Thyroid hormone binding motifs and iodination pattern of thyroglobulin.

A phylogenetically conserved 5-residue thyroid hormone (TH)- binding motif was originally found in a few TH plasma carriers and, more recently, in all known plasma and cell-associated proteins interacting with TH as well as in proteins involved in iodide uptake. Minor variations of the motif were found, depending on the particular class of those proteins. Since thyroglobulin (Tg) is the protein matrix for TH synthesis starting from iodination of a selected number of tyrosines (to form first monoiodotyrosine (MIT) and diiodotyrosine (DIT) and then T3 and T4), we hypothesized that by searching the presence of perfect or imperfect versions of that motif in two Tg species (human and murine) in which the iodinated tyrosines and pattern of iodotyrosine/iodothyronine formation are known, we could have found relevant explanations. Explanations, which are not furnished by the simple possession of tyrosine-iodination motifs and sequence of the iodination motif, concern why only some (but not other) tyrosine residues in one species are iodinated and why they have a particular iodination pattern. In this bioinformatics study, we provide such explanations.

Activation of the Na+/H+ exchanger in isolated cardiomyocytes through ß-Raf dependent pathways. Role of Thr653 of the cytosolic tail.

The mammalian Na+/H+ exchanger isoform 1 (NHE1) is a ubiquitous plasma membrane protein that is a key regulator of intracellular pH in isolated cardiomyocytes. A 500 amino acid membrane domain removes protons and is regulated by a 315 amino acid cytosolic domain. In the myocardium, aberrant regulation of NHE1 contributes to ischemia reperfusion damage and to heart hypertrophy. We examined mechanisms of regulation of NHE1 in the myocardium by endothelin and ß-Raf. Endothelin stimulated NHE1 activity and activated Erk-dependent pathways. Inhibition of ß-Raf reduced NHE1 activity and Erk-pathway activation. We demonstrated that myocardial ß-Raf binds to the C-terminal 182 amino acids of the NHE1 protein and that ß-Raf is associated with NHE1 in intact cardiomyocytes. NHE1 was phosphorylated in vivo and the protein kinase inhibitor sorafenib reduced NHE1 phosphorylation levels. Immunoprecipitates of ß-Raf from cardiomyocytes phosphorylated the C-terminal 182 amino acids of NHE1 and mass spectrometry analysis showed that amino acid Thr653 was phosphorylated. Mutation of this amino acid to Ala resulted in defective activity while mutation to Asp restored the activity. The results demonstrate that Thr653 is an important regulatory amino acid of NHE1 that is activated through ß-Raf dependent pathways by phosphorylation either directly or indirectly by ß-Raf, and this affects NHE1 activity.

Identification of a nuclear protein from rat developing brain as heterodimerization partner with thyroid hormone receptor-beta.

Thyroid hormone receptors (TR) are ligand-activated transcription factors that modulate the expression of certain target genes in a developmental and tissue-specific manner. These specificities are determined by the tissue distribution of the TR isoforms alpha1 and beta1, the structure of the thyroid hormone response element (TRE) bound by the receptor, and heterodimerization partners. Among these, retinoid X receptors (RXR) have been recognized as the principal partners for TR. The present work reports the identification of a novel nuclear protein from 19-day-old embryonic rat brain that displays a distinct interaction pattern with TR isoforms at the level of the TRE of two genes known to be differentially expressed and regulated by thyroid hormone (T3): the ubiquitous malic enzyme and the brain-specific myelin basic protein. Electrophoretic gel mobility shift assays demonstrate that only TRbeta1 forms a specific complex with the rat brain nuclear factor on the myelin basic protein-TRE, but not on the malic enzyme-TRE. Thus, the interaction is selectively determined by both the receptor isoform and the structure of the TRE. The expression of this brain nuclear factor is restricted to the perinatal period, when myelination is sensitive to T3. Gel supershift assays with RXR-specific antibodies indicate that this factor is not one of the known RXR isoforms. However, it is most likely a new member of the RXR subfamily because it could be supershifted with an antibody raised against the highly conserved DNA-binding domain of RXRs.