SAT-448 Limited Adaptive Response by Deiodinase Enzymes in the Perinatal Hypothyroid Cochlea

Thyroid hormone (TH) is essential for cochlear development and normal auditory function. Considering the importance of TH in mediating cochlear development, understanding the degree to which developing tissues can adapt to perturbations in thyroid hormone signaling is extremely important. The deiodinases (Dio2 and Dio3) are enzymes that tightly control TH availability at the tissue level and have been proposed to function as adaptive mechanisms that maintain tissue TH homeostasis. Dio2 converts thyroxine (T4) to a biologically active ligand triiodothyronine (T3); locally amplifying a T3 signal. Conversely, Dio3 inactivates T3 and T4 by converting these iodothyronines to the inactive metabolites diiodothyronine (T2) and reverse T3 (rT3), respectively. During cochlear development, Dio3 expression is high prenatally while Dio2 expression is low. During the first postnatal week, the expression levels of these enzymes invert, resulting in high expression of Dio2 and low expression of Dio3. Together, the deiodinases control the timing of postnatal cochlear remodeling; suggesting a genetic developmental clock controls TH-mediated cochlear development. Considering the role deiodinases as adaptive mechanisms, it is important to understand whether such a developmental clock can be negated during times of developmental thyroid hormone insufficiency. We hypothesize that the perinatal change in deiodinase expression is controlled by a developmental clock rather than environmental clues and therefore have limited capacity function as compensatory mechanisms in response to low TH during development. To test this, timed-pregnant mice were treated with thyroid gland inhibitors to induced hypothyroidism from gestational day 12.5 until pup sacrifice. A parallel set of untreated timed-pregnant mice served as controls. Cochlea were harvest from control and hypothyroid mice at postnatal (P) ages P1, P5, P10 and P15 for qRT-PCR, and P7 for in situ hybridization. In situ hybridization for Dio2 mRNA demonstrated a striking reduction in Dio2 mRNA in hypothyroid animals compared to euthyroid animals. Additionally, we observed a significant effect of age (p<0.001) and an interaction between age and treatment (p=0.0035) on Dio2 mRNA levels analyzed by qRT-PCR. Specifically, Dio2 mRNA levels were similar or reduced in hypothyroid animals compared to controls at P1, P5, and P10. This finding indicates that Dio2 mRNA at these ages did not respond in manner consistent with compensation. However, at P15, Dio2 mRNA levels were increased in hypothyroid animals compared to controls; a finding that is consistent with a compensatory mechanism. Taken together, our results suggest that developmental programs in tissues may be dominant over potential compensatory mechanisms and that developing tissues may be more susceptible to perturbations in tissue TH levels due to a reduced capacity to compensate.