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Science 22 March 1991:
Vol. 251. no. 5000, pp. 1456 - 1464
DOI: 10.1126/science.2006420
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Articles

Science, Vol 251, Issue 5000, 1456-1464
Copyright © 1991 by American Association for the Advancement of Science

articles

The three-dimensional structure of canine parvovirus and its functional implications

J Tsao, MS Chapman, M Agbandje, W Keller, K Smith, H Wu, M Luo, TJ Smith, MG Rossmann, RW Compans, and al. et

Department of Biological Sciences, Purdue University, West Lafayette, IN 47907.

The three-dimensional atomic structure of a single-stranded DNA virus has been determined. Infectious virions of canine parvovirus contain 60 protein subunits that are predominantly VP-2. The central structural motif of VP-2 has the same topology (an eight-stranded antiparallel beta barrel) as has been found in many other icosahedral viruses but represents only about one-third of the capsid protein. There is a 22 angstrom (A) long protrusion on the threefold axes, a 15 A deep canyon circulating about each of the five cylindrical structures at the fivefold axes, and a 15 A deep depression at the twofold axes. By analogy with rhinoviruses, the canyon may be the site of receptor attachment. Residues related to the antigenic properties of the virus are found on the threefold protrusions. Some of the amino termini of VP-2 run to the exterior in full but not empty virions, which is consistent with the observation that some VP-2 polypeptides in full particles can be cleaved by trypsin. Eleven nucleotides are seen in each of 60 symmetry-related pockets on the interior surface of the capsid and together account for 13 percent of the genome.


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