Engineered microparticles modulate arginine metabolism to repolarize tumor-associated macrophages for refractory colorectal cancer treatment

From blockage to biology: Unveiling the role of extracellular matrix dynamics in obstructive colorectal cancer pathogenesis

Colorectal cancer obstruction is a common problem with distinct symptomatic clues on CT/MR images even under incomplete conditions. The choice of management in the emergency setting has a significant effect on the prognosis of obstructive and nonobstructive colorectal cancer patients. Previous studies have demonstrated that obstruction in colorectal cancer is associated with significantly poorer outcomes, alongside distinct alterations in the composition of the extracellular matrix. Based on accumulating evidence, it is hypothesized that ECM remodeling plays a pivotal role in the development of colorectal cancer obstruction. This review explores the pathological features of obstructive colorectal cancer, emphasizing extracellular matrix remodeling as a central process. Key mechanisms include tumor-stromal cell interactions, tumor cell aggregation and migration mediated by the peripheral nervous system, vascular and lymphatic remodeling within the tumor microenvironment, and microbiota-mediated regulation of cancer progression. These findings demonstrate that further remodeling of the extracellular matrix may be a molecular biological feature of obstructive colorectal cancer with poor prognosis.

Metabolomic reprogramming of the tumor microenvironment by dual arginase inhibitor OATD-02 boosts anticancer immunity

Metabolic reprogramming within the tumor microenvironment (TME) plays a central role in cancer progression and immune evasion, with L-arginine metabolism emerging as a key regulatory axis. Arginase overexpression depletes intratumoral L-arginine, thus suppressing T-cell proliferation while fuelling tumor growth through polyamine biosynthesis. OATD-02, a novel dual arginase (ARG1/ARG2) inhibitor, reprograms tumor metabolism by restoring L-arginine availability and reducing the levels of polyamines, thereby shifting the TME toward a more immunostimulatory state. Unlike ARG1-selective inhibitors with limited intracellular uptake, OATD-02 effectively inhibits both extracellular and intracellular arginases, thereby addressing a major limitation of first-generation arginase inhibitors. To visualize the pharmacodynamic effects of OATD-02 dosing in mice with spatial resolution, we employed MALDI mass spectrometry imaging (MALDI-MSI), thus enabling direct mapping of metabolic changes within tumor tissues. In preclinical models, OATD-02 treatment led to widespread accumulation of intratumoral L-arginine with concomitant depletion of polyamines and resulted in metabolic shifts that correlated with increased immune cell infiltration and an improved response to immune checkpoint blockade. These findings underscore the role of dual arginase inhibition in reshaping tumor metabolism and overcoming immune suppression by restoring the metabolic fitness of immune cells to fight cancer. The metabolic changes caused by OATD-02 treatment resulted in significantly enhanced antitumor immune responses, increased T-cell infiltration in tumors, expansion of CD8⁺ T cells in draining lymph nodes, and systemic upregulation of T-cell activation markers. These effects translated into a substantial survival benefit in the CT26 tumor model, particularly when combined with anti-PD-1 therapy, where OATD-02 improved checkpoint blockade efficacy by relieving metabolic constraints affecting tumor-infiltrating lymphocytes. By leveraging the unique capabilities of MALDI-MSI, this study provides high-resolution metabolic insights into the mechanism of action of OATD-02, reinforcing its potential as a next-generation metabolic-immunotherapeutic agent. The observed metabolic reprogramming, coupled with enhanced immune activation and prolonged survival, supports the clinical development of OATD-02 as a promising strategy for enhancing cancer immunotherapy efficacy. OATD-02 is currently undergoing clinical evaluation in a phase I/II trial (NCT05759923), which will further elucidate its safety and therapeutic impact. These findings highlight the potential of arginase-targeted therapies in cancer treatment and underscore the value of MALDI-MSI as a powerful tool for tracking metabolic responses to therapy.

The role of macrophages in liver metastasis: mechanisms and therapeutic prospects

Metastasis is a hallmark of advanced cancer, and the liver is a common site for secondary metastasis of many tumor cells, including colorectal, pancreatic, gastric, and prostate cancers. Macrophages in the tumor microenvironment (TME) promote tumor cell metastasis through various mechanisms, including angiogenesis and immunosuppression, and play a unique role in the development of liver metastasis. Macrophages are affected by a variety of factors. Under conditions of hypoxia and increased acidity in the TME, more factors are now found to promote the polarization of macrophages to the M2 type, including exosomes and amino acids. M2-type macrophages promote tumor cell angiogenesis through a variety of mechanisms, including the secretion of factors such as VEGF, IL-1β, and TGF-β1. M2-type macrophages are subjected to multiple regulatory mechanisms. They also interact with various cells within the tumor microenvironment to co-regulate certain conditions, including the creation of an immunosuppressive microenvironment. This interaction promotes tumor cell metastasis, drug resistance, and immune escape. Based on the advent of single-cell sequencing technology, further insights into macrophage subpopulations in the tumor microenvironment may help in exploring new therapeutic targets in the future. In this paper, we will focus on how macrophages affect the TME, how tumor cells and macrophages as well as other immune cells interact with each other, and further investigate the mechanisms involved in liver metastasis of tumor cells and their potential as therapeutic targets.