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Beta Lactoglobulin

β-Lactoglobulin (β-LG) is the major whey protein of ruminant species and is also present in the milks of many, but not all, other species. Its amino-acid sequence and 3-dimensional structure show that it is a lipocalin, a widely diverse family, most of which bind small hydrophobic ligands and thus may act as specific transporters, as does serum retinol binding protein. Bovine β-LG binds a wide range of ligands, but this may not be the reason for its presence in milk. In reviewing the structure and physicochemical properties of the protein, we present the structures of the ligands cholesterol (at a resolution of 2.0Å, R = 0.221; Rfree = 0.295) and vitamin D2 (at a resolution of 2.4Å, R = 0.212; Rfree = 0.297) each bound to the central binding cavity of bovine β-LG at pH 7.3. Neither ligand is fully visible in the electron density maps, and the less well-ordered regions are the polar end groups at the mouth of the binding site. In a separate experiment, a mercury ion was bound to the free Cys121 (at a resolution of 2.2Å, R = 0.218; Rfree = 0.288) in a way that transmitted a small structural change through Asp137 via Arg148 to the dimer interface. It is not clear if the known dissociation that arises from the reaction of β-LG with HgCl2 results from this perturbation.

In reviewing the structural studies that reveal the ligand binding sites for long-chain fatty acids, retinoids, and steroids, only the central location, common to all lipocalins so far examined, is occupied under the conditions used. We find that there is no crystallographic evidence of another ligand binding site in our crystals grown in approximately 1.3 M citrate, although low ionic strength studies in solution indicate the possible presence of at least one other low affinity site. The apparent ability of the binding site to accommodate a wide range of ligands may point to a possible physiological function. However, by considering the lipocalin family in general, and the species distribution of β-LG in particular, some speculation as to the physiological function can be made. β-Lactoglobulin has been reported as being implicated, inter alia, in hydrophobic ligand transport and uptake, enzyme regulation, and the neonatal acquisition of passive immunity. However, these functions do not appear to be consistent between species. Sequence comparisons among members of the lipocalin family reveal that glycodelin, found in the human endometrium during early pregnancy, is the most closely related to β-LG. Although the function of glycodelin is also unknown, it appears to have effects on the immune system and/or to be involved in differentiation. It is proposed that β-LG, over-expressed in the lactating mammary gland of many, but not all, species, is primarily an important source of amino acids for the offspring of those animals that produce it, but that this function arose by gene duplication from the physiologically essential glycodelin. The other functions that have been associated with β-LG in the neonate are, therefore, fortuitous.

β-Lactoglobulin is a small protein, soluble in dilute salt solution as befits a globulin, with 162 amino acid residues (Mr ∼18,400) that fold up into an 8-stranded, antiparallel β-barrel with a 3-turn α-helix on the outer surface and a ninth β-strand flanking the first strand (see Figure 1). It is this strand that forms a significant part of the dimer interface in the bovine and ovine proteins but, while still present in porcine β-LG, is not involved in the formation of the dimer that forms at low pH. The genetic variants referred to above in the ruminant species result in relatively minor amino acid differences, but the processing properties appear to be significantly affected even by these small changes, such that consideration has been given to removing the less favorable variants by selective breeding (Hill et al., 1997; Harris, 1997). The so-called calyx, or β-barrel, is conical and is made of β-strands A-D forming one sheet, and strands E-H forming a second. Strand A bends through a right angle such that the C-terminal end forms an antiparallel strand with H; strands D and E also form a less significant interaction completely closing the calyx. It is this central cavity, the calyx, that provides the ligand-binding site. On the outer surface of the β-barrel, between strands G and H, is the 3-turn α-helix. The loops that connect the β-strands at the closed end of the calyx, BC, DE, and FG are generally quite short, whereas those at the open end are significantly longer and more flexible.

In particular, the EF loop acts as a gate over the binding site. At low pH, it is in the “closed” position, and binding is inhibited or impossible, whereas at high pH it is open, allowing ligands to penetrate into the hydrophobic binding site. The “latch” for this gate is Glu89, the residue implicated in the Tanford transition observed, although not identified, as having an abnormally high pKa (Tanford et al., 1959; Brownlow et al., 1997; Qin et al., 1998a).

The free Cys121, with its reactive thiol group, has a pH-dependent activity that parallels that of the Tanford transition, and its involvement in the denaturation and aggregation behavior is now firmly established (Havea et al., 2001). The residue is situated on the outer surface of the β-barrel on strand H, under the α-helix, and quite some distance from the EF loop. The effect of this is to mask its accessibility to solvent, particularly at low pH. Reaction with heavy metals like Hg2+ or Cd2+ does occur at most pH values and leads to a dissociation of the dimer. Indeed, reaction of the Cys with almost any thiol reagent appears to enhance dissociation into monomers (McKenzie and Sawyer, 1967; Hambling et al., 1992).

The CD and GH loops in many of the crystallographic analyses are indistinct, and the similarly indistinct nature of the extended AB loop led to the original misthreading of the amino acid sequence into the first electron density map (Papiz et al., 1986; Brownlow et al., 1997). β-Strand I is on the opposite side of strand A from strand H and forms an antiparallel interaction with the same strand of the second monomer. The other dimer-stabilizing interaction comes from the AB loop, where there is an ion pair from Asp33 of one subunit to Arg40 of the other. It is interesting to note that although strand I also exists in the porcine and equine β-LG structures, albeit with a slightly modified sequence, as do the Asp and Arg residues, no similar dimerization occurs at physiological pH. Indeed, site-directed mutagenesis designed to disrupt one or the other of these interactions, or better, both, produces a monomeric bovine protein (Sakurai and Goto, 2002; Wilson and Holt, to be published). There is no direct interaction between the α-helixes, which are antiparallel on the outer surface of the molecule with the polypeptide chains, some 12 Å apart. The closest approach of any atoms of the helix in the A subunit from the triclinic lattice X structure to the helix in the B subunit is 5.8Å, and this involves the flexible side chains of Asp137A and Arg148B and vice versa.

The structure of β-LG has also been determined by NMR techniques by several groups (Belloque and Smith, 1998; Fogolari et al., 1998; Kuwata et al., 1998; Uhrinova et al., 2000) and includes the equine structure (Kobayashi et al., 2000). The bovine protein is monomeric at pH values below 3, and the structure has been determined at this pH. Although there is no matching crystal structure at this pH where flat hexagonal plates of poor diffraction quality can be grown, the structure of the core of the protein is well conserved. However, significant differences do exist, and these have been critically reviewed (Jameson et al., 2002); it is not surprising that it is the external loops that contain these major differences.