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Related Concept Videos

Nuclear Magnetic Resonance (NMR): Overview01:07

Nuclear Magnetic Resonance (NMR): Overview

Nuclear magnetic resonance (NMR) is a phenomenon exhibited by certain nuclei that can absorb characteristic radio frequency radiation under certain conditions. NMR has been extensively applied in molecular spectroscopy and medical diagnostic imaging. In both these applications, the molecule or subject under study is placed in a magnetic field and irradiated with radio frequency energy.
NMR spectroscopy generates a spectrum where the characteristic absorption frequencies of the sample are...
¹H NMR: Complex Splitting01:13

¹H NMR: Complex Splitting

A proton M that is coupled to a proton X results in doublet signals for M. However, NMR-active nuclei can be simultaneously coupled to more than one nonequivalent nucleus. When M is coupled to a second proton A, such as in styrene oxide, each peak in the doublet is split into another doublet.
Splitting diagrams or splitting tree diagrams are routinely used to depict such complex couplings. While drawing splitting diagrams, the splitting with the larger coupling constant is usually applied first.
Two-Dimensional (2D) NMR: Overview01:12

Two-Dimensional (2D) NMR: Overview

The 1D NMR spectrum of large and complex molecules like natural products has complicated splitting patterns and overlapping signals, which can be easily interpreted using 2-dimensional (2D) NMR. Unlike 1D NMR, 2D NMR has two frequency axes that provide the coupling information between the nucleus A and nucleus B in a molecule. The process from which 2D spectra are obtained has four steps.
The first step is the preparation period, during which nucleus A is excited with a radiofrequency pulse.
¹H NMR Chemical Shift Equivalence: Homotopic and Heterotopic Protons01:03

¹H NMR Chemical Shift Equivalence: Homotopic and Heterotopic Protons

Protons in identical electronic environments within a molecule are chemically equivalent and have the same chemical shift. The replacement test is a useful tool to identify chemical equivalence and predict NMR spectra. A substituent replaces each of the protons being examined and the resulting molecules are compared. If the same molecule is obtained, the protons are equivalent or homotopic. Replacement of any hydrogens in ethane by chlorine yields chloroethane because all six protons are...
Applications Of NMR In Biology01:25

Applications Of NMR In Biology

Nuclear magnetic resonance (NMR) spectroscopy is a very valuable analytical technique for researchers. It has been used for more than 50 years as an analytical tool. F. Bloch and E. Purcell formulated NMR in 1946 and won the 1952 Nobel Prize in Physics  for their work. Biological macromolecules such as proteins, nucleic acids, lipids, and organic molecules including pharmaceutical compounds, can be studied using this versatile tool that exploits the magnetic properties of certain nuclei.
The...
2D NMR: Overview of Homonuclear Correlation Techniques01:16

2D NMR: Overview of Homonuclear Correlation Techniques

Homonuclear correlation spectroscopy (COSY) is a powerful technique used in Nuclear Magnetic Resonance (NMR) spectroscopy to study the correlations between nuclei of the same type within a molecule. It provides information about scalar couplings between adjacent nuclei, which helps determine connectivity and structural information. There are several COSY variants, each with its unique strengths and experimental parameters.
COSY90 is the standard two-dimensional (2D) COSY experiment that...

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Structure and Coordination Determination of Peptide-metal Complexes Using 1D and 2D 1H NMR
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Published on: December 16, 2013

Structure activity relationship by NMR and by computer: a comparative study.

Finton Sirockin1, Christian Sich, Sabina Improta

  • 1Contribution from the Laboratoire de Biologie et Génomique Structurales, UMR 7104, Ecole Supérieure de Biotechnologie de Strasbourg, Boulevard S. Brant, FR-67400 Illkirch, France.

Journal of the American Chemical Society
|September 13, 2002
PubMed
Summary
This summary is machine-generated.

Nuclear Magnetic Resonance (NMR) spectroscopy and computational methods were used to identify ligand binding sites on FKBP12. Computational approaches successfully predicted ligand positions matching experimental Nuclear Overhauser Effect (NOE) constraints.

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Area of Science:

  • Biophysics
  • Computational Chemistry
  • Structural Biology

Background:

  • Nuclear Magnetic Resonance (NMR) spectroscopy is increasingly used to map ligand binding sites on macromolecules.
  • Modular approaches involve identifying small ligand binding sites and assembling them into higher-affinity molecules.
  • Similar strategies are applied in in silico drug design for assembling ligands from favorable chemical groups.

Purpose of the Study:

  • To compare experimental and computational methods for identifying ligand binding sites.
  • To validate computational predictions against NMR data for a specific target protein, FKBP12.
  • To assess the accuracy of computational methods in ranking ligand positions based on experimental constraints.

Main Methods:

  • Utilized NMR spectroscopy to identify binding sites of three small ligands on FKBP12.
  • Employed computational methods to independently predict ligand binding sites on FKBP12.
  • Compared experimental NMR data with computational predictions for ligand positioning.

Main Results:

  • Both NMR spectroscopy and computational methods successfully identified binding sites for the tested ligands on FKBP12.
  • Computational predictions accurately identified and favorably ranked ligand positions that satisfied experimental Nuclear Overhauser Effect (NOE) constraints.
  • The study demonstrated concordance between experimental and computational approaches for ligand site identification.

Conclusions:

  • Computational methods are effective tools for predicting ligand binding sites, complementing experimental NMR data.
  • The integration of computational and experimental techniques can accelerate drug discovery by accurately mapping ligand interactions.
  • Validated computational approaches provide reliable insights into ligand-macromolecule interactions for target identification.