bims-metorg 2026-02-01 papers

bims-metorg

Biomed News

on Metabolism and Organotropism

Issue of 2026–02–01
seven papers selected by
Bruna Martins Garcia, CABIMER

Molecular and Immune Mechanisms Governing Cancer Metastasis, Including Dormancy, Microenvironmental Niches, and Tumor-Specific Programs.
Metastatic organotropism in peritoneal metastasis: Paget's hypothesis revisited.
Tumor mutational burden as a determinant of metastatic dissemination patterns.
Modeling the pre-metastatic niche of gastric cancer peritoneal metastasis under spatiotemporal resolution and investigating EVs-mediated immune suppression.
Local metastatic expansion versus secondary intra-organ dissemination: two causes of neurological death explained by fundamentally different metastatic colonization patterns.
Breast Cancer Metastases Harbor Tissue-Specific Metabolic Dependencies.
Metabolic Signatures of Breast Cancer Subtypes and the Metabolic Impact of Chemotherapy.

Int J Mol Sci. 2026 Jan 15. pii: 875. [Epub ahead of print]27(2):

Molecular and Immune Mechanisms Governing Cancer Metastasis, Including Dormancy, Microenvironmental Niches, and Tumor-Specific Programs.

Dae Joong Kim.

  Metastasis is still the leading cause of cancer-related death. It happens when disseminated tumor cells (DTCs) successfully navigate a series of steps and adapt to the unique conditions of distant organs. In this review, key molecular and immune mechanisms that shape metastatic spread, long-term survival, and eventual outgrowth are examined, with a focus on how tumor-intrinsic programs interact with extracellular matrix (ECM) remodeling, angiogenesis, and immune regulation. Gene networks that sustain tumor-cell plasticity and invasion are described, including EMT-linked transcription factors such as SNAIL and TWIST, as well as broader transcriptional regulators like SP1. Also, how epigenetic mechanisms, such as EZH2 activity, DNA methylation, chromatin remodeling, and noncoding RNAs, lock in pro-metastatic states and support adaptation under therapeutic pressure. Finally, proteases and matrix-modifying enzymes that physically and biochemically reshape tissues, including MMPs, uPA, cathepsins, LOX/LOXL2, and heparinase, are discussed for their roles in releasing stored growth signals and building permissive niches that enable seeding and colonization. In parallel, immune-evasion strategies that protect circulating and newly seeded tumor cells are discussed, including platelet-mediated shielding, suppressive myeloid populations, checkpoint signaling, and stromal barriers that exclude effector lymphocytes. A major focus is metastatic dormancy, cellular, angiogenic, and immune-mediated, framed as a reversible survival state regulated by stress signaling, adhesion cues, metabolic rewiring, and niche constraints, and as a key determinant of late relapse. Tumor-specific metastatic programs across mesenchymal malignancies (osteosarcoma, chondrosarcoma, and liposarcoma) and selected high-burden cancers (melanoma, hepatocellular carcinoma, glioblastoma, and breast cancer) are highlighted, emphasizing shared principles and divergent organotropisms. Emerging therapeutic strategies that target both the "seed" and the "soil" are also discussed, including immunotherapy combinations, stromal/ECM normalization, chemokine-axis inhibition, epigenetic reprogramming, and liquid-biopsy-enabled minimal residual disease monitoring, to prevent reactivation and improve durable control of metastatic disease.

Keywords:  DNA methylation; breast cancer; chondrosarcoma; disseminated tumor cells (DTCs); extracellular matrix (ECM); hepatocellular carcinoma; melanoma; metastasis; osteosarcoma; tumor dormancy

DOI:  https://doi.org/10.3390/ijms27020875
Clin Exp Med. 2026 Jan 29. 26(1): 123

Metastatic organotropism in peritoneal metastasis: Paget's hypothesis revisited.

Dongchan Kim, Devesh Kaushal, Robert Beaumont Wilson.

  Peritoneal metastasis (PM) of solid tumours is a major contributor to cancer-associated mortality and morbidity. The mechanism of PM development encapsulates Paget's hypothesis of seed and soil, whereby cancer cells remotely prepare a pre-metastatic niche in the peritoneal microenvironment to facilitate transcoelomic cancer progression. The bidirectional communication between cancer cells and host mesothelial cells, endothelial cells, leukocytes, adipocytes, and fibroblasts occurs via exosomes. Exosomes are nano-sized extracellular vesicles that carry cargos of proteins, cytokines, and microRNA. Cancer-derived exosomes enable exfoliated tumour cells to resist anoikis, disseminate, adhere, and implant in the peritoneum. This process involves the degradation of the peritoneal glycocalyx, the transformation of peritoneal mesothelial cells into cancer-associated fibroblasts via mesothelial-mesenchymal transition, and metabolic coupling with omental and subperitoneal adipocytes. Exosomes also enhance ascites and peritoneal immunosuppression. Exosomes promote PM development from mesenchymal subtypes of epithelial cancers, which have a predilection for transcoelomic metastasis compared to other molecular subtypes. Mesenchymal subtypes include diffuse gastric cancer, CMS4 colorectal cancer, and high-grade serous ovarian carcinoma. Understanding the oncogenic roles of exosomal cargo offers potential for future research and therapy in PM.

Keywords:  Exosomes; Extracellular vesicles; PM; Paget’s theory; Peritoneal metastasis

DOI:  https://doi.org/10.1007/s10238-025-01868-9
Mol Oncol. 2026 Jan 27.

Tumor mutational burden as a determinant of metastatic dissemination patterns.

Eduardo Candeal, Andrea Moreno-Manuel, Miguel Salvadó-Pertierra, Cristina Santos-Vivas, Rebeca Sanz-Pamplona.

  According to the seed and soil hypothesis, the organ specificity of metastasis is not a random process and depends on multiple tumor-intrinsic and microenvironmental factors. In this study, we characterized the mutational landscape of a large cohort of human metastatic samples to investigate whether mutational trends determine metastatic dissemination. Genomic data from nine cancer types (bladder, breast, colorectal, endometrial, melanoma, non-small cell lung cancer, ovarian, pancreatic, and prostate) including 19827 patients were obtained from a pan-cancer study. When restricting the analysis to driver mutations, no robust, recurrent mutational patterns associated with metastatic locations were identified across cancer types. However, when cancer types were analyzed separately, mutational trends associated with specific metastatic locations emerged. Considering the total tumor mutational burden (TMB), central nervous system (CNS)/brain and lung metastases harbored a higher TMB than other metastatic locations. Since higher TMB in CNS/brain metastases was also associated with improved prognosis, these findings may be pivotal in refining immunotherapy strategies. Indeed, this observation was confirmed in an independent dataset including patients treated with immunotherapy. In conclusion, our findings suggest that TMB may have greater influence on metastatic organotropism than driver mutational background.

Keywords:  TMB; immunotherapy; metastasis; mutations; organotropism; prognostic biomarker

DOI:  https://doi.org/10.1002/1878-0261.70200
Front Immunol. 2025 ;16 1734244

Modeling the pre-metastatic niche of gastric cancer peritoneal metastasis under spatiotemporal resolution and investigating EVs-mediated immune suppression.

Xiang Zhang, Cheng Zhang, Zheng Zhang, Xuan Zhang, Kai Wang.

  Gastric cancer peritoneal metastasis (GCPM) is the leading cause of death in patients with advanced gastric cancer. The presence of ascites creates favorable conditions for the formation of the pre-metastatic niche (PMN), thereby providing a conducive environment for cancer cell metastasis. However, the mechanisms behind the formation of the pre-metastatic niche (PMN) are still not fully understood. This review examines the dynamic changes in the PMN of gastric cancer using organoid models combined with high spatiotemporal resolution and looks into the role of extracellular vesicles (EVs) in mediating immune suppression. It gives an overview of the latest advances in organoid modeling technologies, clarifies the biological characteristics of EVs, and discusses their functions in immune regulation. Furthermore, this review also highlights current challenges in this field, proposes future research directions, and identifies potential therapeutic targets. Bringing these insights together is intended to deepen understanding of gastric cancer metastasis and support the development of more effective therapeutic strategies.

Keywords:  extracellular vesicles; gastric cancer; immune suppression; organoid modeling; peritoneal metastasis; pre-metastatic niche

DOI:  https://doi.org/10.3389/fimmu.2025.1734244
Mol Cancer. 2026 Jan 24. 25(1): 17

Local metastatic expansion versus secondary intra-organ dissemination: two causes of neurological death explained by fundamentally different metastatic colonization patterns.

Dorde Komljenovic, Tobias Bäuerle, Jessica Alves-de-Lima, Laura Trigueros, Cara Dietz, Zoltan Winter, Tommaso Araceli, Quirin Strotzer, Christina Wendl, Matthias Brendel, Martin A Proescholdt, Patrick N Harter, Katja Evert, Tobias Pukrop, Raquel Blazquez.

   BACKGROUND: Neurological failure contributes to 15-50% of deaths in patients with brain metastases, yet the underlying mechanisms remain poorly understood. Clinical causes range from local compression to meningeal metastasis. In this context, a link between infiltrative histopathological growth patterns (HGPs) and meningeal metastasis was recently described and prompted this reverse translation study.
METHODS: We conducted a retrospective postmortem histological assessment and a prospective MRI-based proof-of-concept study to explore neurological decline mechanisms in two experimental brain metastasis models with different HGPs: (i) the non-infiltrative TUBO model, characterized by well-defined tumor borders and a multilayered astrocytic capsule; and (ii) the infiltrative E0771-LG model, exhibiting diffuse infiltration and widespread astrogliosis.
RESULTS: In the TUBO model, neurological death resulted from local metastatic expansion compressing vital structures, while the E0771-LG model caused mortality mainly through widespread secondary dissemination. We provide the first direct evidence of contralateral recolonization by secondary metastasis-initiating cells (secMICs), and highlight the high efficiency of secondary spread. Additionally, we show that secMICs exploit distinct anatomical structures to reach distant brain regions, bypassing classical vascular dissemination routes. Notably, the HGP and its associated features are intrinsic to tumor cells and are established early during metastatic colonization.
CONCLUSIONS: This study identifies the HGP as a potential surrogate for predicting the underlying cause of organ failure in brain metastases. Additionally, it highlights the significant role of secondary dissemination and recolonization in brain metastasis, processes that have been largely overlooked in clinical practice. These findings address a critical knowledge gap and may inform future treatment strategies.

Keywords:  Brain metastasis; Cause of death; Histological growth pattern; Infiltration; Local metastatic expansion; MMPI; Meningeal metastasis; Neurological decline; Recolonization; Secondary dissemination

DOI:  https://doi.org/10.1186/s12943-026-02574-0
Cancer Discov. 2026 Jan 23. OF1

Breast Cancer Metastases Harbor Tissue-Specific Metabolic Dependencies.

DOI: https://doi.org/10.1158/2159-8290.CD-RW2026-012
Metabolites. 2026 Jan 08. pii: 54. [Epub ahead of print]16(1):

Metabolic Signatures of Breast Cancer Subtypes and the Metabolic Impact of Chemotherapy.

Aubrey Mattingly, Zoe Vickery, Alex Fiorentino, Ethan Wilson, Sydney McCune, Sydney Clark, Eric Blanchard, Jillian Spencer, Abigail Broom, Diana Ivankovic, Brooklyn Pace, Lauren Baskin, Ludovico Abenavoli, W Jeffery Edenfield, Ki Chung, Christopher L Farrell, Hakon Hakonarson, Luigi Boccuto.

  Background/Objectives: Breast cancer is a prevalent and heterogeneous disease with multiple subtypes, which are defined by characteristics such as molecular biomarkers and metastatic status. This study aimed to profile the metabolic activity of various breast cancer subtypes, both with and without chemotherapy (doxorubicin) application. Methods: Six human breast cell lines were evaluated, two non-tumorigenic controls and four cancerous lines. The cancer lines were clustered as primary-derived, metastasis-derived, triple-negative (TNBC), and strong hormone receptor-positive (ER+/PR+) and analyzed using the Biolog phenotype mammalian microarrays (PM-M1 to PM-M8) to assess metabolic activity via NADH production under a wide array of substrate parameters. Results: Unique metabolic profiles emerged across the subtypes and clusters; the TNBC and metastatic cells demonstrated enhanced utilization of glycolytic and anaerobic substrates consistent with the Warburg effect. The ER+/PR+ cells showed heightened glucose utilization and unique sensitivity to metabolic effectors and doxorubicin. Additionally, significant metabolic differences were observed in nucleoside and amino acid utilization between cancer and control cells, particularly in metastatic and TNBC lines. Conclusions: Our findings reveal the profound metabolic diversity among breast cancer subtypes and highlight distinct substrate dependencies for proliferation. The results additionally provide a framework for developing metabolic biomarkers and targeted therapies for chemotherapy resistance in breast cancer subtypes.

Keywords:  breast cancer; chemotherapy; hormone receptor-positive; metabolic profiling; metabolomics; metastatic; precision medicine; primary; therapeutic tailoring; triple-negative

DOI:  https://doi.org/10.3390/metabo16010054