A spin label study of the thyroid hormone-binding sites in human plasma thyroxine transport proteins

Using bound fatty acids to disclose the functional structure of serum albumin

BACKGROUND

Serum albumin is a major transport protein in mammals and is known to have at least seven binding sites for long-chain fatty acids (FAs).

SCOPE OF REVIEW

We have devised a new electron paramagnetic resonance (EPR) spectroscopic approach to gain information on the functional structure of serum albumin in solution in a "coarse-grained" manner from the ligands' point of view. Our approach is based on using spin labeled (paramagnetic) stearic acids self-assembled with albumin and subsequent nanoscale distance measurements between the FAs using double electron-electron resonance spectroscopy (DEER). Simple continuous wave (CW) EPR spectroscopy, which allows for quantification of bound ligands, complements our studies.

MAJOR CONCLUSIONS

Based on DEER nanoscale distance measurements, the functional solution structure of human serum albumin (HSA) has remarkably been found to have a much more symmetric distribution of entry points to the FA binding sites than expected from the crystal structure, indicating increased surface flexibility and plasticity for HSA in solution. In contrast, for bovine serum albumin (BSA), the entry point topology is in good agreement with that expected from the crystal structure of HSA. Changes in the solution structures between albumins can hence be revealed and extended to more albumins to detect functional differences at the nanoscale. Going beyond fundamental structural studies, our research platform is also excellently suited for general studies of protein-solvent interactions, temperature effects and ligand binding.

GENERAL SIGNIFICANCE

We discuss how our research platform helps illuminate protein dynamics and function and can be used to characterize albumin-based hybrid materials. This article is part of a Special Issue entitled Serum Albumin.

Sea lamprey (Petromyzon marinus) contain four developmentally regulated serum thyroid hormone distributor proteins

Thyroid hormones (THs) are very lipophilic molecules which require a distribution network for efficient transport in serum. Despite observations that THs function in a wide variety of processes, including aspects of fish development (i.e., flat fish metamorphosis and smoltification), the proteins responsible for TH distribution in fish serum remain poorly studied. We chose to investigate the serum TH distributor proteins (THDPs) in lampreys. As one of only two extant agnathans, data on lamprey THDPs may offer new insights into the evolution of the vertebrate TH distribution network and serum proteins in general. Moreover, lampreys appear to contradict the vertebrate model of an increase in TH concentrations initiating and driving vertebrate metamorphosis. We show for the first time that sea lamprey serum contains at least four THDPs and that their presence in serum is temporally regulated throughout the life cycle. The albumin, glycoprotein AS is the dominant THDP present in the sera of larval and metamorphosing sea lamprey. In stage seven of metamorphosis, three additional THDPs appear, including the albumin, glycoprotein SDS-1; the glycolipoprotein CB-III; and an unidentified low molecular weight protein temporarily named Spot-5. The sera of parasitic and upstream migrant sea lampreys lack AS; their serum THDPs are SDS-1, CB-III, and Spot-5. Our data indicate that despite the change in type and number of THDPs, the overall total TH binding capacity of sea lamprey serum remains fairly stable until stage 7 of metamorphosis when a only modest decrease in total binding capacity is observed. Collectively these data indicate that the decline in serum TH concentrations observed during lamprey metamorphosis is not a consequence of a reduction in the distribution and storage capacity of the serum.

Interaction of hexachlorophene and other compounds with spin-labeled brain membranes

Experiments reported here demonstrate that hexachlorophene influences oxidation-reduction events inside the brain membrane, possibly via a free radical mechanism. This was shown by nitroxide spin label quenching inside the rat cerebellum membrane bilayer due to the interaction between hexachlorophene and peroxidase-hydrogen peroxide system. Prior addition of antioxidants, e.g., vitamin E or butylated hydroxytoluene, prevented such membrane-bound fatty acid spin label reduction, presumably due to their free radical scavenging abilities. The 5-doxyl stearic acid spin probe attached to the brain membranes did not exhibit any detectable changes in their ESR spectra nor, consequently, in the microviscosity of the membranes when exposed to up to 40 mM hexachlorophene.