# Beyond the tumor: Enhancing pancreatic cancer therapy through glutamine metabolism and innovative drug delivery

**Authors:** Min Su, Huan Qin, Jie Shen, Hao An, Yu Cao

PMC · DOI: 10.1002/ccs3.70033 · 2025-07-09

## TL;DR

This paper explores how targeting glutamine metabolism in pancreatic cancer could improve treatment by using new drug delivery methods and combination therapies.

## Contribution

The paper introduces innovative drug delivery systems and combination strategies to overcome resistance in glutamine-targeted pancreatic cancer therapies.

## Key findings

- Pancreatic cancer's reliance on glutamine metabolism is influenced by oncogenic drivers and gut microbiota.
- Combining glutamine inhibitors with immune checkpoint inhibitors and nanoparticle delivery systems improves therapeutic outcomes.
- Adaptive resistance through asparagine synthesis and fatty acid oxidation limits single-agent glutamine inhibitors.

## Abstract

Pancreatic ductal adenocarcinoma (PDAC) depends a lot on how it uses glutamine to grow quickly and stay alive. Oncogenic drivers such as KRAS, c‐Myc, and HIF‐1α increase how much glutamine gets taken up and broken down. Meanwhile, the bacteria in the gut and tumor itself also affect how much glutamine is available throughout the body and near the tumor. This impacts both how the tumor grows and how the immune system can detect and respond to it. Multiple strategies have emerged to disrupt this dependence: glutamine antagonists (DON and its prodrugs DRP‐104, JHU‐083), small‐molecule glutaminase inhibitors (CB‐839), antibody–drug conjugates targeting the ASCT2 transporter, and combination regimens pairing glutamine blockade with immune checkpoint inhibitors. Nanoparticle formulations—including pH‐sensitive and PEGylated liposomes co‐delivering DON and gemcitabine—enable targeted delivery and reduce off‐target toxicity. Single‐agent treatments do not work so well because the cells can adapt. They boost enzymes such as asparagine synthetase and increase how they burn fatty acids to make up for the lack of glutamine. To overcome these escape routes, future interventions must concurrently target compensatory pathways and integrate biomarker‐driven patient selection. Combining glutamine‐targeted agents with inhibitors of asparagine synthesis or lipid oxidation, guided by multi‐omics profiling, promises a more durable therapeutic benefit and lays the groundwork for personalized treatment of PDAC.

The top row shows key drivers‐KRAS, c‐Myc and HIF‐1a‐alongside gut and tumor microbiota, all converging on glutamine metabolism in PDAC. At the center, glutamine handling is depicted as the linchpin of tumor growth, biosynthesis and immune modulation. The green panel lists major intervention strategies: DON‐loaded nanoparticles, prodrugs (DRP‐104/JHU‐083), the glutaminase inhibitor CB‐839, and ASCT2‐targeted ADCs plus immunotherapy combinations. Finally, the two yellow‐orange ovals at the bottom highlight adaptive escape routes—upregulated asparagine synthesis and enhanced fatty‐acid oxidation‐that blunt single‐agent glutamine inhibitors and underscore the need for co‐targeting compensatory pathways.

## Linked entities

- **Genes:** KRAS (KRAS proto-oncogene, GTPase) [NCBI Gene 3845], MYC (MYC proto-oncogene, bHLH transcription factor) [NCBI Gene 4609], HIF1A (hypoxia inducible factor 1 subunit alpha) [NCBI Gene 3091], SLC1A5 (solute carrier family 1 member 5) [NCBI Gene 6510], AsnS (Asparagine synthetase) [NCBI Gene 2768965]
- **Chemicals:** glutamine (PubChem CID 738), DRP-104 (PubChem CID 137308771), JHU-083 (PubChem CID 137283416), CB-839 (PubChem CID 71577426), gemcitabine (PubChem CID 60750)
- **Diseases:** pancreatic ductal adenocarcinoma (MONDO:0005184)

## Full-text entities

- **Genes:** MYC (MYC proto-oncogene, bHLH transcription factor) [NCBI Gene 4609] {aka MRTL, MYCC, bHLHe39, c-Myc}, HIF1A (hypoxia inducible factor 1 subunit alpha) [NCBI Gene 3091] {aka HIF-1-alpha, HIF-1A, HIF-1alpha, HIF1, HIF1-ALPHA, MOP1}, SLC1A5 (solute carrier family 1 member 5) [NCBI Gene 6510] {aka AAAT, ASCT2, ATBO, M7V1, M7VS1, R16}, GLS (glutaminase) [NCBI Gene 2744] {aka AAD20, CASGID, DEE71, EIEE71, GAC, GAM}, KRAS (KRAS proto-oncogene, GTPase) [NCBI Gene 3845] {aka 'C-K-RAS, C-K-RAS, CFC2, K-RAS2A, K-RAS2B, K-RAS4A}
- **Diseases:** tumor (MESH:D009369), toxicity (MESH:D064420), pancreatic cancer (MESH:D010190), PDAC (MESH:D021441)
- **Chemicals:** DON (MESH:C005914), CB-839 (MESH:C000593334), DRP-104 (-), glutamine (MESH:D005973), JHU-083 (MESH:C000705828), fatty acids (MESH:D005227), lipid (MESH:D008055), asparagine (MESH:D001216), gemcitabine (MESH:D000093542)
- **Species:** Homo sapiens (human, species) [taxon 9606]

## Figures

5 figures with captions in the complete paper: https://tomesphere.com/paper/PMC12240684/full.md

---
Source: https://tomesphere.com/paper/PMC12240684