Your search keyword '"LeMotte, Peter"' showing total 4 results

1. Structural basis for the catalytic mechanism of human phosphodiesterase 9

Author

Liu, Shenping, Mansour, Mahmoud N., Dillman, Keith S., Perez, Jose R., Danley, Dennis E., Aeed, Paul A., Simons, Samuel P., LeMotte, Peter K., and Menniti, Frank S.

Subjects

Phosphodiesterases -- Physiological aspects, Catalysis -- Research, Enzyme activation -- Research, Science and technology

Abstract

The phosphodiesterases (PDEs) are metal ion-dependent enzymes that regulate cellular signaling by metabolic inactivation of the ubiquitous second messengers cAMP and cGMP. In this role, the PDEs are involved in many biological and metabolic processes and are proven targets of successful drugs for the treatments of a wide range of diseases. However, because of the rapidity of the hydrolysis reaction, an experimental knowledge of the enzymatic mechanisms of the PDEs at the atomic level is still lacking. Here, we report the structures of reaction intermediates accumulated at the reaction steady state in PDE9/crystal and preserved by freeze-trapping. These structures reveal the catalytic process of a PDE and explain the substrate specificity of PDE9 in an actual reaction and the cation requirements of PDEs in general. crystallography | enzyme mechanism | reaction intermediates | freeze-trapping

Published

2008

2. Kinetic analysis of estrogen receptor/ ligand interactions

Author

Rich, Rebecca L., Hoth, Lise R., Geoghegan, Kieran F., Brown, Thomas A., LeMotte, Peter K., Simons, Samuel P., Hensley, Preston, and Myszka, David G.

Subjects

Estrogen -- Receptors, Ligand binding (Biochemistry) -- Research, Biosensors -- Research, Science and technology

Abstract

Surface plasmon resonance biosensor technology was used to directly measure the binding interactions of small molecules to the ligand-binding domain of human estrogen receptor. In a screening mode, specific ligands of the receptor were easily discerned from nonligands. In a high-resolution mode, the association and dissociation phase binding responses were shown to be reproducible and could be fit globally to a simple interaction model to extract reaction rate constants. On average, antagonist ligands (such as tamoxifen and nafoxidine) were observed to bind to the receptor with association rates that were 500-fold slower than agonists (such as estriol and [beta]-estradiol). This finding is consistent with these antagonists binding to an altered conformation of the receptor. The biosensor assay also could identify subtle differences in how the same ligand interacted with two different isoforms of the receptor ([alpha] and [beta]). The biosensor's ability to determine kinetic rate constants for small molecule/protein interactions provides unique opportunities to understand the mechanisms associated with complex formation as well as new information to drive the optimization of drug candidates.

Published

2002

3. Structural basis for the catalytic mechanism of human phosphodiesterase 9.

Author

Shenping Liu, Mansour, Mahmoud N., Diliman, Keith S., Perez, Jose R., Danley, Dennis E., Aeed, Paul A., Simons, Samuel P., LeMotte, Peter K., and Menniti, Frank S.

Subjects

PHOSPHODIESTERASES, ENZYMES, CRYSTALLOGRAPHY, HYDROLYSIS, INTERMEDIATES (Chemistry)

Abstract

The phosphodiesterases (PDEs) are metal ion-dependent enzymes that regulate cellular signaling by metabolic inactivation of the ubiquitous second messengers cAMP and cGMP. In this role, the PDEs are involved in many biological and metabolic processes and are proven targets of successful drugs for the treatments of a wide range of diseases. However, because of the rapidity of the hydrolysis reaction, an experimental knowledge of the enzymatic mechanisms of the PDEs at the atomic level is still lacking. Here, we report the structures of reaction intermediates accumulated at the reaction steady state in PDE9/crystal and preserved by freeze-trapping. These structures reveal the catalytic process of a PDE and explain the substrate specificity of PDE9 in an actual reaction and the cation requirements of POEs in general. [ABSTRACT FROM AUTHOR]

Published

2008

4. Kinetic analysis of estrogen receptor/ligand interactions.

Author

Rich, Rebecca L., Hoth, Lise R., Geoghegan, Kieran F., Brown, Thomas A., LeMotte, Peter K., Simons, Samuel P., Hensley, Preston, and Myszka, David G.

Subjects

ESTROGEN, LIGANDS (Biochemistry), BIOSENSORS

Abstract

Analyzes the kinetics of the interaction between estrogen receptors and ligands. Use of a surface plasmon resonance biosensor technology; Details of the association and disassociation phase of binding responses; Types of ligands.

Published

2002