1KXD

SINDBIS VIRUS CAPSID (N222L MUTANT), TETRAGONAL CRYSTAL FORM

Summary for 1KXD

• Entry DOI: 10.2210/pdb1kxd/pdb
• Descriptor: SINDBIS VIRUS CAPSID PROTEIN (1 entity in total)
• Functional Keywords: sindbis virus capsid protein, chymotrypsin-like serine proteinase, wild type, coat protein, viral protein
• Biological source: Sindbis virus
• Cellular location: Capsid protein: Virion (By similarity). p62: Virion membrane; Single-pass type I membrane protein (By similarity). E2 envelope glycoprotein: Virion membrane; Single-pass type I membrane protein (By similarity). E1 envelope glycoprotein: Virion membrane; Single-pass type I membrane protein (By similarity). 6K protein: Host cell membrane; Multi-pass membrane protein (By similarity): P03316
• Total number of polymer chains: 1
• Total formula weight: 17417.73

Authors

Choi, H.-K.,Rossmann, M.G. (deposition date: 1996-05-05, release date: 1996-11-08, Last modification date: 2024-02-14)

Primary citation

Choi, H.K.,Lee, S.,Zhang, Y.P.,McKinney, B.R.,Wengler, G.,Rossmann, M.G.,Kuhn, R.J.
Structural analysis of Sindbis virus capsid mutants involving assembly and catalysis.
J.Mol.Biol., 262:151-167, 1996

PubMed Abstract: Sindbis virus core protein (SCP) has been isolated from virus and crystallized. The X-ray crystallographic structure showed that the amino-terminal 113 residues appeared to be either disordered or truncated during crystallization and that the carboxy-terminal residues 114 to 264 had a chymotrypsin-like structure. The carboxy-terminal residues 106 to 264 and 106 to 266 of SCP have now been expressed in Escherichia coli. Most crystal forms of the truncated proteins were isomorphous with those of the virally extracted protein. There are only small structural differences between the truncated recombinant protein and the ordered part of the wild-type virus-extracted protein. Hence, E. coli-expressed SCP can be used to study proteolytic properties and the contribution of SCP to nucleocapsid assembly, interaction with the E2 glycoprotein and interaction with RNA. The same dimer that was found in two different crystal forms of the virus-extracted SCP was present also in some of the crystals of the truncated recombinant protein. The monomer-monomer interface is maintained by two pairs of hydrogen bonds and by hydrophobic interactions. Removal of the hydrogen bonds by single substitutions did not prevent dimer formation. However, a mutation that reduced the hydrophobic contacts did inhibit dimer formation. The wild-type truncated SCP is active in E. coli, as evidenced by proteolytic processing of a series of progressively longer precursors that extend beyond residue 264. Unlike the virus-extracted capsid protein, the E. coli-expressed SCP described here is terminated following the carboxy-terminal residue and, therefore, does not require autocatalysis. Nevertheless, the E. coli-expressed protein folds with the carboxy-terminal tryptophan residue in the specificity pocket. Two crystallographically independent molecules of SCP(106 to 266), which had two additional downstream residues and had the essential S215 mutated to alanine, showed two distinct modes of binding the uncleaved carboxy-terminal residues. These may represent successive steps of binding substrate prior to catalytic cleavage. Refinement of the various crystal structures of SCP showed that the amino-terminal arm from residues 107 to 113 was not disordered, but is associated with neighboring molecules. Residues 108 to 111 bind into a hydrophobic pocket composed primarily of Y180, W247 and F166. It had been shown that the double mutant (Y180S; E183G), with the Y180S substitution in this pocket, produced a large number of non-infectious virions, possibly because of modification in the interaction of the glycoprotein spikes with core proteins. The crystal structure of this double mutant showed that there was a large positional change in the side-chain of W247, which moved into the space created by the replacement of Y180 with serine. These conformational changes may alter the stability of the virion and, thus, regulate its functional requirements during cell entry.

PubMed: 8831786
DOI: 10.1006/jmbi.1996.0505

Experimental method

X-RAY DIFFRACTION (3 Å)