@phdthesis{Godbole2018, author = {Godbole, Amod Anand}, title = {A new paradigm in GPCR signaling at the trans-Golgi network of thyroid cells}, url = {http://nbn-resolving.de/urn:nbn:de:bvb:20-opus-147159}, school = {Universit{\"a}t W{\"u}rzburg}, year = {2018}, abstract = {Whereas G-protein coupled receptors (GPCRs) have been long believed to signal through cyclic AMP exclusively at cell surface, our group has previously shown that GPCRs not only signal at the cell surface but can also continue doing so once internalized together with their ligands, leading to persistent cAMP production. This phenomenon, which we originally described for the thyroid stimulating hormone receptor (TSHR) in thyroid cells, has been observed also for other GPCRs. However, the intracellular compartment(s) responsible for such persistent signaling and its consequences on downstream effectors were insufficiently characterized. The aim of this study was to follow by live-cell imaging the trafficking of internalized TSHRs and other involved signaling proteins as well as to understand the consequences of signaling by internalized TSHRs on the downstream activation of protein kinase A (PKA). cAMP and PKA activity was measured in real-time in living thyroid cells using FRET-based sensors Epac1-camp and AKAR2 respectively. The results suggest that TSH co-internalizes with its receptor and that the internalized TSH/TSHR complexes traffic retrogradely to the trans-Golgi network (TGN). This study also provides evidence that these internalized TSH/TSHR complexes meet an intracellular pool of Gs proteins in sorting endosomes and in TGN and activate it there, as visualized in real-time using a conformational biosensor nanobody, Nb37. Acute Brefeldin A-induced Golgi collapse hinders the retrograde trafficking of TSH/TSHR complexes, leading to reduced cAMP production and PKA signaling. BFA pretreatment was also able to attenuate CREB phosphorylation suggesting that an intact Golgi/TGN organisation is essential for an efficient cAMP/PKA signaling by internalized TSH/TSHR complexes. Taken together this data provides evidence that internalized TSH/TSHR complexes meet and activate Gs proteins in sorting endosomes and at the TGN, leading to a local activation of PKA and consequently increased CREB activation. These findings suggest unexpected functions for receptor internalization, with major pathophysiological and pharmacological implications.}, subject = {G-Protein gekoppelte Rezeptoren}, language = {en} } @phdthesis{Schneider2012, author = {Schneider, Mara}, title = {Effects of levothyroxine on bone mineral density, muscle force and bone turnover markers: A cohort study}, url = {http://nbn-resolving.de/urn:nbn:de:bvb:20-opus-85173}, school = {Universit{\"a}t W{\"u}rzburg}, year = {2012}, abstract = {The objective of this prospective observational controlled study was to evaluate potential effects and dose-response relationship of LT4 administration on BMD, parameters of bone and muscle strength, and biochemical variables of calcium homoeostasis and bone turnover.Ninety-seven men and pre-menopausal women after near total thyroidectomy and ¹³¹I remnant ablation for well-differentiated thyroid carcinoma or after strumectomy for non-toxic goitre were stratified by degree of TSH suppression and by gender in three subgroups: 28 men and 46 women on LT4 suppressive treatment and 23 women on LT4 replacement therapy. Patients were matched for age, gender and BMI to 89 healthy controls with a negative history of thyroid disease. Patients and controls were followed and studied for a mean time of 1.1±0.2 years. Peripheral volumetric total and trabecular BMD as well as bone strength (pQCT) were determined at the ultra-distal radius. Central areal BMD (DXA) was measured at the lumbar spine, left and right femoral neck as well as left and right total hip. Maximum grip strength (dynamometer) of the non-dominant forearm and serum markers of calcium and bone metabolism were assessed. BMD at the axial skeleton and muscle strength were not impaired by LT4 medication irrespective of gender, underlying diagnosis or treatment regimen. By contrast, a general trend of inversely affected total and trabecular BMD and of decreased bone strength was detected at the ultra-distal radius. Only in women on LT4 suppressive treatment, loss of total BMD at the ultra-distal radius reached a level of high significance. In women on LT4 replacement therapy, a significant decline of maximum grip strength appeared in comparison with female controls, while appendicular total and trabecular BMD as well as bone strength remained unchanged and did not differ from respective controls. In men on LT4 suppressive treatment, greater reduction of bone strength as compared to female thyroid cancer patients was marginally significant. Calcium balance was stable and serum concentrations of bone metabolism markers levelled off or rather decreased contradicting (high turnover) bone loss. The study did not reveal any dose-related differential influence of LT4 administration either on primary or secondary study endpoints in female patients. A gender-related difference of bone strength in response to LT4 suppressive treatment might not be excluded, as male thyroid cancer patients showed greater decline of bone strength despite unaffected peripheral BMD and muscle strength. In conclusion, there was only little evidence of adverse LT4 effects. For the most part, LT4 administration irrespective of degree of TSH suppression was not associated with low or accelerated loss of BMD at the peripheral and central skeleton and loss of bone and muscle strength, a finding also confirmed biochemically. The ultra-distal radius as a non-weight bearing skeletal site might be at risk for BMD reduction. According to the results, pre-menopausal women on LT4 suppressive therapy might be at risk of bone loss. The more complex approach of this study also took into account biomechanical qualities of bone material as well as structural and geometrical characteristics of bone architecture implying a causal muscle-bone interrelationship.}, subject = {Schilddr{\"u}se}, language = {en} }