Chem 590 moduleNMR analysis of dynamic systems Outline A. Intro to dynamic systems
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Transcript of Chem 590 moduleNMR analysis of dynamic systems Outline A. Intro to dynamic systems
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Chem 590 module NMR analysis of dynamic systems
Outline
A. Intro to dynamic systems
B. Stoichiometry and Kassoc by NMRC. Thermodynamic parameters by NMRD. Assembly kinetics by NMR E. Other techniques — Student presentations
UV-VisFluorescenceIsothermal titration calorimetryPotentiometry
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Learning Aims
A. Become familiar with dynamic systems and the meanings of the quantities used to characterize them.B1. De-mystify the black-box of Kassoc determinations by all methods. B2. Obtain in-depth understanding of the math and models for 1:1 binding equilibria.B3. Understand the mathematics of the 1:1 binding isotherm, its applications, and its limitations.B4. Gain a comprehensive understanding of how d arises when looking at dynamic systems. B5. Get practical, step-by-step instructions for determining stoichiometry and Kassoc by NMR. C. Learn how NMR can be used to determine ∆H and ∆S for a given equilibrium D. Achieve a beginner-level understanding of studying kinetics by NMR. The goal is to allow you to understand literature, not to teach you how to do the experiments.E. Get a beginner-level understanding of other methods for determining Kassoc
UV-Vis, Fluorescence, Isothermal titration calorimetry, Potentiometry
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Dynamic systems and supramolecular chemistry
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Dynamic systems are driven by weak interactions
Electrostatic interactions
Dispersive forces
Hydrogen bonds
Aromatic-aromatic interactions and cation-pi interactions
The hydrophobic effect
+–+–+ –
Ion–Dipole interactions
Dipole–Dipole interactions
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6 H4L + 4 Ga(acac)3 + 12 KOH + 12 Et4NCl K5[Et4N]7[Ga4L6] (+ H2O, KCl, etc)
H4L [Ga4L6]12–
A complex metal-ligand assembly
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A chiral guest allows resolution into enantiomeric cages
Et4N@[Ga4L6] + nicotine@[Ga4L6] nicotine@ ∆∆∆∆-[Ga4L6]
Resolution of diastereomers
Guest exchange
Et4N@ ∆∆∆∆-[Ga4L6]
Exchange back to achiral guest without loss of host chirality
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Exchange of L1 for L2 occurs without complete disassembly
Et4N@ ∆∆∆∆-[Ga4L16] + 6 L2 Et4N@ ∆∆∆∆-[Ga4L2
6] + 6 L1
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Cation-π interactions: Factor Xa – inhibitor binding
Aromatic cage
Kd = 0.28 M Kd = 29 M
S4 pocket-lined by aromatic residues
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Lysozyme mutants fold more weakly when hydrophobic groups are shrunk down to Ala
∆∆G correlates with hydrophobic (interfacial) surface area!
15-20 cal/mol for each Å2
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Cyclodextrin hosts bind hydrophobic guests with different contributions from ∆H and T∆S
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Rates of exchange and NMR
N-methylformamide (left) and methyl formate (right) in CDCl3 at 90 MHz
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Calculated barriers to rotation
0
5
10
15
20
25
-180 -120 -60 0 60 120 180Dihedral angle (degrees)
Rel. energy (kcal/mol)
ThioesterEsterAmide
transcistrans
HF 3-21G
(Gas phase) cistrans
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Rates change as a function of temperature
Variable temperature NMR of DMF
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Slow exchange: integration to determine complex stoichiometry
*
Integration of methoxy (*) and adamantane (•) signals gave a 4:1 molar ratio.
(Later confirmed by X-ray)
*
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A Practical Guide — Job plot sample prep
cA
cA•∆d
1. Prepare stocks[A stock] = 5 mM[B stock] = 5 mM
2. Create samples with fixed [At + Bt] as below:
3. Record Dd, calculate Dd•cA, Plot as shown at right
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More Examples of Job Plot Data
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Diffusion-Ordered SpectroscopY (DOSY)
Stokes-Einstein relationship: D = kT / 6πhRH
D = diffusion coefficientk = Boltzmann constanth = solvent viscosity RH = hydrodynamic radius, which can be related to MW by calibration on related molecules
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DOSY for a host-guest complex
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A system in fast exchange – real data for dfree and dbound
[peptide]t = 1 mM
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Hypothetical curves for f11 vs. conc. plots based on the generalized 1:1 binding isotherm
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Exemplary NMR Titration Data
Schalley et al. Chem. Eur. J. 2003, 9, 1332.
Average Kassoc = 180 M–1
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A Practical Guide — Sample preparation
Choose starting concentrations
1. Prepare 5 mL of stock A2. Remove 0.6 mL of stock and put in NMR tube3. Calculate amount of B needed to make 4 mL of B at 30x [A] 4. Weigh that amount of B into vial, and dissolve in 4 mL of stock A5. Transfer that titrant into a gas-tight 100 or 250 uL syringe
All of this ensures that At stays constant throughout titration.
1.
2. 3. 4.
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A Practical Guide — Titration
1. Record NMR to determine dfree
2. Add 10 uL of titrant3. Record NMR again4. Repeat…
Hints: -You want to observe a significant Dd with each
addition. You want lots of data points on the curved part of the isotherm. You want to get as close to saturation as possible. This will require making judgments on the fly and increasing the amount you add as you go along. It is not unusual for the increments to start at 10 uL and to be 250 uL by the end of the titration.
- Mix well at each addition (invert >5 times). Mixing is slow in a narrow NMR tube.
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A Practical Guide — Data Analysis
1. In a spreadsheet, record dobs and total volume of titrant added for each spectrum.2. Convert to the y and x values needed for plotting, Ddobs and Bt.3. Input these two columns of data into Origin.4. Fit to the 1:1 binding isotherm to determine the parameters Ddmax and Kassoc. Be sure to try a few different initial guesses. Be sure to check the quality of fit. If you haven’t already done so, confirm stoichiometry by Job plot or other method.
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Exemplary Data — van’t Hoff Plots
Normally 4-5 values for T are enough
Rafaella Faraoni, PhD thesis, ETH Zurich
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Exemplary Data — Very Slow Exchange Kinetics
Exchange of guest P (complex 1•P•1; triangles) for guest A (complex 1•A•1; squares) was followed over 4 hours taking a new NMR measurement every 5 minutes.
Rebek et al. Proc. Nat. Acad. Sci. USA 1999, 96, 8344.
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NMR Line-Shape Analysis
A = intensity of NMR signal (y axis)
w= frequency (x axis)
M0 = some magnetization constant, determined in a separate experiment
W1 = wobs–w0 for signal 1 (offset)W2 = wobs–w0 for signal 2 (offset)
At a given temperature where intermediate exchange is observed, k = k1 + k–1 can be determined by fitting:
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Exemplary Data — NMR Line-Shape Analysis
k = 17.5 s–1
k = 735 s–1
k ~ 3500 s–1
- Red traces are fitted curves, black traces are actual data.- There is a built-in module in TOPSPIN that does this fitting (CG?).
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Exemplary EXSY data for guest exchange
Integrate 3D on-axis peaks and cross peaks to obtain k1 and k–1
See Perrin, C. L.; Dwyer, T. J. Chem. Rev. 1990, 90, 935-967 for a review
“Meout” “Mein”