Selective Blockade of the Intermediate-Conductance Ca
            <sup>2+</sup>
            -Activated K
            <sup>+</sup>
            Channel Suppresses Proliferation of Microvascular and Macrovascular Endothelial Cells and Angiogenesis In Vivo

Grgic, Ivica; Eichler, Ines; Heinau, Philipp; Si, Han; Brakemeier, Susanne; Hoyer, Joachim; Köhler, Ralf

doi:10.1161/01.atv.0000156399.12787.5c

Cited by 136 publications

(140 citation statements)

References 33 publications

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“…The SK4‐dependent current fraction (difference between red and black symbols in Fig. 1G) exhibited strong inward rectification as reported for canonical SK4 channels which are usually present at the plasma membrane of, for example, endothelial cells and smooth muscle cells (Grgic et al ., 2005; Toyama et al ., 2008). …”

Section: Resultsmentioning

confidence: 99%

“…Current knowledge suggests that BK (Lallet‐Daher et al ., 2009; Parihar et al ., 2003; Stegen et al ., 2015) and SK4 (Ouadid‐Ahidouch et al ., 2004; Parihar et al ., 2003; Steinle et al ., 2011) activities are required for malignant growth of several tumour‐derived cell lines and of xenografts in immunocompromised mice, highlighting a general role of K Ca channels for cell cycle‐specific functions (Huang and Jan, 2014; Pardo and Stuhmer, 2014). Expression of SK4 and BK in cancer cells follows a cell cycle‐dependent mode (Ouadid‐Ahidouch et al ., 2004; Pardo et al ., 1998) and the mitogen‐dependent regulation of K Ca activity supports a role for both channels in malignant (Faouzi et al ., 2010; Lallet‐Daher et al ., 2009; Wang et al ., 2007a) and nonmalignant cell proliferation (Grgic et al ., 2005; Khanna et al ., 1999; Toyama et al ., 2008; Yu et al ., 2013). By inducing a more negative membrane voltage, activation of K + channels provides a driving force for Ca 2+ influx into the nonexcitable tumour cell.…”

Section: Introductionmentioning

confidence: 99%

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SK4 channels modulate Ca²⁺ signalling and cell cycle progression in murine breast cancer

et al. 2017

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Oncogenic signalling via Ca2+‐activated K+ channels of intermediate conductance (SK4, also known as KCa3.1 or IK) has been implicated in different cancer entities including breast cancer. Yet, the role of endogenous SK4 channels for tumorigenesis is unclear. Herein, we generated SK4‐negative tumours by crossing SK4‐deficient (SK4 KO) mice to the polyoma middle T‐antigen (PyMT) and epidermal growth factor receptor 2 (cNeu) breast cancer models in which oncogene expression is driven by the retroviral promoter MMTV. Survival parameters and tumour progression were studied in cancer‐prone SK4 KO in comparison with wild‐type (WT) mice and in a syngeneic orthotopic mouse model following transplantation of SK4‐negative or WT tumour cells. SK4 activity was modulated by genetic or pharmacological means using the SK4 inhibitor TRAM‐34 in order to establish the role of breast tumour SK4 for cell growth, electrophysiological signalling, and [Ca2+]i oscillations. Ablation of SK4 and TRAM‐34 treatment reduced the SK4‐generated current fraction, growth factor‐dependent Ca2+ entry, cell cycle progression and the proliferation rate of MMTV‐PyMT tumour cells. In vivo, PyMT oncogene‐driven tumorigenesis was only marginally affected by the global lack of SK4, whereas tumour progression was significantly delayed after orthotopic implantation of MMTV‐PyMT SK4 KO breast tumour cells. However, overall survival and progression‐free survival time in the MMTV‐cNeu mouse model were significantly extended in the absence of SK4. Collectively, our data from murine breast cancer models indicate that SK4 activity is crucial for cell cycle control. Thus, the modulation of this channel should be further investigated towards a potential improvement of existing antitumour strategies in human breast cancer.

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Section: Resultsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

SK4 channels modulate Ca²⁺ signalling and cell cycle progression in murine breast cancer

et al. 2017

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“…Conversely, we and others have recently demonstrated in models of experimental angiogenesis (15), post-interventional arterial restenosis (17,19), atherosclerosis (26), and endometrial cancer (27), that selective pharmacological inhibition or knockdown of K Ca 3.1 suppresses mitogen-driven cell proliferation and ameliorates disease progression. Thus, K Ca 3.1 could have a pivotal role in disease states characterized by excessive cell proliferation and may emerge as a promising pharmacotherapeutic target for antiproliferative treatment.…”

mentioning

confidence: 86%

“…Interestingly, mitogens such as bFGF, PDGF, or VEGF have been found to distinctly up-regulate K Ca 3.1 in several cell types (15,21). Conversely, we and others have recently demonstrated in models of experimental angiogenesis (15), post-interventional arterial restenosis (17,19), atherosclerosis (26), and endometrial cancer (27), that selective pharmacological inhibition or knockdown of K Ca 3.1 suppresses mitogen-driven cell proliferation and ameliorates disease progression.…”

mentioning

confidence: 93%

“…Whereas the first directly mediate Ca 2ϩ inflow, the latter regulate membrane potential and thus provide the driving force for Ca 2ϩ entry (13). In particular, the intermediate-conductance K Ca (K Ca 3.1) has been shown to play an important role in promoting mitogenesis in several tissues such as the endothelium (15,16), vascular smooth muscle (17)(18)(19), and T lymphocytes (20) as well as in several cell lines including A7r5 neonatal aortic smooth muscle cells (21), 10T1/2-MRF4 myogenic fibroblasts (22,23), HMEC-1 dermal endothelial cells (15), and some cancer cell lines (24,25).…”

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confidence: 99%

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Renal fibrosis is attenuated by targeted disruption of K _Ca 3.1 potassium channels

Grgic

Kiss

Kaistha

et al. 2009

Proc. Natl. Acad. Sci. U.S.A.

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137

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Proliferation of interstitial fibroblasts is a hallmark of progressive renal fibrosis commonly resulting in chronic kidney failure. The intermediate-conductance Ca 2+ -activated K + channel (K Ca 3.1) has been proposed to promote mitogenesis in several cell types and contribute to disease states characterized by excessive proliferation. Here, we hypothesized that K Ca 3.1 activity is pivotal for renal fibroblast proliferation and that deficiency or pharmacological blockade of K Ca 3.1 suppresses development of renal fibrosis. We found that mitogenic stimulation up-regulated K Ca 3.1 in murine renal fibroblasts via a MEK-dependent mechanism and that selective blockade of K Ca 3.1 functions potently inhibited fibroblast proliferation by G 0 /G 1 arrest. Renal fibrosis induced by unilateral ureteral obstruction (UUO) in mice was paralleled by a robust up-regulation of K Ca 3.1 in affected kidneys. Mice lacking K Ca 3.1 (K Ca 3.1 −/− ) showed a significant reduction in fibrotic marker expression, chronic tubulointerstitial damage, collagen deposition and αSMA + cells in kidneys after UUO, whereas functional renal parenchyma was better preserved. Pharmacological treatment with the selective K Ca 3.1 blocker TRAM-34 similarly attenuated progression of UUO-induced renal fibrosis in wild-type mice and rats. In conclusion, our data demonstrate that K Ca 3.1 is involved in renal fibroblast proliferation and fibrogenesis and suggest that K Ca 3.1 may represent a therapeutic target for the treatment of fibrotic kidney disease.

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Nitric oxide and metastatic cell behaviour

Williams

Djamgoz

2005

BioEssays

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Nitric oxide (NO) is a pleiotropic signalling molecule that subserves a wide variety of basic cellular functions and also manifests itself pathophysiologically. As regards cancer and its progression, however, the reported role of NO appears surprisingly inconsistent. In this review, we focus on metastasis, the process of cancer cell spread and secondary tumour formation. In a 'reductionist' approach, we consider the metastatic cascade to be made up of a series of basic cellular behaviours (such as proliferation, apoptosis, adhesion, secretion migration, invasion and angiogenesis). We evaluate how NO controls such behaviours, in comparison with normal cells. The available information suggests strongly that NO signalling would be expected to regulate these behaviours both positively and negatively and this probably leads to the observed apparent variability in the NO status of cancer cells and tissues. Thus, the role of NO in cancer is more complex than previously thought. A number of suggestions are made, including consideration of novel mechanisms, such as ion channels, in order to achieve a more consistent and integrated understanding of NO signalling in cancer and to realise its clinical potential.

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Selective Blockade of the Intermediate-Conductance Ca ²⁺ -Activated K ⁺ Channel Suppresses Proliferation of Microvascular and Macrovascular Endothelial Cells and Angiogenesis In Vivo

Cited by 136 publications

References 33 publications

SK4 channels modulate Ca²⁺ signalling and cell cycle progression in murine breast cancer

SK4 channels modulate Ca²⁺ signalling and cell cycle progression in murine breast cancer

Renal fibrosis is attenuated by targeted disruption of K _Ca 3.1 potassium channels

Nitric oxide and metastatic cell behaviour

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Selective Blockade of the Intermediate-Conductance Ca 2+ -Activated K + Channel Suppresses Proliferation of Microvascular and Macrovascular Endothelial Cells and Angiogenesis In Vivo

Cited by 136 publications

References 33 publications

SK4 channels modulate Ca2+ signalling and cell cycle progression in murine breast cancer

SK4 channels modulate Ca2+ signalling and cell cycle progression in murine breast cancer

Renal fibrosis is attenuated by targeted disruption of K Ca 3.1 potassium channels

Nitric oxide and metastatic cell behaviour

Contact Info

Product

Resources

About

Selective Blockade of the Intermediate-Conductance Ca ²⁺ -Activated K ⁺ Channel Suppresses Proliferation of Microvascular and Macrovascular Endothelial Cells and Angiogenesis In Vivo

SK4 channels modulate Ca²⁺ signalling and cell cycle progression in murine breast cancer

SK4 channels modulate Ca²⁺ signalling and cell cycle progression in murine breast cancer

Renal fibrosis is attenuated by targeted disruption of K _Ca 3.1 potassium channels