Analytical Ultracentrifugation

Analytical ultracentrifugation is a means for determining molecular weight and the hydrodynamic and thermodynamic properties of a protein or macromolecule. Sample purity, molecular weight determination in the native state, analysis of associating systems, determination of sedimentation and diffusion coefficients and ligand binding can all be determined using this versatile instrument.

The instrument itself (Beckman Optima XL-A) spins a rotor at a controlled speed and temperature under vacuum while recording the concentration distribution at set times. The rotor may spin at speeds up to 60,000 rpm (ª250,000 x g). Special cells that can withstand the high gravitational field and allows the passage of light through the sample are used. The sample itself is contained within a sector-shaped cavity sandwiched between two windows of quartz or sapphire. This cavity is contained within a centerpiece of aluminum alloy, reinforced epoxy, or a polymer (Kel-F). Double sector cells are also used so that the absorbing components of the sample solvent can be taken into account. These cells also allow the measurement of sedimentation coefficient differences and of diffusion coefficients. These centerpieces can have a pathlength of 3 to 12 mm which combined with selectable wavelengths, allows the examination of a wide range of sample concentrations.

The data obtained from the instrument is a record of the concentration distribution. This is accomplished by obtaining a set of concentration measurements at different radial positions and at a given time. This is achieved using either refractometric methods or photoelectric absorption measurements.

Refractometric
Early instruments used refractometric methods to obtain concentration distributions, using either the Schlieren optical system or Rayleigh interference optics. These methods have the disadvantage that they measure concentration difference relative to a reference point. However, they are still used in some cases due to their applicability to samples with little optical absorbance.

Absorbance
The measurement of absorbance allows increased sensitivity and high reproducibility. With the absorption optics, the absolute concentration is available at any point rather than a concentration difference with respect to a reference point. The absorbance optical system for our instrument is shown below. The xenon flash lamp allows the use of wavelengths from 190 nm to 800 nm. This lamp is fired as the selected sector passes the detector and the measured light is normalized against a reflected small fraction of the incident light. A slit below the sample can move to allow the sampling of different radial positions. To help reduce noise, multiple readings are usually taken from a single position and averaged.

In addition to the collection of concentration distribution, several other quantities may be required. The density of the solvent and the partial specific volume of the solute are required for molecular weight determination. The viscosity of the solvent and its temperature dependence is required in order to account for the effects of solvent and temperature on sedimentation behavior.

With analytical centrifugation, the two basic types of experiments are sedimentation velocity and sedimentation equilibrium.

Sedimentation Velocity
The solute particles pellet at the bottom of the cell, producing a depletion of solute near the meniscus and the formation of a boundary between the depleted region and the uniform concentration of the sedimenting solute. This determines the rate of movement of a solute under a centrifugal field. The rate of movement is equal to the sedimentation coefficient (s), which depends directly on the mass of the particle and inversely on the frictional coefficient. This gives a measure of effective size of the particle.

Allows determination of:

• Sedimentation coefficient(s)
• Diffusion coefficient (if the sedimenting components are well separated)
• Effective mass of solute components
• Shape information
• Molecular weight

   

Sedimentation Equilibrium
The solute particles do not pellet at the bottom of the cell. Instead they redistribute over time with increasing concentration as the distance from the center of rotation increases. After an appropriate period of time, the process of diffusion equals the process of sedimentation (called the sedimentation equilibrium). Measurement of the solute concentration at different time points leads to the determination of the molar weight of the sedimenting solute.

Allows calculation of:

• Molecular weight
• Homogeneity with respect to molecular weight
• Aggregation states
• Stoichiometry and equilibrium constants for association processes

   

References:
Beckman, Model XL-A Training Guide, Beckman Instruments, Inc., Palo Also, CA, 1993.

Ralston, G. Analytical Ultracentrifugation Volume 1. Beckman Instruments, Inc., Fullerton, CA, 1993.

Analytical Ultracentrifugation Submission Form (PDF)