HPF1 and nucleosomes mediate a dramatic switch in activity of PARP1 from polymerase to hydrolase.

Johannes Rudolph,Uma M Muthurajan,Karolin Luger,Genevieve Roberts

doi:10.7554/elife.65773

Johannes Rudolph, Uma M Muthurajan + Show 2 more

Open Access

https://doi.org/10.7554/elife.65773

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Journal: eLife	Publication Date: Mar 8, 2021
Citations: 48	License type: CC BY 4.0

Affiliation: University of Colorado Boulder

Abstract

Poly(ADP-ribose) polymerase 1 (PARP1) is an important player in the response to DNA damage. Recently, Histone PARylation Factor (HPF1) was shown to be a critical modulator of the activity of PARP1 by facilitating PARylation of histones and redirecting the target amino acid specificity from acidic to serine residues. Here, we investigate the mechanism and specific consequences of HPF1-mediated PARylation using nucleosomes as both activators and substrates for PARP1. HPF1 provides that catalytic base Glu284 to substantially redirect PARylation by PARP1 such that the histones in nucleosomes become the primary recipients of PAR chains. Surprisingly, HPF1 partitions most of the reaction product to free ADP-ribose (ADPR), resulting in much shorter PAR chains compared to reactions in the absence of HPF1. This HPF1-mediated switch from polymerase to hydrolase has important implications for the PARP1-mediated response to DNA damage and raises interesting new questions about the role of intracellular ADPR and depletion of NAD+.

Highlights

DNA damage is a frequent occurrence in cells and must be continuously monitored and repaired in order to maintain genome stability (Peterson and Cote, 2004)
We show that HPF1 changes the specificity of Poly(ADP-ribose) polymerase 1 (PARP1) from autoPARylation and glutamate modification towards transPARylation and serine modification, it converts PARP1 into a strong NAD+ hydrolase, resulting in much shorter PAR chains and high concentrations of free ADPR
Since HPF1 is known to mediate PARylation of histones, proteins that are tethered to the genome in the form of chromatin, we set out to test the activity of PARP1 using nucleosome substrates

Summary

Introduction

DNA damage is a frequent occurrence in cells and must be continuously monitored and repaired in order to maintain genome stability (Peterson and Cote, 2004). PARP1 elongates this ADPR to form a chain in a process termed poly(ADP-ribosyl)ation (PARylation), which can take place on PARP1 (autoPARylation) or other proteins (transPARylation) (Gibson and Kraus, 2012; Morales et al, 2014; Bai, 2015). These PAR chains are attached to thousands of nuclear proteins with histones being the most abundantly PARylated proteins apart from PARP1 (Bonfiglio et al, 2017a; Larsen et al, 2018). Our results have important implications for the cellular role of HPF1 in PARylation, the PAR code, and the DNA damage response

Results

Discussion

Materials and methods

Funding Funder National Cancer Institute