A Modification of Fujita's Method for the Calculation of Diffusion Coefficients From Boundary Spreading in the Ultracentrifuge

Holde, Kensal E. van

doi:10.1021/j100839a510

Cited by 35 publications

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“…Den Diffusionskoeffizienten erhielt man nach dem Verfahren von Fujita und van Holde [23,24] ebenfalls aus Experimenten in der analytischen Ultrazentrifuge. 4 Versuche (Fig.…”

Section: Molekulargewichtunclassified

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β‐Methylcrotonyl‐CoA‐Carboxylase

Apitz‐Castro¹,

Rehn²,

Lynen³

1970

European Journal of Biochemistry

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β‐Methylcrotonyl‐CoA‐carboxylase was purified 120‐fold from an Achromobacter species. When the cells were grown on isovaleric acid, the enzyme was formed mainly during exponential growth. The enzyme can be labeled by addition of radioactive biotin to growing cells. A former procedure of purification was improved by using adsorption to calcium phosphate gel and chromatography on Sephadex G‐200. Enzyme homogeneous by both sedimentation and Tiselius electrophoresis was thus obtained in a yield of 40–70% and was crystallized in a form resembling crystalline propionyl‐CoA‐carboxylase. The molecular weight of the enzyme as determined by sedimentation velocity is 760000 daltons. The biotin content of 1,27 μmoles/g indicates 4 moles of biotin are bound to 1 mole of protein as is also the case for propionyl‐CoA‐carboxylase and pyruvate carboxylase. Glutamic and aspartic acid comprise 23% of the amino acids in the enzyme. Extrapolation of electrophoretic mobility as a function of pH indicates the isoelectric point of the enzyme is in the vicinity of pH 3.5. Such a value would mean that most of the carboxyl groups of the acidic residues are free. The usual methods of preparations for electron microscopy, even with preceding fixation steps, cause degradation of the enzyme since only particles of about 1/4 of the expected size could be seen. However, ultracentrifugation did not indicate any dissociation of the enzyme into subunits.

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“…Den Diffusionskoeffizienten erhielt man nach dem Verfahren von Fujita und van Holde [23,24] ebenfalls aus Experimenten in der analytischen Ultrazentrifuge. 4 Versuche (Fig.…”

Section: Molekulargewichtunclassified

“…7 Versuche bei verschiedenen Proteinkonzentrationen (Fig. 6) ergaben bei graphischer Extrapolation auf unendliche Verdiinnung den Wert s:~,, = 20,7 S. Den Diffusionskoeffizienten erhielt man nach dem Verfahren von Fujita und van Holde [23,24] ebenfalls aus Experimenten in der analytischen Ultrazentrifuge. 4 Versuche (Fig.…”

Section: Molekulargewichtunclassified

β‐Methylcrotonyl‐CoA‐Carboxylase

Apitz‐Castro¹,

Rehn²,

Lynen³

1970

European Journal of Biochemistry

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“…Fortunately, an erroneous magnitude for k s does not affect the value of s o , the parameter most commonly being sought because of its relevance to the prediction of protein shape from hydrodynamic parameters (Garcia de la Torre et al 2000; Garcia de la Torre and Harding, 2013), although k s , if measured correctly, is itself useful in the delineation of molecular shape. In the event that the extent of boundary spreading is being used to evaluate the translational diffusion coefficient D the magnitude of k s also becomes important because of its use to make quantitative allowance for the effects of boundary sharpening arising from the linear negative s-c dependence exhibited by globular proteins (Fujita 1956(Fujita , 1959Baldwin 1957;Van Holde 1960;Scott et al 2015;Winzor and Scott 2018;Chaturvedi et al 2018). In that regard, the recommendation that use of the commonly used SEDFIT program for determining protein molar mass from sedimentation velocity distributions be confined to the analysis of experiments with low loading concentrations (Schuck 2005) reflected the omission of any allowance for this boundary sharpening effect at that stagea point now emphasized in the recent study dealing with the consequences of hydrodynamic nonideality (Chaturvedi et al 2018).…”

Section: Summary Of Current Approaches To Quantifying S-c Dependencementioning

confidence: 99%

Quantifying the concentration dependence of sedimentation coefficients for globular macromolecules: a continuing age-old problem

et al. 2021

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This retrospective investigation has established that the early theoretical attempts to directly incorporate the consequences of radial dilution into expressions for variation of the sedimentation coefficient as a function of the loading concentration in sedimentation velocity experiments require concentration distributions exhibiting far greater precision than that achieved by the optical systems of past and current analytical ultracentrifuges. In terms of current methods of sedimentation coefficient measurement, until such improvement is made, the simplest procedure for quantifying linear s-c dependence (or linear concentration dependence of 1/s) for dilute systems therefore entails consideration of the sedimentation coefficient obtained by standard c(s), g*(s) or G(s) analysis) as an average parameter ($$ \overline{s} $$ s ¯ ) that pertains to the corresponding mean plateau concentration (following radial dilution) ($$ \overline{c} $$ c ¯ ) over the range of sedimentation velocity distributions used for the determination of $$ \overline{s} $$ s ¯ . The relation of this with current descriptions of the concentration dependence of the sedimentation and translational diffusion coefficients is considered, together with a suggestion for the necessary improvement in the optical system.

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“…A major breakthrough in the analysis of boundary spreading in sedimentation velocity experiments was the report by Fujita (1956Fujita ( , 1962 of an approximate analytical solution to the Lamm equation for solutes exhibiting linear concentration dependence of s and concentration independence of D. Other approximate solutions (Weiss 1964;Weiss and Yphantis 1965;Billick and Weiss 1966) were precursors to the application of numerical simulation for solving the Lamm equation (Dishon et al 1967) that finally generated concentration gradient distributions demonstrating the adequacy of the Fujita approximate analytical solution. Only limited advantage was taken of this breakthrough (Baldwin 1957;Van Holde 1960;Creeth and Winzor 1962;Inkerman et al 1975) before the virtual demise of analytical ultracentrifugation soon thereafter-a technique that was only revitalized by the appearance of a new-generation instrument in the final decade of the twentieth century. A second factor was the movement away from the less sensitive schlieren optical system to UV absorbance optics-a change that allowed experimental data to be obtained at much lower protein concentrations (a lower limit of about 10 μg/ml), where the effects of hydrodynamic nonideality leading to boundary sharpening are negligible.…”

Section: Introductionmentioning

confidence: 99%

“…On grounds of historical significance it seems timely to review the literature on the much earlier practice (Baldwin 1957;Van Holde 1960) of employing the approximate analytical solution (Fujita 1956(Fujita , 1962 of the Lamm equation to determine the diffusion coefficient from sedimentation velocity distributions that reflect the boundary sharpening resulting from linear s−c dependence; and also to take advantage of a current numerical integration procedure (Schuck 1998(Schuck , 2000 for solving the Lamm equation to provide simulated sedimentation velocity distributions that allow more critical assessment of the consequences of the enforced simplification on which the approximate solution is based. Although the effort and understanding required to employ those analytical procedures is likely to preclude any future applications, their review at this time serves to emphasize the advanced level of boundary spreading analysis that had been attained over 60 years ago.…”

Section: Introductionmentioning

confidence: 99%

Allowance for boundary sharpening in the determination of diffusion coefficients by sedimentation velocity: a historical perspective

Winzor

Scott

2018

Biophys Rev

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This review summarizes endeavors undertaken in the middle of last century to employ the Lamm equation for quantitative analysis of boundary spreading in sedimentation velocity experiments on globular proteins, thereby illustrating the ingenuity required to achieve that goal in an era when an approximate analytical solution of that nonlinear differential equation of second order provided the only means for its application. Application of procedures based on that approximate solution to simulated sedimentation velocity distributions has revealed a slight disparity (about 3%) between returned and input values of the diffusion coefficient-a discrepancy comparable with that of estimates obtained by current simulative analyses based on numerical solution of the Lamm equation. Although the massive technological developments in the gathering and treatment of sedimentation velocity data over the past three to four decades have changed dramatically the manner in which boundary spreading is analyzed, they have not led to any significant improvement in the accuracy of the diffusion coefficient thereby deduced.

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A Modification of Fujita's Method for the Calculation of Diffusion Coefficients From Boundary Spreading in the Ultracentrifuge

Abstract: NotesVol. 64 fusion. Put in. another manner, as far as diffusion is concerned the diaphragm does effectively behave as if it were made up of a series of parallel capillaries.

Cited by 35 publications

References 2 publications

β‐Methylcrotonyl‐CoA‐Carboxylase

β‐Methylcrotonyl‐CoA‐Carboxylase

Quantifying the concentration dependence of sedimentation coefficients for globular macromolecules: a continuing age-old problem

Allowance for boundary sharpening in the determination of diffusion coefficients by sedimentation velocity: a historical perspective

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