Lysosome imaging without perturbing intracellular activity remains challenging, as the current commercial lysosome probes contain weakly basic amino groups that could perturb lysosome pH. Herein, we illustrate NIR-emitting dyes 2 and 3 (λ em ≈ 700 nm) with very large Stokes' shifts (Δλ = 231−246 nm), attributing to the presence of a 2-hydroxyphenyl(benzo[d]oxazol) (HBO) unit that undergoes excited-state intramolecular proton transfer (ESIPT). The structures of 2 and 3 also contain a hemicyanine unit with benzothiazolium and indolium as a terminal group, respectively. Although the fluorescent probe 2 (Φ fl ≈ 0.28−0.35 in CH 2 Cl 2 ) does not contain any basic amino functional group, it exhibits excellent selectivity for staining intracellular lysosomes, showing the potential for long-term in vivo lysosome imaging without "alkalinizing effect." However, probe 3 (Φ fl ≈ 0.27, in CH 2 Cl 2 ) exhibits excellent selectivity toward mitochondria. The observation showed that the terminal group in the hemicyanine unit played an essential role in guiding the intracellular selectivity to different organelles. In addition, the probes also displayed a transparent optical window between 520 and 590 nm, which is useful to achieve multicolor co-staining study, without fluorescence crosstalk that is a common problem on fluorescence microscopes.
Mast cells (MCs) develop from hematopoietic progenitors and differentiate into mature MCs that reside within connective or mucosal tissues. Though the number of MCs in tissues usually remains constant, inflammation and asthma disturb this homeostasis, leading to proliferation of MCs. Understanding the signaling events behind this proliferative response could lead to the development of novel strategies for better management of allergic diseases. MC survival, proliferation, differentiation, and migration are all maintained by a MC growth factor, stem cell factor (SCF) via its receptor, KIT. Here, we explored how protein kinase C (PKC) redundancy influences MC proliferation in bone marrow‐derived MC (BMMC). We found that SCF activates PKCα and PKCβ isoforms, which in turn modulates KIT phosphorylation and internalization. Further, PKCα and PKCβ activate p38 mitogen activated protein kinase (MAPK), and this axis subsequently regulates SCF‐induced MC cell proliferation. To ascertain the individual roles of PKCα and PKCβ, we knocked down either PKCα or PKCβ or both via short hairpin RNA (shRNA) and analyzed KIT phosphorylation, p38 MAPK phosphorylation, and MC viability and proliferation. To our surprise, downregulation of neither PKCα nor PKCβ affected MC viability and proliferation. In contrast, blocking both PKCα and PKCβ significantly attenuated SCF‐induced cell viability and proliferation, suggesting that PKCα and PKCβ compensate for each other downstream of SCF signaling to enhance MC viability and proliferation. Our results not only suggest that PKC classical isoforms are novel therapeutic targets for SCF/MC‐mediated inflammatory and allergic diseases, but they also emphasize the importance of inhibiting both PKCα and β isoforms simultaneously to prevent MC proliferation.
Asthma is characterized by pathological airway remodeling resulting from persistent myofibroblast activation. Although transforming growth factor beta 1 (TGFβ1), mechanical signals, and reactive oxygen species (ROS) are implicated in fibroblast differentiation, their integration is still elusive. We identified that Transient Receptor Potential Vanilloid 4 (TRPV4), a mechanosensitive ion channel mediates lung fibroblast (LF) differentiation and D. farinae-induced airway remodeling via a novel TRPV4-NADPH Oxidase 4 (NOX4) interaction. NOX4-mediated ROS production is essential for TGFβ1-induced LF differentiation via myocardin-related transcription factor-A (MRTF-A) and plasminogen activator inhibitor 1 (PAI-1). Importantly, TRPV4 inhibition prevented TGFβ1-induced NOX4 expression and ROS production. Both TRPV4 and NOX4 are activated by phosphatidylinositol 3-kinase (PI3K) downstream of TGFβ1, and signals from both TRPV4 and Rac are necessary for NOX4 upregulation. Notably, NOX4 expression is higher in fibroblasts derived from asthmatic patients (disease human LF; DHLF) in comparison to non-asthmatics (normal human LF; NHLF). Further, NOX4 expression is up-regulated in the lungs of D.farinae-treated wild type mice (WT) relative to saline-treated WT, which was attenuated in TRPV4 knockout (KO) mice. Our findings suggest that TRPV4 integrates TGFβ1 and ROS signaling through NOX4 and, TRPV4-NOX4 interaction is amenable to target lung remodeling during asthma.
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