Jean‐Yves Le Guennec scite author profile

Voltage-gated sodium channels (Na V ) are functionally expressed in highly metastatic cancer cells derived from nonexcitable epithelial tissues (breast, prostate, lung, and cervix). MDA-MB-231 breast cancer cells express functional sodium channel complexes, consisting of Na V 1.5 and associated auxiliary ␤-subunits, that are responsible for a sustained inward sodium current at the membrane potential. Although these channels do not regulate cellular multiplication or migration, their inhibition by the specific blocker tetrodotoxin impairs both the extracellular gelatinolytic activity (monitored with DQ-gelatin) and cell invasiveness leading to the attenuation of colony growth and cell spreading in three-dimensional Matrigel-composed matrices. MDA-MB-231 cells express functional cysteine cathepsins, which we found play a predominant role (ϳ65%) in cancer invasiveness. Matrigel invasion is significantly decreased in the presence of specific inhibitors of cathepsins B and S (CA-074 and Z-FL-COCHO, respectively), and co-application of tetrodotoxin does not further reduce cell invasion. This suggests that cathepsins B and S are involved in invasiveness and that their proteolytic activity partly depends on Na V function. Inhibiting Na V has no consequence for cathepsins at the transcription, translation, and secretion levels. However, Na V activity leads to an intracellular alkalinization and a perimembrane acidification favorable for the extracellular activity of these acidic proteases. We propose that Na v enhance the invasiveness of cancer cells by favoring the pH-dependent activity of cysteine cathepsins. This general mechanism could lead to the identification of new targets allowing the therapeutic prevention of metastases.Breast cancer is the most common female cancer and the primary cause of death in women by cancer worldwide (1).Deaths occur primarily after the development of metastases. The invasive potential of malignant cells is mainly linked to their capacity to degrade basement membranes and extracellular matrices by various proteases. Studies have mostly focused on metalloproteases, including matrix metalloproteinases and the closely related ADAMs (a disintegrin and metalloproteinase) and ADAMTs (a disintegrin and metalloproteinase with thrombospondin motifs) (2), that are key factors in growth, invasion, and angiogenesis, and to a lesser extent on aspartyl and serine proteases. Pharmaceutical inhibitors of matrix metalloproteinases have been developed, but the results from clinical trials with these drugs have so far been disappointing (3,4

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Involvement of a novel fast inward sodium current in the invasion capacity of a breast cancer cell line

Roger

Besson

Guennec

2003

Biochimica et Biophysica Acta (BBA) - Biomembranes

145

202

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This work reports the finding of a unique fast inward sodium current (I(Na)) in MDA-MB-231 cells which is missing in MDA-MB-468 cells and in MCF-7 cells. This current is high-voltage-activated and displays a window current at the membrane potential of MDA-MB-231 cells. This current is blocked by high concentrations of tetrodotoxin (TTX). In MDA-MB-231 cells, which are the most invasive cells among the three cell lines tested, proliferation and migration were not sensitive to TTX while invasion was reduced by approximately 30%. These experiments suggest that I(Na) is involved in the invasion process, probably through its participation to the regulation of the intracellular sodium homeostasis.

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NaV1.5 enhances breast cancer cell invasiveness by increasing NHE1-dependent H+ efflux in caveolae

et al. 2010

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Na V 1.5 sodium channels enhance the invasiveness of breast cancer cells through the acidic-dependent activation of cysteine cathepsins. Here, we showed that the Na þ /H þ exchanger type 1 (NHE1) was an important regulator of H þ efflux in breast cancer cells MDA-MB-231 and that its activity was increased by Na V 1.5. Na V 1.5 and NHE1 were colocalized in membrane rafts containing caveolin-1. The inhibition of Na V 1.5 or NHE1 induced a similar reduction in cell invasiveness and extracellular matrix degradation; no additive effect was observed when they were simultaneously inhibited. Our study suggests that Na V 1.5 and NHE1 are functionally coupled and enhance the invasiveness of cancer cells by increasing H þ efflux.

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Voltage-gated sodium channels potentiate the invasive capacities of human non-small-cell lung cancer cell lines

Roger

Rollin

Barascu

et al. 2007

The International Journal of Biochemistry & Cell Biology

157

142

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Ranolazine inhibits NaV1.5-mediated breast cancer cell invasiveness and lung colonization

et al. 2014

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BackgroundNaV1.5 voltage-gated sodium channels are abnormally expressed in breast tumours and their expression level is associated with metastatic occurrence and patients’ death. In breast cancer cells, NaV1.5 activity promotes the proteolytic degradation of the extracellular matrix and enhances cell invasiveness.FindingsIn this study, we showed that the extinction of NaV1.5 expression in human breast cancer cells almost completely abrogated lung colonisation in immunodepressed mice (NMRI nude). Furthermore, we demonstrated that ranolazine (50 μM) inhibited NaV1.5 currents in breast cancer cells and reduced NaV1.5-related cancer cell invasiveness in vitro. In vivo, the injection of ranolazine (50 mg/kg/day) significantly reduced lung colonisation by NaV1.5-expressing human breast cancer cells.ConclusionsTaken together, our results demonstrate the importance of NaV1.5 in the metastatic colonisation of organs by breast cancer cells and indicate that small molecules interfering with NaV activity, such as ranolazine, may represent powerful pharmacological tools to inhibit metastatic development and improve cancer treatments.Electronic supplementary materialThe online version of this article (doi:10.1186/1476-4598-13-264) contains supplementary material, which is available to authorized users.

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Transmural stretch‐dependent regulation of contractile properties in rat heart and its alteration after myocardial infarction

et al. 2004

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The "stretch-sensitization" response is essential to the regulation of heart contractility. An increase in diastolic volume improves systolic contraction. The cellular mechanisms of this modulation, the Frank-Starling law, are still uncertain. Moreover, their alterations in heart failure remains controversial. Here, using left ventricular skinned rat myocytes, we show a nonuniform stretch-sensitization of myofilament activation across the ventricular wall. Stretch-dependent Ca2+ sensitization of myofilaments increases from sub-epicardium to sub-endocardium and is correlated with an increase in passive tension. This passive tension-dependent component of myofibrillar activation is not associated with expression of titin isoforms, changes in troponin I level, and phosphorylation status. Instead, we observe that stretch induces phosphorylation of ventricular myosin light chain 2 isoform (VLC2b) in sub-endocardium specifically. Thus, VLC2b phosphorylation could act as a stretch-dependent modulator of activation tuned within normal heart. Moreover,in postmyocardial infarcted rat, the gradient of stretch-dependent Ca2+ sensitization disappears associated with a lack of VLC2b phosphorylation in sub-endocardium. In conclusion, nonuniformity is a major characteristic of the normal adult left ventricle (LV). The heterogeneous myocardial deformation pattern might be caused not only by the morphological heterogeneity of the tissue in the LV wall, but also by the nonuniform contractile properties of the myocytes across the wall. The loss of a contractile transmural gradient after myocardial infarction should contribute to the impaired LV function.

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Physiological role of reactive oxygen species as promoters of natural defenses

et al. 2017

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It has been 60 yr since the discovery of reactive oxygen species (ROS) in biology and the beginning of the scientific community's attempt to understand the impact of the unpaired electron of ROS molecules in biological pathways, which was eventually noted to be toxic. Several studies have shown that the presence of ROS is essential in triggering or acting as a secondary factor for numerous pathologies, including metabolic and genetic diseases; however, it was demonstrated that chronic treatment with antioxidants failed to show efficacy and positive effects in the prevention of diseases or health complications that result from oxidative stress. On the contrary, such treatment has been shown to sometimes even worsen the disease. Because of the permanent presence of ROS in organisms, elaborate mechanisms to adapt with these reactive molecules and to use them without necessarily blocking or preventing their actions have been studied. There is now a large body of evidence that shows that living organisms have conformed to the presence of ROS and, in retrospect, have adapted to the bioactive molecules that are generated by ROS on proteins, lipids, and DNA. In addition, ROS have undergone a shift from being molecules that invoked oxidative damage in regulating signaling pathways that impinged on normal physiological and redox responses. Working in this direction, this review unlocks a new conception about the involvement of cellular oxidants in the maintenance of redox homeostasis in redox regulation of normal physiological functions, and an explanation for its essential role in numerous pathophysiological states is noted.-Roy, J., Galano, J.-M., Durand, T., Le Guennec, J.-Y., Lee, J. C.-Y. Physiological role of reactive oxygen species as promoters of natural defenses.

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Voltage-gated sodium channels and cancer: is excitability their primary role?

et al. 2015

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Voltage-gated sodium channels (NaV) are molecular characteristics of excitable cells. Their activation, triggered by membrane depolarization, generates transient sodium currents that initiate action potentials in neurons and muscle cells. Sodium currents were discovered by Hodgkin and Huxley using the voltage clamp technique and reported in their landmark series of papers in 1952. It was only in the 1980's that sodium channel proteins from excitable membranes were molecularly characterized by Catterall and his collaborators. Non-excitable cells can also express NaV channels in physiological conditions as well as in pathological conditions. These NaV channels can sustain biological roles that are not related to the generation of action potentials. Interestingly, it is likely that the abnormal expression of NaV in pathological tissues can reflect the re-expression of a fetal phenotype. This is especially true in epithelial cancer cells for which these channels have been identified and sodium currents recorded, while it was not the case for cells from the cognate normal tissues. In cancers, the functional activity of NaV appeared to be involved in regulating the proliferative, migrative, and invasive properties of cells. This review is aimed at addressing the non-excitable roles of NaV channels with a specific emphasis in the regulation of cancer cell biology.

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