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The type 1 iodothyronine deiodinase (1D-I) in liver and kidney converts the prohormone thyroxine ('1"4) by outer ring deiodination (ORD) to bioactive 3,3',5-triiodothyronine (T3) or by inner ring deiodination (IRD) to inactive 3,3',5-"triiodothronine (rT3), while it also catalyzes the IRD of T3 and the ORD of rT 3, with the latter as the preferred substrate. Sulfation of the phenolic hydroxyl group blocks the ORD of T 4, while it strongly stimulates the IRD of both T 4 and T3, indicating that sulfation is an important step in the irreversible inactivation of thyroid hormone. This review summarizes recent studies concerning this interaction between sulfation and deiodination of iodothyronines, the characterization of iodothyronine sulfotransferase activities, the measurement of iodothyronine sulfates in humans and animals, and the possible physiological importance of iodothyronine sulfation.

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Pharmacokinetics and intracellular distribution of the tumor‐targeted radiopharmaceutical m‐iodo‐benzylguanidine in SK‐N‐SH neuroblastoma and PC‐12 pheochromocytoma cells

Smets

Janssen

Rutgers

et al. 1991

Intl Journal of Cancer

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Radiodinated meta-iodobenzylguandine (MIBG) is increasingly used for the diagnosis and targeted radiotherapy of neuro-adrenergic tumors. We have investigated various conditions for specific tumor loading and prolonged retention of this radiopharmaceutical in poorly differentiated SK-N-SH neuroblastoma and highly differentiated PC-12 pheochromocytoma cells. At a constant value of drug concentration x incubation time, short incubations were superior to protracted incubations for maximal cell loading. This effect was most pronounced in the SH-N-SH neuroblastoma cells. In highly differentiated pheochromocytoma cells, the levels of MIBG storage remained high and unchanged during incubations up to 46 hr in label-free medium, while primitive SK-N-SH cells lost 40-50% of accumulated drug by diffusion. In PC-12 cells, susceptibility of stored MIBG to exocytotic release induced by acetylcholine or K+ was similar to that of natural norepinephrine (NE) and prevented by the Ca(++)-channel blockers verapamil and nifedipine. Conversely, granule-poor SK-N-SH cells were insensitive to exocytotic release of MIBG. Uptake and retention capacities were minimally impaired by an externally delivered radiation dose of 5 Gy to mimic the radiobiological effect of 131I-MIBG in tumors. In pre-irradiated cultures, drug uptake was even stimulated, probably due to enrichment in non-proliferating cells. An autoradiographic comparison of the (sub)cellular distributions of 3H-norepinephrine and 125I-MIBG showed that routine conditions of cell fixation and sample processing do not yield reliable results regarding localization of MIBG.

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A comparison of targetting of neuroblastoma with mIBG and anti L1-CAM antibody mAb chCE7: therapeutic efficacy in a neuroblastoma xenograft model and imaging of neuroblastoma patients

et al. 2001

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Iodine-131 labelled anti L1-CAM antibody mAb chCE7 was compared with the effective neuroblastoma-seeking agent 131I-labelled metaiodobenzylguanidine (MIBG) with regard to (a) its therapeutic efficacy in treating nude mice with neuroblastoma xenografts and (b) its tumour targeting ability in neuroblastoma patients. The SK-N-SH tumour cells used in the mouse experiments show good MIBG uptake and provide a relatively low number of 6,300 binding sites/cell for mAb chCE7. Tumours were treated with single injections of 131I-MIBG (110 MBq) and with 131I-labelled mAb chCE7 (17 MBq) and both agents showed antitumour activity. After therapy with 131I-chCE7, the subcutaneous tumours nearly disappeared; treatment with 131I-MIBG was somewhat less effective, resulting in a 70% reduction in tumour volume. A calculated tumour regrowth delay of 9 days occurred with a radioactivity dose of 17 MBq of an irrelevant control antibody mAb 35, which does not bind to SK-N-SH cells, compared with a regrowth delay of 34 days with 131I-mAb chCE7 and of 24 days with 131I-MIBG. General toxicity appeared to be mild, as assessed by a transient, approximate 10% maximum decrease in body weight during the treatments. The superior growth inhibition achieved by 131I-chCE7 compared with 131I-MIBG can be explained by its prolonged retention in the tumours, due to slower normal tissue and plasma clearance. Cross-reaction of mAb chCE7 with L1-CAM present in normal human tissues was investigated by direct binding of radioiodinated mAb to frozen tissue sections. Results showed a strong reaction with normal human brain tissue and weak but detectable binding to normal adult kidney sections. Seven patients with recurrent neuroblastoma were sequentially imaged with 131I-MIBG and 131I-chCE7. The results underlined the heterogeneity of neuroblastoma and showed the two imaging modalities to be complementary. 131I-chCE7 scintigraphy may have clinical utility in detecting metastases which do not accumulate 131I-MIBG, and the antibody may hold potential for radioimmunotherapy, either by itself or in combination with 131I-MIBG.

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Targeting of meta-iodobenzylguanidine to SK-N-SH human neuroblastoma xenografts: Tissue distribution, metabolism and therapeutic efficacy

et al. 2000

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Uptake of the neuron‐blocking agent meta‐iodobenzylguanidine and serotonin by human platelets and neuro‐adrenergic tumour cells

Rutgers

Tytgat

Verwijs-Janssen

et al. 1993

Intl Journal of Cancer

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The adrenomedulla-imaging agent meta-iodobenzylguanidine (MIBG) is concentrated by various tumours of neuroectodermal origin. Radio-iodinated [131I]MIBG is therefore increasingly used for diagnosis and therapy of these disorders. To study the cause of thrombocytopenia associated with [131I]MIBG therapy, we investigated the uptake of MIBG in human platelets in comparison with that of serotonin. Specific imipramine-sensitive uptake of [131I]MIBG was much slower than of [3H]serotonin, but after prolonged incubation high and serotonin-equivalent uptake levels were observed. Accumulation of MIBG saturated at 10- to 100-fold higher concentration than serotonin, and the affinity for uptake and intracellular storage in platelets was much higher for serotonin than for MIBG. Conversely, serotonin was not detectably concentrated by neuroadrenergic Uptake-I in SK-N-SH neuroblastoma and PC12 pheochromocytoma cells. Fluvoxamine inhibited the uptake of norepinephrine and MIBG in PC12 cells, similarly to that of serotonin in platelets. However, the drug was 100-fold more effective in inhibiting platelet transport of MIBG than of serotonin. The results indicate that MIBG uptake in platelets is not mediated by a neuro-adrenergic Uptake-I, but probably proceeds via the serotonin transport system. MIBG concentration by platelets was at least as efficient as in neuro-adrenergic tumour cells and has therefore (radio)biological potential for injuring these cells or precursor megakaryocytes. Platelet uptake of MIBG could be selectively blocked by fluvoxamine in concentrations which minimally affected its accumulation in neuro-adrenergic target cells.

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Marja Rutgers

The role of sulfation in thyroid hormone metabolism

Pharmacokinetics and intracellular distribution of the tumor‐targeted radiopharmaceutical m‐iodo‐benzylguanidine in SK‐N‐SH neuroblastoma and PC‐12 pheochromocytoma cells

A comparison of targetting of neuroblastoma with mIBG and anti L1-CAM antibody mAb chCE7: therapeutic efficacy in a neuroblastoma xenograft model and imaging of neuroblastoma patients

Targeting of meta-iodobenzylguanidine to SK-N-SH human neuroblastoma xenografts: Tissue distribution, metabolism and therapeutic efficacy

Uptake of the neuron‐blocking agent meta‐iodobenzylguanidine and serotonin by human platelets and neuro‐adrenergic tumour cells

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