DISCRETE BACKBONE DISORDER IN THE NUCLEAR-MAGNETIC-RESONANCE STRUCTURE OF APO INTESTINAL FATTY-ACID-BINDING PROTEIN - IMPLICATIONS FOR THE MECHANISM OF LIGAND ENTRY
Me. Hodsdon et Dp. Cistola, DISCRETE BACKBONE DISORDER IN THE NUCLEAR-MAGNETIC-RESONANCE STRUCTURE OF APO INTESTINAL FATTY-ACID-BINDING PROTEIN - IMPLICATIONS FOR THE MECHANISM OF LIGAND ENTRY, Biochemistry, 36(6), 1997, pp. 1450-1460
The three-dimensional structure of the unliganded form of Escherichia
coli-derived rat intestinal fatty acid-binding protein (I-FABP) has be
en determined using triple-resonance three-dimensional nuclear magneti
c resonance (3D NMR) methods. Sequence-specific H-1, C-13, and N-15 re
sonance assignments were established at pH 7.2 and 33 degrees C and us
ed to determine the consensus H-1/C-13 chemical shift-derived secondar
y structure. Subsequently, an eight-stage iterative procedure was used
to assign the 3D C-13- and N-15-resolved NOESY spectra, yielding a to
tal of 3335 interproton distance restraints or 26 restraints/residue.
The tertiary structures were calculated using a distance geometry/simu
lated annealing algorithm that employs pairwise Gaussian metrization t
o achieve improved sampling and convergence. The final ensemble of NMR
structures exhibited a backbone conformation generally consistent wit
h the beta-clam motif described for members of the lipid-binding prote
in family, However, unlike holo-I-FABP, the structure ensemble for apo
-I-FABP exhibited variability in a discrete region of the backbone. Th
is variability was evaluated by comparing the apo- and holoproteins wi
th respect to their backbone H-1 and C-13 chemical shifts, amide H-1 e
xchange rates, and N-15 relaxation rates. Together, these results esta
blished that the structural variability represented backbone disorder
in apo-I-FABP. The disorder was most pronounced in residues K29-L36 an
d N54-N57, encompassing the distal half of alpha-helix II, the linker
between helix II and beta-strand B, and the reverse turn between beta-
strands C and D. It was characterized by a destablization of long-rang
e interactions between helix II and the C-D turn and a fraying of the
C-terminal half of the helix. Unlike the solution-state NMR structure,
the 1.2-Angstrom X-ray crystal structure of apo-I-FABP did not exhibi
t this backbone disorder. In solution, the disordered region may funct
ion as a dynamic portal that regulates the entry and exit of fatty aci
d. We hypothesize that fatty acid binding shifts the order-disorder eq
uilibrium toward the ordered state and closes the portal by stabilizin
g a series of cooperative interactions resembling a helix capping box.
This proposed mechanism has implications for the acquisition, release
, and targeting of fatty acids by I-FABP within the cell.