The patch-clamp technique and fluorescence polarization analysis were used to study the dependence of Ca2(+)-dependent K+ channel kinetics and membrane fluidity on cholesterol (CHS) levels in the plasma membranes of cultured smooth muscle rabbit aortic cells. Mevinolin (MEV), a potent inhibitor of endogenous CHS biosynthesis was used to deplete the CHS content. Elevation of CHS concentration in the membrane was achieved using a CHS-enriching medium. Treatment of smooth muscle cells with MEV led to a nearly twofold increase in the rotational diffusion coefficient of DPH (D) and to about a ninefold elevation of probability of the channels being open (Po). The addition of CHS to the cells membrane resulted in a nearly twofold decrease in D and about a twofold decrease in Po. Elementary conductance of the channels did not change under these conditions. These data suggest that variations of the CHS content in the plasma membrane of smooth muscle cells affect the kinetic properties of Ca2(+)-dependent K+ channels presumably due to changes in plasma membrane fluidity. Our results give a possible explanation for the reported variability of Ca2(+)-dependent K+ channels kinetics in different preparations.
The influence of different methods of binding the OV-TL16 antibody and its Fab' fragment to N-(2-hydroxypropyl)methacrylamide (HPMA) copolymer--drug (adriamycin [ADR] or meso chlorin e6 mono(N-2-aminoethylamide) (Mce6)) conjugates on the affinity of conjugates to an ovarian carcinoma (OVCAR-3) cell associated antigen was investigated. The binding of the antibody to HPMA copolymer--drug (ADR or Mce6) conjugates via amino groups resulted in conjugates which were heterogeneous in their antigen binding. Coupling, the HPMA copolymer--Mce6 conjugate to the carbohydrate region of the antibody resulted in conjugates with a more homogeneous distribution of affinity constants than conjugates prepared by linking the antibody to the polymer via amino groups. However, both methods resulted in a decrease in the affinity constant compared to the native antibody. Conjugates prepared with the Fab' frgment of the OV-TL16 antibody demonstrated a more homogenous affinity than either conjugate prepared with the whole antibody. To verify the hypothesis that the changes in the binding affinity and homogeneity are a consequence of conformational changes in the antibody structure, a series of physiocochemical methods were employed to characterize the conjugates. The excitation energy transfer between OV-TL16 antibody and drugs (ADR and Mce6) and the spectral properties of Mce6 were used to monitor the interactions between the antibody and drugs. The quenching of the intrinsic fluorescence of the antibody was also employed to study its conformational changes. An attempt has been made to correlate the biorecognition at the cellular surface with the interactions of drug with the antibody molecule and with the changes in antibody conformation.
Anti-fluorescein antibodies are excellent model systems for studying the biochemical basis of molecular recognition because a prodigious amount of both physico-chemical and structural information is available for these antibodies. Furthermore, recombinant single-chain antibodies have been produced for several anti-fluorescein antibodies, and site-specific mutagenesis studies have defined the energetic contributions of a number of key active-site residues. In previous studies, we determined the three-dimensional structure of an antigen-binding fragment of a high-affinity anti-fluorescein antibody (4-4-20) in complex with fluorescein. These studies showed that fluorescein binds tightly in an aromatic slot and participates in a network of electrostatic interactions. In this report, we examine the role of electrostatic interactions in the 4-4-20 antigen-combining site by observing the effects of pH on the fluorescence of fluorescein and antigen-binding affinity. These studies showed that the salt link between fluorescein and Arg-L34 in 4-4-20 probably accounts for about -1.5 kcal/mol-1 of the observed free energy of interaction. Furthermore, at pH 10 and higher, the affinity decreases by more than 100-fold (delta delta G degrees approximately equal to 3 kcal mol-1). We attributed this decrease to the ionization of Tyr-L32, which probably disrupts a hydrogen bond between tyrosine's hydroxyl group and fluorescein's phenylcarboxylate group. The fluorescence lifetime of the 4-4-20/fluorescein complex was determined at both pH 8 and pH 10.6. Only one lifetime component (0.38 ns) was observed at pH 8, while two components (0.3 and 3.4 ns) were observed at pH 10.6.(ABSTRACT TRUNCATED AT 250 WORDS)
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