Thermodynamic evaluation of ligands binding to the Grb2 SH2 domain: effects of α,α-disubstitution at the pY+1 position

Myslinski, James Michael

08 September 2010

A series of phosphotripeptide ligands for the Grb2 SH2 domain was designed and synthesized, each of which derived from the minimal consensus sequence required for binding: Ac-pYXN. The binding affinity and related thermodynamic parameters were determined by isothermal titration calorimetry. Both the size and connectivity of the side-chain was varied. The consequences of incorporating α,α-disubstitution at the pY+1 residue on binding thermodynamics were evaluated, as were the effects of constraining the side-chains in a ring. The series was evaluated from a number of perspectives: (1) increasing size of the pY+1 residue by utilizing various amino acid types: monoalkyl, dialkyl, or cycloalkyl; (2) comparisons between ligands with the same number of carbons (scission control); and (3) by comparing ligands incorporating cyclic pY+1 residues with those incorporating α,α-dialkyl residues with one fewer methylene group (excision control). Inconsistencies in the thermodynamic consequence of constraining the backbone were observed within this set of ligands, which reveal the limitations of our understanding of protein-ligand interactions. Aspects of both the classical and non-classical hydrophobic effect were observed, but the occurance of one over the other could not be explained. / text

Isothermal titration calorimetry

Grb2 SH2 domain

Binding energetics

Characterizing the Phosphorylation State of Tie2 using SH2 Domain Fusion Proteins

Yuth, Kenneth

02 December 2011

The cardiovascular system develops through two distinct processes in embryogenesis: vasculogenesis, whereby the primary plexus in the heart is formed along with embryonic and extraembryonic vasculature, and angiogenesis, which begins after vasculogenesis and results in the refinement and maturation of the branched vessel system. In pathological angiogenesis, tumors expand by releasing pro-angiogenic factors in response to hypoxic conditions. The Tie receptors, Tie1 and Tie2, are receptor tyrosine kinases that are integral to angiogenic pathways. A family of Angiopoietins, Ang1-4, have been shown to act as ligands for Tie2, of which Ang1 and Ang2 are best characterized. Activation of the receptor causes dimerization and autophosphorylation, whereby adaptor proteins recognizing the phosphorylated tyrosine activate downstream signaling via their Src homology 2 (SH2) domains. Currently there are no phosphospecific antibodies for Tie2, therefore, identifying critical residues responsible for certain pathways remains difficult. In our study, we aim to use purified SH2 domains of known binding partners to Tie2 to assess the phosphorylation state of the receptor under various cellular conditions and settings, utilizing immunoprecipitation and western blotting. Unexpectedly, we found that Tie2 can bind non-specifically to nickel sepharose when the SH2 proteins were used as antibody mimetics, and was unable to be consistently precipitated in Protein A sepharose when used in conjunction with a monoclonal YFP antibody. Under the latter conditions however we were able to precipitate the SH2 protein itself. When immunoprecipitations were used with cobalt activated IMAC beads, we were able to precipitate Tie2 in overexpressed systems using the SH2 domains of Shp2 N-C and Grb2. As expected, phosphorylation of Tie2 in the presence of its orphan receptor Tie1 was attenuated compared to wild-type levels. Based upon available data, we anticipate this method as a useful tool to assess the phosphorylation state of Tie2 and its signaling pathways in the near future.

Angiogenesis

Tie2

SH2 domain

Life Sciences

An Exploration into the Molecular Recognition of Signal Transducer and Activator of Transcription 3 Protein Using Rationally Designed Small Molecule Binders

Shahani, Vijay Mohan

14 January 2014

Signal transducer and activator of transcription 3 (STAT3) is a cancer-driving proto-oncoprotein that represents a novel target for the development of chemotherapeutics. In this study, the functional requirements to furnish a potent STAT3 inhibitor was investigated. First, a series of peptidomimetic inhibitors were rationally designed from lead parent peptides. Prepared peptidomimetics overcame the limitations normally associated with peptide agents and displayed improved activity in biophysical evaluations. Notably, lead peptidomimetic agents possessed micromolar cellular activity which was unobserved in both parent peptides. Peptidomimetic design relied on computational methods that were also employed in the design of purine based STAT3 inhibitory molecules. Docking studies with lead STAT3-SH2 domain inhibitory molecules identified key structural and chemical information required for the construction of a pharmacophore model. 2,6,9-heterotrisubstituted purines adequately fulfilled the pharmacophore model and a library of novel purine-based STAT3 inhibitory molecules was prepared utilizing Mitsunobu chemistry. Several agents from this new library displayed high affinity for the STAT3 protein and effectively disrupted the STAT3:STAT3-DNA complex. Furthermore, these agents displayed cancer-cell specific toxicity through a STAT3 dependant mechanism. While purine agents elicited cellular effects, the dose required for cellular efficacy was much higher than those observed for in vitro STAT3 dimer disruption. The diminished cellular activity could be attributed to the apparent poor cell permeability of the first generation purine library; thus, a second library of purine molecules was constructed to improve cell penetration. Unfortunately, iii 2nd generation purine inhibitors failed to disrupt phosphorylated STAT3 activity and suffered from poor cell permeability. However, a lead sulfamate agent was discovered that showed potent activity against multiple myeloma cancer cells. Investigations revealed potential kinase inhibitory activity as the source of the sulfamate purine’s biological effect. Explorations into the development of a potent STAT3 SH2 domain binder, including the creation of salicylic purine and constrained pyrimidine molecules, are ongoing. Finally, progress towards the creation of a macrocyclic purine combinatorial library has been pursued and is reported herein.

Inhibitor design

STAT3

Protein-protein interaction

Molecular recognition

Molecular modelling

Pharmacophore model

Antitumour cell effects

SH2 domain

0491

An Exploration into the Molecular Recognition of Signal Transducer and Activator of Transcription 3 Protein Using Rationally Designed Small Molecule Binders

Shahani, Vijay Mohan

14 January 2014

Signal transducer and activator of transcription 3 (STAT3) is a cancer-driving proto-oncoprotein that represents a novel target for the development of chemotherapeutics. In this study, the functional requirements to furnish a potent STAT3 inhibitor was investigated. First, a series of peptidomimetic inhibitors were rationally designed from lead parent peptides. Prepared peptidomimetics overcame the limitations normally associated with peptide agents and displayed improved activity in biophysical evaluations. Notably, lead peptidomimetic agents possessed micromolar cellular activity which was unobserved in both parent peptides. Peptidomimetic design relied on computational methods that were also employed in the design of purine based STAT3 inhibitory molecules. Docking studies with lead STAT3-SH2 domain inhibitory molecules identified key structural and chemical information required for the construction of a pharmacophore model. 2,6,9-heterotrisubstituted purines adequately fulfilled the pharmacophore model and a library of novel purine-based STAT3 inhibitory molecules was prepared utilizing Mitsunobu chemistry. Several agents from this new library displayed high affinity for the STAT3 protein and effectively disrupted the STAT3:STAT3-DNA complex. Furthermore, these agents displayed cancer-cell specific toxicity through a STAT3 dependant mechanism. While purine agents elicited cellular effects, the dose required for cellular efficacy was much higher than those observed for in vitro STAT3 dimer disruption. The diminished cellular activity could be attributed to the apparent poor cell permeability of the first generation purine library; thus, a second library of purine molecules was constructed to improve cell penetration. Unfortunately, iii 2nd generation purine inhibitors failed to disrupt phosphorylated STAT3 activity and suffered from poor cell permeability. However, a lead sulfamate agent was discovered that showed potent activity against multiple myeloma cancer cells. Investigations revealed potential kinase inhibitory activity as the source of the sulfamate purine’s biological effect. Explorations into the development of a potent STAT3 SH2 domain binder, including the creation of salicylic purine and constrained pyrimidine molecules, are ongoing. Finally, progress towards the creation of a macrocyclic purine combinatorial library has been pursued and is reported herein.

Inhibitor design

STAT3

Protein-protein interaction

Molecular recognition

Molecular modelling

Pharmacophore model

Antitumour cell effects

SH2 domain

0491

SRC homology 2 domain proteins binding specificity: from combinatorial chemistry to cell-permeable inhibitors

Wavreille, Anne-Sophie Marie

01 December 2006

No description available.

Chemistry, Biochemistry

SH2 domain

Binding specificity

SHP-1

SHP-2

Tensin

peptide library

protein interaction

cell-permeable inhibitor

Sequence Specificity of Src Homology-2 Domains

Tan, Pauline H.

06 January 2012

No description available.

Biochemistry

Chemistry

SH2 Domain

Binding Specificity

Src kinase

kinase

SHP2

SH2 mutant

protein-protein interaction

peptide library

protein binding

Investigation of SH2 Domains: Ligand Binding, Structure and Inhibitor Design

Zhang, Yanyan

January 2009

No description available.

Biology

Biomedical Research

Biophysics

Chemistry

SH2 domain

binding specificity

binding kinetics

cyclic peptidyl inhibitor

structure

SHIP2 SH2

Grb2 SH2

X-ray

NMR

SHP2 NSH2