Your search keyword '"Tudor Domain"' showing total 500 results

101. Tudor domain of histone demethylase KDM4B is a reader of H4K20me3

Author

Jing Guo, Feng Li, Jie Xiong, and Ying Xiang

Subjects

Jumonji Domain-Containing Histone Demethylases, Tudor domain, DNA damage, Biophysics, Biochemistry, Cell Line, Histones, 03 medical and health sciences, 0302 clinical medicine, Protein Domains, Humans, Peptide sequence, 030304 developmental biology, 0303 health sciences, biology, Chemistry, General Medicine, Methylation, Surface Plasmon Resonance, Chromatin, Cell biology, Histone, 030220 oncology & carcinogenesis, biology.protein, H3K4me3, Demethylase, Protein Binding

Abstract

The lysine histone demethylase KDM4B is overexpressed in several types of cancers and plays dual roles in genome stability maintenance. Although KDM4B is able to recognize several histone methylations, the underlying molecular mechanism is still unknown. In this study, we purified the KDM4B chromatin-associated hybrid tudor domains (HTDs) and plant home domains (PHDs) and performed the pull-down assay to screen the tri-methyl modified histone peptides that could be efficiently recognized by KDM4B. Our results showed that both HTD alone and the combination of HTD and PHD were able to specifically bind to H3K4me3 and H4K20me3. Because H4K20me3 is essential for KDM4B's rapid recruitment to DNA damage site, we further aligned the multiple tudor peptide sequence and identified two conserved residues Y993 and W987 that are critical for KDM4B-H4K20me3 interaction. The surface plasmon resonance analysis revealed that HTD displayed a rapid H4K20me3 bind-dissociate pattern. These findings therefore provided mechanistic insights into the binding of tudor domain of KDM4B protein with H4K20me3.

Published

2020

102. A capped Tudor domain within a core subunit of the Sin3L/Rpd3L histone deacetylase complex binds to nucleic acid G-quadruplexes

Author

Ryan Dale Marcum, Joseph Hsieh, Maksim Giljen, Emily Justice, Nicolas Daffern, Yongbo Zhang, and Ishwar Radhakrishnan

Subjects

Mammals, chromatin-modifying complex, protein-nucleic acid interactions, Tudor Domain, MBP, maltose-binding protein, BRMS1, breast cancer metastasis suppressor 1, HDAC, histone deacetylase, Cell Biology, transcriptional corepressor, SELEX, systematic evolution of ligands by exponential enrichment, Biochemistry, Histone Deacetylases, CTD, capped Tudor domain, G-Quadruplexes, Sin3 Histone Deacetylase and Corepressor Complex, BAH, bromo adjacent homology, BRMS1L, BRMS1-like, Animals, HAT, histone acetyltransferase, Amino Acid Sequence, Molecular Biology, Protein Binding, Transcription Factors, Research Article, solution NMR

Abstract

Chromatin-modifying complexes containing histone deacetylase (HDAC) activities play critical roles in the regulation of gene transcription in eukaryotes. These complexes are thought to lack intrinsic DNA-binding activity, but according to a well-established paradigm, they are recruited via protein–protein interactions by gene-specific transcription factors and posttranslational histone modifications to their sites of action on the genome. The mammalian Sin3L/Rpd3L complex, comprising more than a dozen different polypeptides, is an ancient HDAC complex found in diverse eukaryotes. The subunits of this complex harbor conserved domains and motifs of unknown structure and function. Here, we show that Sds3, a constitutively-associated subunit critical for the proper functioning of the Sin3L/Rpd3L complex, harbors a type of Tudor domain that we designate the capped Tudor domain. Unlike canonical Tudor domains that bind modified histones, the Sds3 capped Tudor domain binds to nucleic acids that can form higher-order structures such as G-quadruplexes and shares similarities with the knotted Tudor domain of the Esa1 histone acetyltransferase that was previously shown to bind single-stranded RNA. Our findings expand the range of macromolecules capable of recruiting the Sin3L/Rpd3L complex and draw attention to potentially new biological roles for this HDAC complex.

Published

2022

103. Small Molecules Targeting the Specific Domains of Histone-Mark Readers in Cancer Therapy

Author

Huihui Zhu, Yong Cai, Tao Wei, and Jingji Jin

Subjects

Tudor domain, Protein domain, Pharmaceutical Science, Antineoplastic Agents, Computational biology, Review, Methylation, Analytical Chemistry, Chromodomain, Epigenesis, Genetic, lcsh:QD241-441, 03 medical and health sciences, 0302 clinical medicine, Drug Delivery Systems, lcsh:Organic chemistry, Protein Domains, Neoplasms, Drug Discovery, Histone methylation, Animals, Humans, Epigenetics, histone methylation, Physical and Theoretical Chemistry, 030304 developmental biology, 0303 health sciences, biology, histone marks, Organic Chemistry, histone acetylation, Acetylation, Chromatin, Bromodomain, Histone Code, Histone, Chemistry (miscellaneous), 030220 oncology & carcinogenesis, biology.protein, Molecular Medicine, cancer therapy, Protein Binding

Abstract

Epigenetic modifications (or epigenetic tags) on DNA and histones not only alter the chromatin structure, but also provide a recognition platform for subsequent protein recruitment and enable them to acquire executive instructions to carry out specific intracellular biological processes. In cells, different epigenetic-tags on DNA and histones are often recognized by the specific domains in proteins (readers), such as bromodomain (BRD), chromodomain (CHD), plant homeodomain (PHD), Tudor domain, Pro-Trp-Trp-Pro (PWWP) domain and malignant brain tumor (MBT) domain. Recent accumulating data reveal that abnormal intracellular histone modifications (histone marks) caused by tumors can be modulated by small molecule-mediated changes in the activity of the above domains, suggesting that small molecules targeting histone-mark reader domains may be the trend of new anticancer drug development. Here, we summarize the protein domains involved in histone-mark recognition, and introduce recent research findings about small molecules targeting histone-mark readers in cancer therapy.

Published

2019

104. Structure of the UHRF1 Tandem Tudor Domain Bound to a Methylated Non-histone Protein, LIG1, Reveals Rules for Binding and Regulation

Author

Tomohiro Jimenji, Rumie Matsumura, Mamoru Sato, Naoshi Dohmae, Kyohei Arita, Yoichi Shinkai, Satomi Kori, Noriyuki Kodera, Laure Ferry, Toshio Ando, Pierre-Antoine Defossez, Takeshi Tsusaka, Takashi Oda, Shohei Matano, Yokohama City University, Sorbonne Paris Cite, CNRS, Epigenet & Cell Fate UMR7216, Université Paris Diderot - Paris 7 (UPD7), Centre épigénétique et destin cellulaire (EDC (UMR_7216)), Université Paris Diderot - Paris 7 (UPD7)-Centre National de la Recherche Scientifique (CNRS), and Yokohama City University (YCU)

Subjects

Models, Molecular, Tudor domain, Protein Conformation, Ubiquitin-Protein Ligases, Arginine, Crystallography, X-Ray, Methylation, Epigenesis, Genetic, Histones, DNA Ligase ATP, 03 medical and health sciences, Non-histone protein, Protein Domains, Structural Biology, Humans, Epigenetics, Phosphorylation, Molecular Biology, 030304 developmental biology, chemistry.chemical_classification, 0303 health sciences, DNA ligase, Binding Sites, biology, Chemistry, 030302 biochemistry & molecular biology, [SDV.BBM.BM]Life Sciences [q-bio]/Biochemistry, Molecular Biology/Molecular biology, Cell biology, Chromatin, Histone, Gene Expression Regulation, DNA methylation, CCAAT-Enhancer-Binding Proteins, biology.protein, Linker

Abstract

Summary The protein UHRF1 is crucial for DNA methylation maintenance. The tandem Tudor domain (TTD) of UHRF1 binds histone H3K9me2/3 with micromolar affinity, as well as unmethylated linker regions within UHRF1 itself, causing auto-inhibition. Recently, we showed that a methylated histone-like region of DNA ligase 1 (LIG1K126me2/me3) binds the UHRF1 TTD with nanomolar affinity, permitting UHRF1 recruitment to chromatin. Here we report the crystal structure of the UHRF1 TTD bound to a LIG1K126me3 peptide. The data explain the basis for the high TTD-binding affinity of LIG1K126me3 and reveal that the interaction may be regulated by phosphorylation. Binding of LIG1K126me3 switches the overall structure of UHRF1 from a closed to a flexible conformation, suggesting that auto-inhibition is relieved. Our results provide structural insight into how UHRF1 performs its key function in epigenetic maintenance.

Published

2019

105. Molecular basis for the inhibition of the methyl-lysine binding function of 53BP1 by TIRR

Author

Xiuhua Liu, Rong Xie, Xiaochun Yu, Guang Yang, Jiaxu Wang, Yinliang Ma, Chen Wu, Mengxi Wang, Zenglin Yuan, Muzaffer Ahmad Kassab, and Yaqi Cui

Subjects

0301 basic medicine, Tudor domain, DNA repair, DNA damage, Science, General Physics and Astronomy, Plasma protein binding, medicine.disease_cause, General Biochemistry, Genetics and Molecular Biology, 03 medical and health sciences, chemistry.chemical_compound, 0302 clinical medicine, medicine, lcsh:Science, Mutation, Multidisciplinary, biology, Chemistry, General Chemistry, Methylation, 3. Good health, Cell biology, 030104 developmental biology, Histone, biology.protein, lcsh:Q, 030217 neurology & neurosurgery, DNA

Abstract

53BP1 performs essential functions in DNA double-strand break (DSB) repair and it was recently reported that Tudor interacting repair regulator (TIRR) negatively regulates 53BP1 during DSB repair. Here, we present the crystal structure of the 53BP1 tandem Tudor domain (TTD) in complex with TIRR. Our results show that three loops from TIRR interact with 53BP1 TTD and mask the methylated lysine-binding pocket in TTD. Thus, TIRR competes with histone H4K20 methylation for 53BP1 binding. We map key interaction residues in 53BP1 TTD and TIRR, whose mutation abolishes complex formation. Moreover, TIRR suppresses the relocation of 53BP1 to DNA lesions and 53BP1-dependent DNA damage repair. Finally, despite the high-sequence homology between TIRR and NUDT16, NUDT16 does not directly interact with 53BP1 due to the absence of key residues required for binding. Taken together, our study provides insights into the molecular mechanism underlying TIRR-mediated suppression of 53BP1-dependent DNA damage repair.

Published

2018

106. Targeting lysine specific demethylase 4A (KDM4A) tandem TUDOR domain – A fragment based approach

Author

Anup K. Upadhyay, Ron Pithawalla, Rodger F. Henry, Russell A. Judge, Chaohong Sun, Justin A. Simanis, Leiming Li, Violeta L. Marin, Andrew M. Petros, and Pierre M. Bodelle

Subjects

0301 basic medicine, Jumonji Domain-Containing Histone Demethylases, Tudor domain, Clinical Biochemistry, Allosteric regulation, Lysine, Fragment-based lead discovery, Pharmaceutical Science, Biochemistry, Histone H4, Structure-Activity Relationship, 03 medical and health sciences, Histone H3, Oxidoreductase, Drug Discovery, Humans, Nuclear Magnetic Resonance, Biomolecular, Molecular Biology, chemistry.chemical_classification, Dose-Response Relationship, Drug, Molecular Structure, Tudor Domain, 030102 biochemistry & molecular biology, Chemistry, Organic Chemistry, Hydrogen Bonding, Chromatin, 030104 developmental biology, Molecular Medicine, Hydrophobic and Hydrophilic Interactions

Abstract

The tandem TUDOR domains present in the non-catalytic C-terminal half of the KDM4A, 4B and 4C enzymes play important roles in regulating their chromatin localizations and substrate specificities. They achieve this regulatory role by binding to different tri-methylated lysine residues on histone H3 (H3-K4me3, H3-K23me3) and histone H4 (H4-K20me3) depending upon the specific chromatin environment. In this work, we have used a 2D-NMR based fragment screening approach to identify a novel fragment (1a), which binds to the KDM4A-TUDOR domain and shows modest competition with H3-K4me3 binding in biochemical as well as in vitro cell based assays. A co-crystal structure of KDM4A TUDOR domain in complex with 1a shows that the fragment binds stereo-specifically to the methyl lysine binding pocket forming a network of strong hydrogen bonds and hydrophobic interactions. We anticipate that the fragment 1a can be further developed into a novel allosteric inhibitor of the KDM4 family of enzymes through targeting their C-terminal tandem TUDOR domain.

Published

2018

107. PHD finger protein 1 (PHF1) is a novel reader for histone H4R3 symmetric dimethylation and coordinates with PRMT5–WDR77/CRL4B complex to promote tumorigenesis

Author

Yan Wang, Rongfang Qiu, Shuang Wang, Dandan Feng, Yang Yang, Wenqian Yu, Yongqiang Hou, Wei Huang, Xu Teng, Yu Zheng, Gancheng Sun, Shuai Leng, Yi Zeng, Ruiqiong Liu, Jie Gao, and Hang Shi

Subjects

0301 basic medicine, Protein-Arginine N-Methyltransferases, F-Box-WD Repeat-Containing Protein 7, Tudor domain, Transcription, Genetic, Carcinogenesis, Polycomb-Group Proteins, Breast Neoplasms, Methylation, DNA-binding protein, Cell Line, Histones, Mice, 03 medical and health sciences, Histone arginine methylation, Biomarkers, Tumor, Genetics, Polycomb-group proteins, Animals, Humans, Neoplasm Metastasis, Cell Proliferation, biology, Carcinoma, Gene regulation, Chromatin and Epigenetics, Cadherins, Cullin Proteins, Ubiquitin ligase, Chromatin, Cell biology, DNA-Binding Proteins, HEK293 Cells, 030104 developmental biology, Histone, PHD finger, biology.protein, Female, Transcription Factors

Abstract

Histone post–translational modifications regulate chromatin structure and function largely through interactions with effector proteins that often contain multiple histone-binding domains. PHF1 [plant homeodomain (PHD) finger protein 1], which contains two kinds of histone reader modules, a Tudor domain and two PHD fingers, is an essential factor for epigenetic regulation and genome maintenance. While significant progress has been made in characterizing the function of the Tudor domain, the roles of the two PHD fingers are poorly defined. Here, we demonstrated that the N-terminal PHD finger of PHF1 recognizes symmetric dimethylation of H4R3 (H4R3me2s) catalyzed by PRMT5–WDR77. However, the C-terminal PHD finger of PHF1, instead of binding to modified histones, directly interacts with DDB1, the main component of the CUL4B-Ring E3 ligase complex (CRL4B), which is responsible for H2AK119 mono-ubiquitination (H2AK119ub1). We showed that PHF1, PRMT5–WDR77, and CRL4B reciprocally interact with one another and collaborate as a functional unit. Genome-wide analysis of PHF1/PRMT5/CUL4B targets identified a cohort of genes including E-cadherin and FBXW7, which are critically involved in cell growth and migration. We demonstrated that PHF1 promotes cell proliferation, invasion, and tumorigenesis in vivo and in vitro and found that its expression is markedly upregulated in a variety of human cancers. Our data identified a new reader for H4R3me2s and provided a molecular basis for the functional interplay between histone arginine methylation and ubiquitination. The results also indicated that PHF1 is a key factor in cancer progression, supporting the pursuit of PHF1 as a target for cancer therapy.

Published

2018

108. Structural basis for recognition of 53BP1 tandem Tudor domain by TIRR

Author

Aili Zhang, Zheng Zhou, Yaxin Dai, Shan Shan, and Zihua Gong

Subjects

0301 basic medicine, Tudor domain, DNA Repair, Science, Double-Strand DNA Breaks, Regulator, General Physics and Astronomy, RNA-binding protein, Crystallography, X-Ray, Article, General Biochemistry, Genetics and Molecular Biology, Mice, 03 medical and health sciences, 0302 clinical medicine, Protein structure, Cell Line, Tumor, Animals, Humans, DNA Breaks, Double-Stranded, lcsh:Science, Binding Sites, Multidisciplinary, Tudor Domain, biology, Chemistry, HEK 293 cells, RNA-Binding Proteins, General Chemistry, Protein Structure, Tertiary, Cell biology, HEK293 Cells, 030104 developmental biology, Histone, 030220 oncology & carcinogenesis, Dna breaks, biology.protein, lcsh:Q, Carrier Proteins, Tumor Suppressor p53-Binding Protein 1, Protein Binding

Abstract

P53-binding protein 1 (53BP1) regulates the double-strand break (DSB) repair pathway choice. A recently identified 53BP1-binding protein Tudor-interacting repair regulator (TIRR) modulates the access of 53BP1 to DSBs by masking the H4K20me2 binding surface on 53BP1, but the underlying mechanism remains unclear. Here we report the 1.76-Å crystal structure of TIRR in complex with 53BP1 tandem Tudor domain. We demonstrate that the N-terminal region (residues 10–24) and the L8-loop of TIRR interact with 53BP1 Tudor through three loops (L1, L3, and L1′). TIRR recognition blocks H4K20me2 binding to 53BP1 Tudor and modulates 53BP1 functions in vivo. Structure comparisons identify a TIRR histidine (H106) that is absent from the TIRR homolog Nudt16, but essential for 53BP1 Tudor binding. Remarkably, mutations mimicking TIRR binding modules restore the disrupted binding of Nudt16-53BP1 Tudor. Our studies elucidate the mechanism by which TIRR recognizes 53BP1 Tudor and functions as a cellular inhibitor of the histone methyl-lysine readers., The p53-binding protein 1 (53BP1) regulates the choice of the DNA double-strand break repair pathway. Here the authors present the crystal structure of Tudor-interacting repair regulator (TIRR) bound to the 53BP1 tandem Tudor domain, which reveals how TIRR blocks H4K20me2 binding to 53BP1 Tudor and functionally differs from its paralog Nudt16.

Published

2018

109. Structural plasticity of the TDRD3 Tudor domain probed by a fragment screening hit

Author

Ke Ruan, Yang Yang, Rongsheng Ma, Gilbert Nshogoza, Yaqian Liu, Jiuyang Liu, Jiahai Zhang, Shuya Zhang, Fudong Li, Mingqing Liu, Jihui Wu, and Jia Gao

Subjects

Transcriptional Activation, 0301 basic medicine, Tudor domain, Protein Conformation, Protein Data Bank (RCSB PDB), Piwi-interacting RNA, RNA polymerase II, Crystallography, X-Ray, 010402 general chemistry, 01 natural sciences, Biochemistry, Small Molecule Libraries, 03 medical and health sciences, Stress granule, Humans, Amino Acid Sequence, Nuclear Magnetic Resonance, Biomolecular, Molecular Biology, Cell Proliferation, Tudor Domain, biology, Chemistry, Nuclear Proteins, Proteins, Hydrogen Bonding, Isothermal titration calorimetry, Cell Biology, Endonucleases, Small molecule, 0104 chemical sciences, Cell biology, 030104 developmental biology, Cytoplasm, biology.protein, Tumor Suppressor p53-Binding Protein 1

Abstract

As a reader of di-methylated arginine on various proteins, such as histone, RNA polymerase II, PIWI and Fragile X mental retardation protein, the Tudor domain of Tudor domain-containing protein 3 (TDRD3) mediates transcriptional activation in nucleus and formation of stress granules in the cytoplasm. Despite the TDRD3 implication in cancer cell proliferation and invasion, warheads to block the di-methylated arginine recognition pocket of the TDRD3 Tudor domain have not yet been uncovered. Here we identified 14 small molecule hits against the TDRD3 Tudor domain through NMR fragment-based screening. These hits were further cross-validated by using competitive fluorescence polarization and isothermal titration calorimetry experiments. The crystal structure of the TDRD3 Tudor domain in complex with hit 1 reveals a distinct binding mode from the nature substrate. Hit 1 protrudes into the aromatic cage of the TDRD3 Tudor domain, where the aromatic residues are tilted to accommodate a sandwich-like π-π interaction. The side chain of the conserved residue N596 swings away 3.1 A to form a direct hydrogen bond with hit 1. Moreover, this compound shows a decreased affinity against the single Tudor domain of survival motor neuron protein, but no detectable binding to neither the tandem Tudor domain of TP53-binding protein 1 nor the extended Tudor domain of staphylococcal nuclease domain-containing protein 1. Our work depicts the structural plasticity of the TDRD3 Tudor domain and paves the way for the subsequent structure-guided discovery of selective inhibitors targeting Tudor domains. Database Structural data are available in the PDB under the accession number 5YJ8.

Published

2018

110. Tudor staphylococcal nuclease is a structure-specific ribonuclease that degrades RNA at unstructured regions during microRNA decay

Author

Chia-Lung Li, Zhonghao Shi, Hanna S. Yuan, and Wei-Zen Yang

Subjects

0301 basic medicine, Tudor domain, Base pair, RNA Stability, Article, 03 medical and health sciences, Ribonucleases, 0302 clinical medicine, Catalytic Domain, microRNA, Ribonuclease, Caenorhabditis elegans Proteins, Molecular Biology, RNA, Double-Stranded, biology, RNA, Inosine, Cell biology, MicroRNAs, RNA silencing, 030104 developmental biology, RNA editing, 030220 oncology & carcinogenesis, Phosphodiester bond, biology.protein, Calcium

Abstract

Tudor staphylococcal nuclease (TSN) is an evolutionarily conserved ribonuclease in eukaryotes that is composed of five staphylococcal nuclease-like domains (SN1–SN5) and a Tudor domain. TSN degrades hyper-edited double-stranded RNA, including primary miRNA precursors containing multiple I•U and U•I pairs, and mature miRNA during miRNA decay. However, how TSN binds and degrades its RNA substrates remains unclear. Here, we show that the C. elegans TSN (cTSN) is a monomeric Ca2+-dependent ribonuclease, cleaving RNA chains at the 5′-side of the phosphodiester linkage to produce degraded fragments with 5′-hydroxyl and 3′-phosphate ends. cTSN degrades single-stranded RNA and double-stranded RNA containing mismatched base pairs, but is not restricted to those containing multiple I•U and U•I pairs. cTSN has at least two catalytic active sites located in the SN1 and SN3 domains, since mutations of the putative Ca2+-binding residues in these two domains strongly impaired its ribonuclease activity. We further show by small-angle X-ray scattering that rice osTSN has a flexible two-lobed structure with open to closed conformations, indicating that TSN may change its conformation upon RNA binding. We conclude that TSN is a structure-specific ribonuclease targeting not only single-stranded RNA, but also unstructured regions of double-stranded RNA. This study provides the molecular basis for how TSN cooperates with RNA editing to eliminate duplex RNA in cell defense, and how TSN selects and degrades RNA during microRNA decay.

Published

2018

111. Novel Insights into Peptide Binding and Conformational Dynamics of UHRF1

Author

Albert Jeltsch

Subjects

chemistry.chemical_classification, 0303 health sciences, DNA ligase, Binding Sites, Tudor domain, Tudor Domain, Tandem, Chemistry, Stereochemistry, 030302 biochemistry & molecular biology, Peptide, Peptide binding, Crystal structure, DNA Methylation, Histones, 03 medical and health sciences, Structural Biology, CCAAT-Enhancer-Binding Proteins, Phosphorylation, Molecular Biology, Protein Binding, 030304 developmental biology

Abstract

In this issue of Structure, Kori et al. (2019) report the crystal structure of a lysine-methylated non-histone peptide from DNA ligase 1 (LIG1K126me3) bound to the UHRF1 tandem Tudor domain (TTD). LIG1K126me3-TTD exhibits strong interactions involving peptide residues K120 to K126me3, regulated by phosphorylation, which affects the conformation of UHRF1.

Published

2019

112. Conformational Selection of Dimethylarginine Recognition by the Survival Motor Neuron Tudor Domain

Author

Gerd Gemmecker, Anna C. Papageorgiou, Konstantinos Tripsianes, Ville R. I. Kaila, Michael Sattler, Raphael Mathias Peltzer, Mikael P. Johansson, and Shreyas Supekar

Subjects

0301 basic medicine, Tudor domain, Stereochemistry, Protein Conformation, medicine.disease_cause, Arginine, 010402 general chemistry, 01 natural sciences, Catalysis, QM/MM, 03 medical and health sciences, medicine, Selection (genetic algorithm), 030304 developmental biology, Regulation of gene expression, Motor Neurons, Mutation, 0303 health sciences, Tudor Domain, Chemistry, General Chemistry, Nuclear magnetic resonance spectroscopy, General Medicine, Motor neuron, Ligand (biochemistry), 3. Good health, 0104 chemical sciences, 030104 developmental biology, medicine.anatomical_structure, Quantum Theory, Thermodynamics, Protein Processing, Post-Translational

Abstract

Tudor domains bind to dimethylarginine (DMA) residues, which are post-translational modifications that play a central role in gene regulation in eukaryotic cells. NMR spectroscopy and quantum calculations are combined to demonstrate that DMA recognition by Tudor domains involves conformational selection. The binding mechanism is confirmed by a mutation in the aromatic cage that perturbs the native recognition mode of the ligand. General mechanistic principles are delineated from the combined results, indicating that Tudor domains utilize cation-p interactions to achieve ligand recognition.

Published

2017

113. H3K14ac is linked to methylation of H3K9 by the triple Tudor domain of SETDB1

Author

Jurkowska, Renata Z., Qin, Su, Kungulovski, Goran, Tempel, Wolfram, Liu, Yanli, Bashtrykov, Pavel, Stiefelmaier, Judith, Jurkowski, Tomasz P., Kudithipudi, Srikanth, Weirich, Sara, Tamas, Raluca, Wu, Hong, Dombrovski, Ludmila, Loppnau, Peter, Reinhardt, Richard, Min, Jinrong, and Jeltsch, Albert

Subjects

Binding Sites, Tudor Domain, Science, Acetylation, Mouse Embryonic Stem Cells, Histone-Lysine N-Methyltransferase, Crystallography, X-Ray, Methylation, Article, Recombinant Proteins, Histones, Mice, HEK293 Cells, Long Interspersed Nucleotide Elements, Animals, Humans, lcsh:Q, Protein Methyltransferases, lcsh:Science, Protein Processing, Post-Translational, Protein Binding

Abstract

SETDB1 is an essential H3K9 methyltransferase involved in silencing of retroviruses and gene regulation. We show here that its triple Tudor domain (3TD) specifically binds to doubly modified histone H3 containing K14 acetylation and K9 methylation. Crystal structures of 3TD in complex with H3K14ac/K9me peptides reveal that peptide binding and K14ac recognition occurs at the interface between Tudor domains (TD) TD2 and TD3. Structural and biochemical data demonstrate a pocket switch mechanism in histone code reading, because K9me1 or K9me2 is preferentially recognized by the aromatic cage of TD3, while K9me3 selectively binds to TD2. Mutations in the K14ac/K9me binding sites change the sub-nuclear localization of 3TD. ChIP-seq analyses show that SETDB1 is enriched at H3K9me3 regions and K9me3/K14ac is enriched at SETDB1 binding sites overlapping with LINE elements, suggesting that recruitment of the SETDB1 complex to K14ac/K9me regions has a role in silencing of active genomic regions., SETDB1 is a histone methyltransferase that generates H3K9me3 marks in euchromatic regions. Here the authors show that the triple Tudor domain (3TD) of SETDB1 binds histone H3 tails containing K14 acetylation combined with K9 methylation, and that the K9me–K14ac modification defines a novel chromatin state enriched at SETDB1 binding sites.

Published

2017

114. Inherent backbone dynamics fine-tune the functional plasticity of Tudor domains

Author

Björn M. Burmann and Ashish A. Kawale

Subjects

Models, Molecular, 0303 health sciences, Tudor domain, Tudor Domain, Protein Conformation, Chemistry, Escherichia coli Proteins, Protein dynamics, 030302 biochemistry & molecular biology, Dynamics (mechanics), DNA Helicases, Computational biology, Peptide Elongation Factors, 03 medical and health sciences, Bacterial Proteins, Structural Biology, Bacterial transcription, Structural plasticity, Escherichia coli, Trans-Activators, Molecular Biology, Transcription Factors, 030304 developmental biology

Abstract

Tudor domains are crucial for mediating a diversity of protein-protein or protein-DNA interactions involved in nucleic acid metabolism. Using solution NMR spectroscopy, we assess the comprehensive understanding of the dynamical properties of the respective Tudor domains from four different bacterial (Escherichia coli) proteins UvrD, Mfd, RfaH, and NusG involved in different aspects of bacterial transcription regulation and associated processes. These proteins are benchmarked to the canonical Tudor domain fold from the human SMN protein. The detailed analysis of protein backbone dynamics and subsequent analysis by the Lipari-Szabo model-free approach revealed subtle differences in motions of the amide-bond vector on both pico- to nanosecond and micro- to millisecond timescales. On these timescales, our comparative approach reveals the usefulness of discrete amplitudes of dynamics to discern the different functionalities for Tudor domains exhibiting promiscuous binding, including the metamorphic Tudor domain included in the study.

Published

2021

115. Tudor: a versatile family of histone methylation ‘readers’.

Author

Lu, Rui and Wang, Gang Greg

Subjects

*HISTONES, *METHYLATION, *CHEMICAL templates, *LIGANDS (Biochemistry), *DNA, *AROMATIC compounds

Abstract

Highlights: [•] Evidence reveals the versatility of Tudor in reading various histone methylation. [•] Tudor domain uses an aromatic cage to accommodate its histone methylation ligand. [•] Tudor and adjacent modules can combinatorially read multiple histone modifications. [•] Tudor–histone interaction is critical for regulating various DNA-templated processes. [Copyright &y& Elsevier]

Published

2013

116. IDENTIFICATION OF TUDOR DOMAIN CONTAINING 7 PROTEIN AS A NOVEL PARTNER AND A SUBSTRATE FOR RIBOSOMAL PROTEIN S6 KINASES -- S6K1 AND S6K2.

Author

SKOROKHOD, Oleksandr, PANASYUK, Ganna, NEMAZANYY, Ivan, GOUT, Ivan, and FILONENKO, Valeriy

Subjects

*RIBOSOMAL proteins, *CELL size, *ANTISENSE DNA, *MITOGEN-activated protein kinases, *TRANSPOSONS, *IMMUNOPRECIPITATION

Abstract

Ribosomal protein S6 kinases (S6Ks) are principal regulators of cell size, growth and metabolism. Signaling via the PI3K/mTOR pathway mediates the activation of S6Ks in response to various mitogenic stimuli, nutrients and stresses. To date, the regulation and cellular functions of S6Ks are not fully understood. Our aim was to investigate and characterize the interaction of S6Ks with the novel binding partner of S6Ks, Tudor domain containing 7 protein (TDRD7), which is a scaffold protein detected in complexes involved in the regulation of cytoskeleton dynamics, mRNa transport and translation, non-coding piRNas processing and transposons silencing. This interaction was initially detected in the yeast two-hybrid screening of HeLa cDNa library and further confirmed by pull-down and co-immunoprecipitation assays. In addition we demonstrated that TDRD7 can form a complex with other isoform of S6K - S6K2. Notably, both isoforms of S6K were found to phosphorylate TDRD7 in vitro at multiple phosphorylation sites. altogether, these findings demonstrate that TDRD7 is a novel substrate of S6Ks, suggesting the involvement of S6K signaling in the regulation of TDRD7 cellular functions. [ABSTRACT FROM AUTHOR]

Published

2013

117. Organization of Plasmodium falciparum spliceosomal core complex and role of arginine methylation in its assembly.

Author

Hossain, Manzar, Sharma, Shweta, Korde, Reshma, Kanodia, Shivani, Chugh, Monika, Rawat, Khushboo, and Malhotra, Pawan

Subjects

*PLASMODIUM falciparum, *PROTEIN arginine methyltransferases, *METHYLATION, *ERYTHROCYTES, *NUCLEASES

Abstract

Background: Splicing and alternate splicing are the two key biological processes that result in the generation of diverse transcript and protein isoforms in Plasmodium falciparum as well as in other eukaryotic organisms. Not much is known about the organization of splicing machinery and mechanisms in human malaria parasite. Present study reports the organization and assembly of Plasmodium spliceosome Sm core complex. Methods: Presence of all the seven Plasmodium Sm-like proteins in the intra-erythrocytic stages was assessed based on the protein(s) expression analysis using immuno-localization and western blotting. Localization/co-localization studies were performed by immunofluorescence analysis on thin parasite smear using laser scanning confocal microscope. Interaction studies were carried out using yeast two-hybrid analysis and validated by in vitro pull-down assays. PfPRMT5 (arginine methyl transferase) and PfSmD1 interaction analysis was performed by pull-down assays and the interacting proteins were identified by MALDI-TOF spectrometry. Results: PfSm proteins are expressed at asexual blood stages of the parasite and show nucleo-cytoplasmic localization. Protein-protein interaction studies showed that PfSm proteins form a heptameric complex, typical of spliceosome core complex as shown in humans. Interaction of PfSMN (survival of motor neuron, tudor domain containing protein) or PfTu-TSN (Tudor domain of Tudor Staphylococcal nuclease) with PfSmD1 proteins was found to be methylation dependent. Co-localization by immunofluorescence and co-immunoprecipitation studies suggested an association between PfPRMT5 and PfSmD1, indicating the role of arginine methylation in assembly of Plasmodium spliceosome complex. Conclusions: Plasmodium Sm-like proteins form a heptameric ring-like structure, although the arrangement of PfSm proteins slightly differs from human splicing machinery. The data shows the interaction of PfSMN with PfSmD1 and this interaction is found to be methylation dependent. PfPRMT5 probably exists as a part of methylosome complex that may function in the cytoplasmic assembly of Sm proteins at asexual blood stages of P. falciparum. [ABSTRACT FROM AUTHOR]

Published

2013

118. H, N and C resonance assignments for the three LOTUS RNA binding domains of Tudor domain-containing protein TDRD7.

Author

Cui, Gaofeng, Botuyan, Maria, and Mer, Georges

Abstract

The LOTUS or OST-HTH domain is a recently discovered motif of about 80 amino acids and is found in several germline-specific proteins including the Tudor domain-containing proteins TDRD5 and TDRD7, which are important for germ cell development. The LOTUS domain is an RNA binding domain but its exact function is unknown. Here, we report the H, C and N resonance assignments for the three LOTUS domains present in mouse TDRD7. These assignments will allow three-dimensional structure determination of the LOTUS domains and mapping of their interaction with RNA, steps toward deciphering the function of TDRD7. [ABSTRACT FROM AUTHOR]

Published

2013

119. The Caenorhabditis elegans TDRD5/7-like protein, LOTR-1, interacts with the helicase ZNFX-1 to balance epigenetic signals in the germline.

Author

Marnik EA, Almeida MV, Cipriani PG, Chung G, Caspani E, Karaulanov E, Gan HH, Zinno J, Isolehto IJ, Kielisch F, Butter F, Sharp CS, Flanagan RM, Bonnet FX, Piano F, Ketting RF, Gunsalus KC, and Updike DL

Subjects

Animals, Caenorhabditis elegans Proteins, RNA Helicases, RNA, Small Interfering genetics, RNA, Small Interfering metabolism, Tudor Domain, Caenorhabditis elegans genetics, Caenorhabditis elegans metabolism, Epigenesis, Genetic, Germ Cells metabolism

Abstract

LOTUS and Tudor domain containing proteins have critical roles in the germline. Proteins that contain these domains, such as Tejas/Tapas in Drosophila, help localize the Vasa helicase to the germ granules and facilitate piRNA-mediated transposon silencing. The homologous proteins in mammals, TDRD5 and TDRD7, are required during spermiogenesis. Until now, proteins containing both LOTUS and Tudor domains in Caenorhabditis elegans have remained elusive. Here we describe LOTR-1 (D1081.7), which derives its name from its LOTUS and Tudor domains. Interestingly, LOTR-1 docks next to P granules to colocalize with the broadly conserved Z-granule helicase, ZNFX-1. The Tudor domain of LOTR-1 is required for its Z-granule retention. Like znfx-1 mutants, lotr-1 mutants lose small RNAs from the 3' ends of WAGO and mutator targets, reminiscent of the loss of piRNAs from the 3' ends of piRNA precursor transcripts in mouse Tdrd5 mutants. Our work shows that LOTR-1 acts with ZNFX-1 to bring small RNA amplifying mechanisms towards the 3' ends of its RNA templates., Competing Interests: The authors have declared that no competing interests exist.

Published

2022

120. Xtr, a plural tudor domain-containing protein, is involved in the translational regulation of maternal m RNA during oocyte maturation in Xenopus laevis.

Author

Ohgami, Hiroki, Hiyoshi, Masateru, Mostafa, Md. Golam, Kubo, Hideo, Abe, Shin-Ichi, and Takamune, Kazufumi

Subjects

*GENETIC translation, *GENETIC regulation, *MESSENGER RNA, *OVUM, *DEVELOPMENTAL biology, *XENOPUS laevis

Abstract

Xtr in the fertilized eggs of Xenopus has been demonstrated to be a member of a messenger ribonucleoprotein (m RNP) complex that plays a crucial role in karyokinesis during cleavage. Since the Xtr is also present both in oocytes and spermatocytes and its amount increases immediately after spematogenic cells enter into the meiotic phase, this protein was also predicted to act during meiotic progression. Taking advantage of Xenopus oocytes' large size to microinject anti- Xtr antibody into them for inhibition of Xtr function, we examined the role of Xtr in meiotic progression of oocytes. Microinjection of anti- Xtr antibody into immature oocytes followed by reinitiation of oocyte maturation did not affect germinal vesicle break down and the oscillation of Cdc2/cyclin B activity during meiotic progression but caused abnormal spindle formation and chromosomal alignment at meiotic metaphase I and II. Immunoprecipitation of Xtr showed the association of Xtr with FRGY2 and m RNAs such as RCC1 and XL- INCENP m RNAs, which are involved in the progression of karyokinesis. When anti-Xtr antibody was injected into oocytes, translation of XL- INCENP m RNA, which is known to be repressed in immature oocytes and induced after reinitiation of oocyte maturation, was inhibited even if the oocytes were treated with progesterone. A similar translational regulation was observed in oocytes injected with a reporter m RNA, which was composed of an enhanced green fluorescent protein open reading frame followed by the 3′ untranslational region (3′ UTR) of XL- INCENP m RNA. These results indicate that Xtr regulates the translation of XL- INCENP m RNA through its 3′ UTR during meiotic progression of oocyte. [ABSTRACT FROM AUTHOR]

Published

2012

121. Tudor domain proteins in development.

Author

Jun Wei Pek, Anand, Amit, and Toshie Kai

Subjects

*PROTEINS, *DEVELOPMENTAL biology, *METHYLATION, *ARGININE, *LYSINE, *MACROMOLECULES, *RNA, *DNA damage

Abstract

Tudor domain proteins function as molecular adaptors, binding methylated arginine or lysine residues on their substrates to promote physical interactions and the assembly of macromolecular complexes. Here, we discuss the emerging roles of Tudor domain proteins during development, most notably in the Piwi-interacting RNA pathway, but also in other aspects of RNA metabolism, the DNA damage response and chromatin modification. INSETS: Box 1. Timeline of the major discoveries on Tudor domains;Box 2. Processing bodies and stress granules;Box 3. Chromatin modification. [ABSTRACT FROM AUTHOR]

Published

2012

122. Spinal muscular atrophy pathogenic mutations impair the axonogenic properties of axonal-survival of motor neuron.

Author

Locatelli, Denise, d'Errico, Paolo, Capra, Silvia, Finardi, Adele, Colciaghi, Francesca, Setola, Veronica, Terao, Mineko, Garattini, Enrico, and Battaglia, Giorgio

Subjects

*SPINAL muscular atrophy, *MOTOR neurons, *NEUROBLASTOMA, *CELL lines, *AXONS

Abstract

J. Neurochem. (2012) 121, 465-474. Abstract The axonal survival of motor neuron (a-SMN) protein is a truncated isoform of SMN1, the spinal muscular atrophy (SMA) disease gene. a-SMN is selectively localized in axons and endowed with remarkable axonogenic properties. At present, the role of a-SMN in SMA is unknown. As a first step to verify a link between a-SMN and SMA, we investigated by means of over-expression experiments in neuroblastoma-spinal cord hybrid cell line (NSC34) whether SMA pathogenic mutations located in the N-terminal part of the protein affected a-SMN function. We demonstrated here that either SMN1 missense mutations or small intragenic re-arrangements located in the Tudor domain consistently altered the a-SMN capability of inducing axonal elongation in vitro. Mutated human a-SMN proteins determined in almost all NSC34 motor neurons the growth of short axons with prominent morphologic abnormalities. Our data indicate that the Tudor domain is critical in dictating a-SMN function possibly because it is an association domain for proteins involved in axon growth. They also indicate that Tudor domain mutations are functionally relevant not only for FL-SMN but also for a-SMN, raising the possibility that also a-SMN loss of function may contribute to the pathogenic steps leading to SMA. [ABSTRACT FROM AUTHOR]

Published

2012

123. Crystal structures of the Tudor domains of human PHF20 reveal novel structural variations on the Royal Family of proteins

Author

Adams-Cioaba, Melanie A., Li, Zhihong, Tempel, Wolfram, Guo, Yahong, Bian, Chuanbing, Li, Yanjun, Lam, Robert, and Min, Jinrong

Subjects

*CRYSTAL structure, *ZINC-finger proteins, *PROTEIN structure, *TRANSCRIPTION factors, *IMMUNOGLOBULINS, *LIVER cancer, *METHYLTRANSFERASES, *HISTONES

Abstract

Abstract: The human PHD finger protein 20 (PHF20) is a putative transcription factor. While little is known about its cognate cellular role, antibodies against PHF20 are present in sera from patients with hepatocellular carcinoma, glioblastoma and childhood medulloblastula. PHF20 comprises two N-terminal Tudor domains, a central C2H2-link zinc finger domain and a C-terminal zinc-binding PHD domain, and is a component of some MLL methyltransferase complexes. Here, we report the crystal structures of the N-terminal Tudor domains of PHF20 and highlight the novel structural features of each domain. We also confirm previous studies suggesting that the second Tudor domain of PHF20 exhibits preference for dimethylated histone substrates. [Copyright &y& Elsevier]

Published

2012

124. Histone arginine methylation

Author

Di Lorenzo, Alessandra and Bedford, Mark T.

Subjects

*ARGININE, *METHYLATION, *HISTONES, *POST-translational modification, *CYTOPLASM, *PROTEINS, *METHYLTRANSFERASES, *MOLECULES

Abstract

Abstract: Arginine methylation is a common posttranslational modification (PTM). This type of PTM occurs on both nuclear and cytoplasmic proteins, and is particularly abundant on shuttling proteins. In this review, we will focus on one aspect of this PTM: the diverse roles that arginine methylation of the core histone tails play in regulating chromatin function. A family of nine protein arginine methyltransferases (PRMTs) catalyze methylation reactions, and a subset target histones. Importantly, arginine methylation of histone tails can promote or prevent the docking of key transcriptional effector molecules, thus playing a central role in the orchestration of the histone code. [Copyright &y& Elsevier]

Published

2011

125. Novel role of specific Tudor domains in Tudor–Aubergine protein complex assembly and distribution during Drosophila oogenesis

Author

Michael Creed, T., Loganathan, Sudan N., Varonin, Dan, Jackson, Christina A., and Arkov, Alexey L.

Subjects

*DROSOPHILA, *INSECT reproduction, *OOGENESIS, *GERM cells, *RIBOSOMES, *ANIMAL species, *PROTEIN structure

Abstract

Abstract: Germ cells give rise to the next generation and contain ribonucleoprotein particles, germ granules. In these granules, Piwi protein Aubergine has been shown to interact with Tudor protein in Drosophila. Tudor protein has 11 Tudor domains and it has been unclear to what extent all these domains are involved in the interaction with Aubergine. Here we present direct biochemical evidence that Tudor–Aubergine interaction surface is composed of different Tudor domains including those that have not been previously implicated in Aubergine recognition. Furthermore, we show that specific single Tudor domains determine localization of Tudor complex to different sites in ovarian germ cells. Our data suggest that multiple Tudor domains of germline proteins from various species are redundantly used for interaction with the same protein partner during germline development. [Copyright &y& Elsevier]

Published

2010

126. Structural basis for the regulation of NtcA-dependent transcription by proteins PipX and PII.

Author

Llácer, José L., Espinosa, Javier, Castells, Miguel A., Contreras, Asunción, Forchhammer, Karl, and Rubio, Vicente

Subjects

*PROTEINS, *NUCLEIC acids, *RNA polymerases, *CYANOBACTERIA, *MUTAGENESIS, *GENETIC transcription

Abstract

PII, an ancient and widespread signaling protein, transduces nitrogen/carbon/energy abundance signals through interactions with target proteins. We clarify structurally how PII regulates gene expression mediated by the transcription factor NtcA, the global nitrogen regulator of cyanobacteria, shedding light on NtcA structure and function and on how NtcA is activated by 2-oxoglutarate (2OG) and coactivated by the nonenzymatic PII target, protein PipX. We determine for the cyanobacteria Synechococcus elongatus the crystal structures of the PII-PipX and PipX-NtcA complexes and of NtcA in active and inactive conformations (respective resolutions, 3.2, 2.25, 2.3, and 3.05 Å). The structures and the conclusions derived from them are consistent with the results of present and prior site-directed mutagenesis and functional studies. A tudor-like domain (TLD) makes up most of the PipX structure and mediates virtually all the contacts of PipX with PII and NtcA. In the PII-PipX complex, one PII trimer sequesters the TLDs of three PipX molecules between its body and its extended T loops, preventing PipX activation of NtcA. Changes in T loop conformation triggered by 2OG explain PII-PipX dissociation when 2OG is bound. The structure of active dimeric NtcA closely resembles that of the active cAMP receptor protein (CRP). This strongly suggests that with these proteins DNA binding, transcription activation, and allosteric regulation occur by common mechanisms, although the effectors are different. The PipX-NtcA complex consists of one active NtcA dimer and two PipX monomers. PipX coactivates NtcA by stabilizing its active conformation and by possibly helping recruit RNA polymerase but not by providing extra DNA contacts. [ABSTRACT FROM AUTHOR]

Published

2010

127. Structural Insight into p53 Recognition by the 53BP1 Tandem Tudor Domain

Author

Roy, Siddhartha, Musselman, Catherine A., Kachirskaia, Ioulia, Hayashi, Ryo, Glass, Karen C., Nix, Jay C., Gozani, Or, Appella, Ettore, and Kutateladze, Tatiana G.

Subjects

*P53 protein, *GENETIC transcription regulation, *GENETIC toxicology, *POST-translational modification, *GENETIC mutation, *DNA repair, *DNA damage, *MOLECULAR structure

Abstract

Abstract: The tumor suppressor p53 and the DNA repair factor 53BP1 (p53 binding protein 1) regulate gene transcription and responses to genotoxic stresses. Upon DNA damage, p53 undergoes dimethylation at Lys382 (p53K382me2), and this posttranslational modification is recognized by 53BP1. The molecular mechanism of nonhistone methyl-lysine mark recognition remains unknown. Here we report a 1. 6-Å-resolution crystal structure of the tandem Tudor domain of human 53BP1 bound to a p53K382me2 peptide. In the complex, dimethylated Lys382 is restrained by a set of hydrophobic and cation–π interactions in a cage formed by four aromatic residues and an aspartate of 53BP1. The signature HKKme2 motif of p53, which defines specificity, is identified through a combination of NMR resonance perturbations, mutagenesis, measurements of binding affinities and docking simulations, and analysis of the crystal structures of 53BP1 bound to p53 peptides containing other dimethyl-lysine marks, p53K370me2 (p53 dimethylated at Lys370) and p53K372me2 (p53 dimethylated at Lys372). Binding of the 53BP1 Tudor domain to p53K382me2 may facilitate p53 accumulation at DNA damage sites and promote DNA repair as suggested by chromatin immunoprecipitation and DNA repair assays. Together, our data detail the molecular mechanism of p53–53BP1 association and provide the basis for deciphering the role of this interaction in the regulation of p53 and 53BP1 functions. [Copyright &y& Elsevier]

Published

2010

128. UHRF1 Links the Histone Code and DNA Methylation to Ensure Faithful Epigenetic Memory Inheritance.

Author

Bronner, Christian, Fuhrmann, Guy, Chédin, Frédéric L., Macaluso, Marcella, and Dhe-Paganon, Sirano

Subjects

*EPIGENETICS, *MITOSIS, *HISTONES, *DNA methylation, *PROTEIN analysis

Abstract

Epigenetics is the study of the transmission of cell memory through mitosis or meiosis that is not based on the DNA sequence. At the molecular level the epigenetic memory of a cell is embedded in DNA methylation, histone post-translational modifications, RNA interference and histone isoform variation. There is a tight link between histone post-translational modifications (the histone code) and DNA methylation, as modifications of histones contribute to the establishment of DNA methylation patterns and vice versa. Interestingly, proteins have recently been identified that can simultaneously read both methylated DNA and the histone code. UHRF1 fulfills these requirements by having unique structural domains that allow concurrent recognition of histone modifications and methylated DNA. Herein, we review our current knowledge of UHRF1 and discuss how this protein ensures the link between histone marks and DNA methylation. Understanding the molecular functions of this protein may reveal the physiological relevance of the linkage between these layers of epigenetic marks. [ABSTRACT FROM AUTHOR]

Published

2010

129. DMA-tudor interaction modules control the specificity of in vivo condensates

Author

Andrew E.S. Barentine, Dong-Ryoung Lee, Korinna Straube, Edward M. Courchaine, Karla M. Neugebauer, and Joerg Bewersdorf

Subjects

Tudor domain, Coiled Bodies, Biology, Arginine, Ligands, Methylation, Models, Biological, Article, General Biochemistry, Genetics and Molecular Biology, Mice, 03 medical and health sciences, 0302 clinical medicine, Protein Domains, In vivo, Organelle, Animals, Humans, 030304 developmental biology, Biomolecular Condensates, Cell Nucleus, 0303 health sciences, SMN Complex Proteins, Survival of motor neuron, Compartmentalization (psychology), Ribonucleoproteins, Small Nuclear, Ligand (biochemistry), Drosophila melanogaster, HEK293 Cells, Cajal body, NIH 3T3 Cells, Biophysics, Protein Multimerization, 030217 neurology & neurosurgery, HeLa Cells, Protein Binding, Protein ligand

Abstract

Summary Biomolecular condensation is a widespread mechanism of cellular compartmentalization. Because the "survival of motor neuron protein" (SMN) is implicated in the formation of three different membraneless organelles (MLOs), we hypothesized that SMN promotes condensation. Unexpectedly, we found that SMN's globular tudor domain was sufficient for dimerization-induced condensation in vivo, whereas its two intrinsically disordered regions (IDRs) were not. Binding to dimethylarginine (DMA) modified protein ligands was required for condensate formation by the tudor domains in SMN and at least seven other fly and human proteins. Remarkably, asymmetric versus symmetric DMA determined whether two distinct nuclear MLOs—gems and Cajal bodies—were separate or "docked" to one another. This substructure depended on the presence of either asymmetric or symmetric DMA as visualized with sub-diffraction microscopy. Thus, DMA-tudor interaction modules—combinations of tudor domains bound to their DMA ligand(s)—represent versatile yet specific regulators of MLO assembly, composition, and morphology.

Published

2021

130. TIRR inhibits the 53BP1-p53 complex to alter cell-fate programs

Author

Gaofeng Cui, Veronica Rendo, Huy V. Nguyen, Nishita Parnandi, Dipanjan Chowdhury, Rameen Beroukhim, Pascal Drané, Georges Mer, Matthias Altmeyer, Maria Victoria Botuyan, and Michaela Remisova

Subjects

Tudor domain, DNA Repair, Regulator, Biology, Cell fate determination, Article, Histones, 03 medical and health sciences, chemistry.chemical_compound, Transactivation, 0302 clinical medicine, Cell Line, Tumor, Humans, Cell Lineage, DNA Breaks, Double-Stranded, Molecular Biology, Gene, Transcription factor, 030304 developmental biology, 0303 health sciences, Binding Sites, Tudor Domain, RNA-Binding Proteins, DNA, Cell Biology, Cell biology, chemistry, Tumor Suppressor Protein p53, Carrier Proteins, Tumor Suppressor p53-Binding Protein 1, 030217 neurology & neurosurgery, Function (biology), Protein Binding

Abstract

53BP1 influences genome stability via two independent mechanisms: (1) regulating DNA double-strand break (DSB) repair and (2) enhancing p53 activity. We discovered a protein, Tudor-interacting repair regulator (TIRR), that associates with the 53BP1 Tudor domain and prevents its recruitment to DSBs. Here, we elucidate how TIRR affects 53BP1 function beyond its recruitment to DSBs and biochemically links the two distinct roles of 53BP1. Loss of TIRR causes an aberrant increase in the gene transactivation function of p53, affecting several p53-mediated cell-fate programs. TIRR inhibits the complex formation between the Tudor domain of 53BP1 and a dimethylated form of p53 (K382me2) that is poised for transcriptional activation of its target genes. TIRR mRNA expression levels negatively correlate with the expression of key p53 target genes in breast and prostate cancers. Further, TIRR loss is selectively not tolerated in p53-proficient tumors. Therefore, we establish that TIRR is an important inhibitor of the 53BP1-p53 complex.

Published

2021

131. The nuclear kinesin KIF18B promotes 53BP1-mediated DNA double-strand break repair

Author

Silvia Maretto, Noel F. Lowndes, Janna Luessing, Kiefer O. Ramberg, Maryam Sakhteh, Louise Frizzell, Naoyuki Sarai, Nikolay Tsanov, and Peter B. Crowley

Subjects

0301 basic medicine, Tudor domain, QH301-705.5, Amino Acid Motifs, Kinesins, DSB repair, DDR, Methylation, General Biochemistry, Genetics and Molecular Biology, end joining, Histones, Histone H4, 03 medical and health sciences, 0302 clinical medicine, Cell Line, Tumor, Humans, Tudor, DNA Breaks, Double-Stranded, Amino Acid Sequence, Biology (General), Mitosis, Cell Nucleus, KIF18B, Chemistry, Lysine, 53BP1, Double Strand Break Repair, Chromatin, Cell biology, HEK293 Cells, 030104 developmental biology, Kinesin, Interphase, Tumor Suppressor p53-Binding Protein 1, Astral microtubules, 030217 neurology & neurosurgery, Protein Binding

Abstract

Summary: 53BP1 is recruited to chromatin in the vicinity of DNA double-strand breaks (DSBs). We identify the nuclear kinesin, KIF18B, as a 53BP1-interacting protein and define its role in 53BP1-mediated DSB repair. KIF18B is a molecular motor protein involved in destabilizing astral microtubules during mitosis. It is primarily nuclear throughout the interphase and is constitutively chromatin bound. Our observations indicate a nuclear function during the interphase for a kinesin previously implicated in mitosis. We identify a central motif in KIF18B, which we term the Tudor-interacting motif (TIM), because of its interaction with the Tudor domain of 53BP1. TIM enhances the interaction between the 53BP1 Tudor domain and dimethylated lysine 20 of histone H4. TIM and the motor function of KIF18B are both required for efficient 53BP1 focal recruitment in response to damage and for fusion of dysfunctional telomeres. Our data suggest a role for KIF18B in efficient 53BP1-mediated end-joining of DSBs.

Published

2021

132. Xtr, a plural tudor domain-containing protein, coexists with FRGY2 both in cytoplasmic mRNP particle and germ plasm in Xenopus embryo: Its possible role in translational regulation of maternal mRNAs.

Author

Mostafa, Md. Golam, Sugimoto, Tetsuharu, Hiyoshi, Masateru, Kawasaki, Hiroshi, Kubo, Hideo, Matsumoto, Ken, Abe, Shin-Ichi, and Takamune, Kazufumi

Subjects

*NUCLEOPROTEINS, *PROTEINS, *GERMPLASM, *XENOPUS, *GENETIC translation, *MESSENGER RNA, *KARYOKINESIS

Abstract

Xtr is present exclusively in early embryonic and germline cells. We have previously shown that loss-of-function of the Xtr in embryos causes arrest of karyokinesis progression. Since Xtr contains plural tudor domains, which are known to associate with target proteins directly, we examined Xtr-interacting proteins by immunoprecipitation with an anti-Xtr monoclonal antibody and detected a few RNA-binding proteins such as FRGY2, a component of messenger ribonucleoprotein (mRNP) particle. The coexistence of Xtr with FRGY2 by constituting an mRNP particle was further confirmed by gel filtration assay. Search of mRNAs in the immunoprecipitate with Xtr suggested that the Xtr-associated molecules included several mRNAs, of which translational products were known to play crucial roles in karyokinesis progression (RCC1, XRHAMM, and so on) and in germ cell development (XDead end). Immunohistochemical observation clearly showed the co-localization of Xtr with FRGY2 also in germ plasm, in which XDead end mRNA has been shown to be localized specifically. Taken together, we proposed the possible role of Xtr in translational activation of the maternal mRNAs repressed in mRNP particle. [ABSTRACT FROM AUTHOR]

Published

2009

133. Structure and function of histone methylation binding proteins.

Author

Adams-Cioaba, Melanie A. and Min, Jinrong

Subjects

*CHROMATIN, *PROTEINS, *HISTONES, *DNA replication, *RNA

Abstract

Chromatin structure is regulated by chromatin remodeling factors, histone exchange, linker histone association, and histone modification. Covalent modification of histones is an important factor in the regulation of the associated processes. The implementation and removal of various histone modifications have been implicated in DNA replication, repair, recombination, and transcription, and in RNA processing. In recent years, histone methylation has emerged as one of the key modifications regulating chromatin function. However, the mechanisms involved are complex and not well understood. A large volume of structural and biochemical information has been recently amassed for the Tudor, plant homeodomain (PHD), and malignant brain tumor (MBT) protein families. This review summarizes current knowledge of the structures and modes of recognition employed by the PHD, Tudor, and MBT domains in their interactions with target histone peptides. La structure de la chromatine est réglée par les facteurs de remodelage de la chromatine, l’échange d’histones, l’association d’histones internucléosomales et la modification d’histones. Les modifications covalentes des histones constituent un facteur important de régulation des processus associés. L’exécution et le retrait de différentes modifications d’histones ont été impliqués dans la réplication, la réparation, la recombinaison et la transcription d’ADN ainsi que dans la maturation de l’ARN. Au cours des dernières années, il est apparu que la méthylation des histones était l’une des modifications clés réglant la fonction de la chromatine. Cependant, les mécanismes impliqués sont complexes et mal compris. Une grande quantité d’informations structurales et biochimiques ont récemment été recueillies sur les protéines des familles Tudor, PGD et MBT. Cette revue de la littérature résume les connaissances actuelles des structures et des modes de reconnaissance utilisés par les domaines PHD, Tudor et MBT dans leurs interactions avec les peptides d’histones cibles. [ABSTRACT FROM AUTHOR]

Published

2009

134. Structure-based screening combined with computational and biochemical analyses identified the inhibitor targeting the binding of DNA Ligase 1 to UHRF1.

Author

Kori, Satomi, Shibahashi, Yuki, Ekimoto, Toru, Nishiyama, Atsuya, Yoshimi, Sae, Yamaguchi, Kosuke, Nagatoishi, Satoru, Ohta, Masateru, Tsumoto, Kouhei, Nakanishi, Makoto, Defossez, Pierre-Antoine, Ikeguchi, Mitsunori, and Arita, Kyohei

Subjects

*DNA methyltransferases, *DNA, *XENOPUS eggs, *DNA methylation, *MOLECULAR dynamics, *SMALL molecules, *TUMOR suppressor genes, *CANCER cells

Abstract

[Display omitted] • Discovery of the small molecule targeting UHRF1 is a potential for anti-cancer drug. • MD simulation effectively discovered the compounds capable of binding to UHRF1. • 5-amino-2,4-dimethylpyridine stably bound to the Arg-binding cavity of UHRF1. • The compound inhibited UHRF1:LIG1 interaction in Xenopus egg extracts. The accumulation of epigenetic alterations is one of the major causes of tumorigenesis. Aberrant DNA methylation patterns cause genome instability and silencing of tumor suppressor genes in various types of tumors. Therefore, drugs that target DNA methylation-regulating factors have great potential for cancer therapy. Ubiquitin-like containing PHD and RING finger domain 1 (UHRF1) is an essential factor for DNA methylation maintenance. UHRF1 is overexpressed in various cancer cells and down-regulation of UHRF1 in these cells reactivates the expression of tumor suppressor genes, thus UHRF1 is a promising target for cancer therapy. We have previously shown that interaction between the tandem Tudor domain (TTD) of UHRF1 and DNA ligase 1 (LIG1) di/trimethylated on Lys126 plays a key role in the recruitment of UHRF1 to replication sites and replication-coupled DNA methylation maintenance. An arginine binding cavity (Arg-binding cavity) of the TTD is essential for LIG1 interaction, thus the development of inhibitors that target the Arg-binding cavity could potentially repress UHRF1 function in cancer cells. To develop such an inhibitor, we performed in silico screening using not only static but also dynamic metrics based on all-atom molecular dynamics simulations, resulting in efficient identification of 5-amino-2,4-dimethylpyridine (5A-DMP) as a novel TTD-binding compound. Crystal structure of the TTD in complex with 5A-DMP revealed that the compound stably bound to the Arg-binding cavity of the TTD. Furthermore, 5A-DMP inhibits the full-length UHRF1:LIG1 interaction in Xenopus egg extracts. Our study uncovers a UHRF1 inhibitor which can be the basis of future experiments for cancer therapy. [ABSTRACT FROM AUTHOR]

Published

2021

135. A novel mutation at the N-terminal of SMN Tudor domain inhibits its interaction with target proteins.

Author

Kotani, Tomohiro, Sutomo, Retno, Sasongko, Teguh, Sadewa, Ahmad, Minato, Toshinori, Fujii, Emiko, Endo, Shoichi, Lee, Myeong, Ayaki, Hitoshi, Harada, Yosuke, Matsuo, Masafumi, and Nishio, Hisahide

Subjects

*SPINAL muscular atrophy, *MUSCULAR atrophy, *PROTEIN binding, *AMINO acids, *GENETIC mutation, *NEUROMUSCULAR diseases

Abstract

Although most patients with spinal muscular atrophy (SMA) are homozygous for deletion of the SMN1 gene, some patients bear one SMN1 copy with a subtle mutation. Detection of such an intragenic mutation may be helpful not only in confirming diagnosis but also in elucidating functional domains of the SMN protein. In this study, we identified a novel mutation in SMN1 of two Japanese patients with type I SMA. DHPLC and sequencing analysis revealed that they harbored a point mutation in SMN1 exon 3, 275G > C, leading to tryptophan-to-serine substitution at amino acid 92 (W92S) at the Nterminal of SMN Tudor domain. In-vitro protein binding assays showed that the mutation severely reduced interaction of the domain with SmB protein and fibrillarin, suggesting that it impairs the critical function of SMN. In conclusion, we reported here that a novel mutation, W92S, in the Tudor domain affects the interaction of SMN with the target proteins. [ABSTRACT FROM AUTHOR]

Published

2007

136. Protein methylation and DNA repair

Author

Lake, Aimee N. and Bedford, Mark T.

Subjects

*DNA, *DNA damage, *DNA repair, *POST-translational modification

Abstract

Abstract: DNA is under constant attack from intracellular and external mutagens. Sites of DNA damage need to be pinpointed so that the DNA repair machinery can be mobilized to the proper location. The identification of damaged sites, recruitment of repair factors, and assembly of repair “factories” is orchestrated by posttranslational modifications (PTMs). These PTMs include phosphorylation, ubiquitination, sumoylation, acetylation, and methylation. Here we discuss recent data surrounding the roles of arginine and lysine methylation in DNA repair processes. [Copyright &y& Elsevier]

Published

2007

137. Structural basis for arginine methylation-independent recognition of PIWIL1 by TDRD2

Author

Heng Zhang, Sachdev S. Sidhu, Deqiang Ding, Yukihide Tomari, Jinrong Min, Natsuko Izumi, Ke Liu, Haiming Huang, Zuyao Ni, and Chen Chen

Subjects

Male, Models, Molecular, 0301 basic medicine, Transposable element, endocrine system, Tudor domain, Piwi-interacting RNA, Plasma protein binding, Biology, Arginine, Crystallography, X-Ray, Methylation, Epigenesis, Genetic, Structure-Activity Relationship, 03 medical and health sciences, 0302 clinical medicine, Transcription (biology), Animals, Humans, Gene silencing, RNA, Small Interfering, Genetics, Multidisciplinary, urogenital system, RNA-Binding Proteins, RNA, Biological Sciences, HEK293 Cells, 030104 developmental biology, Argonaute Proteins, Mutation, Protein Processing, Post-Translational, 030217 neurology & neurosurgery, Protein Binding, Signal Transduction

Abstract

The P-element-induced wimpy testis (PIWI)-interacting RNA (piRNA) pathway plays a central role in transposon silencing and genome protection in the animal germline. A family of Tudor domain proteins regulates the piRNA pathway through direct Tudor domain-PIWI interactions. Tudor domains are known to fulfill this function by binding to methylated PIWI proteins in an arginine methylation-dependent manner. Here, we report a mechanism of methylation-independent Tudor domain-PIWI interaction. Unlike most other Tudor domains, the extended Tudor domain of mammalian Tudor domain-containing protein 2 (TDRD2) preferentially recognizes an unmethylated arginine-rich sequence from PIWI-like protein 1 (PIWIL1). Structural studies reveal an unexpected Tudor domain-binding mode for the PIWIL1 sequence in which the interface of Tudor and staphylococcal nuclease domains is primarily responsible for PIWIL1 peptide recognition. Mutations disrupting the TDRD2-PIWIL1 interaction compromise piRNA maturation via 3'-end trimming in vitro. Our work presented here reveals the molecular divergence of the interactions between different Tudor domain proteins and PIWI proteins.

Published

2017

138. Multifunctional RNA Binding Protein OsTudor-SN in Storage Protein mRNA Transport and Localization

Author

Li Tian, Hong Li Chou, Thomas W. Okita, Toshihiro Kumamaru, and Shigeki Hamada

Subjects

Models, Molecular, 0301 basic medicine, Tudor domain, Protein Conformation, Physiology, RNA-binding protein, macromolecular substances, Plant Science, Biology, environment and public health, 03 medical and health sciences, Protein structure, Stress granule, Gene Expression Regulation, Plant, Genetics, MRNA transport, RNA, Messenger, Plant Proteins, Cortical endoplasmic reticulum, Nuclear Proteins, Oryza, Articles, Molecular biology, Cell biology, Transport protein, enzymes and coenzymes (carbohydrates), Protein Transport, 030104 developmental biology, RNA, Plant, Plant protein, health occupations, human activities

Abstract

The multifunctional RNA-binding protein Tudor-SN plays multiple roles in transcriptional and posttranscriptional processes due to its modular domain structure, consisting of four tandem Staphylococcus nuclease (SN)-like domains (4SN), followed by a carboxyl-terminal Tudor domain, followed by a fifth partial SN sequence (Tsn). In plants, it confers stress tolerance, is a component of stress granules and P-bodies, and may participate in stabilizing and localizing RNAs to specific subdomains of the cortical-endoplasmic reticulum in developing rice (Oryza sativa) endosperm. Here, we show that, in addition to the intact rice OsTudor-SN protein, the 4SN and Tsn modules exist as independent polypeptides, which collectively may coassemble to form a complex population of homodimer and heteroduplex species. The 4SN and Tsn modules exhibit different roles in RNA binding and as a protein scaffold for stress-associated proteins and RNA-binding proteins. Despite their distinct individual properties, mutations in both the 4SN and Tsn modules mislocalize storage protein mRNAs to the cortical endoplasmic reticulum. These results indicate that the two modular peptide regions of OsTudor-SN confer different cellular properties but cooperate in mRNA localization, a process linking its multiple functions in the nucleus and cytoplasm.

Published

2017

139. A cryptic Tudor domain links BRWD2/PHIP to COMPASS-mediated histone H3K4 methylation

Author

Ryan Rickels, Christie C. Sze, Neil L. Kelleher, Stacy A. Marshall, Andrea Piunti, Kira A. Cozzolino, Marc A. Morgan, Ali Shilatifard, Xiaolin He, Jeffrey N. Savas, Kaixiang Cao, Clayton K. Collings, Nebiyu Abshiru, Hans Martin Herz, and Emily J. Rendleman

Subjects

0301 basic medicine, Tudor domain, Methylation, Epigenesis, Genetic, Histones, Gene Knockout Techniques, Mice, 03 medical and health sciences, Histone H3, Histone methylation, Genetics, Animals, Drosophila Proteins, Humans, Nucleosome, Promoter Regions, Genetic, Regulation of gene expression, Tudor Domain, biology, Acetylation, Histone-Lysine N-Methyltransferase, Chromatin, Cell biology, Drosophila melanogaster, Enhancer Elements, Genetic, 030104 developmental biology, Histone, Gene Expression Regulation, Histone Methyltransferases, biology.protein, CRISPR-Cas Systems, Research Paper, Protein Binding, Transcription Factors, Developmental Biology

Abstract

Histone H3 Lys4 (H3K4) methylation is a chromatin feature enriched at gene cis-regulatory sequences such as promoters and enhancers. Here we identify an evolutionarily conserved factor, BRWD2/PHIP, which colocalizes with histone H3K4 methylation genome-wide in human cells, mouse embryonic stem cells, and Drosophila. Biochemical analysis of BRWD2 demonstrated an association with the Cullin-4–RING ubiquitin E3 ligase-4 (CRL4) complex, nucleosomes, and chromatin remodelers. BRWD2/PHIP binds directly to H3K4 methylation through a previously unidentified chromatin-binding module related to Royal Family Tudor domains, which we named the CryptoTudor domain. Using CRISPR–Cas9 genetic knockouts, we demonstrate that COMPASS H3K4 methyltransferase family members differentially regulate BRWD2/PHIP chromatin occupancy. Finally, we demonstrate that depletion of the single Drosophila homolog dBRWD3 results in altered gene expression and aberrant patterns of histone H3 Lys27 acetylation at enhancers and promoters, suggesting a cross-talk between these chromatin modifications and transcription through the BRWD protein family.

Published

2017

140. SMA mutations in SMN Tudor and C-terminal domains destabilize the protein

Author

Mawaddah Ar Rochmah, Yasuhiro Takeshima, Hiroyuki Awano, Poh San Lai, Hisahide Nishio, Masakazu Shinohara, Kayoko Saito, Atsuko Takeuchi, Ichiro Morioka, Kazumoto Iijima, Nur Imma Fatimah Harahap, Toru Takarada, Toshio Saito, and Yoshihiro Bouike

Subjects

Male, 0301 basic medicine, Tudor domain, Mutant, Gene Expression, SMN1, Biology, medicine.disease_cause, Muscular Atrophy, Spinal, 03 medical and health sciences, Exon, 0302 clinical medicine, Protein Domains, Developmental Neuroscience, medicine, Humans, Child, Genetics, Mutation, Expression vector, Protein Stability, Infant, Survival of motor neuron, General Medicine, Spinal muscular atrophy, medicine.disease, Survival of Motor Neuron 1 Protein, Molecular biology, nervous system diseases, 030104 developmental biology, Child, Preschool, Pediatrics, Perinatology and Child Health, Female, Neurology (clinical), 030217 neurology & neurosurgery, HeLa Cells

Abstract

Background and purpose Most spinal muscular atrophy (SMA) patients are homozygous for survival of motor neuron 1 gene (SMN1) deletion. However, some SMA patients carry an intragenic SMN1 mutation. Such patients provide a clue to understanding the function of the SMN protein and the role of each domain of the protein. We previously identified mutations in the Tudor domain and C-terminal region of the SMN protein in three Japanese SMA patients. To clarify the effect of these mutations on protein stability, we conducted expression assays of SMN with mutated domains. Patients and methods Patients A and B carried a mutation in SMN1 exon 3, which encodes a Tudor domain, c.275G>C (p.Trp92Ser). Patient C carried a mutation in SMN1 exon 6, which encodes a YG-box; c.819_820insT (p.Thr274Tyrfs). We constructed plasmid expression vectors containing wild-type and mutant SMN1 cDNAs. After transfection of HeLa cells with the expression plasmids, RNA and protein were isolated and analyzed by reverse-transcription PCR and western blot analysis. Results The abundance of wild-type and mutant SMN1 transcripts in HeLa cells was almost the same. However, western blot analysis showed lower levels of mutant SMN proteins compared with wild-type SMN. In mutant SMN proteins, it is noteworthy that the level of the p.Thr274Tyrfs mutant was much reduced compared with that of the p.Trp92Ser mutant. Conclusions SMN mutations may affect the stability and levels of the protein.

Published

2017

141. <scp>A</scp> ggregation of SND1 in <scp>S</scp> tress <scp>G</scp> ranules is <scp>A</scp> ssociated with the <scp>M</scp> icrotubule <scp>C</scp> ytoskeleton <scp>D</scp> uring <scp>H</scp> eat <scp>S</scp> hock <scp>S</scp> timulus

Author

Jie Shao, Chao Su, Jinyan He, Zhi Yao, Li Ren, Yunli Zhou, Bingbing Zhang, Jie Yang, Xingjie Gao, Fei Gao, and Meng Zhao

Subjects

0301 basic medicine, SND1, Histology, Tudor domain, RNA, Biology, Cell biology, 03 medical and health sciences, Nocodazole, chemistry.chemical_compound, 030104 developmental biology, Stress granule, chemistry, Microtubule, Cytoplasm, Anatomy, Cytoskeleton, Ecology, Evolution, Behavior and Systematics, Biotechnology

Abstract

Stress granules (SGs) are dynamic dense structures in the cytoplasm that form in response to a variety of environmental stress stimuli. Staphylococcal nuclease and Tudor domain containing 1 (SND1) is a type of RNA-binding protein and has been identified as a transcriptional co-activator. Our previous studies have shown that SND1 is a component of the stress granule, which forms under stress conditions. Here, we observed that SND1 granules were often surrounded by ɑ-tubulin-microtubules in 45°C-treated HeLa cells at 15 min or colocalized with microtubules at 30 or 45 min. Furthermore, Nocodazole-mediated microtubule depolymerization could significantly affect the efficient recruitment of SND1 proteins to the SGs during heat shock stress. In addition, the 45°C heat shock mediated the enhancement of eIF2α phosphorylation, which was not affected by treatment with Nocodazole, an agent that disrupts the cytoskeleton. The intact microtubule cytoskeletal tracks are important for the efficient assembly of SND1 granules under heat shock stress and may facilitate SND1 shuttling between cytoplasmic RNA foci. Anat Rec, 300:2192-2199, 2017. © 2017 The Authors The Anatomical Record published by Wiley Periodicals, Inc. on behalf of American Association of Anatomists.

Published

2017

142. Tudor, MBT and chromo domains gauge the degree of lysine methylation.

Author

Kim, Jeesun, Daniel, Jeremy, Espejo, Alexsandra, Lake, Aimee, Krishna, Murli, Li Xia, Yi Zhang, and Bedford, Mark T.

Subjects

HISTONES, LYSINE, DNA repair, GENETIC translation, DNA replication, METHYLATION

Abstract

The post-translational modification of histones regulates many cellular processes, including transcription, replication and DNA repair. A large number of combinations of post-translational modifications are possible. This cipher is referred to as the histone code. Many of the enzymes that lay down this code have been identified. However, so far, few code-reading proteins have been identified. Here, we describe a protein-array approach for identifying methyl-specific interacting proteins. We found that not only chromo domains but also tudor and MBT domains bind to methylated peptides from the amino-terminal tails of histones H3 and H4. Binding specificity observed on the protein-domain microarray was corroborated using peptide pull-downs, surface plasma resonance and far western blotting. Thus, our studies expose tudor and MBT domains as new classes of methyl-lysine-binding protein modules, and also demonstrates that protein-domain microarrays are powerful tools for the identification of new domain types that recognize histone modifications. [ABSTRACT FROM AUTHOR]

Published

2006

143. SND1 acts as a novel gene transcription activator recognizing the conserved Motif domains of Smad promoters, inducing TGFβ1 response and breast cancer metastasis

Author

L Xin, Zhi Yao, X Sun, Y Di, Wenhong Zhang, Xin Liu, Li Yu, Yi Ren, and Jun Yang

Subjects

Transcriptional Activation, 0301 basic medicine, Cancer Research, SND1, Lung Neoplasms, Tudor domain, Gene Expression, Breast Neoplasms, Smad Proteins, Kaplan-Meier Estimate, Mice, SCID, SMAD, Biology, Conserved sequence, Transforming Growth Factor beta1, 03 medical and health sciences, Cell Movement, Genetics, Animals, Humans, Protein Interaction Domains and Motifs, p300-CBP Transcription Factors, Electrophoretic mobility shift assay, Promoter Regions, Genetic, Molecular Biology, Conserved Sequence, Regulation of gene expression, Base Sequence, Nuclear Proteins, Promoter, MTDH, Endonucleases, Prognosis, Gene Expression Regulation, Neoplastic, HEK293 Cells, 030104 developmental biology, Lymphatic Metastasis, MCF-7 Cells, Cancer research, Female, Neoplasm Transplantation, Protein Binding

Abstract

As an AEG-1/MTDH/LYRIC-binding protein, Staphylococcal nuclease domain-containing 1 (SND1) is upregulated in numerous human cancers where it has been assigned multiple functional roles. In this study, we discovered that SND1 was upregulated in breast cancer tissues, particularly the tissues from patients with distant metastases. The underlying molecular mechanisms demonstrated a novel role of SND1 in regulating the activity of transforming growth factor β1 (TGFβ1) signaling pathway, which promotes metastasis in breast cancer. We illustrated that SND1 physically associated with and recruited the histone acetylase GCN5 to the promoter regions of Smad2/3/4, and consequently enhanced the gene transcriptional activation of Smad2/3/4, which are essential downstream regulators in the TGFβ1 pathway. An electrophoretic mobility shift assay experiment further verified that SND1 could recognize the conserved domains (motifs 1 and 2) in the promoter regions of the Smad genes. Glutathione S-transferase (GST) pulldown assays indicated that the tudor domain of SND1 was responsible for the recruitment of GCN5, which increased histone H3K9 acetylation. Consistent with these results, a loss-of-function of SND1 reduced the protein level of Smads and the phosphorylation of R-Smads, thereby attenuating the R-Smad/Co-Smad depended transcription and, as a result, inhibited TGFβ signaling activation.

Published

2017

144. The Survival of Motor Neuron Protein Acts as a Molecular Chaperone for mRNP Assembly

Author

Jazmin Campos, Gary J. Bassell, Wilfried Rossoll, Megan E. Merritt, Han C. Phan, Paul G. Donlin-Asp, Claudia Fallini, and Ching Chieh Chou

Subjects

0301 basic medicine, Untranslated region, Tudor domain, animal diseases, Biology, General Biochemistry, Genetics and Molecular Biology, Article, Muscular Atrophy, Spinal, 03 medical and health sciences, 0302 clinical medicine, mRNP, medicine, Humans, snRNP, RNA, Messenger, SMA, 3' Untranslated Regions, lcsh:QH301-705.5, Cells, Cultured, Cytoskeleton, Ribonucleoprotein, spinal muscular atrophy, Motor Neurons, RNA-Binding Proteins, beta actin mRNA, Survival of motor neuron, SMN Complex Proteins, Spinal muscular atrophy, medicine.disease, Ribonucleoproteins, Small Nuclear, Molecular biology, Actins, Cell biology, nervous system diseases, SMN, Messenger RNP, 030104 developmental biology, Ribonucleoproteins, nervous system, lcsh:Biology (General), mRNA localization, IMP1, 030217 neurology & neurosurgery, Molecular Chaperones

Abstract

Summary Spinal muscular atrophy (SMA) is a motor neuron disease caused by reduced levels of the survival of motor neuron (SMN) protein. SMN is part of a multiprotein complex that facilitates the assembly of spliceosomal small nuclear ribonucleoproteins (snRNPs). SMN has also been found to associate with mRNA-binding proteins, but the nature of this association was unknown. Here, we have employed a combination of biochemical and advanced imaging methods to demonstrate that SMN promotes the molecular interaction between IMP1 protein and the 3′ UTR zipcode region of β-actin mRNA, leading to assembly of messenger ribonucleoprotein (mRNP) complexes that associate with the cytoskeleton to facilitate trafficking. We have identified defects in mRNP assembly in cells and tissues from SMA disease models and patients that depend on the SMN Tudor domain and explain the observed deficiency in mRNA localization and local translation, providing insight into SMA pathogenesis as a ribonucleoprotein (RNP)-assembly disorder.

Published

2017

145. PHF1 Tudor and N-terminal domains synergistically target partially unwrapped nucleosomes to increase DNA accessibility

Author

Matthew D. Gibson, Tatiana G. Kutateladze, Jovylyn Gatchalian, Andrew Slater, and Michael G. Poirier

Subjects

0301 basic medicine, Tudor domain, Methyltransferase, Lysine, Polycomb-Group Proteins, Biology, Histones, 03 medical and health sciences, Histone H3, chemistry.chemical_compound, Protein Domains, Genetics, Nucleosome, Humans, Tudor Domain, Gene regulation, Chromatin and Epigenetics, DNA, Nucleosomes, DNA-Binding Proteins, 030104 developmental biology, Förster resonance energy transfer, chemistry, Biophysics, biology.protein, PRC2, Protein Binding

Abstract

The Tudor domain of human PHF1 recognizes trimethylated lysine 36 on histone H3 (H3K36me3). PHF1 relies on this interaction to regulate PRC2 methyltransferase activity, localize to DNA double strand breaks and mediate nucleosome accessibility. Here, we investigate the impact of the PHF1 N-terminal domain (NTD) on the Tudor domain interaction with the nucleosome. We show that the NTD is partially ordered when it is natively attached to the Tudor domain. Through a combination of FRET and single molecule studies, we find that the increase of DNA accessibility within the H3K36me3-containing nucleosome, instigated by the Tudor binding to H3K36me3, is dramatically enhanced by the NTD. We demonstrate that this nearly order of magnitude increase is due to preferential binding of PHF1 to partially unwrapped nucleosomes, and that PHF1 alters DNA–protein binding within the nucleosome by decreasing dissociation rates. These results highlight the potency of a PTM-binding protein to regulate DNA accessibility and underscores the role of the novel mechanism by which nucleosomes control DNA–protein binding through increasing protein dissociation rates.

Published

2017

146. Zebrafish z-otu, a novel Otu and Tudor domain-containing gene, is expressed in early stages of oogenesis and embryogenesis

Author

Mo, Saijun, Song, Ping, Lv, Daoyuan, Chen, Yungui, Zhou, Wei, Gong, Wuming, and Zhu, Zuoyan

Subjects

*ZEBRA danio, *BRACHYDANIO, *OOGENESIS, *GAMETOGENESIS

Abstract

Abstract: Several studies have suggested that Otu domain had de-ubiquitinating activity and Tudor domain was important for the formation of germ cells. Here, we reported a novel zebrafish ovary-specific gene containing Otu and Tudor domain, z-otu, which was expressed at stages I–III oocytes and embryonic stages from zygotes to early blastula during embryonic cells maintained their totipotency. Therefore, z-otu might link the ubiquitin signaling pathway to early oogenesis and maintaining the totipotency of embryonic cell. [Copyright &y& Elsevier]

Published

2005

147. Boundaries and physical characterization of a new domain shared between mammalian 53BP1 and yeast Rad9 checkpoint proteins.

Author

Alpha-Bazin, Béatrice, Lorphelin, Alain, Nozerand, Nathalie, Charier, Gaëlle, Marchetti, Charles, Bérenguer, Frédéric, Couprie, Joël, Gilquin, Bernard, Zinn-Justin, Sophie, and Quéméneur, Eric

Abstract

Eukaryotic cells have evolved DNA damage checkpoints in response to genome damage. They delay the cell cycle and activate repair mechanisms. The kinases at the heart of these pathways and the accessory proteins, which localize to DNA lesions and regulate kinase activation, are conserved from yeast to mammals. For Saccharomyces cerevisiae Rad9, a key adaptor protein in DNA damage checkpoint pathways, no clear human ortholog has yet been described in mammals. Rad9, however, shares localized homology with both human BRCA1 and 53BP1 since they all contain tandem C-terminal BRCT (BRCA1 C-terminal) motifs. 53BP1 is also a key mediator in DNA damage signaling required for cell cycle arrest, which has just been reported to possess a tandem Tudor repeat upstream of the BRCT motifs. Here we show that the major globular domain upstream of yeast Rad9 BRCT domains is structurally extremely similar to the Tudor domains recently resolved for 53BP1 and SMN. By expressing several fragments encompassing the Tudor-related motif and characterizing them using various physical methods, we isolated the independently folded unit for yeast Rad9. As in 53BP1, the domain corresponds to the SMN Tudor motif plus the contiguous HCA predicted structure region at the C terminus. These domains may help to further elucidate the structural and functional features of these two proteins and improve knowledge of the proteins involved in DNA damage. [ABSTRACT FROM AUTHOR]

Published

2005

148. Involvement of Xtr (Xenopustudor repeat) in microtubule assembly around nucleus and karyokinesis during cleavage inXenopus laevis.

Author

Hiyoshi, Masateru, Nakajo, Nobushige, Abe, Sin-Ichi, and Takamune, Kazufumi

Subjects

*XENOPUS laevis, *XENOPUS, *GENES, *MOLECULAR genetics, *MICROTUBULES, *ORGANELLES, *KARYOKINESIS, *CELL division

Abstract

We have previously shown that the transcriptional product of the novel gene,Xenopus tudor repeat(Xtr), occurred exclusively in germline cells and early embryonic cells and that the putative Xtr contained plural tudor domains which are thought to play a role in the protein–protein interactions. To understand the role of Xtr, we produced an antibody against a polypeptide containing Xtr tudor domains as an antigen and investigated the distribution and the function of the Xtr. Immunoprecipitation/Western blot and immunohistochemical analyses indicated a similar occurrence of the Xtr to the mRNA except for a slightly different profile of its amount during spermatogenesis. In spite of a large amount of Xtr mRNA at late-secondary spermatogonial stage, the amount of Xtr was kept at a low level until this stage and increased after entering into the meiotic phase. Depletion of the Xtr function in the activated eggs by injection of the anti-Xtr antibody caused the inhibition both of microtubule assembly around nucleus and of karyokinesis progression after prophase, but not of the oscillation of H1 kinase activity. These results suggest that the karyokinesis of at least early embryonic cells are regulated by unique mechanisms in which the Xtr is involved. [ABSTRACT FROM AUTHOR]

Published

2005

149. The p100 EBNA-2 coactivator: a highly conserved protein found in a range of exocrine and endocrine cells and tissues in cattle

Author

Broadhurst, Marita K., Lee, Rita S.-F., Hawkins, Sarah, and Wheeler, Thomas T.

Subjects

*EPSTEIN-Barr virus, *TRANSCRIPTION factors, *CELLS, *HERPESVIRUSES

Abstract

Abstract: The p100 transcriptional coactivator is an evolutionarily conserved protein that has been shown to be a coactivator of the Epstein–Barr virus-encoded transcription factor EBNA-2, as well as Stat5 and Stat6. However, the p100 genomic organisation, phylogeny and expression have not been analysed in detail and its physiological role is uncertain. The cDNA and amino acid sequence of bovine p100 was obtained, and the genomic organisation of the human p100 gene was determined. Homologues of p100 were found in the genomes of 21 diverse eukaryotes. Western blot and immunohistochemical analyses revealed that the bovine p100 protein is present in a range of exocrine and endocrine cells and tissues, including the lactating mammary gland, pancreas, adrenal, parotid, anterior pituitary, corpus luteum, ovarian follicular cells, placenta and small intestine. P100 was present in the nuclei of mammary epithelial cells and pancreatic acinar cells, but only in the extranuclear compartment of the other immunopositive tissues. These data indicate that the p100 protein plays a fundamental role in eukaryotic biology, and functions in secretory cells, at least in cattle. [Copyright &y& Elsevier]

Published

2005

150. Modulation of SMN nuclear foci and cytoplasmic localization by its C-terminus.

Author

Hua, Y. and Zhou, J.

Subjects

*SPINAL muscular atrophy, *MOTOR neurons, *GENES, *AXONS, *CYTOPLASM

Abstract

The survival of motor neuron (SMN1) gene product, SMN, is detected both in the cytoplasm and in nuclear gems and cajal bodies. We show here that SMN exon 6 is essential both for formation of its nuclear foci and for its cytoplasmic localization. However, exon 7 inhibits the formation of SMN nuclear foci but promotes SMN cytoplasmic localization. More interestingly, we find that a random C-terminal tag of five or more amino acids downstream of exon 6 is sufficient to inhibit the occurrence of multiple nuclear foci and to promote cytoplasmic localization of SMN?7, the primary product of theSMN2gene. Moreover, SMN?7 proteins that bear spinal muscular atrophy mutations in exon 6 either showed defects in nuclear foci formation or enhanced cytoplasmic localization. We conclude that exon 6 and exon 7 synergistically regulate SMN distribution that may require specific exon 6 motifs but is independent of specific sequences in exon 7. [ABSTRACT FROM AUTHOR]

Published

2004