Your search keyword '"Landis MD"' showing total 3 results

1. Author Correction: Obesity induces PD-1 on macrophages to suppress anti-tumour immunity.

Author

Bader JE, Wolf MM, Lupica-Tondo GL, Madden MZ, Reinfeld BI, Arner EN, Hathaway ES, Steiner KK, Needle GA, Hatem Z, Landis MD, Faneuff EE, Blackman A, Wolf EM, Cottam MA, Ye X, Bates ME, Smart K, Wang W, Pinheiro LV, Christofides A, Smith D, Boussiotis VA, Haake SM, Beckermann KE, Wellen KE, Reinhart-King CA, Serezani CH, Lee CH, Aubrey C, Chen H, Rathmell WK, Hasty AH, and Rathmell JC

Published

2024

2. Obesity induces PD-1 on macrophages to suppress anti-tumour immunity.

Author

Bader JE, Wolf MM, Lupica-Tondo GL, Madden MZ, Reinfeld BI, Arner EN, Hathaway ES, Steiner KK, Needle GA, Hatem Z, Landis MD, Faneuff EE, Blackman A, Wolf EM, Cottam MA, Ye X, Bates ME, Smart K, Wang W, Pinheiro LV, Christofides A, Smith D, Boussiotis VA, Haake SM, Beckermann KE, Wellen KE, Reinhart-King CA, Serezani CH, Lee CH, Aubrey C, Chen H, Rathmell WK, Hasty AH, and Rathmell JC

Subjects

Animals, Female, Humans, Male, Mice, Antigen Presentation drug effects, B7-2 Antigen antagonists & inhibitors, B7-2 Antigen immunology, B7-2 Antigen metabolism, CD8-Positive T-Lymphocytes immunology, CD8-Positive T-Lymphocytes metabolism, Cell Line, Tumor, Glycolysis drug effects, Histocompatibility Antigens Class I immunology, Histocompatibility Antigens Class II immunology, Immune Checkpoint Inhibitors pharmacology, Immune Checkpoint Inhibitors therapeutic use, Inflammation Mediators immunology, Inflammation Mediators metabolism, Lymphocyte Activation, Mechanistic Target of Rapamycin Complex 1 metabolism, Mechanistic Target of Rapamycin Complex 1 antagonists & inhibitors, Mice, Inbred C57BL, Phagocytosis drug effects, Neoplasms drug therapy, Neoplasms immunology, Neoplasms metabolism, Neoplasms pathology, Obesity immunology, Obesity metabolism, Programmed Cell Death 1 Receptor metabolism, Programmed Cell Death 1 Receptor antagonists & inhibitors, Tumor-Associated Macrophages immunology, Tumor-Associated Macrophages metabolism, Tumor-Associated Macrophages drug effects

Abstract

Obesity is a leading risk factor for progression and metastasis of many cancers 1,2 , yet can in some cases enhance survival 3-5 and responses to immune checkpoint blockade therapies, including anti-PD-1, which targets PD-1 (encoded by PDCD1), an inhibitory receptor expressed on immune cells 6-8 . Although obesity promotes chronic inflammation, the role of the immune system in the obesity-cancer connection and immunotherapy remains unclear. It has been shown that in addition to T cells, macrophages can express PD-1 9-12 . Here we found that obesity selectively induced PD-1 expression on tumour-associated macrophages (TAMs). Type I inflammatory cytokines and molecules linked to obesity, including interferon-γ, tumour necrosis factor, leptin, insulin and palmitate, induced macrophage PD-1 expression in an mTORC1- and glycolysis-dependent manner. PD-1 then provided negative feedback to TAMs that suppressed glycolysis, phagocytosis and T cell stimulatory potential. Conversely, PD-1 blockade increased the level of macrophage glycolysis, which was essential for PD-1 inhibition to augment TAM expression of CD86 and major histocompatibility complex I and II molecules and ability to activate T cells. Myeloid-specific PD-1 deficiency slowed tumour growth, enhanced TAM glycolysis and antigen-presentation capability, and led to increased CD8 + T cell activity with a reduced level of markers of exhaustion. These findings show that obesity-associated metabolic signalling and inflammatory cues cause TAMs to induce PD-1 expression, which then drives a TAM-specific feedback mechanism that impairs tumour immune surveillance. This may contribute to increased cancer risk yet improved response to PD-1 immunotherapy in obesity., (© 2024. The Author(s), under exclusive licence to Springer Nature Limited.)

Published

2024

3. XBP1 promotes triple-negative breast cancer by controlling the HIF1α pathway.

Author

Chen X, Iliopoulos D, Zhang Q, Tang Q, Greenblatt MB, Hatziapostolou M, Lim E, Tam WL, Ni M, Chen Y, Mai J, Shen H, Hu DZ, Adoro S, Hu B, Song M, Tan C, Landis MD, Ferrari M, Shin SJ, Brown M, Chang JC, Liu XS, and Glimcher LH

Subjects

Animals, CD24 Antigen metabolism, Cell Hypoxia genetics, Cell Line, Tumor, Cell Proliferation, DNA-Binding Proteins deficiency, DNA-Binding Proteins genetics, Disease Progression, Female, Gene Expression Regulation, Neoplastic, Gene Regulatory Networks, Gene Silencing, Humans, Hyaluronan Receptors metabolism, Mice, Neoplasm Invasiveness, Neoplasm Recurrence, Local, Prognosis, RNA Polymerase II metabolism, Regulatory Factor X Transcription Factors, Transcription Factors deficiency, Transcription Factors genetics, Transcription, Genetic, Triple Negative Breast Neoplasms blood supply, Triple Negative Breast Neoplasms genetics, Unfolded Protein Response, X-Box Binding Protein 1, DNA-Binding Proteins metabolism, Hypoxia-Inducible Factor 1, alpha Subunit metabolism, Transcription Factors metabolism, Triple Negative Breast Neoplasms metabolism, Triple Negative Breast Neoplasms pathology

Abstract

Cancer cells induce a set of adaptive response pathways to survive in the face of stressors due to inadequate vascularization. One such adaptive pathway is the unfolded protein (UPR) or endoplasmic reticulum (ER) stress response mediated in part by the ER-localized transmembrane sensor IRE1 (ref. 2) and its substrate XBP1 (ref. 3). Previous studies report UPR activation in various human tumours, but the role of XBP1 in cancer progression in mammary epithelial cells is largely unknown. Triple-negative breast cancer (TNBC)--a form of breast cancer in which tumour cells do not express the genes for oestrogen receptor, progesterone receptor and HER2 (also called ERBB2 or NEU)--is a highly aggressive malignancy with limited treatment options. Here we report that XBP1 is activated in TNBC and has a pivotal role in the tumorigenicity and progression of this human breast cancer subtype. In breast cancer cell line models, depletion of XBP1 inhibited tumour growth and tumour relapse and reduced the CD44(high)CD24(low) population. Hypoxia-inducing factor 1α (HIF1α) is known to be hyperactivated in TNBCs. Genome-wide mapping of the XBP1 transcriptional regulatory network revealed that XBP1 drives TNBC tumorigenicity by assembling a transcriptional complex with HIF1α that regulates the expression of HIF1α targets via the recruitment of RNA polymerase II. Analysis of independent cohorts of patients with TNBC revealed a specific XBP1 gene expression signature that was highly correlated with HIF1α and hypoxia-driven signatures and that strongly associated with poor prognosis. Our findings reveal a key function for the XBP1 branch of the UPR in TNBC and indicate that targeting this pathway may offer alternative treatment strategies for this aggressive subtype of breast cancer.

Published

2014