Purification, molecular cloning, and functional expression of the human nicodinamide-adenine dinucleotide phosphate-regulated thyroid hormone-binding protein.

The kidney and several other thyroid hormone-responsive tissues contain a NADP-regulated thyroid hormone (TH)-binding protein (THBP), with an apparent molecular mass of 36 kDa on SDS-PAGE, responsible for most of the intracellular high-affinity T3 and T4 binding. THBP was purified to homogeneity from human kidney cytosol and used to generate proteolytic peptides. Microsequencing of four peptides revealed identity to amino acid sequences deduced from a human cDNA homolog to a cDNA encoding kangaroo mu-crystallin. This protein is a major structural kangaroo lens protein with no known function in other species. A full-sized cDNA (TH5.9) was isolated by 5'- and 3'-rapid amplification of cDNA ends using a human brain cDNA library and gene-specific PCR primers, confirming identity to the previously cloned human cDNA. The TH5.9 cDNA encodes a 314-residue protein (theoretical mol wt = 33,775) with significant homologies (40 to 60%) with two bacterial enzymes: lysine cyclodeaminase and ornithine cyclodeaminase. The TH5.9 cDNA was expressed in Escherichia coli as a glutathione S-transferase (GST) fusion protein. Purified GST fusion protein, but not GST, bound T3 specifically with high affinity [dissociation constant (Kd) = 0.5 nM] in the presence of NADPH, and was labeled by UV-driven cross-linking of underivatized [(125)I]T3. T3 binding and photoaffinity labeling of GST fusion protein were activated by NADPH [activation constant (K[act]) = 10(-8) M], but not by NADH. The expressed protein displays the appropriate binding properties, indicating that TH5.9 cDNA encodes the NADP-regulated THBP characterized in human tissues.

High affinity thyroid hormone-binding protein in human kidney: kinetic characterization and identification by photoaffinity labeling.

The binding of thyroid hormones and its regulation of NADPH and NADP+ were studied in human kidney cytosol, and a 38-kDa polypeptide (p38) was identified by photoaffinity labeling of cytosol with underivatized [125I]T3, SDS-PAGE, and autoradiography. The cytosolic thyroid hormone binding and p38 photolabeling were strongly activated by NADPH (maximum at 10(-7) M), whereas other nucleotides were less effective or ineffective. NADP+ did not activate T3 binding and p38 photolabeling, provided it was protected from conversion to NADPH by the addition of an exogenous oxidizing enzymatic system (oxidized glutathione plus glutathione reductase). Furthermore, NADP+ inhibited NADPH activation (half-maximum inhibitory effect at approximately 2 x 10(-5)M), and oxidation of NADPH to NADP+ induced dissociation of bound T3. The equilibrium dissociation constant (Kd) of the NADPH-activated cytosolic T3-binding sites was 0.3 nM, similar to the Kd of the nuclear T3 receptors. The kidney contained 200 times more cytosolic NADPH-activated thyroid hormone-binding sites than nuclear T3 receptors. Nonradioactive iodothyronines competed with [125I]T3 for both NADPH-activated binding and p38 photolabeling, with the following order of decreasing affinity: D-isomer of T3 > T3 > T4 > triiodothyroacetic acid > 3'-isopropyl-3,5-diiodothyronine > rT3. NADPH-activated T3 binding and photolabeled p38 were also detected in human heart and liver cytosols, but not in pancreas, cultured fibroblast and erythrocyte cytosols, or plasma. Rat kidney cytosol contained a 35-kDa photolabeled polypeptide homolog to human p38. The native molecular mass of the human photolabeled protein was 50 kDa, whereas that of the rat protein was 60 kDa, as determined by nondenaturing polyacrylamide gel electrophoresis. Two-dimensional PAGE of photolabeled p38 indicated an isoelectric point of 5.3. These findings describe the molecular properties of a NADPH/NADP+-regulated thyroid hormone-binding protein not previously identified in human and rat kidney cytosol.

Identification by photoaffinity labelling of a pyridine nucleotide-dependent tri-iodothyronine-binding protein in the cytosol of cultured astroglial cells.

High-affinity 3,3',5-tri-iodo-L-thyronine (T3) binding (Kd approximately 0.3 nM) to the cytosol of cultured rat astroglial cells was strongly activated in the presence of pyridine nucleotides. A 35 kDa pyridine nucleotide-dependent T3-binding polypeptide (35K-TBP) was photoaffinity labelled using underivatized [125I]T3 in the presence of pyridine nucleotides and the free-radical scavenger dithiothreitol. Maximum activations of T3 binding and 35K-TBP photolabelling were obtained at approx. 1 x 10(-7) M NADP+ or NADPH, or 1 x 10(-4) M NADH. NAD+ and other nucleotides were without effect. NADPH is the form which activates T3 binding and 35K-TBP photolabelling, since cytosol contains NADP(+)-reducing activity, and the activation of both processes in the presence of NADPH and NADP+ was prevented by an exogenous NADPH oxidation system. NADPH behaved as an allosteric activator of T3 binding. The NADPH oxidation system promoted the release of bound T3 in the absence of any change in the total concentration of the hormone. The 35K-TBP photolabelling and [125I]T3 binding were similarly inhibited by non-radioactive T3 (half-maximum effect at 0.5-1.0 nM T3). The concentrations of iodothyronine analogues that inhibited both processes were correlated (3,3',5-tri-iodo-D-thyronine > or = T3 > L-thyroxine > tri-iodothyroacetic acid > 3,3'5'-tri-iodo-L-thyronine). Molecular sieving and density-gradient centrifugation of cytosol identified a 65 kDa T3-binding entity, which included the 35K-TBP. These results indicate that 35K-TBP is the cytosolic entity involved in the pyridine nucleotide-dependent T3 binding, and suggest that the sequestration and release of intracellular thyroid hormones are regulated by the redox state of astroglial cell compartment(s).