Molecular structures of proteins involved in vesicle coat formation.

This review includes 16 structures of vesicle coat components and accessory proteins and a description of their roles in vesicle budding or coat disassembly.

Molecular structures of proteins involved in vesicle fusion.

We present a summary of the structures of 13 proteins involved in the docking and fusion of intracellular transport vesicles to their target membranes.

Clathrin self-assembly is mediated by a tandemly repeated superhelix.

Clathrin is a triskelion-shaped cytoplasmic protein that polymerizes into a polyhedral lattice on intracellular membranes to form protein-coated membrane vesicles. Lattice formation induces the sorting of membrane proteins during endocytosis and organelle biogenesis by interacting with membrane-associated adaptor molecules. The clathrin triskelion is a trimer of heavy-chain subunits (1,675 residues), each binding a single light-chain subunit, in the hub domain (residues 1,074-1,675). Light chains negatively modulate polymerization so that intracellular clathrin assembly is adaptor-dependent. Here we report the atomic structure, to 2.6 A resolution, of hub residues 1,210-1,516 involved in mediating spontaneous clathrin heavy-chain polymerization and light-chain association. The hub fragment folds into an elongated coil of alpha-helices, and alignment analyses reveal a 145-residue motif that is repeated seven times along the filamentous leg and appears in other proteins involved in vacuolar protein sorting. The resulting model provides a three-dimensional framework for understanding clathrin heavy-chain self-assembly, light-chain binding and trimerization.

H-bonding maintains the active site of type 1 copper proteins: site-directed mutagenesis of Asn38 in poplar plastocyanin.

Type I Cu proteins maintain a trigonal N2S coordination group (with weak axial ligation) in both oxidation states of the Cu2+/+ ion, thereby reducing the reorganization energy for electron transfer. Requirements for maintaining this coordination group were investigated in poplar plastocyanin (Pcy) by mutation of a conserved element of the type 1 architecture, an asparagine residue (Asn38) adjacent to one of the ligating histidines. The side chain of this asparagine forms an active site clasp via two H-bonds with the residue (Ser85) adjacent to the ligating cysteine (Cys84). In addition, the main chain NH of Asn38 donates an H-bond to the thiolate ligand. We have investigated the importance of these interactions by mutating Asn38 to Gln, Thr, and Leu. The mutant proteins are capable of folding and binding Cu2+, but the blue color fades; the rate of fading increases in the order Gln < Thr < Leu. The color is not restored by ferricyanide, showing that the protein is modified irreversibly, probably by oxidation of Cys84. The more stable mutants N38Q and N38T were characterized spectroscopically. The wild-type properties are slightly perturbed for N38Q, but N38T shows remarkable similarity to another type 1 Cu protein, azurin (Azu) from Pseudomonas aeruginosa. The Cu-S(Cys) bond is longer in Azu than in Pcy, and the NH H-bond to the ligating S atom is shorter. Molecular modeling suggests a similar effect for N38T because the threonine residue shifts toward Ser85 in order to avoid a steric clash and to optimize H-bonding. These results demonstrate that H-bonding adjacent to the type 1 site stabilizes an architecture which both modulates the electronic properties of the Cu, and suppresses side reactions of the cysteine ligand.

Clathrin self-assembly is regulated by three light-chain residues controlling the formation of critical salt bridges.

Clathrin self-assembly into a polyhedral lattice mediates membrane protein sorting during endocytosis and organelle biogenesis. Lattice formation occurs spontaneously in vitro at low pH and, intracellularly, is triggered by adaptors at physiological pH. To begin to understand the cellular regulation of clathrin polymerization, we analyzed molecular interactions during the spontaneous assembly of recombinant hub fragments of the clathrin heavy chain, which bind clathrin light-chain subunits and mimic the self-assembly of intact clathrin. Reconstitution of hubs using deletion and substitution mutants of the light-chain subunits revealed that the pH dependence of clathrin self-assembly is controlled by only three acidic residues in the clathrin light-chain subunits. Salt inhibition of hub assembly identified two classes of salt bridges which are involved and deletion analysis mapped the clathrin heavy-chain regions participating in their formation. These combined observations indicated that the negatively charged regulatory residues, identified in the light-chain subunits, inhibit the formation of high-affinity salt bridges which would otherwise induce clathrin heavy chains to assemble at physiological pH. In the presence of light chains, clathrin self-assembly depends on salt bridges that form only at low pH, but is exquisitely sensitive to regulation. We propose that cellular clathrin assembly is controlled via the simple biochemical mechanism of reversing the inhibitory effect of the light-chain regulatory sequence, thereby promoting high-affinity salt bridge formation.

Sequence replacements in the central beta-turn of plastocyanin.

The role of beta-turns in dictating the structure of a beta-barrel protein is assessed by probing the tolerance of the central beta-turn of poplar plastocyanin to substitution by arbitrary sequences. Native plastocyanin binds copper and is colored bright blue. However, when the wild-type Pro47-Ser48-Gly49-Val50 turn sequence is replaced by arbitrary tetrapeptides, the vast majority (92/98 = 94%) of mutant proteins cannot fold into the native blue structure. Characterization of the colorless mutant proteins demonstrates that the majority of substitutions in this type II beta-turn disrupt the native structure severely. Gross structural changes are indicated by major differences in the CD spectra of the mutants relative to the wild-type protein, and by the much larger apparent size of mutant proteins in gel filtration experiments. These mutant proteins do not bind copper. Furthermore, Cys84 forms a disulfide bond readily in the colorless mutant proteins, indicating that it has moved away from the buried position it occupies in the native copper binding site and has become exposed. These results indicate that the central beta-turn in plastocyanin is not merely a default structure arising in response to the surrounding context; rather, sequence information in this turn plays an active role in dictating the location of a chain reversal in the beta-barrel structure. These findings are discussed in terms of their implications for the folding of natural proteins, as well as the design of de novo proteins.

Periplasmic fractionation of Escherichia coli yields recombinant plastocyanin despite the absence of a signal sequence.

Poplar plastocyanin has been expressed in E. coli from a synthetic gene cloned into the T7 expression system. Despite the absence of a signal sequence, large quantities of the recombinant protein were readily obtained by procedures typically used to isolate proteins from the bacterial periplasm. Several different fractionation methods were equally successful. The presence of plastocyanin in these fractions does not reflect wholesale leakage of intracellular proteins, since neither beta-galactosidase activity nor the bulk of Escherichia coli proteins were released by the fractionation. The identity of the overexpressed protein was unequivocally proven to be poplar plastocyanin by N-terminal amino acid sequence analysis and by spectroscopic characterization of the purified blue copper protein.

Slow-folding kinetics of ribonuclease-A by volume change and circular dichroism: evidence for two independent reactions.

The slow refolding of guanidine-HCl-denatured ribonuclease-A was studied by volume change and by kinetic CD at 222 and 276 nm. Dilatometric measurements revealed that on refolding there is a fast volume change of +232 mL/mol of protein. This is followed by a very slow nonexponential change that takes about 25 min to reach equilibrium. By adding varying amounts of (NH4)2SO4, the slow volume change curve was resolved into 2 concurrent reactions. The faster of the 2 slow events entails a negative volume change of -64 mL/mol of protein and appears to arise from proline isomerization. The slower process, attended by a positive change of +53 mL/mol of protein, has properties consistent with the "XY" reaction of Lin and Brands (1983, Biochemistry 22:563-573). This reaction is so named because the conformational nature of neither its initial (Y) nor its final state (X) is known; the transition is characterized solely by its absorbance and fluorescence kinetics. These are the first direct physical measures attributable to the "XY" process. The early formation of a compact structure in the event responsible for the rapid +232-mL/mol volume change, however, is consistent with the sequential model of folding (Cook KH, Schmid FX, Baldwin RL, 1979, Proc Natl Acad Sci USA 76:6157-6161; Kim PS, Baldwin RL, 1980, Biochemistry 19:6124-6129). The usefulness of volume change measurements as a method of detecting structural rearrangements was confirmed by finding agreement between time constants obtained from parallel volume change and kinetic CD experiments. The measured volume changes arise from both changes in hydration and changes in the packing of atoms in the interior of the protein.