induced degradation and aggregation of misfolded proteins. Herein we identify human NF-KB repressing factor (NKRF) as a nucleolar HSP essential for nucleolus homeostasis and cell survival under proteotoxic stress. NKRF acts as a thermosensor translocating from the nucleolus to the nucleoplasm during heat stress; nucleolar pools are replenished during recovery upon HSF1-mediated NKRF resynthesis. Silencing experiments demonstrate that NKRF is an unconventional HSP crucial for correct ribosomal RNA (rRNA) processing and preventing aberrant rRNA precursors and discarded fragment accumulation. These effects are mediated by NKRF interaction with the 5?-to-3? exoribonuclease XRN2, a key coordinator of multiple pre-rRNA cleavages, driving mature rRNA formation and discarded rRNA decay. Under stress conditions, NKRF directs XRN2 nucleolus/nucleoplasm trafficking, controlling 5?-to-3? exoribonuclease nucleolar levels and regulating rRNA processing. Our study reveals a different aspect of rRNA biogenesis control in human cells and sheds light on a sophisticated mechanism of nucleolar homeostasis surveillance during stress.

Human NF-kB repressing factor acts as a stress-regulated switch for ribosomal RNA processing and nucleolar homeostasis surveillance

Rossi A;Trotta E;Santoro MG
2017

Abstract

The nucleolus, a dynamic nuclear compartment long regarded as the cell ribosome factory, is emerging as an important player in the regulation of cell survival and recovery from stress. In larger eukaryotes, the stress-induced transcriptional response is mediated by a family of heat-shock transcription factors. Among these, HSF1, considered the master regulator of stress-induced transcriptional responses, controls the expression of cytoprotective heat shock proteins (HSPs), molecular chaperones/cochaperones constituting a major component of the cell protein quality control machinery essential to circumvent stress-induced degradation and aggregation of misfolded proteins. Herein we identify human NF-KB repressing factor (NKRF) as a nucleolar HSP essential for nucleolus homeostasis and cell survival under proteotoxic stress. NKRF acts as a thermosensor translocating from the nucleolus to the nucleoplasm during heat stress; nucleolar pools are replenished during recovery upon HSF1-mediated NKRF resynthesis. Silencing experiments demonstrate that NKRF is an unconventional HSP crucial for correct ribosomal RNA (rRNA) processing and preventing aberrant rRNA precursors and discarded fragment accumulation. These effects are mediated by NKRF interaction with the 5?-to-3? exoribonuclease XRN2, a key coordinator of multiple pre-rRNA cleavages, driving mature rRNA formation and discarded rRNA decay. Under stress conditions, NKRF directs XRN2 nucleolus/nucleoplasm trafficking, controlling 5?-to-3? exoribonuclease nucleolar levels and regulating rRNA processing. Our study reveals a different aspect of rRNA biogenesis control in human cells and sheds light on a sophisticated mechanism of nucleolar homeostasis surveillance during stress.
2017
FARMACOLOGIA TRASLAZIONALE - IFT
Inglese
WOS:000393196300077
114
1045
1050
6
2-s2.0-85010931757
https://www.pnas.org/doi/10.1073/pnas.1616112114?url_ver=Z39.88-2003&rfr_id=ori:rid:crossref.org&rfr_dat=cr_pub 0pubmed
heat shock factor 1 | NF-kappaB | nucleolus | proteotoxic stress | rRNA processing
Coccia M. and Rossi A. contributed equally to this work The Article has been Highlighted in the section EDITORS' CHOISE Science Signalling Vol. 10, Issue 465, eaam9083 DOI: 10.1126/scisignal.aam9083 NF-?B repressing factor controls localization and activation of an rRNA processing protein in heat stress response. Increased temperature causes cells to initiate heat shock responses in the nucleus, including activating heat shock transcription factors (HSFs), which bind to heat shock elements (HSEs) to promote the expression of genes encoding heat shock proteins (HSPs). Many HSPs are molecular chaperones that stabilize proteins, which can unfold during heat stress, but some genes induced by heat shock encode proteins that are not molecular chaperones. Coccia et al. found that HSF1, a master transcription factor activated by heat stress, promoted the expression of the gene encoding nuclear factor ?B repressing factor (NKRF), which enabled ribosomal RNA (rRNA) processing during recovery from temperature stress. HeLa cells exposed to 43°C (or 39°C, to mimic fever conditions) exhibited increased NKRF mRNA, a response lacking in HSF1-silenced cells. The promoter region of the gene encoding NKRF contains two putative HSEs, one of which promoted transcription in response to heat stress in a reporter assay using wild-type HeLa cells but not HSF1-silenced cells. However, the amount of NKRF protein decreased during the heat shock period and took several hours after the temperature was returned to 37°C to recover in abundance, suggesting that NKRF mRNA accumulated during heat shock and then was translated during the recovery period. NKRF shifted from the soluble fraction in nonstressed cells to the insoluble fraction in heat-stressed cells, which may trigger its degradation. NKRF colocalized with the 5?-to-3? exonuclease XRN2, which converts 32.5S pre-rRNA into 32S rRNA and degrades the residual fragments in the nucleolus. Both XRN2 and NKRF moved from the nucleolus to the nucleoplasm during heat stress and returned to the nucleolus within 3 hours after the return to 37°C. The relocalization of XRN2 to the nucleolus during recovery from heat stress required NKRF. Silencing NKRF under normal temperature resulted in the accumulation of unprocessed pre-rRNA and rRNA fragments. In heat-stressed wild-type cells, unprocessed pre-rRNA accumulated during heat stress but decreased after cells were returned to normal temperature, consistent with inhibition of processing followed by resumption. In NKRF-silenced cells, the amount of unprocessed rRNA remained high after cells were returned to normal temperature and cell death increased. The authors propose a model wherein HSF1 induces transcription of NKRF during heat shock, providing a pool of transcript for translation upon the return to normal temperature and thereby enabling the return of XNR2 to the nucleolus and reactivation of pre-rRNA processing.
5
info:eu-repo/semantics/article
262
Coccia, M; Rossi, A; Riccio, A; Trotta, E; Santoro, Mg
01 Contributo su Rivista::01.01 Articolo in rivista
open
01.01 Articolo in rivista
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Utilizza questo identificativo per citare o creare un link a questo documento: https://hdl.handle.net/20.500.14243/353657
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