Endothelial cells and organ function: applications and implications of understanding unique and reciprocal remodelling

Reiterer, Moritz; Branco, Cristina

doi:10.1111/febs.15143

“…Importantly, cell senescence is associated with an inflammatory microenvironment ( Coppé et al, 2008 ; Kuilman et al, 2008 ; Wajapeyee et al, 2008 ), identified in epirubicin-treated hUVEC conditioned medium ( Figures 2C,D ). The effects of inflammation in vascular function are notably reciprocal, and associated with a myriad of chronic health conditions, such as diabetes, aging and neurodegeneration and multiple respiratory syndromes ( Augustin and Koh, 2017 ; Reiterer and Branco, 2020 ).…”

Section: Discussionmentioning

confidence: 99%

“…Human umbilical vein EC (hUVEC) were used to investigate effects on EC survival and function. Additionally, naïve (tumor-free) mice were treated with intravenous epirubicin to assess effects of treatment on lung vascular parameters, considering that lung disease and associated comorbidities are heavily associated with vascular dysfunction ( Reiterer and Branco, 2020 ), and this is also a common metastatic site. Primary microvascular EC (MVEC) were also isolated from lung tissue ( Reiterer et al, 2019 ) to investigate the effects of epirubicin on EC behavior following in vivo exposure.…”

Section: Introductionmentioning

confidence: 99%

Circulating Levels of Epirubicin Cause Endothelial Senescence While Compromising Metabolic Activity and Vascular Function

Eakin

¹

,

Erlain

²

,

Burke

³

et al. 2020

Front. Cell Dev. Biol.

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Anthracycline-based chemotherapy is a common treatment for cancer patients. Because it is delivered intravenously, endothelial cells are exposed first and to the highest concentrations, prior to diffusion to target cells. Not surprisingly, vascular dysfunction is a consequence of anthracycline therapy. While chemotherapy-induced endothelial damage at administration sites has been investigated, the effects of lower doses encountered by distant microvascular networks has not. The aim of this study was to investigate the impact of epirubicin, a widely used anthracycline, on healthy endothelial cells to elucidate its effects on microvascular physiology. Here, endothelial cells were briefly exposed to low doses of epirubicin to recapitulate levels in circulation following dilution in the blood and compound half-life in circulation. Both immediate and prolonged responses to treatment were assessed to determine changes in endothelial function. Epirubicin caused a decrease in proliferation and viability in hUVEC, with lower doses resulting in a senescent phenotype in a large proportion of cells, accompanied by a significant increase in pro-inflammatory cytokines and a significant decrease in metabolic activity. Epirubicin exposure also impaired endothelial function with delayed wound closure, reduced angiogenic potential and increased monolayer permeability downstream of VE-cadherin internalization. Primary lung endothelial cells obtained from epirubicin-treated mice similarly demonstrated reduced viability and functional impairment. In vivo, epirubicin treatment resulted in persistent reduction in lung vascular density and significantly increased infiltration of myeloid cells. Modulation of endothelial status and inflammatory tissue microenvironment observed in response to low doses of epirubicin may predict risk for long-term secondary pathologies associated with chemotherapy.

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“…Importantly, cell senescence is associated with an inflammatory microenvironment (Coppé, Patil et al 2008, Kuilman, Michaloglou et al 2008, Wajapeyee, Serra et al 2008, identified in epirubicin-treated hUVEC conditioned medium (Figure 2C, D). The effects of inflammation in vascular function are notably reciprocal, and associated with a myriad of chronic health conditions, such as diabetes, ageing and neurodegeneration and multiple respiratory syndromes (Augustin andKoh 2017, Reiterer andBranco 2020).…”

Section: Discussionmentioning

confidence: 99%

Circulating levels of epirubicin cause endothelial senescence while compromising metabolic activity and vascular function

Eakin

¹

,

McErlain

²

,

Burke

³

et al. 2020

Preprint

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0

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Anthracycline-based chemotherapy is a common treatment for cancer patients. Because it is delivered intravenously, endothelial cells are exposed first and to the highest concentrations, prior to diffusion to target cells. Not surprisingly, vascular dysfunction is a consequence of anthracycline therapy. While chemotherapy-induced endothelial damage at administration sites has been investigated, the effects of lower doses encountered by distant microvascular networks has not. The aim of this study was to investigate the impact of epirubicin, a widely used anthracycline, on healthy endothelial cells to elucidate its effects on microvascular physiology.Here, endothelial cells were briefly exposed to low doses of epirubicin to recapitulate levels in circulation following dilution in the blood and compound half-life in circulation. Both immediate and prolonged responses to treatment were assessed to determine changes in endothelial function.Epirubicin caused a decrease in proliferation and viability in hUVEC, with lower doses resulting in a senescent phenotype in a large proportion of cells, accompanied by a significant increase in proinflammatory cytokines and a significant decrease in metabolic activity. Epirubicin exposure also impaired endothelial function with delayed wound closure, reduced angiogenic potential and increased monolayer permeability downstream of VE-cadherin internalization. Primary lung endothelial cells obtained from epirubicin-treated mice similarly demonstrated reduced viability and functional impairment. In vivo, epirubicin treatment resulted in persistent reduction in lung vascular density and significantly increased infiltration of myeloid cells.Modulation of endothelial status and inflammatory tissue microenvironment observed in response to low doses of epirubicin may predict risk for long-term secondary pathologies associated with chemotherapy.3 potential for onset and success of distant metastases (Kennecke, Yerushalmi et al. 2010, Martin, Cagney et al. 2017, Xiao, Zheng et al. 2018.The aim of this study is to investigate the consequences of low-level exposure of epirubicin on healthy EC. In spite of its known reduced toxicity in comparison to Doxorubicin, this drug has not been studied in the context of its effects on microvascular physiology and the downstream impact this may have on vascular pathogenesis.In the present study, EC were exposed to short treatments of physiological doses of epirubicin, to emulate exposure in following drug dilution in the blood stream, and accounting for its relatively short half-life (Robert 1994). The aim was to investigate how EC response may educate the organ microenvironment, to what extent, and the duration and/or reversibility of EC adaptations.Human umbilical vein EC (hUVEC) were used to investigate effects on EC survival and function. Additionally, naïve (tumour-free) mice were treated with intravenous epirubicin to assess effects of treatment on lung vascular parameters, considering that lung disease and associated comorbidities are heavily assoc...

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“…EC form a continuous but very heterogeneous organ, with unique functional and metabolic profiles, which responds to stress and inflammation in an organ-specific manner [50]; this may actually underlie therapy-driven metastatic organotropism. Most studies investigating vascular damage in response to prolonged exposure to chemotherapy use HUVECs as their model, which does not address the impact on organ function in light of microvascular heterogeneity [51]. For example, expression of genes involved in substrate transport, ECM remodelling, barrier function and endothelial activation, are significantly altered following doxorubicin exposure [52], but their baseline expression varies significantly across the microvascular EC of the brain, lung and heart [50]-the first two are common metastatic organs for TNBC [53], and the cardiac microvascular EC perform essential roles in cardiac muscle function [54].…”

Section: Relapsementioning

confidence: 99%

“…While microvascular cell plasticity ensures that metabolic demands are met at specific organs and in specific contexts [64], their adaptive responses to stress can involve structural, angiogenic, intercellular communication and metabolic changes likely to favour dissemination and proliferation of circulating tumour cells (CTC) [48,51,[65][66][67]. In turn, CTC have been shown to more efficiently evade cytotoxic treatments, as a result of enhanced DNA repair mechanisms [68].…”

Section: Relapsementioning

confidence: 99%

Life after Cell Death—Survival and Survivorship Following Chemotherapy

Erlain

¹

,

Burke

²

,

Branco

³

2021

Cancers

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To prevent cancer cells replacing and outnumbering their functional somatic counterparts, the most effective solution is their removal. Classical treatments rely on surgical excision, chemical or physical damage to the cancer cells by conventional interventions such as chemo- and radiotherapy, to eliminate or reduce tumour burden. Cancer treatment has in the last two decades seen the advent of increasingly sophisticated therapeutic regimens aimed at selectively targeting cancer cells whilst sparing the remaining cells from severe loss of viability or function. These include small molecule inhibitors, monoclonal antibodies and a myriad of compounds that affect metabolism, angiogenesis or immunotherapy. Our increased knowledge of specific cancer types, stratified diagnoses, genetic and molecular profiling, and more refined treatment practices have improved overall survival in a significant number of patients. Increased survival, however, has also increased the incidence of associated challenges of chemotherapy-induced morbidity, with some pathologies developing several years after termination of treatment. Long-term care of cancer survivors must therefore become a focus in itself, such that along with prolonging life expectancy, treatments allow for improved quality of life.

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Endothelial cells and organ function: applications and implications of understanding unique and reciprocal remodelling

Cited by 21 publications

References 115 publications

Circulating Levels of Epirubicin Cause Endothelial Senescence While Compromising Metabolic Activity and Vascular Function

Circulating Levels of Epirubicin Cause Endothelial Senescence While Compromising Metabolic Activity and Vascular Function

Circulating levels of epirubicin cause endothelial senescence while compromising metabolic activity and vascular function

Life after Cell Death—Survival and Survivorship Following Chemotherapy

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