Chun En Kung scite author profile

9-(Dicyanovinyl)julolidine (DCVJ) is a fluorescent dye whose intramolecular rotational relaxation is solvent dependent. Since its quantum yield increases with decreasing free volume, this molecule has been very useful in monitoring synthetic polymer reactions and measuring local microviscosity changes in phospholipid bilayers [Loutfy, R. O. (1986) Pure Appl. Chem. 58, 1239-1248; Kung, C. E., & Reed, J. K. (1986) Biochemistry 25, 6114-6121]. We have used DCVJ to follow the polymerization of tubulin, a protein that can assemble into a variety of polymorphic microstructures. DCVJ binding to free tubulin is accompanied by an increase in quantum yield, indicating that DCVJ has become partially immobilized. At 4 degrees C, DCVJ binds to a single population of high-affinity hydrophobic sites (Kd = 1.12 +/- 0.26 microM) with a stoichiometry that is protein concentration dependent. n, the number of moles of DCVJ bound per mole of alpha beta dimer, approaches 1 at concentrations less than or equal to 0.5 mg/mL but decreases to a lower limit of approximately 0.3 at concentrations greater than or equal to 2.0 mg/mL. The quantum yield also increases with increasing protein concentration. This trend is unaltered by the presence of microtubule-associated proteins. These results are analyzed in terms of a concentration-dependent oligomerization of tubulin at 4 degrees C. When tubulin is polymerized at 37 degrees C to microtubules or to sheets in the presence of Zn2+, the fluorescence intensity of DCVJ increases although the magnitude of this increase differs significantly. We are able to use the distinct fluorescent and binding characteristics of the bound dye to distinguish between these two polymorphs on a molecular level.

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An energetic evaluation of a “Smith” collagen microfibril model

Chen

Kung

Feairheller

et al. 1991

J Protein Chem

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An energy minimized three-dimensional structure of a collagen microfibril template was constructed based on the five-stranded model of Smith (1968), using molecular modeling methods and Kollman force fields (Weiner and Kollman, 1981). For this model, individual molecules were constructed with three identical polypeptide chains [Gly-Pro-Pro)n, (Gly-Prop-Hyp)n, or (Gly-Ala-Ala)n, where n = 4, 12, and 16) coiled into a right-handed triple-helical structure. The axial distance between adjacent amino acid residues is about 0.29 nm per polypeptide chain, and the pitch of each chain is approximately 3.3 residues. The microfibril model consists of five parallel triple helices packed so that a left-handed superhelical twist exists. The structural characteristics of the computed microfibril are consistent with those obtained for collagen by X-ray diffraction and electron microscopy. The energy minimized Smith microfibril model for (Gly-Pro-Pro)12 has an axial length of about 10.2 nm (for a 36 amino acid residue chain), which gives an estimated D-spacing (234 amino acids per chain) of approximately 66.2 nm. Studies of the microfibril models (Gly-Pro-Pro)12, (Gly-Pro-Hyp)12, and (Gly-Ala-Ala)12 show that nonbonded van der Waals interactions are important for microfibril formation, while electrostatic interactions contribute to the stability of the microfibril structure and determine the specificity by which collagen molecules pack within the microfibril.

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A membrane-mediated catalytic event in prothrombin activation.

Kung

Hayes²,

Mann³

1994

Journal of Biological Chemistry

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Chun En Kung

Microviscosity measurements of phospholipid bilayers using fluorescent dyes that undergo torsional relaxation

Fluorescent molecular rotors: a new class of probes for tubulin structure and assembly

An energetic evaluation of a “Smith” collagen microfibril model

A membrane-mediated catalytic event in prothrombin activation.

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