Yong Gang Chang scite author profile

The oscillator of the circadian clock of cyanobacteria is composed of three proteins, KaiA, KaiB, and KaiC, which together generate a selfsustained ∼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.dynamic allostery | NMR | protein structure | kinase | kinetics

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

Chang

Kuo

Tseng

et al. 2011

Proc. Natl. Acad. Sci. U.S.A.

144

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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: CII ST flexible → CII SpT flexible → CII pSpT rigid → CII pST very-rigid → CII ST flexible . 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.

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

Wood¹,

Bridwell‐Rabb

Kim

et al. 2010

Proc. Natl. Acad. Sci. U.S.A.

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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.

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Highly efficient expression and purification system of small-size protein domains in Escherichia coli for biochemical characterization

Bao

Gao

Chang

et al. 2006

Protein Expression and Purification

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

Chang

Yan

Xie

et al. 2008

Journal of Biological Chemistry

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ISG15 (interferon-stimulated gene 15) is a novel ubiquitinlike (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.ISG15 (interferon-stimulated gene 15) is highly induced and conjugated to a large number of cellular proteins upon Type I interferon (IFN) 3 treatment (1, 2). ISG15 protein belongs to the family of ubiquitin-like (UbL) modifiers whose members are capable of forming conjugates to cellular proteins (3). Similar to the ubiquitination pathway, the ISG15 modification or ISGylation process involves the concerted action of a set of enzymes: the activating (UBE1L), conjugating (UbcH8), and ligating enzymes (4 -8). However, ISG15 is distinct from other members of the UbLs, such as SUMO and NEDD8 that contain one single UbL domain, in that it possesses two tandem UbL domains. Another two-UbL domain-containing protein, FAT10, can modify a very limited number of as-yet-unidentified proteins and has been associated with apoptosis (9, 10). In contrast, ISG15 in response to Type I IFN stimulation is potent in modifying a wide array of cellular proteins that have such diverse roles as RNA splicing, antiviral ability, cytoskeleton regulation, and signal transduction (7,11,12). Recently, ISG15 has been shown to be a critical component in IFN-mediated inhibition of human immunodeficiency virus, type 1 release (13). Furthermore, it has also been demonstrated to be a critical antiviral molecule against influenza, herpes, and Sindbis viruses (14, 15). Given that ISG15 possesses the antiviral property, it is not surprising that the Influenza B virus has developed a strategy to block the ISG15 modification of cellular proteins through its nonstructural protein NS1 (NS1B) (4).To explore the respective roles of the two UbL domains of ISG15, we carried out a series of biochemical experiments to study their specific functions in ISGylation pathway as well as to elucidate the molecular mechanism by which NS1B inhibits ISG15 conjugation to cellular proteins. EXPERIMENTAL PROCEDURES Generation of Expression Constructs and Protein Purification-The encoding sequences for UBE1L, NS1B-1-103, NS1B-1-90, NS1B-91-103, ISG15, and its two separate domains, I...

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Solution structure of the ubiquitin‐associated domain of human BMSC‐UbP and its complex with ubiquitin

et al. 2006

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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 a-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 b-sheet of ubiquitin via hydrophobic interactions with the dissociation constant (K D) of ;17 mM. 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.

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Structural Insights into the Specific Binding of Huntingtin Proline-Rich Region with the SH3 and WW Domains

et al. 2006

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The 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.

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

Heisler

Chavan

Chang

et al. 2019

MPs

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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.

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Yong Gang Chang

Rhythmic ring–ring stacking drives the circadian oscillator clockwise

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

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

Highly efficient expression and purification system of small-size protein domains in Escherichia coli for biochemical characterization

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

Solution structure of the ubiquitin‐associated domain of human BMSC‐UbP and its complex with ubiquitin

Structural Insights into the Specific Binding of Huntingtin Proline-Rich Region with the SH3 and WW Domains

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

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