Mechanisms involved in the nongenomic action of thyroid hormone on the expression and translocation of the isoform of glucose transporter 4 (GLUT4) a study in skeletal muscle and adipose tissue.

The thyroid hormone (TH) participates in the control of essential functions of the organism. Most of its effects are mediated by modulation of gene transcription and take place over a long enough period of time to allow the transcription of specific genes. On the other hand, evidence that TH also promotes the effects that occur in a short period of time and which manifest even in the presence of inhibitors of gene transcription have been increasingly found in literature. GLUT4 is the main transporter of glucose in skeletal muscle, the heart and adipose tissue. Its translocation and insertion in the plasma membrane result from the activation of signaling pathways triggered by the interaction of insulin with membrane receptors. In skeletal muscle and the heart, a second pathway that activates the mechanism of GLUT4 translocation involves the activation of AMPK, a process triggered by muscle contraction. This study aimed at evaluating: (i) in the in vivo model (Wistar rats), if T3 and T4 acutely cause translocation of GLUT4 to the plasma membrane, (ii) in the in vitro model (L6 muscle cells and adipocytes 3T3 -L1), if T3 and T4 cause the effect described above; and (iii) whether this effect occurs by activation of the signaling pathways of insulin and/or muscle contraction. Our in vivo studies demonstrate that administration of T3 rapidly increased the amount of GLUT4 in the fraction corresponding to the plasma membrane in skeletal muscle and adipose tissue. However, this action did not depend on the activation of PI3-K and AMPK. In vitro studies showed that T3 quickly increases the glucose uptake in L6 cells, but without changing the amount of GLUT4 present in the membrane. These results suggest that this action of T3 occurs due to activation of GLUT4 already present in the membrane or due to some process which does not depend on this protein. Our results demonstrate that other than its known genomic actions, TH acts through nongenomic mechanisms regulating GLUT4 translocation. In addition, they strongly suggest that T3 participates, also through non-genomic mechanisms, in the activation process of GLUT4 already inserted in the membrane. (AU)