TY - JOUR
T1 - The angiogenic inhibitor long pentraxin PTX3 forms an asymmetric octamer with two binding sites for FGF2
AU - Inforzato, Antonio
AU - Baldock, Clair
AU - Jowitt, Thomas A.
AU - Holmes, David F.
AU - Lindstedt, Ragnar
AU - Marcellini, Marcella
AU - Rivieccio, Vincenzo
AU - Briggs, David C.
AU - Kadler, Karl E.
AU - Verdoliva, Antonio
AU - Bottazzi, Barbara
AU - Mantovani, Alberto
AU - Salvatori, Giovanni
AU - Day, Anthony J.
N1 - 16539, Arthritis Research Campaign, United KingdomG0701180, Medical Research Council, United Kingdom
PY - 2010/6/4
Y1 - 2010/6/4
N2 - The inflammation-associated long pentraxin PTX3 plays key roles in innate immunity, female fertility, and vascular biology (e.g. it inhibits FGF2 (fibroblast growth factor 2)-mediated angiogenesis). PTX3 is composed of multiple protomers, each composed of distinct N- and C-terminal domains; however, it is not known how these are organized or contribute to its functional properties. Here, biophysical analyses reveal that PTX3 is composed of eight identical protomers, associated through disulfide bonds, forming an elongated and asymmetric, molecule with two differently sized domains interconnected by a stalk. The N-terminal region of the protomer provides the main structural determinant underlying this quaternary organization, supporting formation of a disulfide-linked tetramer and a dimer of dimers (a non-covalent tetramer), giving rise to the asymmetry of the molecule. Furthermore, the PTX3 octamer is shown to contain two FGF2 binding sites, where it is the tetramers that act as the functional units in ligand recognition. Thus, these studies provide a unifying model of the PTX3 oligomer, explaining both its quaternary organization and how this is required for its antiangiogenic function. © 2010 by The American Society for Biochemistry and Molecular Biology, Inc.
AB - The inflammation-associated long pentraxin PTX3 plays key roles in innate immunity, female fertility, and vascular biology (e.g. it inhibits FGF2 (fibroblast growth factor 2)-mediated angiogenesis). PTX3 is composed of multiple protomers, each composed of distinct N- and C-terminal domains; however, it is not known how these are organized or contribute to its functional properties. Here, biophysical analyses reveal that PTX3 is composed of eight identical protomers, associated through disulfide bonds, forming an elongated and asymmetric, molecule with two differently sized domains interconnected by a stalk. The N-terminal region of the protomer provides the main structural determinant underlying this quaternary organization, supporting formation of a disulfide-linked tetramer and a dimer of dimers (a non-covalent tetramer), giving rise to the asymmetry of the molecule. Furthermore, the PTX3 octamer is shown to contain two FGF2 binding sites, where it is the tetramers that act as the functional units in ligand recognition. Thus, these studies provide a unifying model of the PTX3 oligomer, explaining both its quaternary organization and how this is required for its antiangiogenic function. © 2010 by The American Society for Biochemistry and Molecular Biology, Inc.
U2 - 10.1074/jbc.M109.085639
DO - 10.1074/jbc.M109.085639
M3 - Article
C2 - 20363749
SN - 1083-351X
VL - 285
SP - 17681
EP - 17692
JO - Journal of Biological Chemistry
JF - Journal of Biological Chemistry
IS - 23
ER -