AmycretinvsAT7687

Amycretin is a unimolecular co-agonist that simultaneously activates both the GLP-1 receptor and the amylin (AMY) receptor — the first peptide engineered to combine these two complementary satiety pathways in a single molecule rather than as a two-drug combination. The design philosophy is to deliver the additive weight-loss benefit demonstrated by CagriSema (semaglutide + cagrilintide) without the manufacturing, dosing, and patient-acceptance complexities of co-formulating two separate drugs.

The GLP-1 component drives appetite suppression centrally through hypothalamic POMC/CART activation and NPY/AgRP inhibition, slows gastric emptying via vagal signalling, and stimulates glucose-dependent insulin secretion from pancreatic beta cells. The amylin component activates calcitonin-receptor/RAMP heterodimer complexes concentrated in the area postrema and nucleus tractus solitarius — brainstem regions outside the blood-brain barrier that form a parallel satiety circuit reducing meal size and food-seeking behaviour through neuroanatomically distinct pathways.

Because GLP-1 and amylin signal through different receptor families and target different neurons in the appetite control network, their effects are additive rather than redundant. Phase 1b/2a data showed up to 22% body weight reduction at 36 weeks for the subcutaneous form — comparable to CagriSema with a simpler one-molecule profile. A particularly notable feature is the parallel development of an oral formulation, which would be the first oral peptide combination therapy for obesity if approved. Novo Nordisk's branded development name is zenagamtide, and the molecule is positioned as the company's strategic answer to retatrutide and tirzepatide.

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.