Your search keyword '"Yan, Chunli"' showing total 7 results

1. Molecular architecture and functional dynamics of the pre-incision complex in nucleotide excision repair.

Author

Yu J, Yan C, Paul T, Brewer L, Tsutakawa SE, Tsai CL, Hamdan SM, Tainer JA, and Ivanov I

Subjects

Humans, Transcription Factor TFIIH metabolism, Transcription Factor TFIIH chemistry, Transcription Factor TFIIH genetics, Xeroderma Pigmentosum Group D Protein metabolism, Xeroderma Pigmentosum Group D Protein genetics, Xeroderma Pigmentosum Group D Protein chemistry, Cryoelectron Microscopy, Xeroderma Pigmentosum Group A Protein metabolism, Xeroderma Pigmentosum Group A Protein genetics, Transcription Factors metabolism, Transcription Factors genetics, Protein Binding, DNA metabolism, DNA chemistry, DNA genetics, Replication Protein A metabolism, Replication Protein A genetics, Models, Molecular, DNA, Single-Stranded metabolism, DNA, Single-Stranded genetics, Excision Repair, Nuclear Proteins, DNA Repair, DNA-Binding Proteins metabolism, DNA-Binding Proteins genetics, DNA-Binding Proteins chemistry, Endonucleases metabolism, Endonucleases genetics

Abstract

Nucleotide excision repair (NER) is vital for genome integrity. Yet, our understanding of the complex NER protein machinery remains incomplete. Combining cryo-EM and XL-MS data with AlphaFold2 predictions, we build an integrative model of the NER pre-incision complex(PInC). Here TFIIH serves as a molecular ruler, defining the DNA bubble size and precisely positioning the XPG and XPF nucleases for incision. Using simulations and graph theoretical analyses, we unveil PInC's assembly, global motions, and partitioning into dynamic communities. Remarkably, XPG caps XPD's DNA-binding groove and bridges both junctions of the DNA bubble, suggesting a novel coordination mechanism of PInC's dual incision. XPA rigging interlaces XPF/ERCC1 with RPA, XPD, XPB, and 5' ssDNA, exposing XPA's crucial role in licensing the XPF/ERCC1 incision. Mapping disease mutations onto our models reveals clustering into distinct mechanistic classes, elucidating xeroderma pigmentosum and Cockayne syndrome disease etiology., (© 2024. The Author(s).)

Published

2024

2. Dynamic conformational switching underlies TFIIH function in transcription and DNA repair and impacts genetic diseases.

Author

Yu J, Yan C, Dodd T, Tsai CL, Tainer JA, Tsutakawa SE, and Ivanov I

Subjects

Transcription Factor TFIIH genetics, Transcription Factor TFIIH metabolism, Molecular Conformation, DNA metabolism, Transcription, Genetic, DNA Repair, DNA Helicases genetics, DNA Helicases metabolism

Abstract

Transcription factor IIH (TFIIH) is a protein assembly essential for transcription initiation and nucleotide excision repair (NER). Yet, understanding of the conformational switching underpinning these diverse TFIIH functions remains fragmentary. TFIIH mechanisms critically depend on two translocase subunits, XPB and XPD. To unravel their functions and regulation, we build cryo-EM based TFIIH models in transcription- and NER-competent states. Using simulations and graph-theoretical analysis methods, we reveal TFIIH's global motions, define TFIIH partitioning into dynamic communities and show how TFIIH reshapes itself and self-regulates depending on functional context. Our study uncovers an internal regulatory mechanism that switches XPB and XPD activities making them mutually exclusive between NER and transcription initiation. By sequentially coordinating the XPB and XPD DNA-unwinding activities, the switch ensures precise DNA incision in NER. Mapping TFIIH disease mutations onto network models reveals clustering into distinct mechanistic classes, affecting translocase functions, protein interactions and interface dynamics., (© 2023. The Author(s).)

Published

2023

3. A scanning-to-incision switch in TFIIH-XPG induced by DNA damage licenses nucleotide excision repair.

Author

Bralić A, Tehseen M, Sobhy MA, Tsai CL, Alhudhali L, Yi G, Yu J, Yan C, Ivanov I, Tsutakawa SE, Tainer JA, and Hamdan SM

Subjects

DNA metabolism, DNA Damage, DNA, Single-Stranded, Endonucleases metabolism, Nucleotides, DNA Repair, Transcription Factor TFIIH metabolism

Abstract

Nucleotide excision repair (NER) is critical for removing bulky DNA base lesions and avoiding diseases. NER couples lesion recognition by XPC to strand separation by XPB and XPD ATPases, followed by lesion excision by XPF and XPG nucleases. Here, we describe key regulatory mechanisms and roles of XPG for and beyond its cleavage activity. Strikingly, by combing single-molecule imaging and bulk cleavage assays, we found that XPG binding to the 7-subunit TFIIH core (coreTFIIH) stimulates coreTFIIH-dependent double-strand (ds)DNA unwinding 10-fold, and XPG-dependent DNA cleavage by up to 700-fold. Simultaneous monitoring of rates for coreTFIIH single-stranded (ss)DNA translocation and dsDNA unwinding showed XPG acts by switching ssDNA translocation to dsDNA unwinding as a likely committed step. Pertinent to the NER pathway regulation, XPG incision activity is suppressed during coreTFIIH translocation on DNA but is licensed when coreTFIIH stalls at the lesion or when ATP hydrolysis is blocked. Moreover, ≥15 nucleotides of 5'-ssDNA is a prerequisite for efficient translocation and incision. Our results unveil a paired coordination mechanism in which key lesion scanning and DNA incision steps are sequentially coordinated, and damaged patch removal is only licensed after generation of ≥15 nucleotides of 5'-ssDNA, ensuring the correct ssDNA bubble size before cleavage., (© The Author(s) 2022. Published by Oxford University Press on behalf of Nucleic Acids Research.)

Published

2023

4. Mechanism of Rad26-assisted rescue of stalled RNA polymerase II in transcription-coupled repair.

Author

Yan C, Dodd T, Yu J, Leung B, Xu J, Oh J, Wang D, and Ivanov I

Subjects

Adenosine Triphosphatases, Cockayne Syndrome genetics, Computational Biology, Cryoelectron Microscopy, DNA chemistry, DNA metabolism, DNA Helicases genetics, DNA Repair Enzymes metabolism, Humans, Models, Molecular, Mutation, Poly-ADP-Ribose Binding Proteins metabolism, Protein Interaction Domains and Motifs, RNA Polymerase II genetics, DNA Helicases chemistry, DNA Helicases metabolism, DNA Repair, RNA Polymerase II chemistry, RNA Polymerase II metabolism

Abstract

Transcription-coupled repair is essential for the removal of DNA lesions from the transcribed genome. The pathway is initiated by CSB protein binding to stalled RNA polymerase II. Mutations impairing CSB function cause severe genetic disease. Yet, the ATP-dependent mechanism by which CSB powers RNA polymerase to bypass certain lesions while triggering excision of others is incompletely understood. Here we build structural models of RNA polymerase II bound to the yeast CSB ortholog Rad26 in nucleotide-free and bound states. This enables simulations and graph-theoretical analyses to define partitioning of this complex into dynamic communities and delineate how its structural elements function together to remodel DNA. We identify an allosteric pathway coupling motions of the Rad26 ATPase modules to changes in RNA polymerase and DNA to unveil a structural mechanism for CSB-assisted progression past less bulky lesions. Our models allow functional interpretation of the effects of Cockayne syndrome disease mutations., (© 2021. The Author(s).)

Published

2021

5. Envisioning how the prototypic molecular machine TFIIH functions in transcription initiation and DNA repair.

Author

Tsutakawa SE, Tsai CL, Yan C, Bralić A, Chazin WJ, Hamdan SM, Schärer OD, Ivanov I, and Tainer JA

Subjects

DNA metabolism, DNA Helicases metabolism, DNA-Binding Proteins metabolism, Humans, Models, Molecular, Protein Conformation, Transcription Factor TFIIH chemistry, Xeroderma Pigmentosum Group D Protein metabolism, DNA Damage, DNA Repair, Transcription Factor TFIIH metabolism, Transcription Initiation, Genetic

Abstract

Critical for transcription initiation and bulky lesion DNA repair, TFIIH provides an exemplary system to connect molecular mechanisms to biological outcomes due to its strong genetic links to different specific human diseases. Recent advances in structural and computational biology provide a unique opportunity to re-examine biologically relevant molecular structures and develop possible mechanistic insights for the large dynamic TFIIH complex. TFIIH presents many puzzles involving how its two SF2 helicase family enzymes, XPB and XPD, function in transcription initiation and repair: how do they initiate transcription, detect and verify DNA damage, select the damaged strand for incision, coordinate repair with transcription and cell cycle through Cdk-activating-kinase (CAK) signaling, and result in very different specific human diseases associated with cancer, aging, and development from single missense mutations? By joining analyses of breakthrough cryo-electron microscopy (cryo-EM) structures and advanced computation with data from biochemistry and human genetics, we develop unified concepts and molecular level understanding for TFIIH functions with a focus on structural mechanisms. We provocatively consider that TFIIH may have first evolved from evolutionary pressure for TCR to resolve arrested transcription blocks to DNA replication and later added its key roles in transcription initiation and global DNA repair. We anticipate that this level of mechanistic information will have significant impact on thinking about TFIIH, laying a robust foundation suitable to develop new paradigms for DNA transcription initiation and repair along with insights into disease prevention, susceptibility, diagnosis and interventions., (Copyright © 2020 The Authors. Published by Elsevier B.V. All rights reserved.)

Published

2020

6. Repair complexes of FEN1 endonuclease, DNA, and Rad9-Hus1-Rad1 are distinguished from their PCNA counterparts by functionally important stability.

Author

Querol-Audí J, Yan C, Xu X, Tsutakawa SE, Tsai MS, Tainer JA, Cooper PK, Nogales E, and Ivanov I

Subjects

Amino Acid Sequence, Base Sequence, Binding Sites, Cell Cycle Proteins genetics, Cell Cycle Proteins metabolism, DNA genetics, DNA metabolism, Electrophoresis, Polyacrylamide Gel, Exonucleases genetics, Exonucleases metabolism, Flap Endonucleases genetics, Flap Endonucleases metabolism, Humans, Microscopy, Electron, Models, Molecular, Molecular Dynamics Simulation, Molecular Sequence Data, Multiprotein Complexes chemistry, Multiprotein Complexes metabolism, Multiprotein Complexes ultrastructure, Nucleic Acid Conformation, Proliferating Cell Nuclear Antigen genetics, Proliferating Cell Nuclear Antigen metabolism, Protein Binding, Protein Structure, Quaternary, Protein Structure, Tertiary, Cell Cycle Proteins chemistry, DNA chemistry, DNA Repair, Exonucleases chemistry, Flap Endonucleases chemistry, Proliferating Cell Nuclear Antigen chemistry

Abstract

Processivity clamps such as proliferating cell nuclear antigen (PCNA) and the checkpoint sliding clamp Rad9/Rad1/Hus1 (9-1-1) act as versatile scaffolds in the coordinated recruitment of proteins involved in DNA replication, cell-cycle control, and DNA repair. Association and handoff of DNA-editing enzymes, such as flap endonuclease 1 (FEN1), with sliding clamps are key processes in biology, which are incompletely understood from a mechanistic point of view. We have used an integrative computational and experimental approach to define the assemblies of FEN1 with double-flap DNA substrates and either proliferating cell nuclear antigen or the checkpoint sliding clamp 9-1-1. Fully atomistic models of these two ternary complexes were developed and refined through extensive molecular dynamics simulations to expose their conformational dynamics. Clustering analysis revealed the most dominant conformations accessible to the complexes. The cluster centroids were subsequently used in conjunction with single-particle electron microscopy data to obtain a 3D EM reconstruction of the human 9-1-1/FEN1/DNA assembly at 18-Å resolution. Comparing the structures of the complexes revealed key differences in the orientation and interactions of FEN1 and double-flap DNA with the two clamps that are consistent with their respective functions in providing inherent flexibility for lagging strand DNA replication or inherent stability for DNA repair.

Published

2012

7. Envisioning how the prototypic molecular machine TFIIH functions in transcription initiation and DNA repair

Author

Tsutakawa, Susan E, Tsai, Chi-Lin, Yan, Chunli, Bralić, Amer, Chazin, Walter J, Hamdan, Samir M, Schärer, Orlando D, Ivanov, Ivaylo, and Tainer, John A

Subjects

Genetics, 2.1 Biological and endogenous factors, Aetiology, 1.1 Normal biological development and functioning, Underpinning research, Cancer, Generic health relevance, Good Health and Well Being, DNA, DNA Damage, DNA Helicases, DNA Repair, DNA-Binding Proteins, Humans, Models, Molecular, Protein Conformation, Transcription Factor TFIIH, Transcription Initiation, Genetic, Xeroderma Pigmentosum Group D Protein, TFIIH, Helicase, Transcription initiation, Transcription-coupled repair, Nucleotide excision repair, XPB, XPD, Translocase, DNA damage, DNA repair, Biochemistry and Cell Biology, Developmental Biology

Abstract

Critical for transcription initiation and bulky lesion DNA repair, TFIIH provides an exemplary system to connect molecular mechanisms to biological outcomes due to its strong genetic links to different specific human diseases. Recent advances in structural and computational biology provide a unique opportunity to re-examine biologically relevant molecular structures and develop possible mechanistic insights for the large dynamic TFIIH complex. TFIIH presents many puzzles involving how its two SF2 helicase family enzymes, XPB and XPD, function in transcription initiation and repair: how do they initiate transcription, detect and verify DNA damage, select the damaged strand for incision, coordinate repair with transcription and cell cycle through Cdk-activating-kinase (CAK) signaling, and result in very different specific human diseases associated with cancer, aging, and development from single missense mutations? By joining analyses of breakthrough cryo-electron microscopy (cryo-EM) structures and advanced computation with data from biochemistry and human genetics, we develop unified concepts and molecular level understanding for TFIIH functions with a focus on structural mechanisms. We provocatively consider that TFIIH may have first evolved from evolutionary pressure for TCR to resolve arrested transcription blocks to DNA replication and later added its key roles in transcription initiation and global DNA repair. We anticipate that this level of mechanistic information will have significant impact on thinking about TFIIH, laying a robust foundation suitable to develop new paradigms for DNA transcription initiation and repair along with insights into disease prevention, susceptibility, diagnosis and interventions.

Published

2020