SummaryPoly(ADP-ribose)polymerase 1 (PARP-1) is a key eukaryotic stress sensor that responds in seconds to DNA single-strand breaks (SSBs), the most frequent genomic damage. A burst of poly(ADP-ribose) synthesis initiates DNA damage response, whereas PARP-1 inhibition kills BRCA-deficient tumor cells selectively, providing the first anti-cancer therapy based on synthetic lethality. However, the mechanism underlying PARP-1’s function remained obscure; inherent dynamics of SSBs and PARP-1’s multi-domain architecture hindered structural studies. Here we reveal the structural basis of SSB detection and how multi-domain folding underlies the allosteric switch that determines PARP-1’s signaling response. Two flexibly linked N-terminal zinc fingers recognize the extreme deformability of SSBs and drive co-operative, stepwise self-assembly of remaining PARP-1 domains to control the activity of the C-terminal catalytic domain. Automodifcation in cis explains the subsequent release of monomeric PARP-1 from DNA, allowing repair and replication to proceed. Our results provide a molecular framework for understanding PARP inhibitor action and, more generally, allosteric control of dynamic, multi-domain proteins.
The anti-cancer drug target poly(ADP-ribose) polymerase 1 (PARP1) and its close homologue, PARP2, are early responders to DNA damage in human cells 1 , 2 . Upon binding to genomic lesions, these enzymes utilise NAD + to modify a plethora of proteins with mono- and poly(ADP-ribose) signals that are important for subsequent chromatin decompaction and repair factor recruitment 3 , 4 . These post-translational modification events are predominantly serine-linked and require HPF1, an accessory factor that is specific for DNA damage response and switches the amino-acid specificity of PARP1/2 from aspartate/glutamate to serine residues 5 – 10 . Here, we report a co-structure of HPF1 bound to the catalytic domain of PARP2 that, in combination with NMR and biochemical data, reveals a composite active site formed by residues from both PARP1/2 and HPF1. We further show that the assembly of this new catalytic centre is essential for DNA damage-induced protein ADP-ribosylation in human cells. In response to DNA damage and NAD + binding site occupancy, the HPF1-PARP1/2 interaction is enhanced via allosteric networks operating within PARP1/2, providing an additional level of regulation in DNA repair induction. As HPF1 forms a joint active site with PARP1/2, our data implicate HPF1 as an important determinant of the response to clinical PARP inhibitors.
Many proteins involved in pre-mRNA processing contain one or more copies of a 70-90-amino-acid alphabeta module called the ribonucleoprotein domain. RNA maturation depends on the specific recognition by ribonucleoproteins of RNA elements within pre-mRNAs and small nuclear RNAs. The human U1A protein binds an RNA hairpin during splicing, and regulates its own expression by binding an internal loop in the 3'-untranslated region of its pre-mRNA, preventing polyadenylation. Here we report the nuclear magnetic resonance structure of the complex between the regulatory element of the U1A 3'-untranslated region (UTR) and the U1A protein RNA-binding domain. Specific intermolecular recognition requires the interaction of the variable loops of the ribonucleoprotein domain with the well-structured helical regions of the RNA. Formation of the complex then orders the flexible RNA single-stranded loop against the protein beta-sheet surface, and reorganizes the carboxy-terminal region of the protein to maximize surface complementarity and functional group recognition.
Steroid hormone receptors control gene expression through binding, as dimers, to short palindromic response elements located upstream of the genes they regulate. An independent domain of approximately 70 amino acids directs this sequence-specific DNA binding and is highly conserved between different receptor proteins and related transcription factors. This domain contains two zinc-binding Cys2-Cys2 sequence motifs, which loosely resemble the 'zinc-finger' motifs of TFIIIA. Here we describe the structure of the DNA-binding domain from the oestrogen receptor, as determined by two-dimensional 1H NMR techniques. The two 'zinc-finger'-like motifs fold to form a single structural domain and are thus distinct from the independently folded units of the TFIIIA-type zinc fingers. The structure consists of two helices perpendicular to each other. A zinc ion, coordinated by four conserved cysteines, holds the base of a loop at the N terminus of each helix. This novel structural domain seems to be a general structure for protein-DNA recognition.
Eukaryotic transcriptional repressors function by recruiting large co-regulatory complexes that target histone deacetylase enzymes to gene promoters/enhancers. Transcriptional repression complexes, assembled by the co-repressor NCoR, and its homologue SMRT, play critical roles in many processes including development and metabolic physiology. The core repression complex involves the recruitment of three proteins: HDAC3, GPS2 and TBL1 to a highly conserved repression domain within SMRT and NCoR. We have used a variety of structural and functional approaches to gain insight into the assembly, stoichiometry and biological role of this complex. We report the crystal structure of the tetrameric oligomerization domain of TBL1, which interacts with both SMRT and GPS2, and the NMR structure of the interface complex between GPS2 and SMRT. These structures, together with computational docking, mutagenesis and functional assays, reveal the assembly mechanism and stoichiometry of the co-repressor complex.The regulated repression of transcription plays a key role in many biological processes. These include cell fate decisions during development and cellular differentiation, as well as the maintenance of homeostasis. SMRT and NCoR are large homologous co-repressor proteins that were identified through their role in transcriptional repression by many 5 Corresponding author: john.schwabe@le.ac.uk. 4 These authors should be considered co-first authors. Author ContributionsThe contributions of J.O., L.F. & P.W. were critical to the final manuscript and these authors should be considered co-first authors. J.O. (assisted by J.Gooch) performed most of the protein cloning, expression, purification and interaction mapping, although important preliminary experiments were performed by B.K. J.O. prepared the GPS2-SMRT complex for NMR structure determination which was carried out by J-C.Y. and D.N. Crystallizations were performed primarily by J.O., with some later trials by J.Greenwood and L.F. Crystal structure determinations were performed by L.F., J.O. and J.W.R.S. The interaction motifs in GPS2 and SMRT were identified by J.W.R.S. and tested by pull-down experiments by J.O. Fluorescence polarization, co-immunoprecipitation and co-transfection/ purification assays were performed by P.W. The two-hybrid assays, gel filtrations and NMR comparisons of WT and MT TBL1 were performed by P.W., Z.C. and B.G. In silico docking experiments were performed by T.K. The laboratories of L.N. and D.N. provided experimental expertise for transfection and NMR studies respectively. J.W.R.S. planned and supervised the project and prepared the manuscript with assistance from the other authors. Accession Codes1H, 13C and 15N NMR resonance assignments for the SMRT(167-207) -GPS2(53-90) complex have been deposited at the BioMagResBank under accession code 17271, and the coordinates have been deposited under the pdb accession code 215G. The TBL1 X-ray structures have been deposited with the PDB codes (2XTC, 2XTD & 2XTE). When purified from HeLa cell extr...
Poly(ADP-ribose)polymerase-1 (PARP-1) is a highly abundant chromatin-associated enzyme present in all higher eukaryotic cell nuclei, where it plays key roles in the maintenance of genomic integrity, chromatin remodeling and transcriptional control. It binds to DNA single- and double-strand breaks through an N-terminal region containing two zinc fingers, F1 and F2, following which its C-terminal catalytic domain becomes activated via an unknown mechanism, causing formation and addition of polyadenosine-ribose (PAR) to acceptor proteins including PARP-1 itself. Here, we report a biophysical and structural characterization of the F1 and F2 fingers of human PARP-1, both as independent fragments and in the context of the 24-kDa DNA-binding domain (F1 + F2). We show that the fingers are structurally independent in the absence of DNA and share a highly similar structural fold and dynamics. The F1 + F2 fragment recognizes DNA single-strand breaks as a monomer and in a single orientation. Using a combination of NMR spectroscopy and other biophysical techniques, we show that recognition is primarily achieved by F2, which binds the DNA in an essentially identical manner whether present in isolation or in the two-finger fragment. F2 interacts much more strongly with nicked or gapped DNA ligands than does F1, and we present a mutational study that suggests origins of this difference. Our data suggest that different DNA lesions are recognized by the DNA-binding domain of PARP-1 in a highly similar conformation, helping to rationalize how the full-length protein participates in multiple steps of DNA single-strand breakage and base excision repair.
The main features of the protein structure are two antiparallel beta-sheets (a central one with three strands and another with two), a short helix that packs against the three-stranded beta-sheet, and a carboxy-terminal region that, although lacking regular secondary structure, is well defined and packs against the three-stranded beta-sheet, on the opposite face to the helix. We have used the structure, in combination with existing biochemical data, to identify residues that may be involved in C8 binding.
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