Novel mutations in scavenger receptor BI associated with high HDL cholesterol in humans.

The scavenger receptor class B, member 1 (SR-BI), is a key cellular receptor for high-density lipoprotein (HDL) in mice, but its relevance to human physiology has not been well established. Recently a family was reported with a mutation in the gene encoding SR-BI and high HDL cholesterol (HDL-C). Here we report two additional individuals with extremely high HDL-C (greater than the 90th percentile for age and gender) with rare mutations in the gene encoding SR-BI. These mutations segregate with high HDL-C in family members of each proband and are associated with a 37% increase in plasma HDL-C in heterozygous individuals carrying them. Both mutations occur at highly conserved positions in the large extracellular loop region of SR-BI and are predicted to impair the function of the SR-BI protein. Our findings, combined with the prior report of a single mutation in the gene encoding SR-BI, further validate that mutations in SR-BI are a rare but recurring cause of elevated HDL-C in humans.

Investigating site-specific effects of the -X glutamate in a parvalbumin CD site model peptide.

The -X glutamate in a 33-residue model peptide comprising the CD site of carp parvalbumin 4.25 (ParvCD) was replaced with aspartate (ParvCD-XD) and the effect on calcium-dependent dimerization and calcium affinity assessed. The peptide ParvCD demonstrates a 10(5)-fold lower calcium affinity than the same site in the native protein. Both the ParvCD and ParvCD-XD model peptides fail to bind magnesium. The low calcium affinity and failure of the model ParvCD site to bind magnesium may be due to higher enthalpic costs of chelation by the -X glutamate. Replacement of the -X glutamate with an aspartate resulted in a twofold increase in the calcium affinity of both the monomer and dimer forms and a twofold increase in the calcium dependent dimerization of the peptide. A -X glutamate to aspartate replacement in 33-residue model peptides corresponding to bovine brain calmodulin site 3 (R. M. Procyshyn and R. E. Reid, Arch. Biochem. Biophys. 311, 425-429, 1994) and in Escherichia coli d-galactose-binding protein (S. K. Drake, K. L. Lee, and J. J. Falke, Biochemistry 35, 6697-6705, 1996) agree with results in the ParvCD site. However, in rat oncomodulin a -X glutamate to aspartate replacement increases calcium affinity (R. C. Hapak, P. J. Lammers, W. A. Palmisano, E. R. Birnbaum, and M. T. Henzl, J. Biol. Chem. 264, 18751-18760, 1989). The different effect of a -X glutamate to aspartate substitution in the different sites suggests site-specific factors dictating the thermodynamic contribution of the -X glutamate to calcium affinity.

A model for circular dichroism monitored dimerization and calcium binding in an EF-hand synthetic peptide.

EF-hand peptides have been shown to bind calcium and dimerize to form an intact protein domain [Shaw, G.S., Hodges, R.S. & Sykes, B.D. (1990). Science, 249, 280-283]. A synthetic 33-residue EF-hand peptide with the sequence of carp parvalbumin CD site demonstrated a seven-fold increase in the apparent calcium dissociation constant with a eight-fold decrease in peptide concentration when fit to a single-site calcium-binding model. This observation is consistent with EF-hand dimerization. This paper describes a method to determine the dimerization dissociation constant and the calcium dissociation constants for both the monomer and dimer forms of this EF-hand peptide using circular dichroism techniques. By monitoring the increase in negative molar ellipticity at 222 nm with increasing peptide concentration under calcium-saturating conditions the dimerization dissociation constant for the synthetic parvalbumin CD site was determined to be 55.68+/-10.76 microM. Using the dimerization constant, the calcium dissociation constants for both the monomer and dimer forms of this peptide were determined by monitoring the change in ellipticity of peptide solutions on addition of increasing amounts of calcium. A fit of this data to a mathematical model that takes into account dimerization results in calcium dissociation constants of 421.3+/-21.56 and 47.06+/-6.72 microM for the monomer and dimer forms, respectively.