Karin Mellström

Selective thyroid hormone receptor-β activation: A strategy for reduction of weight, cholesterol, and lipoprotein (a) with reduced cardiovascular liability

Few treatments for obesity exist and, whereas efficacious therapeutics for hyperlipidemia are available, further improvements are desirable. Thyroid hormone receptors (TRs) regulate both body weight and cholesterol levels. However, thyroid hormones also have deleterious effects, particularly on the heart. The TRβ subtype is involved in cholesterol lowering and possibly elevating metabolic rate, whereas TRα appears to be more important for control of heart rate (HR). In the current studies, we examined the effect of TRβ activation on metabolic rate and HR with either TRα1–/– mice or the selective TRβ agonist KB-141 in mice, rats, and monkeys. 3,5,3′-triiodi-l-thyronine (T3) had a greater effect on increasing HR in WT than in TRα–/– mice (ED15 values of 34 and 469 nmol/kg/day, respectively). T3 increased metabolic rate [whole body oxygen consumption (MVO2)] in both WT and TRα–/– mice, but the effect in the TRα1–/– mice at the highest dose was half that of the WT mice. Thus, stimulation of MVO2 is likely due to both TRα and -β. T3 had equivalent potency for cholesterol reduction in WT and TRα–/– mice. KB-141 increased MVO2 with selectivities of 16.5- and 11.2-fold vs. HR in WT and TRα1–/– mice, respectively. KB-141 also increased MVO2 with a 10-fold selectivity and lowered cholesterol with a 27-fold selectivity vs. HR in rats. In primates, KB-141 caused significant cholesterol, lipoprotein (a), and body-weight reduction (up to 7% after 1 wk) with no effect on HR. TRβ-selective agonists may constitute a previously uncharacterized class of drugs to treat obesity, hypercholesterolemia, and elevated lipoprotein (a).

The thyroid hormone mimetic compound KB2115 lowers plasma LDL cholesterol and stimulates bile acid synthesis without cardiac effects in humans

Atherosclerotic cardiovascular disease is a major problem despite the availability of drugs that influence major risk factors. New treatments are needed, and there is growing interest in therapies that may have multiple actions. Thyroid hormone modulates several cardiovascular risk factors and delays atherosclerosis progression in humans. However, use of thyroid hormone is limited by side effects, especially in the heart. To overcome this limitation, pharmacologically selective thyromimetics that mimic metabolic effects of thyroid hormone and bypass side effects are under development. In animal models, such thyromimetics have been shown to stimulate cholesterol elimination through LDL and HDL pathways and decrease body weight without eliciting side effects. We report here studies on a selective thyromimetic [KB2115; (3-[[3,5-dibromo-4-[4-hydroxy-3-(1-methylethyl)-phenoxy]-phenyl]-amino]-3-oxopropanoic acid)] in humans. In moderately overweight and hypercholesterolemic subjects KB2115 was found to be safe and well tolerated and elicited up to a 40% lowering of total and LDL cholesterol after 14 days of treatment. Bile acid synthesis was stimulated without evidence of increased cholesterol production, indicating that KB2115 induced net cholesterol excretion. KB2115 did not provoke detectable effects on the heart, suggesting that the pharmacological selectivity observed in animal models translates to humans. Thus, selective thyromimetics deserve further study as agents to treat dyslipidemia and other risk factors for atherosclerosis.

Therapeutic Potential for Thyroid Hormone Receptor-β Selective Agonists for Treating Obesity, Hyperlipidemia and Diabetes

Obesity and metabolic syndrome are increasing dramatically worldwide, contributing to cardiovascular morbidity and mortality. There are currently few safe and efficacious therapeutics for obesity and most strategies are focused on appetite suppression. Thyroid hormones reduce adiposity via increased metabolic rate, but unfortunately they cause large changes in metabolic rate and direct cardiac acceleration, making them useless for treating obesity. Thyroid hormone receptors (TRs) work as transcription factors and two subtypes exist: TRalpha and TRbeta. TRalpha mediates tachycardia and much of the metabolic rate effect, while TRbeta mediates cholesterol and TSH lowering effects of thyroid hormones. TRbeta activation modestly increases metabolic rate such that a therapeutic window of 5-10 fold increases in metabolic rate can be seen without tachycardia. This was initially studied in TRalpha(1)(-/-) mice. Recent structure activity work has resulted in the discovery of several TRbeta selective thyromimetics such as KB-141. Studies with KB-141 show that it has a 10-fold window in which therapeutic increases in metabolic rate are seen without tachycardia or cardiac hypertrophy. This agent lowers cholesterol in rats and primates. In primates, KB-141 causes significant weight and cholesterol reduction in addition to the independent risk factor Lp(a). These effects were seen without any effect on heart rate, unlike thyroid hormone (T(3)). Further work with TRbeta selective agents is warranted and recent work suggests the possibility of developing compounds that selectively penetrate different tissues which may have an even more desirable therapeutic window. Selective thyromimetics, therefore, may be useful as adjunctive therapy to appetite suppressants along with exercise and diet restriction.