Exploring Surfaces and Cavities in Lipoxygenase and Other Proteins by Hyperpolarized Xenon-129 NMR

Bowers, Clifford R.; Storhaug, Vincent J.; Webster, Charles Edwin; Bharatam, J.; Cottone, and Andrew; Gianna, R.; Betsey, K.; Gaffney, Betty J.

doi:10.1021/ja991443+

Cited by 55 publications

(44 citation statements)

References 41 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…Xenon binding to myoglobin has been well characterized by NMR spectroscopy (43,44) and X-ray crystallography (45), and metmyoglobin-Xe association constants have been measured to be approximately 200 and 10 M −1 (45,46). Comparable affinities have been determined for other naturally occurring sites in hemoglobin (44), lipoxygenase (47), and lipid transfer protein (48), as well as specially designed hydrophobic cavities in T4 lysozyme (49), ribose-binding protein (50), and other examples (51,52). We showed previously that xenon binds water-soluble cryptophanes approximately 1.5-fold less avidly in human plasma than in aqueous buffer solution (14).…”

Section: Resultsmentioning

confidence: 99%

Measurement of radon and xenon binding to a cryptophane molecular host

Jacobson

Khan²,

Collé³

et al. 2011

Proc. Natl. Acad. Sci. U.S.A.

View full text Add to dashboard Cite

Xenon and radon have many similar properties, a difference being that all 35 isotopes of radon ( 195 Rn– 229 Rn) are radioactive. Radon is a pervasive indoor air pollutant believed to cause significant incidence of lung cancer in many geographic regions, yet radon affinity for a discrete molecular species has never been determined. By comparison, the chemistry of xenon has been widely studied and applied in science and technology. Here, both noble gases were found to bind with exceptional affinity to tris-(triazole ethylamine) cryptophane, a previously unsynthesized water-soluble organic host molecule. The cryptophane–xenon association constant, K a = 42,000 ± 2,000 M -1 at 293 K, was determined by isothermal titration calorimetry. This value represents the highest measured xenon affinity for a host molecule. The partitioning of radon between air and aqueous cryptophane solutions of varying concentration was determined radiometrically to give the cryptophane–radon association constant K a = 49,000 ± 12,000 M -1 at 293 K.

show abstract

Section: Resultsmentioning

confidence: 99%

Measurement of radon and xenon binding to a cryptophane molecular host

Jacobson

Khan²,

Collé³

et al. 2011

Proc. Natl. Acad. Sci. U.S.A.

View full text Add to dashboard Cite

show abstract

“…For the initial demonstration of this technique, biotin and avidin were chosen because of their high association constant (Ϸ10 15 M Ϫ1 ) (25) and the extensive literature characterizing binding properties of modified avidin or biotin (26). The cage chosen for the prototype is a cryptophane-A molecule (21) with a polar peptide chain attached to make the cryptophane water soluble.…”

Section: Resultsmentioning

confidence: 99%

“…Laserpolarized xenon is being developed as a diagnostic agent for medical magnetic resonance imaging (9) and spectroscopy (10) and as a probe for the investigation of surfaces and cavities in porous materials and biological systems. Xenon provides information both through direct observation of its NMR spectrum (11)(12)(13)(14)(15)(16)(17) and by the transfer of its enhanced polarization to surrounding spins (18,19). In a protein solution, weak xenonprotein interactions render the chemical shift of xenon dependent on the accessible protein surface and even allow the monitoring of the protein conformation (20).…”

mentioning

confidence: 99%

Functionalized xenon as a biosensor

Spence

Rubin

Dimitrov

et al. 2001

Proc. Natl. Acad. Sci. U.S.A.

305

325

View full text Add to dashboard Cite

The detection of biological molecules and their interactions is a significant component of modern biomedical research. In current biosensor technologies, simultaneous detection is limited to a small number of analytes by the spectral overlap of their signals. We have developed an NMR-based xenon biosensor that capitalizes on the enhanced signal-to-noise, spectral simplicity, and chemical-shift sensitivity of laser-polarized xenon to detect specific biomolecules at the level of tens of nanomoles. We present results using xenon ''functionalized'' by a biotin-modified supramolecular cage to detect biotin-avidin binding. This biosensor methodology can be extended to a multiplexing assay for multiple analytes.R ecent biosensor technologies exploit surface plasmon resonance (1), fluorescence polarization (2), and fluorescence resonance energy transfer (3) as detection methods. Although the sensitivity of such techniques is excellent, extending these assays to multiplexing capabilities has proven challenging because of the difficulty in distinguishing signals from different binding events. Although NMR spectroscopy is able to finely resolve signals from different molecules and environments, the spectral complexity and low sensitivity of NMR spectroscopy normally preclude its use as a detector of molecular targets in complex mixtures. Notable successes (4, 5) in the application of NMR to such problems are still limited by long acquisition times or a limited number of detectable analytes. Laser-polarized xenon NMR benefits from good signal-to-noise and spectral simplicity with the added advantage of substantial chemical-shift sensitivity.Optical pumping (6) has enhanced the use of xenon as a sensitive probe of its molecular environment (7,8). Laserpolarized xenon is being developed as a diagnostic agent for medical magnetic resonance imaging (9) and spectroscopy (10) and as a probe for the investigation of surfaces and cavities in porous materials and biological systems. Xenon provides information both through direct observation of its NMR spectrum (11)(12)(13)(14)(15)(16)(17) and by the transfer of its enhanced polarization to surrounding spins (18,19). In a protein solution, weak xenonprotein interactions render the chemical shift of xenon dependent on the accessible protein surface and even allow the monitoring of the protein conformation (20). To use xenon as a specific sensor of molecules, it would be valuable to ''functionalize'' the xenon for the purpose of reporting specific interactions with a molecular target.In this report, we demonstrate an example of such a functionalized system that exhibits molecular target recognition. Fig. 1 shows the chemical principle used for our initial study, a biosensor molecule designed to bind both xenon and protein.The molecule consists of three parts: the cage, which contains the xenon; the ligand, which directs the functionalized xenon to a specific protein; and the tether, which links the ligand and the cage. The ligand and target can be any two molecules or constructs. In su...

show abstract

“…[35][36][37] Recently, extensive reviews regarding the history and development of hyperpolarized xenon NMR have been published. 38,39 Biological systems studied with 129 Xe NMR include globular proteins such as myoglobin and hemoglobin, [40][41][42][43][44][45][46] membrane associated peptides such as gramicidin, 47 and lipid membranes themselves. 48 While xenon shows appreciable binding to many proteins, as evidenced by its use in making heavy atom derivatives of protein crystals for x-ray crystallography, 49 In spite of the favorable attributes of xenon interacting with proteins in solution, high-sensitivity molecular sensing is not compatible with the fast-exchange characteristic of xenon-protein interactions.…”

Section: Introductionmentioning

confidence: 99%

Development of a Functionalized Xenon Biosensor

et al. 2004

View full text Add to dashboard Cite

NMR-based biosensors that utilize laser-polarized xenon offer potential advantages beyond current sensing technologies. These advantages include the capacity to simultaneously detect multiple analytes, the applicability to in vivo spectroscopy and imaging, and the possibility of "remote" amplified detection. Here we present a detailed NMR characterization of the binding of a biotin-derivatized caged-xenon sensor to avidin. Binding of "functionalized" xenon to avidin leads to a change in the chemical shift of the encapsulated xenon in addition to a broadening of the resonance, both of which serve as NMR markers of ligand-target interaction. A control experiment in which the biotin-binding site of avidin was blocked with native biotin showed no such spectral changes, confirming that only specific binding, rather than nonspecific contact, between avidin and functionalized xenon leads to the effects on the xenon NMR spectrum. The exchange rate of xenon (between solution and cage) and the xenon spin-lattice relaxation rate were not changed significantly upon binding. We describe two methods for enhancing the signal from functionalized xenon by exploiting the laser-polarized xenon magnetization reservoir. We also show that the xenon chemical shifts are distinct for xenon encapsulated in different diastereomeric cage molecules. This demonstrates the potential for tuning the encapsulated xenon chemical shift, which is a key requirement for being able to multiplex the biosensor.

show abstract

Exploring Surfaces and Cavities in Lipoxygenase and Other Proteins by Hyperpolarized Xenon-129 NMR

Cited by 55 publications

References 41 publications

Measurement of radon and xenon binding to a cryptophane molecular host

Measurement of radon and xenon binding to a cryptophane molecular host

Functionalized xenon as a biosensor

Development of a Functionalized Xenon Biosensor

Contact Info

Product

Resources

About