Your search keyword '"DEY, RAJA"' showing total 4 results

1. Structural Insights into the Induced-fit Inhibition of Fascin by a Small-Molecule Inhibitor.

Author

Huang, Jianyun, Dey, Raja, Wang, Yufeng, Jakoncic, Jean, Kurinov, Igor, and Huang, Xin-Yun

Subjects

*SMALL molecules, *METASTASIS, *CANCER-related mortality, *CANCER cell migration, *FILOPODIA

Abstract

Tumor metastasis is responsible for ~ 90% of all cancer deaths. One of the key steps of tumor metastasis is tumor cell migration and invasion. Filopodia are cell surface extensions that are critical for tumor cell migration. Fascin protein is the main actin-bundling protein in filopodia. Small-molecule fascin inhibitors block tumor cell migration, invasion, and metastasis. Here we present the structural basis for the mechanism of action of these small-molecule fascin inhibitors. X-ray crystal structural analysis of a complex of fascin and a fascin inhibitor shows that binding of the fascin inhibitor to the hydrophobic cleft between the domains 1 and 2 of fascin induces a ~ 35 o rotation of domain 1, leading to the distortion of both the actin-binding sites 1 and 2 on fascin. Furthermore, the crystal structures of an inhibitor alone indicate that the conformations of the small-molecule inhibitors are dynamic. Mutations of the inhibitor-interacting residues decrease the sensitivity of fascin to the inhibitors. Our studies provide structural insights into the molecular mechanism of fascin protein function as well as the action of small-molecule fascin inhibitors. [ABSTRACT FROM AUTHOR]

Published

2018

2. Structure of the MADS-box/MEF2 Domain of MEF2A Bound to DNA and Its Implication for Myocardin Recruitment

Author

Wu, Yongqing, Dey, Raja, Han, Aidong, Jayathilaka, Nimanthi, Philips, Michael, Ye, Jun, and Chen, Lin

Subjects

*PROTEIN structure, *DNA-protein interactions, *MUSCLE cells, *GENE expression, *TRANSCRIPTION factors, *X-ray crystallography, *LIGAND binding (Biochemistry), *DRUG development

Abstract

Abstract: Myocyte enhancer factor 2 (MEF2) regulates specific gene expression in diverse developmental programs and adaptive responses. MEF2 recognizes DNA and interacts with transcription cofactors through a highly conserved N-terminal domain referred to as the MADS-box/MEF2 domain. Here we present the crystal structure of the MADS-box/MEF2 domain of MEF2A bound to DNA. In contrast to previous structural studies showing that the MEF2 domain of MEF2A is partially unstructured, the present study reveals that the MEF2 domain participates with the MADS-box in both dimerization and DNA binding as a single domain. The sequence divergence at and immediately following the C-terminal end of the MEF2 domain may allow different MEF2 dimers to recognize different DNA sequences in the flanking regions. The current structure also suggests that the ligand-binding pocket previously observed in the Cabin1–MEF2B–DNA complex and the HDAC9 (histone deacetylase 9)–MEF2B–DNA complex is not induced by cofactor binding but rather preformed by intrinsic folding. However, the structure of the ligand-binding pocket does undergo subtle but significant conformational changes upon cofactor binding. On the basis of these observations, we generated a homology model of MEF2 bound to a myocardin family protein, MASTR, that acts as a potent coactivator of MEF2-dependent gene expression. The model shows excellent shape and chemical complementarity at the binding interface and is consistent with existing mutagenesis data. The apo structure presented here can also serve as a target for virtual screening and soaking studies of small molecules that can modulate the function of MEF2 as research tools and therapeutic leads. [Copyright &y& Elsevier]

Published

2010

3. 1.6Å Crystal Structure of the Secreted Chorismate Mutase from Mycobacterium tuberculosis: Novel Fold Topology Revealed

Author

Ökvist, Mats, Dey, Raja, Sasso, Severin, Grahn, Elin, Kast, Peter, and Krengel, Ute

Subjects

*MYCOBACTERIUM tuberculosis, *ESCHERICHIA coli, *MICROORGANISMS, *LIGAND binding (Biochemistry)

Abstract

The presence of exported chorismate mutases produced by certain organisms such as Mycobacterium tuberculosis has been shown to correlate with their pathogenicity. As such, these proteins comprise a new group of promising selective drug targets. Here, we report the high-resolution crystal structure of the secreted dimeric chorismate mutase from M. tuberculosis (*MtCM; encoded by Rv1885c), which represents the first 3D-structure of a member of this chorismate mutase family, termed the AroQγ subclass. Structures are presented both for the unliganded enzyme and for a complex with a transition state analog. The protomer fold resembles the structurally characterized (dimeric) Escherichia coli chorismate mutase domain, but exhibits a new topology, with helix H4 of *MtCM carrying the catalytic site residue missing in the shortened helix H1. Furthermore, the structure of each *MtCM protomer is significantly more compact and only harbors one active site pocket, which is formed entirely by one polypeptide chain. Apart from the structural model, we present evidence as to how the substrate may enter the active site. [Copyright &y& Elsevier]

Published

2006

4. Regulation, Signaling, and Physiological Functions of G-Proteins.

Author

Syrovatkina, Viktoriya, Alegre, Kamela O., Dey, Raja, and Huang, Xin-Yun

Subjects

*G proteins, *G protein coupled receptors, *CELL membranes, *CELLULAR signal transduction, *VESICLE associated membrane protein, *DIGLYCERIDES

Abstract

Heterotrimeric guanine-nucleotide-binding regulatory proteins (G-proteins) mainly relay the information from G-protein-coupled receptors (GPCRs) on the plasma membrane to the inside of cells to regulate various biochemical functions. Depending on the targeted cell types, tissues, and organs, these signals modulate diverse physiological functions. The basic schemes of heterotrimeric G-proteins have been outlined. In this review, we briefly summarize what is known about the regulation, signaling, and physiological functions of G-proteins. We then focus on a few less explored areas such as the regulation of G-proteins by non-GPCRs and the physiological functions of G-proteins that cannot be easily explained by the known G-protein signaling pathways. There are new signaling pathways and physiological functions for G-proteins to be discovered and further interrogated. With the advancements in structural and computational biological techniques, we are closer to having a better understanding of how G-proteins are regulated and of the specificity of G-protein interactions with their regulators. [ABSTRACT FROM AUTHOR]

Published

2016