Your search keyword '"Liu, Maili"' showing total 6 results

1. Solution structure of the DNA binding domain of Arabidopsis transcription factor WRKY11.

Author

Wang, Jiannan, Lin, Yaling, Yang, Ju, Zhang, Qiang, Liu, Maili, Hu, Yunfei, and Dong, Xu

Subjects

*DNA structure, *TRANSCRIPTION factors, *PLANT proteins, *ARABIDOPSIS, *NUCLEAR magnetic resonance spectroscopy, *ZINC-finger proteins

Abstract

The Arabidopsis WRKY11 (AtWRKY11) protein is an important transcription factor involved in plant response to biotic and abiotic stresses. Its DNA-binding domain specifically binds to gene promoter regions harboring the W-box consensus motif. Herein we report the high-resolution structure of the AtWRKY11 DNA-binding domain (DBD) determined by solution NMR spectroscopy. The results show that AtWRKY11-DBD adopts an all-β fold comprising five β-strands packed in an antiparallel topology, stabilized by a zinc-finger motif. Structural comparison reveals that the long β 1 -β 2 loop shows the highest structural variation from other available WRKY domain structures. Moreover, this loop was further found to contribute to the binding between AtWRKY11-DBD and W-box DNA. Our current study provides atomic-level structural basis for further understanding the structure-function relationship of plant WRKY proteins. • This is the first structure reported for the IId subgroup of the WRKY superfamily. • The β1-β2 loop region of AtWRKY11-DBD shows high variation among other WRKY proteins. • The DNA-binding site on AtWRKY11 involves not only the consensus WRKY motif, but also the aforementioned β1-β2 loop region. • Our model of the AtWRKY11-DNA complex suggests the possible roles of the β1-β2 loop in binding DNA. [ABSTRACT FROM AUTHOR]

Published

2023

2. Mutation of two residues converts the ligand-binding domain of RXRα into a uniform monomer without impairing the binding of retinoic acid and cofactors.

Author

Wang, Ru, Yue, Xiali, Zhu, Jiang, Hu, Rui, Li, Ying, Yang, Yunhuang, and Liu, Maili

Subjects

*RETINOID X receptors, *TRETINOIN, *MONOMERS, *HETERODIMERS, *RECOMBINANT proteins, *LIGAND binding (Biochemistry)

Abstract

Retinoid X receptor (RXRα) is a nuclear receptor (NR) for retinoic acid (RA) and regulates various NR signaling pathways. Ligand-binding domain (LBD) of RXRα can bind with its ligand 9-cis-RA and cofactors, and mediate the forming of homodimer and homotetramer of RXRα and its heterodimer with other NRs, conferring RXRα the ability to play complicated roles in development and diseases. Due to the coexistence of monomer, dimer and tetramer, there are difficulties to study the structure and interaction of RXRα-LBD with its ligands and cofactors in solution and to distinguish the roles of different forms of RXRα in cell. Here, through analyzing available structures of RXRα-LBD, we selected two residues, D379 and L420, in the homodimer interface to design three mutants of RXRα-LBD. Recombinant proteins of the three mutants showed decreased proportions of dimer and tetramer but unchanged overall structure and binding affinities to 9-cis-RA, corepressor SMRT, and coactivator SRC2. Especially, the double-site mutant RXRα-LBDD379A−L420G existed as a uniform monomer. Furthermore, L420 was found to play a similar role in forming RXRα-LBD homodimer and its heterodimer with various NRs, while the role of D379 varies a lot, as it shows almost no interaction with RARα/β, LXRα/β, and THRα/β. This study provides a new insight into the mechanism for forming RXRα-LBD homodimer and its heterodimer with other NRs, and will facilitate the studies on the structure and interaction of RXRα-LBD with ligands, cofactors and drugs in solution, and the broad physiological functions of RXRα cooperating with various NRs in cell. • Mutation of D379 or L420 can destabilize the homodimer of RXRα-LBD. • Double-site mutant of D379 and L420 exists as a uniform monomer. • Mutation of D379 and L420 does not change the binding to RA and cofactors. • Mutation of L420 impairs the interaction of RXRα-LBD with RARα-LBD. • D379 plays little role in the interaction of RXRα-LBD with RARα-LBD. [ABSTRACT FROM AUTHOR]

Published

2023

3. Mutation of leucine 20 causes a change of local conformation indirectly impairing the DNA binding of SP_0782 from Streptococcus pneumoniae.

Author

Gong, Yixuan, Li, Shuangli, Li, Ying, Zhu, Jiang, Yang, Yunhuang, and Liu, Maili

Subjects

*STREPTOCOCCUS pneumoniae, *LEUCINE, *DNA-binding proteins, *DNA, *SINGLE-stranded DNA, *CIRCULAR dichroism

Abstract

SP_0782 from Streptococcus pneumoniae is a dimeric PC4-like protein binding single-stranded DNA (ssDNA), and is potentially involved in maintenance of genome stability and natural transformation. SP_0782 binds with different lengths of ssDNA in various patterns through accommodating nucleotides differently in its two DNA-binding regions (DBRs). Here, we report the characterization of a novel site, leucine 20 (L20), which is not located in the DBRs but impairs the DNA binding when mutated to alanine (L20A). The L20A mutation markedly reduced the DNA-binding affinity of SP_0782 for ssDNA dT19G1, and affected the formation of high-order SP_0782:dT19G1 complexes. The side chain of L20 shows interactions with several residues at the backside of the DBRs in apo SP_0782 structure, and the L20A mutation led to a change of circular dichroism (CD) spectrum and broad chemical shift perturbations (CSPs) in NMR spectrum compared with the wild type. The most affected residues in NMR spectrum included F39 and R49 located in DBR2, as well as K60 in DBR1, which was suggested to be important for cooperative binding of ssDNA by the two subunits in SP_0782 dimer. Thus, the L20A mutation caused a local conformational change of SP_0782, which exerted an indirect effect on the DNA-binding interface and therefore impaired the affinity for ssDNA dT19G1. Interestingly, this L20 site is conserved in bacterial but not eukaryotic PC4-like proteins, suggesting an evolutionary divergence. This study provides an insight into the structure-function relationship of SP_0782, and an amino-acid site probably targeted for inhibiting bacteria selectively. • L20A mutation markedly impairs the binding affinity of SP_0782 for dT19G1. • L20A mutation changes the local conformation of SP_0782. • L20A mutation exerts an indirect effect on the DNA-binding interface of SP_0782. • The L20 site is conserved in bacterial but not eukaryotic PC4-like proteins. [ABSTRACT FROM AUTHOR]

Published

2020

4. Rational modulation of the enzymatic intermediates for tuning the phosphatase activity of histidine kinase HK853.

Author

Ji, Shixia, Luo, Liang, Li, Conggang, Liu, Maili, Liu, Yixiang, and Jiang, Ling

Subjects

*CELLULAR signal transduction, *DRUG design, *BACTERIAL diseases, *HISTIDINE, *THERMOTOGA maritima, *PHOSPHATASES, *CONFORMATIONAL analysis

Abstract

Histidine kinase (HK) of two-component signal transduction system (TCS) is a potential drug target for treating bacterial infections, and most HKs are bifunctional. We have previously identified the HXXXT motif of HK in HisKA subfamily to perform the phosphatase activity, but the specific working mechanism of the threonine is not well understood. In this paper, we use the phosphate group analog BeF 3 − to capture the enzymatic intermediates between HK853 and RR468 from Thermotoga maritima during dephosphorylation, and demonstrate that the T264 site is essential for populating capable near attack conformers (NAC) between enzyme and substrate to facilitate catalysis. Importantly, mutations at this site can modulate the phosphatase activity of HK. Our results help to understand the TCS signal transduction mechanisms and provide a reference for drug design. • Capture the intermediate state of HK853 enzymatic reaction. • Construct HK853 mutants with different activities based on near attack conformation theory. • Clarify the cooperation between T and H in the H×××T motif. • Elucidate the important role of T264 in the formation of near attack conformation. [ABSTRACT FROM AUTHOR]

Published

2020

5. Solution NMR structure and ligand identification of human Gas7 SH3 domain reveal a typical SH3 fold but a non-canonical ligand-binding mode.

Author

Nie, Yao, Zhu, Jiang, Ramelot, Theresa A., Kennedy, Michael A., Liu, Maili, He, Ting, and Yang, Yunhuang

Subjects

*LIGAND binding (Biochemistry), *NEURAL development, *CELL physiology, *ALZHEIMER'S disease, *IDENTIFICATION

Abstract

Growth arrest specific 7 (Gas7) protein is a cytoskeleton regulator playing a crucial role in neural cell development and function, and has been implicated in Alzheimer disease, schizophrenia and cancers. In human, three Gas7 isoforms can be expressed from a single Gas7 gene, while only the longest isoform, hGas7c, possesses an SH3 domain at the N-terminus. To date, the structure and function of hGas7 SH3 domain are still unclear. Here, we reported the solution NMR structure of hGas7 SH3 domain (hGas7-SH3), which displays a typical SH3 β-barrel fold comprising five β-strands and one 3 10 -helix. Structural and sequence comparison showed that hGas7-SH3 shares high similarity with Abl SH3 domain, which binds to a high-affinity proline-rich peptide P41 in a canonical SH3-ligand binding mode through two hydrophobic pockets and a specificity site in the RT-loop. However, unlike Abl-SH3, only six residues in the RT-loop and two residues adjacent to but not in the two hydrophobic pockets of hGas7-SH3 showed significant chemical shift perturbations in NMR titrations, suggesting a low affinity and a non-canonical binding mode of hGas7-SH3 for P41. Furthermore, four peptides selected from phage-displayed libraries also bound weakly to hGas7-SH3, and the binding region of hGas7-SH3 was mainly located in the RT-loop as well. The ligand identifications through structural similarity searching and peptide library screening in this study imply that although hGas7-SH3 adopts a typical SH3 fold, it probably possesses distinctive ligand-binding specificity. • Human Gas7 SH3 domain adopts a typical SH3 β-barrel fold. • hGas7-SH3 exhibits highly structural similarity with Abl SH3 domain. • hGas7-SH3 binds weakly with peptide P41 and the peptides selected via phage display. • The RT-loop of hGas7-SH3 is important for ligand binding. • hGas7-SH3 may bind with ligands through a non-canonical mode. [ABSTRACT FROM AUTHOR]

Published

2019

6. Structural insights into the impact of two holoprosencephaly-related mutations on human TGIF1 homeodomain.

Author

Zhu, Jiang, Li, Shuangli, Ramelot, Theresa A., Kennedy, Michael A., Liu, Maili, and Yang, Yunhuang

Subjects

*CIRCULAR dichroism, *HOMEOBOX proteins, *GENETIC mutation, *CHEMICAL shift (Nuclear magnetic resonance), *SUBSTITUENTS (Chemistry)

Abstract

Abstract Human protein TGIF1 is an essential regulator of cell fate with broad roles in different tissues, and has been implicated in holoprosencephaly (HPE) and many cancers. The function of TGIF1 in transcriptional regulation depends on its three-amino acid loop extension (TALE) type of homeodomain (HD). Two missense mutations that led to P192A and R219C substitutions in TGIF1-HD were previously found in HPE patients and suggested to be the causes for these cases. However, how these mutations affected TGIF1 function has not been investigated from a structural view. Here, we investigated the roles of P192 and R219 in TGIF1-HD structure packing through determining the NMR structure of TGIF1-HD. Surprisingly, P192 and R219 were found to play roles in packing α1 and α2 to α3 together with A190 and F215 through side-chain interactions. Circular dichroism (CD) showed that P192A and R219C mutants displayed structural change and less folding compared with wild-type TGIF1-HD, and 1H-15N HSQC spectrum of P192A mutant exhibited chemical shift perturbations in all three helices of TGIF1-HD. Thus, it is suggested that P192A and R219C mutations led to structure disturbances of TGIF1-HD, which subsequently reduced the DNA-binding affinity of TGIF1-HD by 23-fold and 10-fold respectively, as revealed by the isothermal titration calorimetry (ITC) experiments. Our study provides structural insights of the probable pathogenesis mechanism of two TGIF1-related HPE cases, and evidences for the roles of P192 and R219 in HD folding. Highlights • HPE-related mutations P129A and R219C impair DNA affinity of TGIF1 homeodomain. • P192 and R219 play roles in packing α1 and α2 to α3 in TGIF1 homeodomain. • P129A and R219C lead to structural change and less folding of TGIF1 homeodomain. • P192A results in chemical shift perturbations in all three helices of TGIF1 homeodomain. [ABSTRACT FROM AUTHOR]

Published

2018