NMR DETERMINATION OF THE SECONDARY STRUCTURE AND THE 3-DIMENSIONAL POLYPEPTIDE BACKBONE FOLD OF THE HUMAN STEROL CARRIER PROTEIN-2

Nuclear magnetic resonance (NMR) spectroscopy was used to determine the secondary structure and the three-dimensional polypeptide backbone fold of the human sterol carrier protein 2 (hSCP2), which is a basic protein with 123 residues believed to participate in the intracellular transport of cholesterol and various other lipids. Sequence-specific assignments were obtained for nearly all backbone H-1 and N-15 resonances, as well as for about two-thirds of the side-chain H-1 resonances, using uniform N-15-labeling of the protein combined with homonuclear two-dimensional H-1 NMR and three-dimensional N-15-correlated H-1 NMR. Three a-helices comprising the polypeptide segments of residues 9-22, 25-30 and 78-84 were identified by sequential and medium-range nuclear Overhauser effects (NOE). The analysis of long-range backbone-backbone NOEs showed that hSCP2 further contains a five-stranded P-sheet including the residues 33-41, 47-54, 60-62, 71-76 and 100-102, which is a central feature of the molecular architecture. The first three strands are arranged in an antiparallel fashion, the polypeptide chain then crosses over this three-stranded sheet in a right-handed sense so that the fourth strand is added parallel to the first one. The fifth strand runs antiparallel to the fourth one, so that the overall topology is +1, +1, -3x, -1. The three-dimensional arrangement of the beta-sheet and the first two helices was determined using an input of 625 NOE upper distance constraints and 95 scalar coupling constants for a preliminary structure calculation with the distance geometry program DIANA.