Victor Pui-Yan Ma

A Metal-Based Inhibitor of Tumor Necrosis Factor-α†

Staying in the pocket: A cyclometalated iridium(III) biquinoline complex targets the protein-protein interface (see picture; C yellow, N blue, Ir dark green) of the tumor necrosis factor-α (TNF-α) trimer. Molecular-modeling studies confirm the nature of this interaction. Both enantiomers of the iridium complex display comparable in vitro potency to the strongest small-molecule inhibitor of TNF-α.

Detection of base excision repair enzyme activity using a luminescent G-quadruplex selective switch-on probe

We report herein a simple and convenient luminescent assay for detection of base excision repair enzyme activity using an Ir(III) complex as a G-quadruplex selective probe. Using uracil-DNA glycosylase (UDG) as a model enzyme, the assay achieved high sensitivity and selectivity for UDG over other tested enzymes. The utility of the assay for screening potential UDG inhibitors was also demonstrated.

A label-free G-quadruplex-based switch-on fluorescence assay for the selective detection of ATP

A G-quadruplex-based, label-free, switch-on fluorescence detection method has been developed for the selective detection of ATP in aqueous solution using crystal violet as a G-quadruplex-selective probe. The assay is highly simple and rapid, and does not require the use of fluorescent labeling.

DNA-based nanoparticle tension sensors reveal that T-cell receptors transmit defined pN forces to their antigens for enhanced fidelity.

Significance T cells protect the body against pathogens and cancer by recognizing specific foreign peptides on the cell surface. Because antigen recognition occurs at the junction between a migrating T cell and an antigen-presenting cell (APC), it is likely that cellular forces are generated and transmitted through T-cell receptor (TCR)-ligand bonds. Here we develop a DNA-based nanoparticle tension sensor producing the first molecular maps of TCR-ligand forces during T cell activation. We find that TCR forces are orchestrated in space and time, requiring the participation of CD8 coreceptor and adhesion molecules. Loss or damping of TCR forces results in weakened antigen discrimination, showing that T cells harness mechanics to optimize the specificity of response to ligand. T cells are triggered when the T-cell receptor (TCR) encounters its antigenic ligand, the peptide-major histocompatibility complex (pMHC), on the surface of antigen presenting cells (APCs). Because T cells are highly migratory and antigen recognition occurs at an intermembrane junction where the T cell physically contacts the APC, there are long-standing questions of whether T cells transmit defined forces to their TCR complex and whether chemomechanical coupling influences immune function. Here we develop DNA-based gold nanoparticle tension sensors to provide, to our knowledge, the first pN tension maps of individual TCR-pMHC complexes during T-cell activation. We show that naïve T cells harness cytoskeletal coupling to transmit 12–19 pN of force to their TCRs within seconds of ligand binding and preceding initial calcium signaling. CD8 coreceptor binding and lymphocyte-specific kinase signaling are required for antigen-mediated cell spreading and force generation. Lymphocyte function-associated antigen 1 (LFA-1) mediated adhesion modulates TCR-pMHC tension by intensifying its magnitude to values >19 pN and spatially reorganizes the location of TCR forces to the kinapse, the zone located at the trailing edge of migrating T cells, thus demonstrating chemomechanical crosstalk between TCR and LFA-1 receptor signaling. Finally, T cells display a dampened and poorly specific response to antigen agonists when TCR forces are chemically abolished or physically “filtered” to a level below ∼12 pN using mechanically labile DNA tethers. Therefore, we conclude that T cells tune TCR mechanics with pN resolution to create a checkpoint of agonist quality necessary for specific immune response.

Discovery of a natural product inhibitor targeting protein neddylation by structure-based virtual screening

NEDD8-activating enzyme (NAE) controls the specific degradation of proteins regulated by cullin-RING ubiquitin E3 ligase, and has been considered as an attractive molecular target for the development of anti-cancer drugs. We report herein the identification of the dipeptide-conjugated deoxyvasicinone derivative (1) as an inhibitor of NAE by virtual screening of over 90,000 compounds from the ZINC database of natural products. Molecular modelling results suggested that 1 may be a non-covalent competitive inhibitor of NAE by blocking the ATP-binding domain. Compound 1 was able to inhibit NAE activity in both cell-free and cell-based assay with potencies in the micromolar range and selectivity over analogous E1 enzymes UAE and SAE. We envisage that the identification and molecular docking analysis of this bioactive scaffold as an NAE inhibitor would provide the scientific community with useful information in order to generate more potent analogues.

A G-quadruplex-selective luminescent switch-on probe for the detection of sub-nanomolar human neutrophil elastase

A novel G-quadruplex-selective luminescent iridium(III) complex has been employed as a signal-transducing element for the sensitive and selective switch-on detection of sub-nanomolar human neutrophil elastase (HNE) in homogenous solution.

In silico screening of quadruplex-binding ligands

Recent advances in computational processing power and molecular docking algorithms have facilitated the development of computer-aided methods for the rapid and efficient discovery of G-quadruplex-interacting molecules. In this article, we provide an introductory framework for the methodology of in silico screening for the identification of novel DNA G-quadruplex ligands from chemical libraries. We discuss aspects of model construction, database selection and molecular docking techniques, and highlight representative examples from this field. Finally, we offer a perspective on the potential application of in silico techniques for the discovery of RNA G-quadruplex-binding ligands in the future.

A highly selective G-quadruplex-based luminescent switch-on probe for the detection of nanomolar strontium(II) ions in sea water

A G-quadruplex-selective luminescent iridium(III) switch-on probe has been developed for the selective detection of Sr2+ ions in buffered solutions and sea water. The method achieves high sensitivity towards Sr2+ ions with a detection limit in the nanomolar range and high selectivity for Sr2+ ions over other metal ions.

DNA‐Binding Small Molecules as Inhibitors of Transcription Factors

Accumulating evidence implicating the role of aberrant transcription factor signaling in the pathogenesis of various human diseases such as cancer and inflammation has stimulated the development of small molecule ligands capable of targeting transcription factor activity and modulating gene expression. The use of DNA‐binding small molecules to selectively inhibit transcription factor–DNA interactions represents one possible approach toward this goal. In this review, we summarize the development of DNA‐binding small molecule inhibitors of transcription factors from 2004 to 2011, and their binding mode and therapeutic potential will be discussed.

Inhibition of Janus kinase 2 by cyclometalated rhodium complexes

Cyclometalated rhodium complexes were synthesized and evaluated as JAK2 metal-based inhibitors. Complexes 1 and 2 inhibited JAK2 enzyme phosphorylation activity, reduced JAK2 autophosphorylation in cellulo and exhibited cytotoxicity towards HEL cancer cells. To our knowledge, these are the first two examples of metal-based inhibitors of JAK2.