Tranilast-induced stress alleviation in solid tumors improves the efficacy of chemo- and nanotherapeutics in a size-independent manner

Papageorgis, Panagiotis; Polydorou, Christiana; Mpekris, Fotios; Voutouri, Chrysovalantis; Agathokleous, Eliana A.; Kapnissi‐Christodoulou, Constantina P.; Stylianopoulos, Triantafyllos

doi:10.1038/srep46140

Cited by 103 publications

(116 citation statements)

References 45 publications

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“…In details, we investigated the expression level of pSmad2/3 after incubating TGF‐β‐activated NIH3T3 cells with fraxinellone free drug (Frax) and Frax‐NP‐CGKRK. The antiasthmatic drug tranilast, which possessed antifibrotic effect on tumor‐bearing mice, served as the positive control. Clearly, Frax and Frax‐NP‐CGKRK treatments reversed the increments of pSmad2/3 expression that promoted by TGF‐β (Figure B,C).…”

Section: Resultsmentioning

confidence: 99%

Sequential Targeting TGF‐β Signaling and KRAS Mutation Increases Therapeutic Efficacy in Pancreatic Cancer

Pei

Liang

Huang

et al. 2019

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Pancreatic cancer is a highly aggressive malignancy that strongly resists extant treatments. The failure of existing therapies is majorly attributed to the tough tumor microenvironment (TME) limiting drug access and the undruggable targets of tumor cells. The formation of suppressive TME is regulated by transforming growth factor beta (TGF‐β) signaling, while the poor response and short survival of almost 90% of pancreatic cancer patients results from the oncogenic KRAS mutation. Hence, simultaneously targeting both the TGF‐β and KRAS pathways might dismantle the obstacles of pancreatic cancer therapy. Here, a novel sequential‐targeting strategy is developed, in which antifibrotic fraxinellone‐loaded CGKRK‐modified nanoparticles (Frax‐NP‐CGKRK) are constructed to regulate TGF‐β signaling and siRNA‐loaded lipid‐coated calcium phosphate (LCP) biomimetic nanoparticles (siKras‐LCP‐ApoE3) are applied to interfere with the oncogenic KRAS. Frax‐NP‐CGKRK successfully targets the tumor sites through the recognition of overexpressed heparan sulfate proteoglycan, reverses the activated cancer‐associated fibroblasts (CAFs), attenuates the dense stroma barrier, and enhances tumor blood perfusion. Afterward, siKras‐LCP‐ApoE3 is efficiently internalized by the tumor cells through macropinocytosis and specifically silencing KRAS mutation. Compared with gemcitabine, this sequential‐targeting strategy significantly elongates the lifespans of pancreatic tumor‐bearing animals, hence providing a promising approach for pancreatic cancer therapy.

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Section: Resultsmentioning

confidence: 99%

Sequential Targeting TGF‐β Signaling and KRAS Mutation Increases Therapeutic Efficacy in Pancreatic Cancer

Pei

Liang

Huang

et al. 2019

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“…The elastic modulus of mammary glands was determined using an unconfined compression protocol, as previously described Papageorgis et al 2017;Polydorou et al 2017). Following in utero exposures, the fourth inguinal mammary glands were harvested from mice at either 4 weeks or 12 weeks of age, for each treatment group.…”

Section: Mammary Stiffness Assaymentioning

confidence: 99%

In uteroestrogenic endocrine disruption alters the stroma to increase extracellular matrix density and mammary gland stiffness

Wormsbaecher

Hindman

Avendano

et al. 2019

Preprint

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AbstractIn utero endocrine disruption is linked to increased risk of breast cancer later in life. Despite numerous studies establishing this linkage, the long-term molecular changes that predispose mammary cells to carcinogenic transformation are unknown. Several lines of evidence indicate the stroma mediates endocrine disruption following early-life (or in utero) exposure. Herein, we utilized BPA as a model of estrogenic endocrine disruption to analyze the long-term consequences in the stroma. Using RNA-seq transcriptional profiling of adult primary fibroblasts isolated from female mice exposed to BPA in utero, we identified deregulated genes associated with the extracellular matrix. Specifically, multiple collagen genes had increased expression in exposed mice. In line with the transcriptional data, collagen deposition is increased in adult BPA-exposed mice. We further demonstrate in vitro that fibroblasts exposed to BPA in utero remodel a collagen matrix, thereby decreasing permeability of the collagen matrix. These alterations to the mammary gland resulted in increased gland stiffness in the adult mice. Our data connects early life endocrine disruption to breast density. Interestingly, increased collagen deposition and gland stiffness were not observed in the developing glands of younger mice, suggesting risk factors for breast cancer continue to develop throughout life following these exposures. Finally, we assessed whether in utero exposure to two other endocrine disruptors, BPS and DES, also increase breast stiffness in adult mice. While DES increased breast stiffness, BPS did not, suggesting this BPA alternative may in fact pose less breast cancer risk than its predecessor. As breast stiffness, extracellular matrix density, and collagen deposition have been directly linked to breast cancer risk, these data mechanistically link endocrine disruptor exposures and molecular alterations to increased disease susceptibility in the gland.

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“…This can be understood as a stress-alleviation treatment, in which the tumor is treated with matrix degrading agents to decrease tissue stiffness. In fact, a decrease in stiffness, and thus in mechanical stress levels, may lead to less malignant tumor phenotypes in terms of a reduction in IW 34 . This is shown in Figure 5C, in which the difference between IW at α = 5 × 10 2 Pa and α = 5 × 10 3 Pa is displayed over the (D, r) space.…”

Section: Nutrient-driven Phenotypic Transitionsmentioning

confidence: 99%

“…33 with mechanical-driven phenotypic transitions, and (ii) to evaluate the effects of a stress-alleviation treatment on glioma progression and invasion. Models describing the application of stress-alleviation treatments already exist in the literature 34 ; however, to the authors knowledge, the influence of cellular phenotypic transitions -resulting from these microenvironmental treatments -on tumor progression have not been investigated yet.…”

Section: Introductionmentioning

confidence: 99%

On the impact of chemo-mechanically induced phenotypic transitions in gliomas

Mascheroni

Alfonso

Kalli

et al. 2018

Preprint

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Tumor microenvironment is a critical player in glioma progression and novel therapies for its targeting have been recently proposed. In particular, stress-alleviation strategies act on the tumor by reducing its stiffness, decreasing solid stresses and improving blood perfusion. However, these microenvironmental changes trigger chemo-mechanically induced cellular phenotypic transitions whose impact on therapy outcomes is not completely understood. In this work, we perform experiments to analyze the effects of mechanical compression on migration and proliferation of two glioma cell lines. From these experiments, we derive a mathematical model of glioma progression focusing on cellular phenotypic plasticity. The model reveals a trade-off between tumor infiltration and cellular content as a consequence of stress-alleviation approaches. We discuss how these findings can improve the current understanding of glioma/microenvironment interactions, and suggest strategies to improve therapeutic outcomes. 4/2513/25 14/25

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Tranilast-induced stress alleviation in solid tumors improves the efficacy of chemo- and nanotherapeutics in a size-independent manner

Cited by 103 publications

References 45 publications

Sequential Targeting TGF‐β Signaling and KRAS Mutation Increases Therapeutic Efficacy in Pancreatic Cancer

Sequential Targeting TGF‐β Signaling and KRAS Mutation Increases Therapeutic Efficacy in Pancreatic Cancer

In uteroestrogenic endocrine disruption alters the stroma to increase extracellular matrix density and mammary gland stiffness

On the impact of chemo-mechanically induced phenotypic transitions in gliomas

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