The context-dependent role of the Na+/Ca2+-exchanger (NCX) in pancreatic stellate cell migration

A CNA-35-based high-throughput fibrosis assay reveals ORAI1 as a regulator of collagen release from pancreatic stellate cells

RATIONALE

Pancreatic stellate cells (PSCs) produce a collagen-rich connective tissue in chronic pancreatitis and pancreatic ductal adenocarcinoma (PDAC). Ca2+-permeable ion channels such as ORAI1 are known to affect PSC proliferation and myofibroblastic phenotype. However, it is unknown whether these channels play a role in collagen secretion.

METHODS

Using the PSC cell line PS-1, we characterized their cell-derived matrices using staining, mass spectroscopy, and cell migration assays. We developed and validated a high-throughput in vitro fibrosis assay to rapidly determine collagen quantity either with Sirius Red or, in the optimized version, with the collagen-binding peptide CNA-35-tdTomato. We assessed collagen deposition upon stimulating cells with transforming growth factor β1 (TGF-β1) and/or vitamin C without or with ORAI1 modulation. Orai1 expression was assessed by immunohistochemistry in the fibrotic tumor tissue of a murine PDAC model (KPfC).

RESULTS

We found that TGF-β1 and vitamin C promote collagen deposition from PSCs. We used small interfering RNA (siRNA) and the inhibitor Synta-66 to demonstrate that ORAI1 regulates collagen secretion of PSCs but not NIH-3T3 fibroblasts. Physiological levels of vitamin C induce a drastic increase of the intracellular [Ca2+] in PSCs, with Synta-66 inhibiting Ca2+ influx. Lastly, we revealed Orai1 expression in cancer-associated fibroblasts (CAFs) in murine PDAC (KPfC) samples.

CONCLUSION

In conclusion, our study introduces a robust in vitro assay for fibrosis and identifies ORAI1 as being engaged in PSC-driven fibrosis.

K2P2.1 channels modulate the pH- and mechanosensitivity of pancreatic stellate cells

Pancreatic stellate cells (PSCs) are central in the development of acute pancreatitis and tumor fibrosis in pancreatic ductal adenocarcinoma (PDAC). Fibrosis and a unique pH landscape represent characteristic properties of the PDAC microenvironment. Mechanosensitive ion channels are involved in the activation of PSCs. Among these channels, K2P2.1 has not yet been studied in PSCs. K2P2.1 channels are pH- and mechanosensitive. We confirmed K2P2.1 expression in PSCs by RT-qPCR and immunofluorescence. PSCs from K2P2.1+/+ and K2P2.1-/- mice were studied under conditions mimicking properties of the PDAC microenvironment (acidic extracellular pH (pHe), ambient pressure elevated by + 100 mmHg). Migration and the cell area were taken as surrogates for PSC activation and evaluated with live cell imaging. pHe-dependent changes of the membrane potential of PSCs were investigated with DiBAC4(3), a voltage-sensitive fluorescent dye. We observed a correlation between morphological activation and progressive hyperpolarization of the cells in response to changes in pHe and pressure. The effect was in part dependent on the expression of K2P2.1 channels because the membrane potential of K2P2.1+/+ PSCs was always more hyperpolarized than that of K2P2.1-/- PSCs. Cell migration velocity of K2P2.1+/+ cells decreased upon pressure application when cells were kept in an acidic medium (pHe 6.6). This was not the case in K2P2.1-/- PSCs. Taken together, our study highlights the critical role of K2P2.1 channels in the combined sensing of environmental pressure and pHe by PSCs and in coordinating cellular morphology with membrane potential dynamics. Thus, K2P2.1 channels are important mechano-sensors in murine PSCs.

Membrane potential dynamics of C5a-stimulated neutrophil granulocytes

Neutrophil granulocytes play a crucial role in host defense against invading pathogens and in inflammatory diseases. The aim of this study was to elucidate membrane potential dynamics during the initial phase of neutrophil activation and its relation to migration and production of reactive oxygen species (ROS). We performed ROS production measurements of neutrophils from healthy C57BL/6J mice after TNFα-priming and/or C5a stimulation. The actin cytoskeleton was visualized with fluorescence microscopy. Furthermore, we combined migration assays and measurements of membrane potential dynamics after stimulating unprimed and/or TNFα-primed neutrophils with C5a. We show that C5a has a concentration-dependent effect on ROS production and chemokinetic migration. Chemokinetic migration and chemotaxis are impaired at C5a concentrations that induce ROS production. The actin cytoskeleton of unstimulated and of ROS-producing neutrophils is not distributed in a polarized way. Inhibition of the phagocytic NADPH oxidase NOX2 with diphenyleneiodonium (DPI) leads to a polarized distribution of the actin cytoskeleton and rescues chemokinetic migration of primed and C5a-stimulated neutrophils. Moreover, C5a evokes a pronounced depolarization of the cell membrane potential by 86.6 ± 4.2 mV starting from a resting membrane potential of -74.3 ± 0.7 mV. The C5a-induced depolarization occurs almost instantaneously (within less than one minute) in contrast to the more gradually developing depolarization induced by PMA (lag time of 3-4 min). This initial depolarization is accompanied by a decrease of the migration velocity. Collectively, our results show that stimulation with C5a evokes parallel changes in membrane potential dynamics, neutrophil ROS production and motility. Notably, the amplitude of membrane potential dynamics is comparable to that of excitable cells.

pH-regulated single cell migration

Over the last two decades, extra- and intracellular pH have emerged as fundamental regulators of cell motility. Fundamental physiological and pathological processes relying on appropriate cell migration, such as embryonic development, wound healing, and a proper immune defense on the one hand, and autoimmune diseases, metastatic cancer, and the progression of certain parasitic diseases on the other, depend on surrounding pH. In addition, migrating single cells create their own localized pH nanodomains at their surface and in the cytosol. By this means, the migrating cells locally modulate their adhesion to, and the re-arrangement and digestion of, the extracellular matrix. At the same time, the cytosolic nanodomains tune cytoskeletal dynamics along the direction of movement resulting in concerted lamellipodia protrusion and rear end retraction. Extracellular pH gradients as found in wounds, inflamed tissues, or the periphery of tumors stimulate directed cell migration, and long-term exposure to acidic conditions can engender a more migratory and invasive phenotype persisting for hours up to several generations of cells after they have left the acidic milieu. In the present review, the different variants of pH-dependent single cell migration are described. The underlying pH-dependent molecular mechanisms such as conformational changes of adhesion molecules, matrix protease activity, actin (de-)polymerization, and signaling events are explained, and molecular pH sensors stimulated by H+ signaling are presented.

Activation and Regulation of Pancreatic Stellate Cells in Chronic Pancreatic Fibrosis: A Potential Therapeutic Approach for Chronic Pancreatitis

In the complex progression of fibrosis in chronic pancreatitis, pancreatic stellate cells (PSCs) emerge as central figures. These cells, initially in a dormant state characterized by the storage of vitamin A lipid droplets within the chronic pancreatitis microenvironment, undergo a profound transformation into an activated state, typified by the secretion of an abundant extracellular matrix, including α-smooth muscle actin (α-SMA). This review delves into the myriad factors that trigger PSC activation within the context of chronic pancreatitis. These factors encompass alcohol, cigarette smoke, hyperglycemia, mechanical stress, acinar cell injury, and inflammatory cells, with a focus on elucidating their underlying mechanisms. Additionally, we explore the regulatory factors that play significant roles during PSC activation, such as TGF-β, CTGF, IL-10, PDGF, among others. The investigation into these regulatory factors and pathways involved in PSC activation holds promise in identifying potential therapeutic targets for ameliorating fibrosis in chronic pancreatitis. We provide a summary of recent research findings pertaining to the modulation of PSC activation, covering essential genes and innovative regulatory mediators designed to counteract PSC activation. We anticipate that this research will stimulate further insights into PSC activation and the mechanisms of pancreatic fibrosis, ultimately leading to the discovery of groundbreaking therapies targeting cellular and molecular responses within these processes.