Characterization by NMR and molecular modeling of the binding of polyisoprenols and polyisoprenyl recognition sequence peptides: 3D structure of the complexes reveals sites of specific interactions

doi:10.1093/glycob/cwg008

Glycobiology Advance Access originally published online on November 1, 2002

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Glycobiology, 2003, Vol. 13, No. 2 51-71
© 2003 Oxford University Press

Characterization by NMR and molecular modeling of the binding of polyisoprenols and polyisoprenyl recognition sequence peptides: 3D structure of the complexes reveals sites of specific interactions

Guo-ping Zhou¹ and Frederic A. Troy, II²

Department of Biological Chemistry, University of California Schoolof Medicine, One Shields Avenue, Davis, CA 95616-8635, USA

Received on April 16, 2002; revised on August 27, 2002; accepted on September 6, 2002

The objective of these studies was to test the hypothesis thatproteins that contain potential polyisoprenyl recognition sequences(PIRSs) in their transmembrane-spanning domain can bind to thepolyisoprenyl (PI) glycosyl carrier lipids undecaprenyl phosphate(C₅₅-P) and dolichyl phosphate (C₉₅-P). A number of prokaryoticand eukaryotic glycosyltransferases that utilize PI coenzymescontain a conserved PIRS postulated to be the active PI bindingdomain. To study this problem, we first determined the 3D structureof a PIRS peptide, NeuE, by homonuclear 2D ¹H–nuclearmagnetic resonance (NMR) spectroscopy. Experimentally generateddistance constraints derived from nuclear Overhauser enhancementand torsion angle constraints derived from coupling constantswere used for restrained molecular dynamics and energy minimizationcalculations. Molecular models of the NeuE peptide were builtbased on calculations of energy minimization using the DGIIprogram NMRchitect. 3D models of dolichol (C₉₅) and C₉₅-P werebuilt based on our 2D ¹H-NMR nuclear Overhauser enhancementspectroscopy (NOESY) results and refined by energy minimizationwith respect to all atoms using the AMBER (assisted modelingwith energy refinements) force field. Our energy minimizationstudies were carried out on a conformational model of dolicholthat was originally derived from small-angle X-ray scatteringand molecular mechanics methods. These results revealed thatthe PIs are conformationally nearly identical tripartite molecules,with their three domains arranged in a coiled, helical structure.Analyses of the intermolecular cross-peaks in the 2D NOESY spectraof PIRS peptides in the presence of PIs confirmed a highly specificinteraction and identified key contact amino acids in the NeuEpeptide that constituted a binding motif for interacting withthe PIs. These studies also showed that subtle conformationalchanges occurred within both the PIs and the NeuE peptide afterbinding. 3D structures of the resulting molecular complexesrevealed that each PI could bind more than one PIRS peptide.These studies thus represent the first evidence for a directphysical interaction between specific contact amino acids inthe PIRS peptides and the PIs and supports the hypothesis ofa bifunctional role for the PIs. The central idea is that thesesuperlipids may serve as a structural scaffold to organize andstabilize in functional domains PIRS-containing proteins withinmultiglycosyltransferase complexes that participate in biosyntheticand translocation processes.

¹ Present address: Harvard Medical School, Beth Israel DeaconessMedical Center, 41 Avenue Louis Pasteur, Research East Room301, Boston, MA 02115, USA.

2 To whom correspondence should be addressed; e-mail: fatroy{at}ucdavis.edu

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