Your search keyword '"Yong-Gang Chang"' showing total 35 results

1. Real-Time In Vitro Fluorescence Anisotropy of the Cyanobacterial Circadian Clock

Author

Joel Heisler, Archana Chavan, Yong-Gang Chang, and Andy LiWang

Subjects

fluorescence, circadian clock, cyanobacteria, protein, phosphorylation, Biology (General), QH301-705.5

Abstract

Uniquely, the circadian clock of cyanobacteria can be reconstructed outside the complex milieu of live cells, greatly simplifying the investigation of a functioning biological chronometer. The core oscillator component is composed of only three proteins, KaiA, KaiB, and KaiC, and together with ATP they undergo waves of assembly and disassembly that drive phosphorylation rhythms in KaiC. Typically, the time points of these reactions are analyzed ex post facto by denaturing polyacrylamide gel electrophoresis, because this technique resolves the different states of phosphorylation of KaiC. Here, we describe a more sensitive method that allows real-time monitoring of the clock reaction. By labeling one of the clock proteins with a fluorophore, in this case KaiB, the in vitro clock reaction can be monitored by fluorescence anisotropy on the minutes time scale for weeks.

Published

2019

2. Structure of the metastatic factor P-Rex1 reveals a two-layered autoinhibitory mechanism

Author

Yong-Gang Chang, Christopher J. Lupton, Charles Bayly-Jones, Alastair C. Keen, Laura D’Andrea, Christina M. Lucato, Joel R. Steele, Hari Venugopal, Ralf B. Schittenhelm, James C. Whisstock, Michelle L. Halls, and Andrew M. Ellisdon

Subjects

Structural Biology, Molecular Biology

Abstract

P-Rex (PI(3,4,5)P3-dependent Rac exchanger) guanine nucleotide exchange factors potently activate Rho GTPases. P-Rex guanine nucleotide exchange factors are autoinhibited, synergistically activated by Gβγ and PI(3,4,5)P3 binding and dysregulated in cancer. Here, we use X-ray crystallography, cryogenic electron microscopy and crosslinking mass spectrometry to determine the structural basis of human P-Rex1 autoinhibition. P-Rex1 has a bipartite structure of N- and C-terminal modules connected by a C-terminal four-helix bundle that binds the N-terminal Pleckstrin homology (PH) domain. In the N-terminal module, the Dbl homology (DH) domain catalytic surface is occluded by the compact arrangement of the DH-PH-DEP1 domains. Structural analysis reveals a remarkable conformational transition to release autoinhibition, requiring a 126° opening of the DH domain hinge helix. The off-axis position of Gβγ and PI(3,4,5)P3 binding sites further suggests a counter-rotation of the P-Rex1 halves by 90° facilitates PH domain uncoupling from the four-helix bundle, releasing the autoinhibited DH domain to drive Rho GTPase signaling.

Published

2022

3. A Night-Time Edge Site Intermediate in the Cyanobacterial Circadian Clock Identified by EPR Spectroscopy

Author

Gary K. Chow, Archana G. Chavan, Joel Heisler, Yong-Gang Chang, Ning Zhang, Andy LiWang, and R. David Britt

Subjects

Colloid and Surface Chemistry, Circadian Clocks, Chemical Sciences, General Chemistry, Sleep Research, Biochemistry, Catalysis

Abstract

As the only circadian oscillator that can be reconstituted in vitro with its constituent proteins KaiA, KaiB, and KaiC using ATP as an energy source, the cyanobacterial circadian oscillator serves as a model system for detailed mechanistic studies of day-night transitions of circadian clocks in general. The day-to-night transition occurs when KaiB forms a night-time complex with KaiC to sequester KaiA, the latter of which interacts with KaiC during the day to promote KaiC autophosphorylation. However, how KaiB forms the complex with KaiC remains poorly understood, despite the available structures of KaiB bound to hexameric KaiC. It has been postulated that KaiB-KaiC binding is regulated by inter-KaiB cooperativity. Here, using spin labeling continuous-wave electron paramagnetic resonance spectroscopy, we identified and quantified two subpopulations of KaiC-bound KaiB, corresponding to the "bulk" and "edge" KaiBC sites in stoichiometric and substoichiometric KaiBiC6 complexes (i = 1-5). We provide kinetic evidence to support the intermediacy of the "edge" KaiBC sites as bridges and nucleation sites between free KaiB and the "bulk" KaiBC sites. Furthermore, we show that the relative abundance of "edge" and "bulk" sites is dependent on both KaiC phosphostate and KaiA, supporting the notion of phosphorylation-state controlled inter-KaiB cooperativity. Finally, we demonstrate that the interconversion between the two subpopulations of KaiC-bound KaiB is intimately linked to the KaiC phosphorylation cycle. These findings enrich our mechanistic understanding of the cyanobacterial clock and demonstrate the utility of EPR in elucidating circadian clock mechanisms.

Published

2022

4. Structural analysis of the PTEN:P-Rex2 signaling complex reveals how cancer-associated mutations coordinate to hyperactivate Rac1

Author

Elsa A. Marquez, Christina Anne Mitchell, Christina M A Lucato, James C. Whisstock, Christopher J. Lupton, Cheng Huang, Michelle L. Halls, Ralf B. Schittenhelm, Srgjan Civciristov, Andrew M. Ellisdon, Chantel Mastos, Yong-Gang Chang, Hans Elmlund, and Laura D’Andrea

Subjects

rac1 GTP-Binding Protein, Phosphatase, PDZ domain, RAC1, Biochemistry, Receptor tyrosine kinase, law.invention, 03 medical and health sciences, Phosphatidylinositol 3-Kinases, 0302 clinical medicine, law, Neoplasms, Pi, PTEN, Guanine Nucleotide Exchange Factors, Humans, Molecular Biology, 030304 developmental biology, 0303 health sciences, biology, Chemistry, PTEN Phosphohydrolase, Cell Biology, Cell biology, Mutation, biology.protein, Suppressor, Guanine nucleotide exchange factor, 030217 neurology & neurosurgery, Signal Transduction

Abstract

The dual-specificity phosphatase PTEN functions as a tumor suppressor by hydrolyzing PI(3,4,5)P3 to PI(4,5)P2 to inhibit PI3K-AKT signaling and cellular proliferation. P-Rex2 is a guanine nucleotide exchange factor for Rho GTPases and can be activated by Gβγ subunits downstream of G protein-coupled receptor signaling and by PI(3,4,5)P3 downstream of receptor tyrosine kinases. The PTEN:P-Rex2 complex is a commonly mutated signaling node in metastatic cancer. Assembly of the PTEN:P-Rex2 complex inhibits the activity of both proteins, and its dysregulation can drive PI3K-AKT signaling and cellular proliferation. Here, using cross-linking mass spectrometry and functional studies, we gained mechanistic insights into PTEN:P-Rex2 complex assembly and coinhibition. We found that PTEN was anchored to P-Rex2 by interactions between the PDZ-interacting motif in the PTEN C-terminal tail and the second PDZ domain of P-Rex2. This interaction bridged PTEN across the P-Rex2 surface, preventing PI(3,4,5)P3 hydrolysis. Conversely, PTEN both allosterically promoted an autoinhibited conformation of P-Rex2 and blocked its binding to Gβγ. In addition, we observed that the PTEN-deactivating mutations and P-Rex2 truncations combined to drive Rac1 activation to a greater extent than did either single variant alone. These insights enabled us to propose a class of gain-of-function, cancer-associated mutations within the PTEN:P-Rex2 interface that uncouple PTEN from the inhibition of Rac1 signaling.

Published

2021

5. Real-Time In Vitro Fluorescence Anisotropy of the Cyanobacterial Circadian Clock

Author

Andy LiWang, Archana G. Chavan, Joel Heisler, and Yong-Gang Chang

Subjects

0301 basic medicine, Quantitative Biology::Biomolecules, 030102 biochemistry & molecular biology, Chemistry, Quantitative Biology::Molecular Networks, Kinetics, Circadian clock, Polarization (waves), Fluorescence, In vitro, Quantitative Biology::Cell Behavior, Quantitative Biology::Subcellular Processes, 03 medical and health sciences, 030104 developmental biology, Biophysics, Fluorescence anisotropy

Abstract

Stochastic diffusion of a solution of fluorophores after photoselection reduces the polarization of emission, or fluorescence anisotropy. Because this randomization process is slower for larger molecules, fluorescence anisotropy is effective for measuring the kinetics of protein-binding events. Here, we describe how to use the technique to carry out real-time observations in vitro of the cyanobacterial circadian clock.

Published

2020

6. Solution NMR structure of Se0862, a highly conserved cyanobacterial protein involved in biofilm formation

Author

Rakefet Schwarz, Sergey Ovchinnikov, Andy LiWang, Ning Zhang, Roger Tseng, and Yong-Gang Chang

Subjects

Cyanobacteria, Protein Conformation, alpha-Helical, Synechococcus elongatus, Protein Conformation, Nuclear Magnetic Resonance, S. elongatus PCC 7942, Microorganism, Biophysics, cyanobacteria, Biochemistry, biofilm, 03 medical and health sciences, NMR spectroscopy, Protein structure, Bacterial Proteins, Extracellular, protein structure, Other Information and Computing Sciences, Molecular Biology, Nuclear Magnetic Resonance, Biomolecular, 030304 developmental biology, Synechococcus, 0303 health sciences, biology, Chemistry, alpha-Helical, 030302 biochemistry & molecular biology, Biofilm, Computation Theory and Mathematics, Nuclear magnetic resonance spectroscopy, biology.organism_classification, Biofilms, beta-Strand, Protein Conformation, beta-Strand, Biochemistry and Cell Biology, elongatus PCC 7942, Sustainable production, Protein Structure Reports, Biomolecular

Abstract

Biofilms are accumulations of microorganisms embedded in extracellular matrices that protect against external factors and stressful environments. Cyanobacterial biofilms are ubiquitous and have potential for treatment of wastewater and sustainable production of biofuels. But the underlying mechanisms regulating cyanobacterial biofilm formation are unclear. Here, we report the solution NMR structure of a protein, Se0862, conserved across diverse cyanobacterial species and involved in regulation of biofilm formation in the cyanobacterium Synechococcus elongatus PCC 7942. Se0862 is a class α+β protein with ααββββαα topology and roll architecture, consisting of a four-stranded β-sheet that is flanked by four α-helices on one side. Conserved surface residues constitute a hydrophobic pocket and charged regions that are likely also present in Se0862 orthologs.

Published

2020

7. Monitoring Protein-Protein Interactions in the Cyanobacterial Circadian Clock in Real Time via Electron Paramagnetic Resonance Spectroscopy

Author

Andy LiWang, Joel Heisler, Yong-Gang Chang, Gary K Chow, R. David Britt, and Archana G. Chavan

Subjects

Synechococcus, 0303 health sciences, Biochemistry & Molecular Biology, Chemistry, Circadian Rhythm Signaling Peptides and Proteins, Period (gene), 030302 biochemistry & molecular biology, Circadian clock, Mutant, Electron Spin Resonance Spectroscopy, Medical Biochemistry and Metabolomics, Biochemistry, Protein–protein interaction, 03 medical and health sciences, Medicinal and Biomolecular Chemistry, Bacterial Proteins, KaiC, KaiA, Biophysics, CLOCK Proteins, Circadian rhythm, Generic health relevance, Biochemistry and Cell Biology, Sleep Research

Abstract

[Image: see text] The cyanobacterial circadian clock in Synechococcus elongatus consists of three proteins, KaiA, KaiB, and KaiC. KaiA and KaiB rhythmically interact with KaiC to generate stable oscillations of KaiC phosphorylation with a period of 24 h. The observation of stable circadian oscillations when the three clock proteins are reconstituted and combined in vitro makes it an ideal system for understanding its underlying molecular mechanisms and circadian clocks in general. These oscillations were historically monitored in vitro by gel electrophoresis of reaction mixtures based on the differing electrophoretic mobilities between various phosphostates of KaiC. As the KaiC phospho-distribution represents only one facet of the oscillations, orthogonal tools are necessary to explore other interactions to generate a full description of the system. However, previous biochemical assays are discontinuous or qualitative. To circumvent these limitations, we developed a spin-labeled KaiB mutant that can differentiate KaiC-bound KaiB from free KaiB using continuous-wave electron paramagnetic resonance spectroscopy that is minimally sensitive to KaiA. Similar to wild-type (WT-KaiB), this labeled mutant, in combination with KaiA, sustains robust circadian rhythms of KaiC phosphorylation. This labeled mutant is hence a functional surrogate of WT-KaiB and thus participates in and reports on autonomous macroscopic circadian rhythms generated by mixtures that include KaiA, KaiC, and ATP. Quantitative kinetics could be extracted with improved precision and time resolution. We describe design principles, data analysis, and limitations of this quantitative binding assay and discuss future research necessary to overcome these challenges.

Published

2020

8. A Novel Regulatory Role for the Circadian Clock Protein TOC1 via RNA binding

Author

Yi Li, Yong-Gang Chang, Dawn H. Nagel, Tingjian Chen, Matias L Rugnone, Andy LiWang, and Steve A. Kay

Subjects

0303 health sciences, biology, Chemistry, Circadian clock, TOC1, Mutant, RNA, 010402 general chemistry, biology.organism_classification, 01 natural sciences, 0104 chemical sciences, Cell biology, 03 medical and health sciences, chemistry.chemical_compound, Arabidopsis, MYB, Transcription factor, DNA, 030304 developmental biology

Abstract

The circadian clock enables plants to predict daily changes of external signals and synchronize them with internal processes, conferring enhanced fitness and growth vigor. The first described Arabidopsis circadian clock protein is TIMING OF CAB EXPRESSION 1 (TOC1), which functions in a transcriptional feedback loop with two myb transcription factors, CIRCADIAN CLOCK-ASSOCIATED 1 (CCA1) and LATE ELONGATED HYPOCOTYL (LHY). Previous studies have shown that TOC1 is a DNA-binding transcriptional repressor of CCA1 and LHY. However, the DNA motifs enriched amongst TOC1 targets share weak sequence similarity and lack consensus, suggesting that TOC1 regulates the expression of its targets through a novel mechanism. Here we show that the TOC1 protein binds directly to RNA via its conserved CCT domain. Using in vitro RNA selection, we identified an RNA motif that is recognized by the TOC1-CCT domain. The TOC1-CCT domain binds to this RNA sequence with nanomolar affinity determined by quantitative electrophoretic mobility shift assays (EMSAs) and isothermal titration calorimetry (ITC). NMR experiments showed that two CCT fragments, CCT533-547 and CCT550-565, use basic residues to bind the RNA motif. Mutational analysis confirmed that lysyl and arginyl residues bind to RNA in a cooperative manner. Furthermore, transiently expressed wildtype and mutant TOC1 in protoplasts demonstrated that RNA binding activity of TOC1 is required for its function as a transcriptional repressor in vivo. Our results reveal a novel regulatory mechanism for TOC1 through RNA binding, suggesting that TOC1 might play key roles as a multi-function protein.

Published

2020

9. Structural analysis of the PTEN:P-Rex2 signalling node reveals how cancer-associated mutations coordinate to hyperactivate Rac1

Author

Michelle L. Halls, James C. Whisstock, Hans Elmlund, Elsa A. Marquez, Srgjan Civciristov, Ralf B. Schittenhelm, Christina M. Lucato, Christina Anne Mitchell, Cheng Huang, Andrew M. Ellisdon, Yong-Gang Chang, and Laura D’Andrea

Subjects

0303 health sciences, biology, Cell growth, Chemistry, PDZ domain, Cancer, RAC1, medicine.disease, Cell biology, 03 medical and health sciences, 0302 clinical medicine, Signalling, biology.protein, medicine, PTEN, Functional studies, 030217 neurology & neurosurgery, 030304 developmental biology, G protein-coupled receptor

Abstract

The PTEN:P-Rex2 complex is one of the most commonly mutated signaling nodes in metastatic cancer. Assembly of the PTEN:P-Rex2 complex inhibits the activity of both proteins, and its dysregulation can drive PI3K-AKT signaling and cell proliferation. Here, using extensive crosslinking mass spectrometry and functional studies, we provide crucial mechanistic insights into PTEN:P-Rex2 complex assembly and co-inhibition. PTEN is anchored to P-Rex2 by interactions between the PTEN PDZ-BM tail and the second PDZ domain of P-Rex2. This interaction bridges PTEN across the P-Rex2 surface, occluding PTEN membrane-binding and PI(3,4,5)P3hydrolysis. Conversely, PTEN both allosterically promotes an autoinhibited P-Rex2 conformation and occludes Gβγ binding and GPCR activation. These insights allow us to define a new gain-of-function class of cancer mutations within the PTEN:P-Rex2 interface that uncouples PTEN inhibition of Rac1 signaling. These findings provide a mechanistic framework to understand the dysregulation of the PTEN:P-Rex2 signaling node in metastatic cancer.

Published

2020

10. Real-Time In Vitro Fluorescence Anisotropy of the Cyanobacterial Circadian Clock

Author

Archana G. Chavan, Joel Heisler, Andy LiWang, and Yong-Gang Chang

Subjects

0301 basic medicine, Fluorophore, Circadian clock, Fluorescence Polarization, Biochemistry, Genetics and Molecular Biology (miscellaneous), cyanobacteria, 03 medical and health sciences, chemistry.chemical_compound, 0302 clinical medicine, Structural Biology, Circadian Clocks, KaiC, circadian clock, Protocol, KaiA, CLOCK Proteins, Iodine clock reaction, Polyacrylamide gel electrophoresis, lcsh:QH301-705.5, Chemistry, phosphorylation, 030104 developmental biology, Mental Health, lcsh:Biology (General), Biophysics, fluorescence, Generic health relevance, protein, Sleep Research, 030217 neurology & neurosurgery, Fluorescence anisotropy, Biotechnology

Abstract

Uniquely, the circadian clock of cyanobacteria can be reconstructed outside the complex milieu of live cells, greatly simplifying the investigation of a functioning biological chronometer. The core oscillator component is composed of only three proteins, KaiA, KaiB, and KaiC, and together with ATP they undergo waves of assembly and disassembly that drive phosphorylation rhythms in KaiC. Typically, the time points of these reactions are analyzed ex post facto by denaturing polyacrylamide gel electrophoresis, because this technique resolves the different states of phosphorylation of KaiC. Here, we describe a more sensitive method that allows real-time monitoring of the clock reaction. By labeling one of the clock proteins with a fluorophore, in this case KaiB, the in vitro clock reaction can be monitored by fluorescence anisotropy on the minutes time scale for weeks.

Published

2019

11. What Time is it? Reconstituting a Cyanobacteria Clock to Time the Gene Expression In Vitro

Author

Archana G. Chavan, Andy LiWang, Yong-Gang Chang, and Joel Heisler

Subjects

Cyanobacteria, biology, Gene expression, Biophysics, biology.organism_classification, In vitro, Cell biology

Published

2020

12. Genome-wide fitness assessment during diurnal growth reveals an expanded role of the cyanobacterial circadian clock protein KaiA

Author

Scott A. Rifkin, Yong-Gang Chang, Susan S. Golden, Andy LiWang, Spencer Diamond, Benjamin E. Rubin, and David G. Welkie

Subjects

0301 basic medicine, Transposable element, genetic structures, 1.1 Normal biological development and functioning, 030106 microbiology, Circadian clock, Biology, Genome, cyanobacteria, 03 medical and health sciences, Bacterial Proteins, Transcription (biology), Underpinning research, KaiC, Circadian Clocks, circadian clock, KaiA, Genetics, Circadian rhythm, Photosynthesis, transposon sequencing, Gene, 030304 developmental biology, 2. Zero hunger, Synechococcus, 0303 health sciences, Multidisciplinary, photosynthesis, 030306 microbiology, Circadian Rhythm Signaling Peptides and Proteins, Cell biology, PNAS Plus, Generic health relevance, Sleep Research, diurnal physiology, Signal Transduction, Genome-Wide Association Study

Abstract

The recurrent pattern of light and darkness generated by Earth’s axial rotation has profoundly influenced the evolution of organisms, selecting for both biological mechanisms that respond acutely to environmental changes and circadian clocks that program physiology in anticipation of daily variations. The necessity to integrate environmental responsiveness and circadian programming is exemplified in photosynthetic organisms such as cyanobacteria, which depend on light-driven photochemical processes. The cyanobacterium Synechococcus elongatus PCC 7942 is an excellent model system for dissecting these entwined mechanisms. Its core circadian oscillator, consisting of three proteins KaiA, KaiB, and KaiC, transmits time-of-day signals to clock-output proteins, which reciprocally regulate global transcription. Research performed under constant light facilitates analysis of intrinsic cycles separately from direct environmental responses, but does not provide insight into how these regulatory systems are integrated during light-dark cycles. Thus, we sought to identify genes that are specifically necessary in a day-night environment. We screened a dense bar-coded transposon library in both continuous light and daily cycling conditions and compared the fitness consequences of loss of each nonessential gene in the genome. Although the clock itself is not essential for viability in light-dark cycles, the most detrimental mutations revealed by the screen were those that disrupt KaiA. The screen broadened our understanding of light-dark survival in photosynthetic organisms, identified unforeseen clock-protein interaction dynamics, and reinforced the role of the clock as a negative regulator of a night-time metabolic program that is essential for S. elongatus to survive in the dark.SignificanceUnderstanding how photosynthetic bacteria respond to and anticipate natural light–dark cycles is necessary for predictive modeling, bioengineering, and elucidating metabolic strategies for diurnal growth. Here, we identify the genetic components that are important specifically under light-dark cycling conditions and determine how a properly functioning circadian clock prepares metabolism for darkness, a starvation period for photoautotrophs. This study establishes that the core circadian clock protein KaiA is necessary to enable rhythmic de-repression of a night-time circadian program.

Published

2018

13. A protein fold switch joins the circadian oscillator to clock output in cyanobacteria

Author

Sheng Li, Susan S. Golden, William K. Myers, Shannon Kang, Connie Phong, Joseph S. Boyd, Andy LiWang, Michael J. Rust, Susan E. Cohen, Li Zhang, Yong Ick Kim, David Lee, Roger Tseng, Yong-Gang Chang, R. David Britt, Yvonne M Lee, and Jenny J. Lin

Subjects

Synechococcus, Cyanobacteria, Protein Folding, Multidisciplinary, biology, Circadian Rhythm Signaling Peptides and Proteins, Circadian clock, A protein, Joins, biology.organism_classification, Article, Protein Structure, Secondary, Circadian Rhythm, Cell biology, Bacterial Proteins, KaiC, KaiA, Circadian rhythm, Active state, Phosphorylation

Abstract

Biochemical basis of a 24-hour clock Circadian clocks keep organisms in synch with such daily cycles as illumination, activity, and food availability. The circadian clock in cyanobacteria has the necessary 24-hour period despite its three component proteins having biochemical activities that occur on a much faster time scale. Abe et al. focused on the cyanobacterial clock component KaiC, an adenosine triphosphatase (ATPase) that can autophosphorylate and autodephosphorylate. The slow ATPase activity of KaiC, which is linked to a peptide isomerisation, provided the slow kinetics that set the speed of the 24-hour clock. Chang et al. found that another clock component, KaiB, also has slow changes in its protein conformation that help to set the oscillation period of the clock and its signaling output. Science , this issue pp. 312 and 324

Published

2015

14. Structural basis of the day-night transition in a bacterial circadian clock

Author

Joel Heisler, Andy LiWang, Yong-Gang Chang, Jansen Luu, Susan S. Golden, Sheng Li, Alicia K. Michael, Sarvind Tripathi, Susan E. Cohen, Carrie L. Partch, Archana G. Chavan, Roger Tseng, and Nicolette F. Goularte

Subjects

0301 basic medicine, General Science & Technology, Nuclear Magnetic Resonance, Circadian clock, Crystallography, X-Ray, Cyanobacteria, Article, 03 medical and health sciences, Adenosine Triphosphate, Bacterial Proteins, Protein Domains, Signaling proteins, KaiC, Sasa, Circadian Clocks, Gene expression, KaiA, Genetics, Nuclear Magnetic Resonance, Biomolecular, Multidisciplinary, Crystallography, Transition (genetics), biology, Circadian Rhythm Signaling Peptides and Proteins, Hydrolysis, A protein, biology.organism_classification, Cell biology, 030104 developmental biology, Biochemistry, X-Ray, Generic health relevance, Protein Multimerization, Sleep Research, Protein Kinases, Biomolecular

Abstract

Molecular clockwork from cyanobacteria The cyanobacterial circadian clock oscillator can be reconstituted in a test tube from just three proteins—KaiA, KaiB, and KaiC—and adenosine triphosphate (ATP). Tseng et al. studied crystal and nuclear magnetic resonance structures of complexes of the oscillator proteins and their signaling output proteins and tested the in vivo effects of structure-based mutants. Large conformational changes in KaiB and ATP hydrolysis by KaiC are coordinated with binding to output protein, which couples signaling and the day-night transitions of the clock. Snijder et al. provide complementary analysis of the oscillator proteins by mass spectrometry and cryo–electron microscopy. Their results help to explain the structural basis for the dynamic assembly of the oscillator complexes. Science , this issue p. 1174 , p. 1181

Published

2017

15. Nuclear Magnetic Resonance Spectroscopy of the Circadian Clock of Cyanobacteria

Author

Roger Tseng, Andy LiWang, Yong-Gang Chang, and Nai-Wei Kuo

Subjects

Cyanobacteria, Magnetic Resonance Spectroscopy, Aqueous solution, Materials science, biology, Circadian Rhythm Signaling Peptides and Proteins, Circadian clock, Plant Science, Nuclear magnetic resonance spectroscopy, biology.organism_classification, Magnetic field, Ionic strength, Chemical physics, Circadian Clocks, Keeping Time During Animal Evolution: Conservation and Innovation of the Circadian Clock, Condensed Matter::Strongly Correlated Electrons, Animal Science and Zoology, Solubility, Spectroscopy

Abstract

The most well-understood circadian clock at the level of molecular mechanisms is that of cyanobacteria. This overview is on how solution-state nuclear magnetic resonance (NMR) spectroscopy has contributed to this understanding. By exciting atomic spin-frac12; nuclei in a strong magnetic field, NMR obtains information on their chemical environments, inter-nuclear distances, orientations, and motions. NMR protein samples are typically aqueous, often at near-physiological pH, ionic strength, and temperature. The level of information obtainable by NMR depends on the quality of the NMR sample, by which we mean the solubility and stability of proteins. Here, we use examples from our laboratory to illustrate the advantages and limitations of the technique.

Published

2013

16. Rhythmic ring–ring stacking drives the circadian oscillator clockwise

Author

Nai-Wei Kuo, Andy LiWang, Yong-Gang Chang, and Roger Tseng

Subjects

Models, Molecular, Magnetic Resonance Spectroscopy, Stereochemistry, Circadian clock, Stacking, Biology, Cyanobacteria, Ring (chemistry), Chromatography, Affinity, Protein structure, Bacterial Proteins, Circadian Clocks, Commentaries, KaiC, Escherichia coli, KaiA, Cloning, Molecular, Phosphorylation, Binding site, Binding Sites, Multidisciplinary, Circadian Rhythm Signaling Peptides and Proteins, Adenosine Diphosphate, Spectrometry, Fluorescence, Domain (ring theory), Chromatography, Gel, Biophysics

Abstract

The oscillator of the circadian clock of cyanobacteria is composed of three proteins, KaiA, KaiB, and KaiC, which together generate a self-sustained ∼24-h rhythm of phosphorylation of KaiC. The mechanism propelling this oscillator has remained elusive, however. We show that stacking interactions between the CI and CII rings of KaiC drive the transition from the phosphorylation-specific KaiC–KaiA interaction to the dephosphorylation-specific KaiC–KaiB interaction. We have identified the KaiB-binding site, which is on the CI domain. This site is hidden when CI domains are associated as a hexameric ring. However, stacking of the CI and CII rings exposes the KaiB-binding site. Because the clock output protein SasA also binds to CI and competes with KaiB for binding, ring stacking likely regulates clock output. We demonstrate that ADP can expose the KaiB-binding site in the absence of ring stacking, providing an explanation for how it can reset the clock.

Published

2012

17. Solution structure of the ubiquitin-associated domain of human BMSC-UbP and its complex with ubiquitin

Author

Donghai Lin, Xiao Jing Lin, Yong-Gang Chang, Yong-Guang Gao, Xuetao Cao, Ai Xin Song, Hong-Yu Hu, and Yan Hong Shi

Subjects

Models, Molecular, Sequestosome-1 Protein, Magnetic Resonance Spectroscopy, Protein Conformation, Recombinant Fusion Proteins, Molecular Sequence Data, Biology, Biochemistry, Article, Protein structure, Bacterial Proteins, Ubiquitin, Humans, Amino Acid Sequence, Ubiquitins, Molecular Biology, Peptide sequence, Adaptor Proteins, Signal Transducing, Binding Sites, C-terminus, Proteins, Molecular biology, Protein Structure, Tertiary, Cell biology, Ubiquitin ligase, DNA-Binding Proteins, Solutions, DNA Repair Enzymes, Mutagenesis, Structural Homology, Protein, biology.protein, Hydrophobic and Hydrophilic Interactions, Software, Binding domain

Abstract

Ubiquitin is an important cellular signal that targets proteins for degradation or regulates their functions. The previously identified BMSC-UbP protein derived from bone marrow stromal cells contains a ubiquitin-associated (UBA) domain at the C terminus that has been implicated in linking cellular processes and the ubiquitin system. Here, we report the solution NMR structure of the UBA domain of human BMSC-UbP protein and its complex with ubiquitin. The structure determination was facilitated by using a solubility-enhancement tag (SET) GB1, immunoglobulin G binding domain 1 of Streptococcal protein G. The results show that BMSC-UbP UBA domain is primarily comprised of three alpha-helices with a hydrophobic patch defined by residues within the C terminus of helix-1, loop-1, and helix-3. The M-G-I motif is similar to the M/L-G-F/Y motifs conserved in most UBA domains. Chemical shift perturbation study revealed that the UBA domain binds with the conserved five-stranded beta-sheet of ubiquitin via hydrophobic interactions with the dissociation constant (KD) of approximately 17 microM. The structural model of BMSC-UbP UBA domain complexed with ubiquitin was constructed by chemical shift mapping combined with the program HADDOCK, which is in agreement with the result from mutagenesis studies. In the complex structure, three residues (Met76, Ile78, and Leu99) of BMSC-UbP UBA form a trident anchoring the domain to the hydrophobic concave surface of ubiquitin defined by residues Leu8, Ile44, His68, and Val70. This complex structure may provide clues for BMSC-UbP functions and structural insights into the UBA domains of other ubiquitin-associated proteins that share high sequence homology with BMSC-UbP UBA domain.

Published

2006

18. Solution structure of the ubiquitin-like domain of human DC-UbP from dendritic cells

Author

Yan-Hong Shi, Hong-Yu Hu, Ai-Xin Song, Xuetao Cao, Yong-Gang Chang, Donghai Lin, Yi-Zi Yu, Shuxun Liu, and Yong-Guang Gao

Subjects

Models, Molecular, Cellular differentiation, Molecular Sequence Data, Static Electricity, Nerve Tissue Proteins, Sequence alignment, Sequence (biology), Biochemistry, NEDD8, Article, Domain (software engineering), Ubiquitin, Amino Acid Sequence, Nuclear Magnetic Resonance, Biomolecular, Ubiquitins, Molecular Biology, biology, Chemistry, C-terminus, Solution structure, Protein Structure, Tertiary, Cell biology, Solutions, biology.protein, Sequence Alignment

Abstract

The previously identified dendritic cell-derived ubiquitin-like protein (DC-UbP) was implicated in cellular differentiation and apoptosis. Sequence alignment suggested that it contains a ubiquitin-like (UbL) domain in the C terminus. Here, we present the solution NMR structure and backbone dynamics of the UbL domain of DC-UbP. The overall structure of the domain is very similar to that of Ub despite low similarity (

Published

2005

19. Identification, expression, and purification of a unique stable domain from human HSPC144 protein

Author

Xiao Jing Lin, Yong-Guang Gao, Donghai Lin, Qiu Hua Hang, Ai Xin Song, Yong-Gang Chang, Yan Hong Shi, and Hong-Yu Hu

Subjects

Spectrometry, Mass, Electrospray Ionization, EGF-like domain, Sequence analysis, Proteolysis, Molecular Sequence Data, Protein domain, Gene Expression, Biology, medicine.disease_cause, Protein Structure, Secondary, EVH1 domain, Escherichia coli, medicine, Humans, Amino Acid Sequence, Nuclear Magnetic Resonance, Biomolecular, Gene, Protein secondary structure, Sequence Homology, Amino Acid, medicine.diagnostic_test, Circular Dichroism, Nuclear Proteins, Molecular biology, Peptide Fragments, Recombinant Proteins, Molecular Weight, Chromatography, Gel, Endopeptidase K, Biotechnology

Abstract

HSPC144 is a newly identified gene in human CD34(+) hematopoietic stem/progenitor cells, In this work. we have expressed and purified the 225-residue protein from Escherichia coli BL21 (DE3) and identified a stable fragment HSPC144-P (residues 44 225) by limited proteolysis method. The HSPC144-P fragment exhibits high stability with a little increase of secondary structure percentage as compared with the full-length protein. We anticipated that the N-terminally truncated protein possesses a more compact structure. By sequence analysis, the proteolytic fragment shares a great similarity with DUF5899 domain. I previously identified domain with unknown function. This novel domain is highly conserved in Thy28 proteins and is worthy of structural and functional studies. We have subcloned this homologous domain from HSPC144 protein and purified to homogeneity for structure analysis. The N-15 and N-15/C-13-labeled DUF589 domain samples have been prepared successfully and determination of the NMR structure is in progress. (c) 2005 Elsevier Inc. All rights reserved.

Published

2005

20. Expression, purification, crystallization and preliminary structural characterization of the GTPase domain of human Rheb

Author

Sheng Li, Yadong Yu, Qiuhua Huang, Yong-Gang Chang, Jianping Ding, and Hong-Yu Hu

Subjects

Subfamily, GTP', Protein Conformation, GTPase, Plasma protein binding, Biology, Crystallography, X-Ray, Catalysis, GTP Phosphohydrolases, Protein structure, Structural Biology, Humans, Cloning, Molecular, PI3K/AKT/mTOR pathway, Monomeric GTP-Binding Proteins, Kinase, X-Rays, Neuropeptides, Brain, General Medicine, Recombinant Proteins, Protein Structure, Tertiary, Biochemistry, biology.protein, Ras Homolog Enriched in Brain Protein, Plasmids, Protein Binding, Signal Transduction, RHEB

Abstract

Ras homologue enriched in brain (Rheb) represents a unique group of small GTPases and shares moderate sequence identity with the Ras/Rap subfamily. It acts downstream of nutrient signalling as the direct target of the tuberous sclerosis complex (TSC) and upstream of mTOR/S6K1/4EBP in the insulin-signalling pathway. The GTPase domain of human Rheb (hRheb) has been recombinantly expressed in Escherichia coli, purified and cocrystallized in complexes with GDP, GTP and GppNHp using the hanging-drop vapour-diffusion method. Crystals of the hRheb-GDP complex belong to space group P2(1)2(1)2(1), with unit-cell parameters a = 44.5, b = 52.3, c = 70.6 A. The hRheb-GppNHp complex crystallized in two crystal forms: one has the same space group and unit-cell parameters as the hRheb-GDP complex and the other belongs to space group C222(1), with unit-cell parameters a = 102.9, b = 99.2, c = 48.0 A. The hRheb-GTP complex also crystallized in two crystal forms: one belongs to space group C222(1), with unit-cell parameters a = 102.4, b = 98.3, c = 47.9 A, and the other belongs to space group P2(1), with unit-cell parameters a = 77.3, b = 47.9, c = 71.9 A, beta = 89.0 degrees. All these crystals diffract X-rays to better than 2.8 A resolution and at least one diffraction data set has been collected for each crystal form using an in-house R-AXIS IV++ diffractometer. Structural studies of hRheb in complexes with various substrates may provide insights into the recognition and specificity of substrate and the catalytic mechanism of mammalian Rhebs and shed light on the biological functions of Rhebs in the mTOR signalling pathway.

Published

2004

21. Cooperative KaiA-KaiB-KaiC interactions affect KaiB/SasA competition in the circadian clock of cyanobacteria

Author

Andy LiWang, Nai-Wei Kuo, Ian Bravo, Abdullah R. Chaudhary, Roger Tseng, Robert Latham, and Yong-Gang Chang

Subjects

Protein subunit, Circadian clock, Molecular Sequence Data, Cooperativity, Biology, Cyanobacteria, Models, Biological, Article, Dephosphorylation, Bacterial Proteins, Structural Biology, KaiC, Sasa, Circadian Clocks, KaiA, Amino Acid Sequence, Phosphorylation, Molecular Biology, Circadian Rhythm Signaling Peptides and Proteins, Phosphotransferases, biology.organism_classification, Biochemistry, Biophysics, Protein Multimerization, Protein Processing, Post-Translational, Protein Binding

Abstract

The circadian oscillator of cyanobacteria is composed of only three proteins, KaiA, KaiB, and KaiC. Together, they generate an autonomous ~24-h biochemical rhythm of phosphorylation of KaiC. KaiA stimulates KaiC phosphorylation by binding to the so-called A-loops of KaiC, whereas KaiB sequesters KaiA in a KaiABC complex far away from the A-loops, thereby inducing KaiC dephosphorylation. The switch from KaiC phosphorylation to dephosphorylation is initiated by the formation of the KaiB-KaiC complex, which occurs upon phosphorylation of the S431 residues of KaiC. We show here that formation of the KaiB-KaiC complex is promoted by KaiA, suggesting cooperativity in the initiation of the dephosphorylation complex. In the KaiA-KaiB interaction, one monomeric subunit of KaiB likely binds to one face of a KaiA dimer, leaving the other face unoccupied. We also show that the A-loops of KaiC exist in a dynamic equilibrium between KaiA-accessible exposed and KaiA-inaccessible buried positions. Phosphorylation at the S431 residues of KaiC shift the A-loops toward the buried position, thereby weakening the KaiA-KaiC interaction, which is expected to be an additional mechanism promoting formation of the KaiABC complex. We also show that KaiB and the clock-output protein SasA compete for overlapping binding sites, which include the B-loops on the CI ring of KaiC. KaiA strongly shifts the competition in KaiB's favor. Thus, in addition to stimulating KaiC phosphorylation, it is likely that KaiA plays roles in switching KaiC from phosphorylation to dephosphorylation, as well as regulating clock output.

Published

2013

22. Genome-wide fitness assessment during diurnal growth reveals an expanded role of the cyanobacterial circadian clock protein KaiA.

Author

Welkie, David G., Rubin, Benjamin E., Yong-Gang Chang, Diamond, Spencer, Rifkin, Scott A., LiWang, Andy, and Golden, Susan S.

Subjects

CYANOBACTERIAL proteins, BIOMECHANICS, CYANOBACTERIA, TRANSPOSONS, PHOTOSYNTHESIS

Abstract

The recurrent pattern of light and darkness generated by Earth's axial rotation has profoundly influenced the evolution of organisms, selecting for both biological mechanisms that respond acutely to environmental changes and circadian clocks that program physiology in anticipation of daily variations. The necessity to integrate environmental responsiveness and circadian programming is exemplified in photosynthetic organisms such as cyanobacteria, which depend on light-driven photochemical processes. The cyanobacterium Synechococcus elongatus PCC 7942 is an excellent model system for dissecting these entwined mechanisms. Its core circadian oscillator, consisting of three proteins, KaiA, KaiB, and KaiC, transmits time-of-day signals to clock-output proteins, which reciprocally regulate global transcription. Research performed under constant light facilitates analysis of intrinsic cycles separately from direct environmental responses but does not provide insight into how these regulatory systems are integrated during light-dark cycles. Thus, we sought to identify genes that are specifically necessary in a day-night environment. We screened a dense bar-coded transposon library in both continuous light and daily cycling conditions and compared the fitness consequences of loss of each nonessential gene in the genome. Although the clock itself is not essential for viability in light-dark cycles, the most detrimental mutations revealed by the screen were those that disrupt KaiA. The screen broadened our understanding of light-dark survival in photosynthetic organisms, identified unforeseen clock-protein interaction dynamics, and reinforced the role of the clock as a negative regulator of a nighttime metabolic program that is essential for S. elongatus to survive in the dark. [ABSTRACT FROM AUTHOR]

Published

2018

23. Flexibility of the C-terminal, or CII, ring of KaiC governs the rhythm of the circadian clock of cyanobacteria

Author

Andy LiWang, Yong-Gang Chang, Roger Tseng, and Nai-Wei Kuo

Subjects

Conformational change, Multidisciplinary, Circadian Rhythm Signaling Peptides and Proteins, Circadian clock, Autophosphorylation, Allosteric regulation, Phosphotransferases, Biology, Biological Sciences, Molecular Dynamics Simulation, Cyanobacteria, Biochemistry, Bacterial Proteins, KaiC, Circadian Clocks, Commentaries, KaiA, Biophysics, Phosphorylation, Circadian rhythm

Abstract

In the cyanobacterial circadian oscillator, KaiA and KaiB alternately stimulate autophosphorylation and autodephosphorylation of KaiC with a periodicity of approximately 24 h. KaiA activates autophosphorylation by selectively capturing the A loops of KaiC in their exposed positions. The A loops and sites of phosphorylation, residues S431 and T432, are located in the CII ring of KaiC. We find that the flexibility of the CII ring governs the rhythm of KaiC autophosphorylation and autodephosphorylation and is an example of dynamics-driven protein allostery. KaiA-induced autophosphorylation requires flexibility of the CII ring. In contrast, rigidity is required for KaiC-KaiB binding, which induces a conformational change in KaiB that enables it to sequester KaiA by binding to KaiA’s linker. Autophosphorylation of the S431 residues around the CII ring stabilizes the CII ring, making it rigid. In contrast, autophosphorylation of the T432 residues offsets phospho-S431-induced rigidity to some extent. In the presence of KaiA and KaiB, the dynamic states of the CII ring of KaiC executes the following circadian rhythm: . Apparently, these dynamic states govern the pattern of phosphorylation, ST → SpT → pSpT → pST → ST. CII-CI ring-on-ring stacking is observed when the CII ring is rigid, suggesting a mechanism through which the ATPase activity of the CI ring is rhythmically controlled. SasA, a circadian clock-output protein, binds to the CI ring. Thus, rhythmic ring stacking may also control clock-output pathways.

Published

2011

24. Structural Gymnastics by Proteins make the Clock Mechanism go Round and Round

Author

David Britt, Jonathan D. Kerby, William K. Myers, Yong-Gang Chang, Roger Tseng, and Andy LiWang

Subjects

Mechanism (engineering), Dephosphorylation, KaiC, Biophysics, KaiA, Phosphorylation, Model system, Circadian rhythm, Biology

Abstract

Endogenous clocks regulate metabolism, physiology and behavior of most organisms in anticipation of daily swings in ambient light and temperature by synchronizing them to a ∼24-h biochemical rhythm. Here, we will show in a model system that structural gymnastics by proteins make the clock mechanism go round and round. The “gears” of the cyanobacterial clock are composed of three proteins, KaiA, KaiB, and KaiC. Remarkably, when they are mixed together in a test tube with ATP, they generate a circadian rhythm of (auto)phosphorylation and (auto)dephosphorylation of the KaiC protein for many days. KaiA stimulates KaiC phosphorylation, whereas KaiB antagonizes KaiA to promote KaiC dephosphorylation. The field has been attempting to crack the mechanism using published crystal structures to model complexes of these proteins. However, we will show that surprisingly large conformational changes (not captured in the crystal structures) determine when and how the KaiABC complexes assemble and disassemble, setting up time steps in the clock. We can also explain how the oscillator is entrained by environmental light/dark cycles, and how the clock transmits timing signals.View Large Image | View Hi-Res Image | Download PowerPoint Slide

Published

2014

25. The KaiA protein of the cyanobacterial circadian oscillator is modulated by a redox-active cofactor

Author

Yong-Gang Chang, Jennifer Bridwell-Rabb, Thammajun L. Wood, David P. Barondeau, Tiyu Gao, Susan S. Golden, Yong Ick Kim, and Andy LiWang

Subjects

Models, Molecular, Circadian clock, Bacterial Proteins, KaiC, KaiA, Circadian rhythm, Binding site, Phosphorylation, Nuclear Magnetic Resonance, Biomolecular, Synechococcus, Multidisciplinary, Binding Sites, biology, Circadian Rhythm Signaling Peptides and Proteins, Protein Stability, Biological Sciences, biology.organism_classification, Recombinant Proteins, Cell biology, Circadian Rhythm, Protein Structure, Tertiary, Dibromothymoquinone, Signal transduction, Protein Multimerization, Oxidation-Reduction, Protein Kinases, Signal Transduction

Abstract

The circadian rhythms exhibited in the cyanobacterium Synechococcus elongatus are generated by an oscillator comprised of the proteins KaiA, KaiB, and KaiC. An external signal that commonly affects the circadian clock is light. Previously, we reported that the bacteriophytochrome-like protein CikA passes environmental signals to the oscillator by directly binding a quinone and using cellular redox state as a measure of light in this photosynthetic organism. Here, we report that KaiA also binds the quinone analog 2,5-dibromo-3-methyl-6-isopropyl- p -benzoquinone (DBMIB), and the oxidized form of DBMIB, but not its reduced form, decreases the stability of KaiA in vivo, causes multimerization in vitro, and blocks KaiA stimulation of KaiC phosphorylation, which is central to circadian oscillation. Our data suggest that KaiA directly senses environmental signals as changes in redox state and modulates the circadian clock.

Published

2010

26. Different roles for two ubiquitin-like domains of ISG15 in protein modification

Author

Xian Zhong Yan, Xue Chao Gao, Yuanyuan Xie, Yong-Gang Chang, Ai Xin Song, Dong-Er Zhang, and Hong-Yu Hu

Subjects

Magnetic Resonance Spectroscopy, Plasma protein binding, Ubiquitin-Activating Enzymes, Viral Nonstructural Proteins, Biochemistry, Cell Line, Substrate Specificity, Ubiquitin, Interferon, medicine, Humans, Amino Acid Sequence, Molecular Biology, Peptide sequence, Gene, Ubiquitins, chemistry.chemical_classification, biology, Titrimetry, Cell Biology, ISG15, Ubiquitin ligase, Cell biology, Enzyme, chemistry, Ubiquitin-Conjugating Enzymes, biology.protein, Cytokines, Protein Processing, Post-Translational, medicine.drug, Protein Binding

Abstract

ISG15 (interferon-stimulated gene 15) is a novel ubiquitin-like (UbL) modifier with two UbL domains in its architecture. We investigated different roles for the two UbL domains in protein modification by ISG15 (ISGylation) and the impact of Influenza B virus NS1 protein (NS1B) on regulation of the pathway. The results show that, although the C-terminal domain is sufficient to link ISG15 to UBE1L and UbcH8, the N-terminal domain is dispensable in the activation and transthiolation steps but required for efficient E3-mediated transfer of ISG15 from UbcH8 to its substrates. NS1B specifically binds to the N-terminal domain of ISG15 but does not affect ISG15 linkage via a thioester bond to its activating and conjugating enzymes. However, it does inhibit the formation of cellular ISG15 conjugates upon interferon treatment. We propose that the N-terminal UbL domain of ISG15 mainly functions in the ligation step and NS1B inhibits ISGylation by competing with E3 ligases for binding to the N-terminal domain.

Published

2008

27. Structural insights into the specific binding of huntingtin proline-rich region with the SH3 and WW domains

Author

Yong-Gang Chang, Xian Zhong Yan, Ai Xin Song, Nan Jiang, Yong-Guang Gao, Qi Zhang, Xue Chao Gao, and Hong-Yu Hu

Subjects

Models, Molecular, congenital, hereditary, and neonatal diseases and abnormalities, Huntingtin, Magnetic Resonance Spectroscopy, Proline, PROTEINS, Protein Conformation, Molecular Sequence Data, Nerve Tissue Proteins, Plasma protein binding, Biology, MOLNEURO, SH3 domain, src Homology Domains, Protein structure, Imaging, Three-Dimensional, Structural Biology, mental disorders, Huntingtin Protein, Humans, Amino Acid Sequence, Binding site, Molecular Biology, Peptide sequence, Genetics, Binding Sites, C-terminus, Nuclear Proteins, nervous system diseases, Cell biology, Protein Structure, Tertiary, Spin Labels, Peptides, Protein Binding

Abstract

SummaryThe interactions of huntingtin (Htt) with the SH3 domain- or WW domain-containing proteins have been implicated in the pathogenesis of Huntington's disease (HD). We report the specific interactions of Htt proline-rich region (PRR) with the SH3GL3-SH3 domain and HYPA-WW1-2 domain pair by NMR. The results show that Htt PRR binds with the SH3 domain through nearly its entire chain, and that the binding region on the domain includes the canonical PxxP-binding site and the specificity pocket. The C terminus of PRR orients to the specificity pocket, whereas the N terminus orients to the PxxP-binding site. Htt PRR can also specifically bind to WW1-2; the N-terminal portion preferentially binds to WW1, while the C-terminal portion binds to WW2. This study provides structural insights into the specific interactions between Htt PRR and its binding partners as well as the alteration of these interactions that involve PRR, which may have implications for the understanding of HD.

Published

2006

28. 1H, 13C and 15N backbone resonance assignments of the DUF589 domain from human HSPC144 protein

Author

Hong-Yu Hu, Donghai Lin, Yan Hong Shi, Yong-Gang Chang, and Ai Xin Song

Subjects

Carbon Isotopes, Nitrogen Isotopes, Stereochemistry, Chemistry, Resonance, Nuclear Proteins, Biochemistry, Peptide Fragments, Domain (software engineering), Nuclear magnetic resonance, Animals, Humans, Amino Acid Sequence, Nuclear protein, Amino Acids, Chickens, Nuclear Magnetic Resonance, Biomolecular, Spectroscopy, Conserved Sequence, Hydrogen

Published

2006

29. Structural basis of the day-night transition in a bacterial circadian clock.

Author

Tseng, Roger, Goularte, Nicolette F., Chavan, Archana, Jansen Luu, Cohen, Susan E., Yong-Gang Chang, Heisler, Joel, Sheng Li, Michael, Alicia K., Tripathi, Sarvind, Golden, Susan S., Andy LiWang, and Partch, Carrie L.

Published

2017

30. Effects of segment substitution on the structure and stability of immunoglobulin G binding domain of streptococcal protein G

Author

Donghai Lin, Hong-Yu Hu, Hai-Ning Du, Tie Ying Zhang, and Yong-Gang Chang

Subjects

Protein Folding, biology, Chemistry, Recombinant Fusion Proteins, Organic Chemistry, Substitution (logic), Molecular Sequence Data, Biophysics, Sequence (biology), General Medicine, Biochemistry, Protein tertiary structure, Immunoglobulin G, Protein Structure, Secondary, Protein Structure, Tertiary, Biomaterials, Crystallography, Bacterial Proteins, Streptococcal protein G, biology.protein, Protein folding, Amino Acid Sequence, Beta (finance), Binding domain

Abstract

Structural formation of segments plays pivotal roles in protein folding and stability, but how the segment influences the structural ensemble remains elusive. We engineered two hybrid-proteins by replacing the central helical segment of immunoglobulin G binding domain of streptococcal protein G with an alpha-helix or beta(2)-strand element of a structural homologue, the immunoglobulin G binding domain of streptococcal protein L. The results show that substitution by the a-helical sequence retains a folded structure predominantly with a three-stranded beta-sheet but slightly destabilizes the compact ensemble, while substitution by the beta(2)-strand sequence completely destroys the structural formation. The finding implies that the local segment may influence the tertiary structure and overall stability, and the tertiary interactions may modulate structural formation of the segment, which might be considered when studying protein folding, prediction, design, and engineering. (c) 2005 Wiley Periodicals, Inc.

Published

2005

31. How do Three Proteins Generate Circadian Rhythms? The Detailed Timing Mechanism of the Cyanobacterial Circadian Oscillator

Author

Andy LiWang, Yong-Gang Chang, Roger Tseng, and Jonathan D. Kerby

Subjects

0303 health sciences, Circadian clock, Biophysics, Biology, Cell biology, Dephosphorylation, 03 medical and health sciences, 0302 clinical medicine, Biochemistry, KaiC, KaiA, Phosphorylation, CLOCK Proteins, Circadian rhythm, 030217 neurology & neurosurgery, Function (biology), 030304 developmental biology

Abstract

Virtually all organisms contain a circadian clock that regulates gene expression, metabolic pathway and cell division. These regulations enhance the fitness of organisms by anticipating daily changes. To generate a clock, a stable oscillation must be maintained. Thus, we focus on understanding how molecular components form an oscillator which drives a biological clock.To study clock mechanism in detail, we use the cyanobacterial oscillator because it is the only system that can be functionally reconstituted in a test tube. Mixing three clock proteins, KaiA, KaiB, and KaiC, and ATP produces a robust 24-hour rhythm of KaiC phosphorylation/dephosphorylation. All other oscillators are difficult to study at the mechanistic level because they cannot be isolated from the complex milieu of living cells.This oscillator has two distinct phases: 1) in Phosphorylation Phase, KaiA binds to the C-terminal residues of KaiC known as the A-loop and stimulates KaiC phosphorylation; 2) in Dephosphorylation Phase, KaiA is inhibited from binding to A-loop by KaiB, then KaiC dephosphorylates.Our central hypothesis is that the KaiA binding site on KaiC (i.e. A-loop) experiences a range of dynamic changes that drive preferential KaiA-KaiC interaction which is critical to the rhythm. Here we will present our latest findings of this unique oscillator to gain a deep mechanistic insight into how these three proteins form transient and time-dependent interactions that are central to the function of this oscillator.

Published

2013

32. A protein fold switch joins the circadian oscillator to clock output in cyanobacteria.

Author

Yong-Gang Chang, Cohen, Susan E., Phong, Connie, Myers, William K., Yong-Ick Kim, Tseng, Roger, Lin, Jenny, Li Zhang, Boyd, Joseph S., Yvonne Lee, Kang, Shannon, Lee, David, Sheng Li, Britt, R. David, Rust, Michael J., Golden, Susan S., and LiWang, Andy

Subjects

*CIRCADIAN rhythms, *PROTEIN folding, *PHOSPHORYLATION, *CELL communication, *PROTEIN binding, *GENETICS of circadian rhythms, *THERMOSYNECHOCOCCUS elongatus, *SYNECHOCOCCUS elongatus, *CYANOBACTERIA

Abstract

Organisms are adapted to the relentless cycles of day and night, because they evolved timekeeping systems called circadian clocks, which regulate biological activities with ~24-hour rhythms. The clock of cyanobacteria is driven by a three-protein oscillator composed of KaiA, KaiB, and KaiC, which together generate a circadian rhythm of KaiC phosphorylation. We show that KaiB flips between two distinct three-dimensional folds, and its rare transition to an active state provides a time delay that is required to match the timing of the oscillator to that of Earth's rotation. Once KaiB switches folds, it binds phosphorylated KaiC and captures KaiA, which initiates a phase transition of the circadian cycle, and it regulates components of the clock-output pathway, which provides the link that joins the timekeeping and signaling functions of the oscillator. [ABSTRACT FROM AUTHOR]

Published

2015

33. Flexibility of the C-terminal, or CII, ring of KaiC governs the rhythm of the circadian clock of cyanobacteria.

Author

Yong-Gang Chang, Nai-Wei Kuo, Tseng, Roger, and LiWang, Andy

Subjects

*CYANOBACTERIA, *PHOSPHORYLATION, *ADENOSINE triphosphatase, *CIRCADIAN rhythms, *CYCLES, *ALGAE

Abstract

In the cyanobacterial circadian oscillator, KaiA and KaiB alternately stimulate autophosphorylation and autodephosphorylation of KaiC with a periodicity of approximately 24 h. KaiA activates autophosphorylation by selectively capturing the A loops of KaiC in their exposed positions. The A loops and sites of phosphorylation, residues S431 and T432, are located in the CII ring of KaiC. We find that the flexibility of the CII ring governs the rhythm of KaiC autophosphorylation and autodephosphorylation and is an example of dynamics-driven protein allostery. KaiA-induced autophosphorylation requires flexibility of the CII ring. In contrast, rigidity is required for KaiC-KaiB binding, which induces a conformational change in KaiB that enables it to sequester KaiA by binding to KaiA's linker. Autophosphorylation of the S431 residues around the CII ring stabilizes the CII ring, making it rigid. In contrast, autophosphorylation of the T432 residues offsets phospho-S431-induced rigidity to some extent. In the presence of KaiA and KaiB, the dynamic states of the CII ring of KaiC executes the following circadian rhythm: CIISTflexible → CIISpTflexible → CIIpSpTrigid → CIIpSTvery-rigid → CIISTflexible. Apparently, these dynamic states govern the pattern of phosphorylation, ST → SpT → pSpT → pST → ST. CII-CI ring-on-ring stacking is observed when the CII ring is rigid, suggesting a mechanism through which the ATPase activity of the CI ring is rhythmically controlled. SasA, a circadian clock-output protein, binds to the CI ring. Thus, rhythmic ring stacking may also control clock-output pathways. [ABSTRACT FROM AUTHOR]

Published

2011

34. The KaiA protein of the cyanobacterial circadian oscillator is modulated by a redox-active cofactor.

Author

Wood, Thammajun L., BridweII-Rabb, Jennifer, Yong-Ick Kim, Gao, Tiyu, Yong-Gang Chang, LiWang, Andy, Barondeau, David R., and Golden, Susan S.

Subjects

CYANOBACTERIA physiology, PHYSIOLOGICAL effects of light, QUINONE, PHOSPHORYLATION, OSCILLATING chemical reactions

Abstract

The circadian rhythms exhibited in the cyanobacterium Synechococcus elongatus are generated by an oscillator comprised of the proteins KaiA, KaiB. and KaiC. An external signal that commonly affects the circadian clock is light. Previously, we reported-that the bacteriophytochrome-like protein CikA passes environmental signals to the oscillator by directly binding a quinone and using cellular redox state as a measure of light in this photosynthetic organism. Here, we report that KaiA also binds the quinone analog 2,5-dibromo-3-methyl-6-isopropyl-p-benzoquinone (DBMIB), and the oxidized form of DBMJB, but not its reduced form, decreases the stability of KaiA in vivo, causes multimerization in vitro, and blocks KaiA stimulation of KaiC phosphorylation, which us central to circadian oscillation. Our data suggest that KaiA directly senses environmental signals as changes in redox state and modulates the circadian clock. [ABSTRACT FROM AUTHOR]

Published

2010

35. Different Roles for Two Ubiquitin-like Domains of ISG15 in Protein Modification.

Author

Yong-Gang Chang, Xian-Zhong Yan, Yuan-Yuan Xie, Xue-Chao Gao, Ai-Xin Song, Dong-Er Zhang, and Hong-Yu Hu

Subjects

*GLYCOPROTEINS, *PROTEINS, *ENZYMES, *INFLUENZA, *UBIQUITIN, *LIGASES, *INTERFERONS, *VIRUSES, *CELLS

Abstract

ISG15 (interferon-stimulated gene 15) is a novel ubiquitin-like (UbL) modifier with two UbL domains in its architecture. We investigated different roles for the two UbL domains in protein modification by ISG15 (ISGylation) and the impact of Influenza B virus NS1 protein (NS1B) on regulation of the pathway. The results show that, although the C-terminal domain is sufficient to link ISG15 to UBE1L and UbcH8, the N-terminal domain is dispensable in the activation and transthiolation steps but required for efficient E3-mediated transfer of ISG15 from UbcH8 to its substrates. NS1B specifically binds to the N-terminal domain of ISG15 but does not affect ISG15 linkage via a thioester bond to its activating and conjugating enzymes. However, it does inhibit the formation of cellular ISG15 conjugates upon interferon treatment. We propose that the N-terminal UbL domain of ISG15 mainly functions in the ligation step and NS1B inhibits ISGylation by competing with E3 ligases for bind- ing to the N-terminal domain. [ABSTRACT FROM AUTHOR]

Published

2008