AT7687vsGLP-1

AT7687 is a long-acting GIP receptor antagonist designed to reduce fat storage rather than suppress appetite — a fundamentally different mechanism from every other obesity drug currently on the market or in late-stage development. The rationale is grounded in human genetics: loss-of-function variants in the GIP receptor are associated with lower body mass index and reduced cardiometabolic risk, suggesting that pharmacologically blocking GIP signalling should reproduce these protective effects.

GIP (glucose-dependent insulinotropic polypeptide) normally functions as a fat-storage signal — released from intestinal K-cells in response to food intake, it instructs adipose tissue to take up and store circulating fatty acids. By blocking the GIP receptor specifically on adipocytes, AT7687 prevents this fat-storage signal from being transmitted, leading to reduced lipid uptake into fat cells and a metabolic shift favouring fat oxidation in muscle and liver. Because the mechanism does not depend on suppressing hunger or slowing gastric emptying, the gastrointestinal side effects that limit GLP-1 drug tolerability are largely absent.

This mechanism is the conceptual mirror of MariTide (which combines GLP-1 agonism with GIP antagonism in a single molecule) — AT7687 isolates the GIP-antagonist component to test whether it can produce meaningful weight loss alone or in future combination with GLP-1 agonists. Antag Therapeutics' first-in-human Phase 1 results in 2026 showed acceptable tolerability with mild GI symptoms, plus reductions in LDL cholesterol and resting heart rate — early signals consistent with the predicted cardiometabolic benefit profile. Phase 2 trials are expected to define the magnitude of weight loss achievable in obese patients.

GLP-1 (glucagon-like peptide 1) is the native incretin hormone produced by enteroendocrine L-cells in the distal small intestine and colon in response to nutrient ingestion. It is the endogenous molecule that all GLP-1 receptor agonist drugs (semaglutide, liraglutide, etc.) are designed to mimic. Understanding native GLP-1 is essential to understanding the entire drug class built upon its biology.

Upon release, GLP-1 binds to GLP-1 receptors (GLP-1R) — G protein-coupled receptors expressed on pancreatic beta cells, the GI tract, the heart, the kidneys, and critically, the brain. In the pancreas, GLP-1R activation stimulates adenylyl cyclase, raising intracellular cAMP levels, which potentiates glucose-stimulated insulin secretion. This glucose-dependence is a key safety feature — GLP-1 only promotes insulin release when blood sugar is elevated, minimizing hypoglycemia risk. Simultaneously, GLP-1 suppresses glucagon secretion from alpha cells, further reducing hepatic glucose output.

In the brain, GLP-1 receptors in the hypothalamus (arcuate nucleus, paraventricular nucleus) and brainstem (area postrema, nucleus tractus solitarius) mediate appetite suppression and satiety. GLP-1 also activates vagal afferents to slow gastric emptying, prolonging nutrient absorption and post-meal satiety. The critical limitation of native GLP-1 is its extremely rapid degradation by the enzyme dipeptidyl peptidase-4 (DPP-4), which cleaves the first two amino acids within 1-2 minutes, rendering it inactive. This ultra-short half-life is why pharmaceutical GLP-1 analogues require structural modifications (albumin binding, DPP-4 resistance) to achieve clinically useful durations of action.