Your search keyword '"Guo HC"' showing total 6 results

1. RNAi Reveals Phase-Specific Global Regulators of Human Somatic Cell Reprogramming.

Author

Toh CX, Chan JW, Chong ZS, Wang HF, Guo HC, Satapathy S, Ma D, Goh GY, Khattar E, Yang L, Tergaonkar V, Chang YT, Collins JJ, Daley GQ, Wee KB, Farran CA, Li H, Lim YP, Bard FA, and Loh YH

Subjects

Cells, Cultured, Gene Knockdown Techniques, Genetic Testing, Genome, Human, Humans, Kinetics, Microtubule-Associated Proteins genetics, Microtubule-Associated Proteins metabolism, RNA Splicing genetics, RNA, Messenger genetics, RNA, Messenger metabolism, RNA, Small Interfering metabolism, Repressor Proteins metabolism, Serine-Arginine Splicing Factors metabolism, Cellular Reprogramming genetics, RNA Interference

Abstract

Incomplete knowledge of the mechanisms at work continues to hamper efforts to maximize reprogramming efficiency. Here, we present a systematic genome-wide RNAi screen to determine the global regulators during the early stages of human reprogramming. Our screen identifies functional repressors and effectors that act to impede or promote the reprogramming process. Repressors and effectors form close interacting networks in pathways, including RNA processing, G protein signaling, protein ubiquitination, and chromatin modification. Combinatorial knockdown of five repressors (SMAD3, ZMYM2, SFRS11, SAE1, and ESET) synergistically resulted in ∼85% TRA-1-60-positive cells. Removal of the novel splicing factor SFRS11 during reprogramming is accompanied by rapid acquisition of pluripotency-specific spliced forms. Mechanistically, SFRS11 regulates exon skipping and mutually exclusive splicing of transcripts in genes involved in cell differentiation, mRNA splicing, and chromatin modification. Our study provides insights into the reprogramming process, which comprises comprehensive and multi-layered transcriptional, splicing, and epigenetic machineries., (Copyright © 2016 The Author(s). Published by Elsevier Inc. All rights reserved.)

Published

2016

2. Systematic identification of factors for provirus silencing in embryonic stem cells.

Author

Yang BX, El Farran CA, Guo HC, Yu T, Fang HT, Wang HF, Schlesinger S, Seah YF, Goh GY, Neo SP, Li Y, Lorincz MC, Tergaonkar V, Lim TM, Chen L, Gunaratne J, Collins JJ, Goff SP, Daley GQ, Li H, Bard FA, and Loh YH

Subjects

Animals, Chromatin Assembly Factor-1 genetics, Chromatin Assembly Factor-1 metabolism, Embryonal Carcinoma Stem Cells virology, Epigenesis, Genetic, Mice, Small Ubiquitin-Related Modifier Proteins metabolism, Embryonic Stem Cells virology, Endogenous Retroviruses genetics, Proviruses genetics

Abstract

Embryonic stem cells (ESCs) repress the expression of exogenous proviruses and endogenous retroviruses (ERVs). Here, we systematically dissected the cellular factors involved in provirus repression in embryonic carcinomas (ECs) and ESCs by a genome-wide siRNA screen. Histone chaperones (Chaf1a/b), sumoylation factors (Sumo2/Ube2i/Sae1/Uba2/Senp6), and chromatin modifiers (Trim28/Eset/Atf7ip) are key determinants that establish provirus silencing. RNA-seq analysis uncovered the roles of Chaf1a/b and sumoylation modifiers in the repression of ERVs. ChIP-seq analysis demonstrates direct recruitment of Chaf1a and Sumo2 to ERVs. Chaf1a reinforces transcriptional repression via its interaction with members of the NuRD complex (Kdm1a, Hdac1/2) and Eset, while Sumo2 orchestrates the provirus repressive function of the canonical Zfp809/Trim28/Eset machinery by sumoylation of Trim28. Our study reports a genome-wide atlas of functional nodes that mediate proviral silencing in ESCs and illuminates the comprehensive, interconnected, and multi-layered genetic and epigenetic mechanisms by which ESCs repress retroviruses within the genome., (Copyright © 2015 Elsevier Inc. All rights reserved.)

Published

2015

3. Structural basis of a point mutation that causes the genetic disease aspartylglucosaminuria.

Author

Sui L, Lakshminarasimhan D, Pande S, and Guo HC

Subjects

Crystallography, X-Ray, Humans, Models, Molecular, Aspartylglucosaminuria genetics, Aspartylglucosylaminase genetics, Point Mutation

Abstract

Aspartylglucosaminuria (AGU) is a lysosomal storage disease caused by a metabolic disorder of lysosomes to digest Asn-linked glycoproteins. The specific enzyme linked to AGU is a lysosomal hydrolase called glycosylasparaginase. Crystallographic studies revealed that a surface loop blocks the catalytic center of the mature hydrolase. Autoproteolysis is therefore required to remove this P loop and open up the hydrolase center. Nonetheless, AGU mutations result in misprocessing of their precursors and are deficient in hydrolyzing glycoasparagines. To understand the catalytic and structural consequences of AGU mutations, we have characterized two AGU models, one corresponding to a Finnish allele and the other found in a Canadian family. We also report a 2.1 Å resolution structure of the latter AGU model. The current crystallographic study provides a high-resolution structure of an AGU mutant. It reveals substantial conformation changes at the defective autocleavage site of the AGU mutant, which is trapped as an inactive precursor., (Copyright © 2014 Elsevier Ltd. All rights reserved.)

Published

2014

4. An asymmetric complex of restriction endonuclease MspI on its palindromic DNA recognition site.

Author

Xu QS, Kucera RB, Roberts RJ, and Guo HC

Subjects

Amino Acid Sequence, Catalytic Domain, Crystallography, X-Ray, Deoxyribonucleases, Type II Site-Specific chemistry, Dimerization, Hydrogen Bonding, Macromolecular Substances, Models, Molecular, Molecular Sequence Data, Protein Structure, Secondary, Base Sequence, DNA metabolism, Deoxyribonuclease HpaII chemistry, Deoxyribonuclease HpaII genetics, Protein Structure, Tertiary

Abstract

Most well-known restriction endonucleases recognize palindromic DNA sequences and are classified as Type IIP. Due to the recognition and cleavage symmetry, Type IIP enzymes are usually found to act as homodimers in forming 2-fold symmetric enzyme-DNA complexes. Here we report an asymmetric complex of the Type IIP restriction enzyme MspI in complex with its cognate recognition sequence. Unlike any other Type IIP enzyme reported to date, an MspI monomer and not a dimer binds to a palindromic DNA sequence. The enzyme makes specific contacts with all 4 base pairs in the recognition sequence, by six direct and five water-mediated hydrogen bonds and numerous van der Waal contacts. This MspI-DNA structure represents the first example of asymmetric recognition of a palindromic DNA sequence by two different structural motifs in one polypeptide. A few possible pathways are discussed for MspI to cut both strands of DNA, either as a monomer or dimer.

Published

2004

5. A dual role for an aspartic acid in glycosylasparaginase autoproteolysis.

Author

Qian X, Guan C, and Guo HC

Subjects

Aspartylglucosylaminase genetics, Binding Sites, Crystallography, X-Ray, Dimerization, Enzyme Precursors chemistry, Enzyme Precursors metabolism, Glycine metabolism, Kinetics, Models, Molecular, Molecular Structure, Mutagenesis, Site-Directed, Point Mutation, Protein Binding, Protein Conformation, Spectrum Analysis, Raman, Structure-Activity Relationship, Water chemistry, Aspartic Acid metabolism, Aspartylglucosylaminase chemistry, Aspartylglucosylaminase metabolism

Abstract

Glycosylasparaginase uses an autoproteolytic processing mechanism, through an N-O acyl shift, to generate a mature/active enzyme from a single-chain precursor. Structures of glycosylasparaginase precursors in complex with a glycine inhibitor have revealed the backbone in the immediate vicinity of the scissile peptide bond to be in a distorted trans conformation, which is believed to be the driving force for the N-O acyl shift to break the peptide bond. Here we report the effects of point mutation D151N. In addition to the loss of the base essential in autoproteolysis, this mutation also eradicates the backbone distortion near the scissile peptide bond. Binding of the glycine inhibitor to the autoproteolytic site of the D151N mutant does not restore the backbone distortion. Therefore, Asp151 plays a dual role, acting as the general base to activate the nucleophile and holding the distorted trans conformation that is critical for initiating an N-O acyl shift.

Published

2003

6. Structural insights into the mechanism of intramolecular proteolysis.

Author

Xu Q, Buckley D, Guan C, and Guo HC

Subjects

Crystallography, X-Ray, Flavobacterium enzymology, Glycine metabolism, Kinetics, Models, Chemical, Models, Molecular, Molecular Sequence Data, Mutagenesis, Protein Binding, Protein Conformation, Protein Structure, Tertiary, Aspartylglucosylaminase metabolism, Binding Sites, Protein Precursors metabolism

Abstract

A variety of proteins, including glycosylasparaginase, have recently been found to activate functions by self-catalyzed peptide bond rearrangements from single-chain precursors. Here we present the 1.9 A crystal structures of glycosylasparaginase precursors that are able to autoproteolyze via an N --> O acyl shift. Several conserved residues are aligned around the scissile peptide bond that is in a highly strained trans peptide bond configuration. The structure illustrates how a nucleophilic side chain may attack the scissile peptide bond at the immediate upstream backbone carbonyl and provides an understanding of the structural basis for peptide bond cleavage via an N --> O or N --> S acyl shift that is used by various groups of intramolecular autoprocessing proteins.

Published

1999