周 新宇

L-type amino acid transporter 1 (LAT1, SLC7A5), overexpressed in various cancers, mediates the uptake of essential amino acids crucial for tumor growth. It has emerged as a promising target for cancer therapy. Nanvuranlat (JPH203/KYT-0353), a LAT1 inhibitor, has shown antitumor activity in preclinical studies and efficacy in biliary tract cancer during clinical trials. This study provides a comprehensive pharmacological characterization of nanvuranlat and its N-acetyl metabolite, including structural insights into their LAT1 interactions. Both compounds demonstrated high selectivity for LAT1 over LAT2 and other amino acid transporters. Nanvuranlat acts as a competitive, non-transportable LAT1 inhibitor (Ki = 38.7 nM), while its N-acetyl metabolite retains selectivity but with reduced affinity (Ki = 1.68 µM). Nanvuranlat exhibited a sustained inhibitory effect on LAT1 even after its removal, indicating the potential for prolonged therapeutic effects. Both compounds showed comparable dissociation rates, suggesting that N-acetylation does not affect the interaction responsible for slow dissociation. The U-shaped conformation adopted by nanvuranlat when bound to LAT1 likely contributes to its high affinity, selectivity, sustained inhibitory effect, and non-transportable nature observed in this study. These insights into nanvuranlat's mechanism and metabolic impact provide essential information for understanding its clinical efficacy and advancing LAT1-targeted cancer therapies.

L-type amino acid transporter 1 (LAT1, SLC7A5) is upregulated in various cancers and associated with disease progression. Nanvuranlat (Nanv; JPH203, KYT-0353), a selective LAT1 inhibitor, suppresses the uptake of large neutral amino acids required for rapid growth and proliferation of cancer cells. Previous studies have suggested that the inhibition of LAT1 by Nanv induces the cell cycle arrest at G0/G1 phase, although the underlying mechanisms remain unclear. Using pancreatic cancer cells arrested at the restriction check point (R) by serum deprivation, we found that the Nanv drastically suppresses the G0/G1-S transition after release. This blockade of the cell cycle progression was accompanied by a sustained activation of p38 mitogen-activated protein kinase (MAPK) and subsequent phosphorylation-dependent proteasomal degradation of cyclin D1. Isoform-specific knockdown of p38 MAPK revealed the predominant contribution of p38α. Proteasome inhibitors restored the cyclin D1 amount and released the cell cycle arrest caused by Nanv. The increased phosphorylation of p38 MAPK and the decrease of cyclin D1 were recapitulated in xenograft tumor models treated with Nanv. This study contributes to delineating the pharmacological activities of LAT1 inhibitors as anti-cancer agents and provides significant insights into the molecular basis of the amino acid-dependent cell cycle checkpoint at G0/G1 phase.

Glutamate is a pivotal excitatory neurotransmitter in mammalian brains, but excessive glutamate causes numerous neural disorders. Almost all extracellular glutamate is retrieved by the glial transporter, Excitatory Amino Acid Transporter 2 (EAAT2), belonging to the SLC1A family. However, in some cancers, EAAT2 expression is enhanced and causes resistance to therapies by metabolic disturbance. Despite its crucial roles, the detailed structural information about EAAT2 has not been available. Here, we report cryo-EM structures of human EAAT2 in substrate-free and selective inhibitor WAY213613-bound states at 3.2 Å and 2.8 Å, respectively. EAAT2 forms a trimer, with each protomer consisting of transport and scaffold domains. Along with a glutamate-binding site, the transport domain possesses a cavity that could be disrupted during the transport cycle. WAY213613 occupies both the glutamate-binding site and cavity of EAAT2 to interfere with its alternating access, where the sensitivity is defined by the inner environment of the cavity. We provide the characterization of the molecular features of EAAT2 and its selective inhibition mechanism that may facilitate structure-based drug design for EAAT2.