Short-term topiramate treatment prevents radiation-induced cytotoxic edema in preclinical models of breast-cancer brain metastasis.

BACKGROUND: Brain edema is a common complication of brain metastases (BM) and associated treatment. The extent to which cytotoxic edema, the first step in the sequence that leads to ionic edema, vasogenic edema, and brain swelling, contributes to radiation-induced brain edema during BM remains unknown. This study aimed to determine whether radiation-associated treatment of BM induces cytotoxic edema and the consequences of blocking the edema in preclinical models of breast-cancer brain metastases (BCBM). METHODS: Using in vitro and in vivo models, we measured astrocytic swelling, trans-electric resistance (TEER), and aquaporin 4 (AQP4) expression following radiation. Genetic and pharmacological inhibition of AQP4 in astrocytes and cancer cells was used to assess the role of AQP4 in astrocytic swelling and brain water intake. An anti-epileptic drug that blocks AQP4 function (topiramate) was used to prevent cytotoxic edema in models of BM. RESULTS: Radiation-induced astrocytic swelling and transient upregulation of AQP4 occurred within the first 24 hours following radiation. Topiramate decreased radiation-induced astrocytic swelling and loss of TEER in astrocytes in vitro, and acute short-term treatment (but not continuous administration), prevented radiation-induced increase in brain water content without pro-tumorigenic effects in multiple preclinical models of BCBM. AQP4 was expressed in clinical BM and breast-cancer cell lines, but AQP4 targeting had limited direct pro-tumorigenic or radioprotective effects in cancer cells that could impact its clinical translation. CONCLUSIONS: Patients with BM could find additional benefits from acute and temporary preventive treatment of radiation-induced cytotoxic edema using anti-epileptic drugs able to block AQP4 function.

Short-term Topiramate treatment prevents radiation-induced cytotoxic edema in preclinical models of breast-cancer brain metastasis.

Background: Brain edema is a common complication of brain metastases (BM) and associated treatment. The extent to which cytotoxic edema, the first step in the sequence that leads to ionic edema, vasogenic edema and brain swelling, contributes to radiation-induced brain edema during BM remains unknown. This study aimed to determine whether radiation-associated treatment of BM induces cytotoxic edema and the consequences of blocking the edema in pre-clinical models of breast cancer brain metastases (BCBM). Methods: Using in vitro and in vivo models, we measured astrocytic swelling, trans-electric resistance (TEER) and aquaporin 4 (AQP4) expression following radiation. Genetic and pharmacological inhibition of AQP4 in astrocytes and cancer cells was used to assess the role of AQP4 in astrocytic swelling and brain water intake. An anti-epileptic drug that blocks AQP4 function (topiramate) was used to prevent cytotoxic edema in models of BM. Results: Radiation-induced astrocytic swelling and transient upregulation of AQP4 within the first 24 hours following radiation. Topiramate decreased radiation-induced astrocytic swelling, loss of TEER in astrocytes in vitro , and acute short term treatment (but not continuous administration), prevented radiation-induced increase in brain water content without pro-tumorigenic effects in multiple pre-clinical models of BCBM. AQP4 was expressed in clinical BM and breast cancer cell lines, but AQP4 targeting had limited direct pro-tumorigenic or radioprotective effects in cancer cells that could impact its clinical translation. Conclusions: Patients with BM could find additional benefits from acute and temporary preventive treatment of radiation-induced cytotoxic edema using anti-epileptic drugs able to block AQP4 function. Key points: Radiation induces cytotoxic edema via acute dysregulation of AQP4 in astrocytes in preclinical models of BM. Pharmacologic blockage of AQP4 function prevents water intake, astrocytic swelling and restores TEER in vitro. Pre-treatment with single-dose Topiramate prevents brain radiation-induced brain edema without direct tumor effects in pre-clinical models of BCBM. IMPORTANCE OF THE STUDY: In this study we describe a novel role for astrocytic swelling and cytotoxic edema in the progression of radiation-induced brain edema during BM treatment. While radiation-induced edema has been fully attributed to the disruption of the blood-brain barrier (BBB) and ensuing vasogenic effects, our results suggest that cytotoxic edema affecting astrocytes in the acute setting plays an important role in the progression of brain edema during BM standard of care. Current standard of care for brain edema involves pre-treatment with steroids and the use of bevacizumab only after clinically significant edema develops. Both interventions are presumed to target vasogenic edema. This study suggests that patients with BM could find additional benefits from acute and temporary preventive treatment of radiation-induced cytotoxic edema using an already FDA-approved anti-epileptic drug. Such early prevention strategy can be easily clinically implemented with the goal of minimizing treatment-related toxicities.

IL13Rα2 Promotes Proliferation and Outgrowth of Breast Cancer Brain Metastases.

PURPOSE: The survival of women with brain metastases (BM) from breast cancer remains very poor, with over 80% dying within a year of their diagnosis. Here, we define the function of IL13Rα2 in outgrowth of breast cancer brain metastases (BCBM) in vitro and in vivo, and postulate IL13Rα2 as a suitable therapeutic target for BM. EXPERIMENTAL DESIGN: We performed IHC staining of IL13Rα2 in BCBM to define its prognostic value. Using inducible shRNAs in TNBC and HER2+ breast-brain metastatic models, we assessed IL13Rα2 function in vitro and in vivo. We performed RNAseq and functional studies to define the molecular mechanisms underlying IL13Rα2 function in BCBM. RESULTS: High IL13Rα2 expression in BCBM predicted worse survival after BM diagnoses. IL13Rα2 was essential for cancer-cell survival, promoting proliferation while repressing invasion. IL13Rα2 KD resulted in FAK downregulation, repression of cell cycle and proliferation mediators, and upregulation of Ephrin B1 signaling. Ephrin-B1 (i) promoted invasion of BC cells in vitro, (ii) marked micrometastasis and invasive fronts in BCBM, and (iii) predicted shorter disease-free survival and BM-free survival (BMFS) in breast primary tumors known to metastasize to the brain. In experimental metastases models, which bypass early tumor invasion, downregulation of IL13Rα2 before or after tumor seeding and brain intravasation decreased BMs, suggesting that IL13Rα2 and the promotion of a proliferative phenotype is critical to BM progression. CONCLUSIONS: Non-genomic phenotypic adaptations at metastatic sites are critical to BM progression and patients' prognosis. This study opens the road to use IL13Rα2 targeting as a therapeutic strategy for BM.