Bidirectional signalling between the tumour and stroma shapes tumour aggressiveness and metastasis. ATF4 is a major effector of the Integrated Stress Response, a homeostatic mechanism that couples cell growth and survival to bioenergetic demands. Using conditional knockout ATF4 mice, we show that global, or fibroblast-specific loss of host ATF4, results in deficient vascularization and a pronounced growth delay of syngeneic melanoma and pancreatic tumours. Single-cell transcriptomics of tumours grown in Atf4Δ/Δ mice uncovered a reduction in activation markers in perivascular cancer-associated fibroblasts (CAFs). Atf4Δ/Δ fibroblasts displayed significant defects in collagen biosynthesis and deposition and a reduced ability to support angiogenesis. Mechanistically, ATF4 regulates the expression of the Col1a1 gene and levels of glycine and proline, the major amino acids of collagen. Analyses of human melanoma and pancreatic tumours revealed a strong correlation between ATF4 and collagen levels. Our findings establish stromal ATF4 as a key driver of CAF functionality, malignant progression and metastasis.
Purpose: Radiation-induced cardiotoxicity is a significant concern in thoracic oncology patients. However, the basis for this disease pathology is not well characterized. We developed a novel mouse model of radiation-induced cardiotoxicity to investigate pathophysiologic mechanisms and identify clinically targetable biomarkers of cardiac injury. Experimental Design: Single radiation doses of 20, 40, or 60 Gy were delivered to the cardiac apex of female C57BL/6 mice ages 9-11 weeks, with or without adjacent lung tissue, using conformal radiotherapy. Cardiac tissue was harvested up to 24 weeks postradiotherapy for histologic analysis. Echocardiography and Technetium-99m sestamibi single photon emission computed tomography (SPECT) at 8 and 16 weeks post-radiotherapy were implemented to evaluate myocardial function and perfusion. Mouse cardiac tissue and mouse and human plasma were harvested for biochemical studies. Results: Histopathologically, radiotherapy resulted in perivascular fibrosis 8 and 24 (P < 0.05) weeks post-radiotherapy. Apical perfusion deficits on SPECT and systolic and diastolic dysfunction on echocardiography 8 and 16 weeks postradiotherapy were also observed (P < 0.05). Irradiated cardiac tissue and plasma showed significant increases in placental growth factor (PlGF), IL6, and TNFa compared with nonradiated matched controls, with greater increases in cardiac cytokine levels when radiotherapy involved lung. Human plasma showed increased PlGF (P ¼ 0.021) and TNFa (P ¼ 0.036) levels after thoracic radiotherapy. PlGF levels demonstrated a strong correlation (r ¼ 0.89, P ¼ 0.0001) with mean heart dose. Conclusions: We developed and characterized a pathophysiologically relevant mouse model of radiation-induced cardiotoxicity involving in situ irradiation of the cardiac apex. The model can be used to integrate radiomic and biochemical markers of cardiotoxicity to inform early therapeutic intervention and human translational studies.
Radiation therapy (RT) is an important modality in cancer treatment with >50% of cancer patients undergoing RT for curative or palliative intent. In patients with breast, lung, and esophageal cancer, as well as mediastinal malignancies, incidental RT dose to heart or vascular structures has been linked to the development of Radiation-Induced Heart Disease (RIHD) which manifests as ischemic heart disease, cardiomyopathy, cardiac dysfunction, and heart failure. Despite the remarkable progress in the delivery of radiotherapy treatment, off-target cardiac toxicities are unavoidable. One of the best-studied pathological consequences of incidental exposure of the heart to RT is collagen deposition and fibrosis, leading to the development of radiation-induced myocardial fibrosis (RIMF). However, the pathogenesis of RIMF is still largely unknown. Moreover, there are no available clinical approaches to reverse RIMF once it occurs and it continues to impair the quality of life of long-term cancer survivors. Hence, there is an increasing need for more clinically relevant preclinical models to elucidate the molecular and cellular mechanisms involved in the development of RIMF. This review offers an insight into the existing preclinical models to study RIHD and the suggested mechanisms of RIMF, as well as available multi-modality treatments and outcomes. Moreover, we summarize the valuable detection methods of RIHD/RIMF, and the clinical use of sensitive radiographic and circulating biomarkers.
ATF4 is a major effector of the Integrated Stress Response (ISR), a homeostatic mechanism coupling cell growth and survival to bioenergetic demands. Although the pro-tumorigenic role of the ISR in a tumor cell-intrinsic manner has been established, its role in cell-extrinsic processes remains unexplored. Using novel conditional knockout ATF4 mouse models, we show that global, or fibroblast (FB)-specific loss of host ATF4 results in abnormal tumor vascularization and a pronounced tumor growth delay in syngeneic melanoma and pancreatic tumor models, a phenotype which is largely reversed by co-injection of ATF4wt/wt FBs. Single-cell tumor transcriptomics uncovered a reduction of markers associated with FB activation in a cluster of perivascular cancer-associated fibroblasts (CAF) in ATF4Δ/Δ mice. ATF4Δ/Δ FBs displayed significant defects in collagen biosynthesis and deposition and reduced ability to support angiogenesis in vitro. Mechanistically, ATF4 directly regulates the expression of the Col1a1 gene as well as the biosynthesis of glycine and proline, the major amino acids comprising collagen fibers. Analysis of human tumor samples revealed a strong correlation between ATF4 and collagen levels and between an ATF4 FB signature and expression of collagen genes. Our findings uncover a novel role of stromal ATF4 in shaping CAF functionality, a key driver of disease progression and therapy resistance.
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