Spectrin, a highly dynamic skeletal membrane protein, plays an important role in maintaining the disk biconcave shape of the human erythrocyte. The sequence of spectrin is mostly composed of repeating segments of 106 amino acids which have been proposed to form unique structural domains. Electronic and vibrational circular dichroism and Fourier transform infrared (FTIR) spectroscopy were used as complementary techniques to study the secondary structure of spectrin. The amide I and II regions of the FTIR absorbance spectra were analyzed using partial least-squares analysis. The secondary structure of spectrin under physiological buffer conditions was estimated to be about 70% alpha-helix, 10% beta-sheet, and 20% other. We believe that this is the first detailed experimental evidence of significant beta-sheet content in spectrin secondary structure. The antiparallel beta-sheet SH3 domain in the center of the alpha-subunit in spectrin accounts for only about 1.5% of the total amino acid residues in the dimer. Hydrodynamic studies have shown spectrin to be sensitive to changes in ionic strength and to addition of denaturing agents. Our FTIR results showed that the secondary structure of spectrin treated with detergent or NaOH changed by 10-20%. The Stokes radii of the spectrin samples used for FTIR measurements were found to vary as a function of the ionic strength, but their secondary structures did not change as a function of ionic strength. These results indicate that while the overall hydrodynamic dimension of spectrin depends on the medium ionic strength, the secondary structure remains essentially constant.(ABSTRACT TRUNCATED AT 250 WORDS)
Dynamic light scattering measurements were performed on spectrin from human erythrocytes in 25 mM Tris buffer at pH 7.6 with 100 mM NaCl and 5 mM EDTA. Measurements were made on spectrin solutions prepared as dimers and tetramers over the temperature range from 23 to 41 degrees C, as a function of the square of the scattering vector (K2) over the range of 0.7 x 10(10) cm-2 less than or equal to K1 less than or equal to 20 x 10(10) cm-2. Analysis of the autocorrelation functions collected for these solutions revealed the presence of two predominant motional components over the entire range of K2. Plots of the diffusion coefficients (D20) of these components, with viscosity and temperature corrected to water at 20 degrees C, as a function of K2 indicated three rather distinct regions, flat regions at low and high K2 joined by a sloping intermediate region. At small K2 (less than or equal to 4 x 10(10) cm-2) the D20 values were (7.3 +/- 2.0) x 10(-8) cm2/s for the slow component and (20.3 +/- 2.0) x 10(-8) cm2/s for the fast component. At large K2 (greater than or equal to 10 x 10(10) cm-2) the values increased to (13.0 +/- 2.0) x 10(-8) cm2/s for the slow component and (39.4 +/- 2.0) x 10(-8) cm2/s for the fast component. In the intermediate K2 region, D20 is a linear function of K2 and appears as a transition between the low and high K2 regions.(ABSTRACT TRUNCATED AT 250 WORDS)
We used electron microscopy, quasi-elastic light scattering and static light scattering to show that human hemoglobin (Hb) interacts with bovine brain phosphatidylserine lipid vesicles and promotes vesicle fusion in an isotonic buffer at pH 7.4. The fusogenic properties of Hb were observed in both small unilamellar vesicles (SUVs) and large unilamellar vesicles (LUVs). A simple turbidity measurement method was used to follow increases in vesicle size (scattering diameter) as a function of time. For the first 3 h, upon incubation with oxygenated Hb, the scattering diameters of vesicles increased at a rate of 7.8 nm/h for LUVs. Continuous incubation with Hb led to complicated vesicle fusion, probably due to the oxidation products of Hb and lipid molecules. In the absence of both Hb and lipid oxidation, using Hb liganded with carbon monoxide, we obtained, for the entire 20 h incubation period, a fusion rate of 2.9 nm/h for LUVs. We also studied interactions between sickle Hb and vesicles under the same conditions and found that the vesicle fusion rates for sickle Hb were about 2 times faster than those for normal Hb. These results showed that sickle Hb exhibited more extensive interactions with lipid bilayer than normal Hb at physiological pH and ionic strength conditions, and provide insights toward understanding the molecular mechanisms in sickle cell abnormalities.
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