Characterization of the knob domain of the adenovirus type 5 fiber protein expressed in Escherichia coli.

The adenovirus fiber protein is used for attachment of the virus to a specific receptor on the cell surface. Structurally, the protein consists of a long, thin shaft that protrudes from the vertex of the virus capsid and terminates in a globular domain termed the knob. To verify that the knob is the domain which interacts with the cellular receptor, we have cloned and expressed the knob from adenovirus type 5 together with a single repeat of the shaft in Escherichia coli. The protein was purified by conventional chromatography and functionally characterized for its interaction with the adenovirus receptor. The recombinant knob domain bound about 4,700 sites per HeLa cell with an affinity of 3 x 10(9) M-1 and blocked adenovirus infection of human cells. Antibodies raised against the knob also blocked virus infection. By gel filtration and X-ray diffraction analysis of protein crystals, the knob was shown to consist of a homotrimer of 21-kDa subunits. The results confirm that the trimeric knob is the ligand for attachment to the adenovirus receptor.

The crystal structure of the Bacillus lentus alkaline protease, subtilisin BL, at 1.4 A resolution.

The crystal structure of subtilisin BL, an alkaline protease from Bacillus lentus with activity at pH 11, has been determined to 1.4 A resolution. The structure was solved by molecular replacement starting with the 2.1 A structure of subtilisin BPN' followed by molecular dynamics refinement using X-PLOR. A final crystallographic R-factor of 19% overall was obtained. The enzyme possesses stability at high pH, which is a result of the high pI of the protein. Almost all of the acidic side-chains are involved in some type of electrostatic interaction (ion pairs, calcium binding, etc.). Furthermore, three of seven tyrosine residues have potential partners for forming salt bridges. All of the potential partners are arginine with a pK around 12. Lysine would not function well in a salt bridge with tyrosine as it deprotonates at around the same pH as tyrosine ionizes. Stability at high pH is acquired in part from the pI of the protein, but also from the formation of salt bridges (which would affect the pI). The overall structure of the enzyme is very similar to other subtilisins and shows that the subtilisin fold is more highly conserved than would be expected from the differences in amino acid sequence. The amino acid side-chains in the hydrophobic core are not conserved, though the inter-residue interactions are. Finally, one third of the serine side-chains in the protein have multiple conformations. This presents an opportunity to correlate computer simulations with observed occupancies in the crystal structure.

Crystallographic analysis of trypsin-G226A. A specificity pocket mutant of rat trypsin with altered binding and catalysis.

The crystal structure of trypsin-G226A has been determined, in the presence of benzamidine, to a resolution of 1.75 A with an R-factor of 14.6%. The mutation was designed to alter substrate specificity by disrupting arginine binding, but was previously found to disrupt catalysis to a greater extent than binding. The arginine analog, benzamidine, has rotated 40 degrees and 49 degrees and translated 1.1 A in the specificity pocket, relative to the position in wild-type trypsin. The salt-bridge between the amidinium group of benzamidine and the carboxylate of D189 as well as four other hydrogen bonds have been replaced by a set of six new hydrogen bonds. Based on these interactions, computer modeling of an arginine substrate demonstrates that arginine terminal nitrogen atoms can occupy the new benzamidine nitrogen positions with torsion angle adjustments and without short contacts. In the secondary orientation, arginine substrates appear to be forced out of alignment with the active site. This may account for the larger drop in kcat with arginine relative to lysine substrates. A second possible cause of the altered activity is a change of the enzyme structure with concomitant loss of activity. No evidence of such a change is seen in the co-ordinates or temperature factors of the trypsin-G226A-benzamidine complex. A226 disrupts mainly the co-ordinates of amino acids with which it has direct contacts such that the effects of the mutation are absorbed locally.

Crystal structure of rat trypsin-S195C at -150 degrees C. Analysis of low activity of recombinant and semisynthetic thiol proteases.

The X-ray crystal structure of trypsin-S195C, a rat anionic trypsin mutant in which the active site serine has been replaced by cysteine, was determined at -150 degrees C and room temperature to 1.6 A resolution, R = 15.4% and 1.8 A resolution, R = 15.0%, respectively. Cryo-crystallography was employed to improve the quality of the diffraction data and the resulting structure by eliminating radiation damage and decreasing atomic thermal motion. The average temperature factor decreased by 10 A2 relative to that of the room temperature structure. No radiation-induced decay of the data was detected. The side-chains of the catalytic cysteine and histidine of trypsin-S195C are found with 25% occupancy in secondary orientations rotated 104 degrees and 90 degrees out of the active site, respectively. These alterations, as well as more subtle changes in the active site may be caused by the oxidation of the catalytic sulfur to sulfenic acid. The position of the carbonyl carbon of the tetrahedral intermediate analog, p-amidinophenylpyruvic acid, modeled into trypsin-S195C, is 1.1 A from the catalytic sulfur. The large size and altered approach of the catalytic sulfur to substrates could account for the observed low catalytic activity relative to wild-type trypsin. In addition to the benzamidine in the specificity pocket, two additional binding sites for benzamidine are characterized. One of these mediates an intermolecular contact that appears to maintain the crystal lattice.

Crystal structures of two engineered thiol trypsins.

We have determined the three-dimensional structures of engineered rat trypsins which mimic the active sites of two classes of cysteine proteases. The catalytic serine was replaced with cysteine (S195C) to test the ability of sulfur to function as a nucleophile in a serine protease environment. This variant mimics the cysteine trypsin class of thiol proteases. An additional mutation of the active site aspartate to an asparagine (D102N) created the catalytic triad of the papain-type cysteine proteases. Rat trypsins S195C and D102N,S195C were solved to 2.5 and 2.0 A, respectively. The refined structures were analyzed to determine the structural basis for the 10(6)-fold loss of activity of trypsin S195C and the 10(8)-fold loss of activity of trypsin D102N,S195C, relative to rat trypsin. The active site thiols were found in a reduced state in contrast to the oxidized thiols found in previous thiol protease structures. These are the first reported structures of serine proteases with the catalytic centers of sulfhydryl proteases. Structure analysis revealed only subtle global changes in enzyme conformation. The substrate binding pocket is unaltered, and active site amino acid 102 forms hydrogen bonds to H57 and S214 as well as to the backbone amides of A56 and H57. In trypsin S195C, D102 is a hydrogen-bond acceptor for H57 which allows the other imidazole nitrogen to function as a base during catalysis. In trypsin D102N,S195C, the asparagine at position 102 is a hydrogen-bond donor to H57 which places a proton on the imidazole nitrogen proximal to the nucleophile. This tautomer of H57 is unable to act as a base in catalysis.(ABSTRACT TRUNCATED AT 250 WORDS)