Glucagon-like peptide-1 (GLP-1) reduces insulin requirement in diabetes mellitus and promotes satiety. GLP-1 in the periphery (outside the CNS) has been shown to act on the brain to reduce food ingestion. As GLP-1 is readily degraded in blood, we focused on the interactions of [Ser8]GLP-1, an analog with similar biological effects and greater stability, with the blood-brain barrier (BBB). The influx of radiolabeled [Ser8]GLP-1 into brain has several distinctive characteristics: 1. A rapid influx rate of 8.867 +/- 0.798 x 10(4) mL/g-min as measured by multiple-time regression analysis after iv injection in mice. 2. Lack of self-inhibition by excess doses of the unlabeled [Ser8]GLP-1 either iv or by in situ brain perfusion, indicating the absence of a saturable transport system at the BBB. 3. Lack of modulation by short-term fasting and some other ingestive peptides that may interact with GLP-1, including leptin, glucagon, insulin, neuropeptide Y, and melanin-concentrating hormone. 4. No inhibition of influx by the selective GLP-1 receptor antagonist exendin(9-39), suggesting that the GLP-1 receptor is not involved in the rapid entry into brain. Similarly, there was no efflux system for [Ser8]GLP-1 to exit the brain other than following the reabsorption of cerebrospinal fluid (CSF). The fast influx was not associated with high lipid solubility. Upon reaching the brain compartment, substantial amounts of [Ser8]GLP-1 entered the brain parenchyma, but a large proportion was loosely associated with the vasculature at the BBB. Finally, the influx rate of [Ser8]GLP-1 was compared with that of GLP-1 in a blood-free brain perfusion system; radiolabeled GLP-1 had a more rapid influx than its analog and neither peptide showed the self-inhibition indicative of a saturable transport system. Therefore, we conclude that [Ser8]GLP-1 and the endogenous peptide GLP-1 can gain access to the brain from the periphery by simple diffusion and thus contribute to the regulation of feeding.
OBJECTIVE: Peripherally administered exendin-4 is in clinical trials for the treatment of diabetes mellitus and obesity. Since its effects on food intake are mediated centrally, we determined the degree and type of its blood-to-brain penetration of the mouse blood-brain barrier (BBB). MEASUREMENTS AND RESULTS: High-performance liquid chromatography showed that exendin-4 was stable in blood, with most of the injected peptide reaching the brain intact. Capillary depletion studies with washout showed that the injected exendin-4 reached brain parenchyma rather than being trapped in the endothelial cells composing the BBB. Multiple-time regression analysis showed that exendin-4 crossed the BBB directly at a fast rate. The rapid brain entry of exendin-4, helped by its high lipophilicity as demonstrated by the octanol/buffer partition coefficient, was not dependent upon circumventricular organs and was not affected by food deprivation for 24 h. The simultaneous i.v. injection of high doses of unlabeled exendin-4 resulted in self-inhibition (saturation) that only became statistically significant (Po0.05) when the results of four experiments were combined; this suggests a possible limit to the amount of peripherally administered exendin-4 that can reach the brain after injection of high doses. CONCLUSION: The results indicate that exendin-4 is well conformed for exerting central effects involved in the control of obesity.
Orally bioavailable SERDs may offer greater systemic drug exposure, improved clinical efficacy, and more durable treatment outcome for patients with ER-positive endocrine-resistant breast cancer. We report the design and synthesis of a boronic acid modified fulvestrant (5, ZB716), which binds to ERα competitively (IC50 = 4.1 nM) and effectively downregulates ERα in both tamoxifen-sensitive and tamoxifen-resistant breast cancer cells. Furthermore, It has superior oral bioavailability (AUC = 2547.1 ng·h/mL) in mice, indicating its promising clinical utility as an oral SERD.
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