Pradip K. Nandi

Structural characterization of labeled clathrin and coated vesicles

Clathrin (8 S) and coated vesicles have been covalently labeled by using the sulfhydryl-labeling fluorescent probe N-(1-anilinonaphthalene)maleimide. A large increase in energy transfer from Trp to anilinonaphthalene (AN) residues was observed in clathrin in the pH range approximately 6.5-6.0, where the rate of clathrin self-association increased rapidly. The change in energy transfer was indicative of a conformational rearrangement, which could be responsible for the initiation of the clathrin self-association reaction to form coat structure. The AN label was found in both the coat and membrane proteins after dissociation of coated vesicles at pH 8.5. The labeled coat and membrane proteins readily recombined to form coated vesicles after reducing the pH to 6.5, indicating that the labeling did not interfere with the ability of clathrin to self-associate and interact with uncoated vesicles to form coat structure. A comparison of the AN fluorescence with the Coomassie blue pattern after electrophoresis in sodium dodecyl sulfate-gels revealed that a 180,000-Da protein (clathrin) was mainly labeled in coated vesicles, while a 110,000-Da protein was also strongly labeled in uncoated vesicles. AN-labeled baskets and coated vesicles have been prepared. Trypsin digestion reduced the sedimentation rate of baskets from 150 S to 120 S and of coated vesicles from 200 S to 150 S. Gel electrophoresis of baskets and coated vesicles showed extensive conversion of clathrin (Mr 180,000) to a product of Mr approximately equal to 110,000, suggesting equivalent structural organization of the coat in coated vesicles as in baskets. In both cases, the peptide(s) released from the vesicles by digestion were essentially free of fluorescent label. In the case of the uncoated vesicles, tryptic digestion released most of the proteins remaining after coat removal.

Effects of several antimalarials and phenothiazine compounds on the formation of coat structure from clathrin.

We have evaluated the effects of two phenothiazine and several antimalarial drugs on the rates of polymerization of 8S clathrin molecules to 300S coat structures. Most of the drugs investigated have been shown in other studies to inhibit receptor-mediated endocytosis through the coated pit regions of plasma membranes. The two types of drugs were found to accelerate the polymerization rate without having much effect on the size distribution of the polymer species. The activities of the drugs appear to depend on the dibasic moiety and a large, hydrophobic aromatic ring in their structures.

The stability and transitions of tryptic-digested clathrin

The pH-dependence of dissociation of trypsin-digested baskets has been determined by light scattering and compared with that of undigested baskets. Essentially no difference was found between the two types of baskets. The molecular transitions of clathrin derived from digested baskets have been studied by fluorescence spectra and polarization measurements and compared with those of undigested baskets. The transitions in both forms of clathrin were very similar. It is clear, therefore, that removal of about 1/3 of the mass from the distal portions of the arms of the clathrin triskelion does not affect its structural transitions. The interactions between clathrin molecules in the basket structure and those within the molecule appear, therefore, to remain intact in the smaller clathrin chains remaining after tryptic digestion. The function of the distal portion of the clathrin chain still awaits elucidation.