The liver fatty acid binding protein - comparison of cavity properties of intracellular lipid-binding proteins

The crystal and solution structures of all of the intracellular lipid binding proteins (iLBPs) reveal a common -barrel framework with only small local perturbations. All existing evidence points to the binding cavity and a poorly delimited portal region as defining the function of each family member. The importance of local structure within the cavity appears to be its influence on binding affinity and specificity for the lipid. The portal region appears to be involved in the regulation of ligand exchange. Within the iLBP family, liver fatty acid binding protein or LFABP, has the unique property of binding two fatty acids within its internalized binding cavity rather than the commonly observed stoichiometry of one. Furthermore, LFABP will bind hydrophobic molecules larger than the ligands which will associate with other iLBPs. The crystal structure of LFABP contains two bound oleate molecules and provides the explanation for its unusual stoichiometry. One of the bound fatty acids is completely internalized and has its carboxylate interacting with an arginine and two serines. The second oleate represents an entirely new binding mode with the carboxylate on the surface of LFABP. The two oleates also interact with each other. Because of this interaction and its inner location, it appears the first oleate must be present before the second more external molecule is bound.     

Structural properties of the adipocyte lipid binding protein

The adipocyte lipid binding protein, ALBP (also adipocyte fatty acid binding protein, A-FABP, 422 protein, aP2, and p15 protein), is one of the most studied of the intracellular lipid binding protein family. Here we sequentially compare the different sources of ALBP and describe the idea that one-third of the amino acid side chains near the N-terminal end appear to play a major role in conformational dynamics and in ligand transfer. Crystallographic data for mouse ALBP are summarized and the ligand binding cavity analyzed in terms of the overall surface and conformational dynamics. The region of the proposed ligand portal is described. Amino acid side chains critical to cavity formation and fatty acid interactions are analyzed by comparing known crystal structures containing a series of different hydrophobic ligands. Finally, we address ALBP ligand binding affinity and thermodynamic studies.     

Liver fatty acid binding protein: species variation and the accommodation of different ligands

The crystal structure of rat liver fatty acid binding protein (LFABP) and an alignment of amino acid sequences of all known species have been used to demonstrate two groups or sub-classes. Based on estimates at neutral pH and the electrostatic field calculated using the crystal coordinates, some evidence of changes that occur in going from holo- to apo-forms has been obtained. LFABP belongs to a large family frequently referred to as the intracellular lipid binding proteins or iLBPs. LFABP, unlike other family members, has two fatty acid binding sites. The two cavity sites have been reviewed and arguments for interactions between the sites are presented. Based on the crystal structure of rat LFABP, differences between the A and B groups have been postulated. Last of all, hypothetical models have been built of complexes of LFABP and heme, and LFABP and oleoyl CoA. In both cases, the stoichiometry is one to one and the models show why this is likely.