Protein Kinase C Activity Research Articles

Validation of Machine Learning-assisted Screening of PKC Ligands: PKC Binding Affinity and Activation.

Protein kinase C (PKC) is a family of serine/threonine kinases, and PKC ligands have the potential to be therapeutic seeds for cancer, Alzheimer's disease, and human immunodeficiency virus infection. However, in addition to desired therapeutic effects, most PKC ligands also exhibit undesirable pro-inflammatory effects. The discovery of new scaffolds for PKC ligands is important for developing less inflammatory PKC ligands, such as bryostatins. We previously reported that machine learning combined with our knowledge of the pharmacophore yielded 15 PKC ligand candidates, but we did not evaluate their PKC binding affinities fully. In this paper, PKC binding affinities of four candidates were examined to assess their potential as PKC ligands and to validate machine learning-assisted screening. Although compound 3' did not bind to PKC C1 domains, 1a, 2', and 4a exhibited moderate PKC binding affinities, suggesting that machine learning-assisted screening is advantageous in identifying new PKC ligand scaffolds.

Activation of protein kinase C decreases equilibrative nucleobase transporter 1-mediated substrate uptake via phosphorylation of threonine 231.

Protein kinase C (PKC) signalling has been shown to be dysregulated in various cancers including acute lymphoblastic leukemia (ALL). We have previously determined that changes in the expression levels of SLC43A3-encoded equilibrative nucleobase transporter 1 (ENBT1) can significantly alter 6-mercaptopurine (6-MP) toxicity in ALL cells. 6-MP is a common drug used in ALL chemotherapy. Furthermore, it has been reported that activation of PKC by phorbol 12-myristate 13-acetate (PMA) impacts nucleobase uptake via an ENBT1-like transporter in Lilly Laboratories Culture-Porcine Kidney 1 (LLC-PK1) cells. We hypothesized that activation of PKC would also alter ENBT1-mediated uptake of nucleobases in leukemia cell models. Using MOLT-4, SUP-B15, and K562 cells, we incubated the cells with PMA or its inactive isoform 4α-PMA for 30min and determined changes to ENBT1-mediated substrate uptake. All of the cell lines tested showed decreased ENBT1-mediated substrate uptake when exposed PMA, relative to that observed using 4α-PMA. Pre-incubation with the broad-spectrum PKC inhibitor, Gö6983, reversed the decrease caused by PMA. Finally, to determine the residue responsible for this PKC-mediated effect, we transiently transfected HEK293 cells (which do not express endogenous ENBT1) with wild-type SLC43A3 transcript or constructs mutated to modify the predicted PKC sites in ENBT1. We found that the mutation of threonine 231 to alanine prevents the decrease in ENBT1-mediated uptake following incubation with PMA, suggesting its involvement. This study shows that activation of PKC decreases ENBT1-mediated uptake, suggesting that aberrant activation of PKC in ALL could decrease ENBT1-mediated 6-MP uptake potentially leading to decreased therapeutic efficacy.

A2B adenosine receptor-triggered intracellular calcium mobilization: Cell type-dependent involvement of Gi, Gq, Gs proteins and protein kinase C.

Activation of PLCβ enzymes by G iβγ and G αq/11 proteins is a common mechanism to trigger cytosolic Ca 2+ increase. We and others reported that G αq/11 inhibitor FR900358 (FR) can inhibit both and G αq - and, surprisingly, G iβγ -mediated intracellular Ca 2+ mobilization. Thus, the G αi -G βγ -PLCβ-Ca 2+ signaling axis depends entirely on the presence of active G αq , which reasonably explained FR-inhibited G iβγ -induced Ca 2+ release. However, the conclusion that G iβγ signaling is controlled by G αq derives mostly from HEK293 cells. Here we show that indeed in HEK293 cells both G αq/11 siRNA and G αq/11 inhibitors diminished Ca 2+ increase triggered by native G q -coupled P2Y 1 receptors, or by transfected G i -coupled A 1 - or G s -coupled A 2B adenosine receptors (ARs). However, in T24 bladder cancer cells, G i inhibitor PTX, but not G αq/11 inhibitors, FR, YM254890 (YM) or G q/11 siRNA, inhibited Ca 2+ increase triggered by native A 2B AR activation. Simultaneous inactivation of G i and G s further suppressed A 2B AR-triggered Ca 2+ increase in T24 cells. The G αq/11 inhibitor YM fully and partially inhibited endogenous P2Y 1 - and β 2 -adrenergic receptor-induced Ca 2+ increase in T24 cells, respectively. PKC activator PMA partially diminished A 2B AR-triggered but completely diminished β 2 -adrenergic receptor-triggered Ca 2+ increase in T24 cells. Neither β-arrestin1 nor β-arrestin2 siRNA affected A 2B AR-mediated Ca 2+ increase. Unlike in T24 cells, YM inhibited native A 2B AR-triggered calcium mobilization in MDA-MB-231 breast cancer cells. Thus, G αq/11 is vital for Ca 2+ increase in some cell types, but G iβγ -mediated Ca 2+ signaling can be Gα q/11 -dependent or independent based on cell type and receptor activated. Besides G proteins, PKC also modulates cytosolic Ca 2+ increase depending on cell type and receptor.

Roles for PKC signaling in chromaffin cell exocytosis

Chromaffin cells of the adrenal medulla have an important role in the sympathetic stress response. They secrete catecholamines and other hormones into the bloodstream upon stimulation by the neurotransmitter pituitary adenylate cyclase-activating polypeptide (PACAP). PACAP causes a long-lasting and robust secretory response from chromaffin cells. However, the cellular mechanisms by which PACAP causes secretion remain unclear. Our previous work showed that the secretory response to PACAP relies on signaling through phospholipase C ε (PLCε). The objective of this study was to clarify the role of signaling events downstream of PLCε. Here, it is demonstrated that a brief exposure of chromaffin cells to PACAP caused diacylglycerol (DAG) production – a process that was dependent on PLCε activity. DAG then activated protein kinase C (PKC), prompting its redistribution to the plasma membrane. PKC activation is important for the increases in cytosolic Ca2+ and exocytosis that are evoked by PACAP. Indeed, pharmacological inhibition of PKC with NPC 15437, a competitive inhibitor of DAG binding, significantly disrupted the secretory response. NPC 15437 application also eliminated PACAP-stimulated effects on the readily releasable pool size, the Ca2+ sensitivity of granule fusion, and the voltage-dependence of Ca2+ channel activation. Quantitative PCR revealed PKCβ, PKCε, and PKCμ to be highly expressed in the mouse chromaffin cell. Genetic knockdown of PKCβ and PKCε disrupted PACAP-evoked secretion, while knockdown of PKCμ had no measurable effect. This study highlights important roles for PKC signaling in a highly regulated pathway for exocytosis that is stimulated by PACAP.

Pyr3 inhibits cell viability and PKCα activity to suppress migration in human bladder cancer cells.

Bladder cancer, more prevalent in men, has high recurrence rates in non-muscle-invasive forms and is highly lethal upon metastasis in muscle-invasive cases. Transient receptor potential canonical channels (TRPCs), specifically TRPC3, play a role in calcium signaling, influencing cancer cell behavior. This study examines the effects of Pyr3, a TRPC3 inhibitor, and TRPC3 knockdown on both muscle-invasive (T24) and non-muscle-invasive (RT4) bladder cancer cells. Pyr3 treatment reduced cell viability, migration, adhesion, and calcium influx in these cells. Additionally, Pyr3 treatment and siTRPC3 downregulated protein kinase C alpha (PKCα), phospho-PKCα, and protein phosphatase 2A (PP2A) levels. While PKC activator phorbol 12-myristate 13-acetate (PMA) could not restore Pyr3-induced viability loss, it reversed the migration inhibition. In a xenograft model, Pyr3 suppressed T24 cell viability, Ki67, phospho-PKCα, PP2A and TRPC3 expression. These findings suggest that Pyr3 inhibits bladder cancer cell migration through PKC signaling and holds potential as a therapeutic agent for bladder cancer.

The Role of Protein Kinase C During the Differentiation of Stem and Precursor Cells into Tissue Cells.

Protein kinase C (PKC) plays an essential role during many biological processes including development from early embryonic stages until the terminal differentiation of specialized cells. This review summarizes the current knowledge about the involvement of PKC in molecular processes during the differentiation of stem/precursor cells into tissue cells with a particular focus on osteogenic, adipogenic, chondrogenic and neuronal differentiation by using a comprehensive approach. Interestingly, studies examining the overall role of PKC, or one of its three isoform groups (classical, novel and atypical PKCs), often showed controversial results. A discrete observation of distinct isoforms demonstrated that the impact on differentiation differs highly between the isoforms, and that during a certain process, the influence of only some isoforms is crucial, while others are less important. In particular, PKCβ inhibits, and PKCδ strongly supports osteogenesis, whereas it is the other way around for adipogenesis. PKCε is another isoform that overwhelmingly supports adipogenic differentiation. In addition, PKCα plays an important role in chondrogenesis, while neuronal differentiation has been positively associated with numerous isoforms including classical, novel and atypical PKCs. In a cellular context, various upstream mediators, like the canonical and non-canonical Wnt pathways, endogenously control PKC activity and thus, their activity interferes with the influence of PKC on differentiation. Downstream of PKC, several proteins and pathways build the molecular bridge between the enzyme and the control of differentiation, of which only a few have been well characterized so far. In this context, PKC also cooperates with other kinases like Akt or protein kinase A (PKA). Furthermore, PKC is capable of directly phosphorylating transcription factors with pivotal function for a certain developmental process. Ultimately, profound knowledge about the role of distinct PKC isoforms and the involved signaling pathways during differentiation constitutes a promising tool to improve the use of stem cells in regenerative therapies by precisely manipulating the activity of PKC or downstream effectors.

Modified lipoprotein-induced sFlt1 production in human placental trophoblasts is mediated by protein kinase C

BackgroundPreeclampsia is prevalent in women with diabetes, but the mechanism is unclear. We previously found that oxidized, glycated lipoproteins robustly upregulated soluble fms-like tyrosine kinase-1 (sFlt1), a key mediator of preeclampsia. Here, we determined the role of protein kinase C (PKC) and its subtypes in sFlt1 regulation in placental trophoblasts, and whether this mechanism might mediate the effect of modified lipoproteins. MethodsCultured human HTR8/SVneo and BeWo trophoblasts were treated with the PKC activator phorbol-12-myristate-13-acetate (PMA) for 24h, ± PKC inhibitors GF109203X (general), Ro31-8220 (PKCα-selective), LY333531 (PKCβ-selective) and rottlerin (PKCδ-selective). The effect of ‘heavily oxidized, glycated’ low-density lipoproteins (HOG-LDL) vs. native LDL (N-LDL), ± high glucose (30 mM), was evaluated in HTR8/SVneo cells. sFlt1 secretion (ELISA), mRNA expression (RT-qPCR), and cellular PKC activity were measured. ResultsPMA stimulated robust sFlt1 release and mRNA expression in both cell lines; these effects were inhibited by GF109203X, Ro31-8220 and LY333531 in a concentration-dependent manner. Rottlerin inhibited sFlt1 in BeWo, but modestly enhanced it in HTR8/SVneo cells. HOG-LDL enhanced PKC activity vs. N-LDL in HTR8/SVneo cells. Also, HOG-LDL, but not high glucose, significantly increased sFlt1 secretion and mRNA expression; this response was inhibited by GF109203X, Ro31-8220 and LY333531 at concentrations comparable to those that blocked PMA induction of sFlt1. ConclusionModified lipoproteins upregulate sFlt1 in trophoblasts via a PKC-mediated mechanism, involving at least α and β isoforms. The data suggest potential therapeutic targets to reduce the risk of preeclampsia in women with diabetes.

TMET-30. ONCOLYTIC HSV REWIRES METABOLISM TO PROMOTE ANTITUMOR IMMUNITY THROUGH REDUCTIVE CARBOXYLATION AND FERROPTOSIS

Abstract Cancer cells autonomously rewire metabolism to meet increased bioenergetic demands. Oncolytic HSVs (oHSVs) are attenuated Herpes simplex type 1 derived viruses that lyse tumor cells releasing damage-associated molecules triggering antitumor immunity. Currently one oHSV-1 derived virus is approved for melanoma treatment in the USA and another for recurrent GBM in Japan. While several other viruses are being evaluated in clinical trials for safety and efficacy, an understanding of the impact of oHSV therapy on cancer cell metabolism is largely unexplored. A detailed understanding of how oHSV impact tumor cell metabolism and oxidative stress is important to understand the unique susceptibilities that can further be exploited to improve the therapeutic index. Here, we analyzed transcriptomic changes in tumor biopsies of recurrent high-grade glioma patients treated with oHSV. RNA-seq data obtained from pre- and post-G207 treated biopsies from phase-Ib study patients (NCT00028158) revealed enrichment in pathways related to citric acid cycle, oxidative phosphorylation, and glutamate metabolism. We confirmed these changes by RNA sequencing of oHSV-infected patient derived GBM cells. Mechanistically, oHSV hijacked cellular glucose metabolism to increase oxidative phosphorylation and modulated cellular glutamine metabolism towards reductive carboxylation and reduced free glutathione, collectively contributing to increased ROS generation. Kinome profiling revealed PKC activation upon treatment with oHSV. Increased ROS combined with reduced glutathione, and PKC activation promoted ferroptotic cell death characterized by increased lipid peroxidation and smaller, ruptured mitochondria, and contributed to immunotherapy by this treatment. IDH mutant tumors that block reductive carboxylation were resistant to oHSV-induced ferroptotic cell death and did not benefit from oHSV-induced antitumor benefit. Together, this study presents avenues to enhance antitumor immunity by oHSV therapy.

The role of protein kinase C and the glycoprotein Ibα cytoplasmic tail in anti-glycoprotein Ibα antibody-induced platelet apoptosis and thrombocytopenia

IntroductionImmune thrombocytopenia (ITP) is an autoimmune disease characterized by low platelet counts. ITP patients with anti-platelet glycoprotein (GP) Ibα (a subunit of GPIb-IX-V complex) autoantibodies, which induce Fc-independent signaling and platelet clearance, are refractory to conventional treatment. Protein kinase C (PKC) is activated by the binding of the ligand von Willebrand factor (VWF) to GPIbα and regulates VWF-GPIbα-induced platelet activation. However, the role of PKC in anti-GPIbα antibody-induced thrombocytopenia remains unknown. Materials and methodsThe anti-GPIbα antibody-induced PKC activation and its underlying mechanisms were first detected by Western blot, and then the effects of PKC inhibitors, PKC knockout, or GPIbα C-terminal removal on anti-GPIbα antibody-induced platelet apoptosis, activation, aggregation, and clearance were investigated by flow cytometry, platelet aggregometry, and platelet posttransfusion, respectively. Meanwhile, platelet retention and co-localization with macrophages in the liver were detected by spinning disc intravital confocal microscopy. ResultsAnti-GPIbα antibody-induced PKC activation depends on GPIbα clustering and phosphoinositide 3-kinase (PI3K) activation and results in Akt phosphorylation. Pharmacologic inhibition or genetic ablation of PKC suppresses anti-GPIbα antibody-induced platelet apoptosis and activation. Moreover, the GPIbα cytoplasmic tail is required for antibody-induced PKC activation, platelet apoptosis, and activation. Inhibition or ablation of PKC and deletion of the GPIbα cytoplasmic tail protect platelets from clearance in vivo. ConclusionsOur study indicates the important role of PKC and the GPIbα cytoplasmic tail in anti-GPIbα antibody-mediated platelet signaling and clearance and suggests a novel therapeutic target for ITP and other thrombocytopenic diseases.

Phosphorylation of Piezo1 at a single residue, serine-1612, regulates its mechanosensitivity and invivo mechanotransduction function.

Piezo1 is a mechanically activated cation channel that converts mechanical force into diverse physiological processes. Owing to its large protein size of more than 2,500 amino acids and complex 38-transmembrane helix topology, how Piezo1 is post-translationally modified for regulating its invivo mechanotransduction functions remains largely unexplored. Here, we show that PKA activation potentiates the mechanosensitivity and slows the inactivation kinetics of mouse Piezo1 and identify the major phosphorylation site, serine-1612 (S1612), that also responds to PKC activation and shear stress. Mutating S1612 abolishes PKA and PKC regulation of Piezo1 activities. Primary endothelial cells derived from the Piezo1-S1612A knockin mice lost PKA- and PKC-dependent phosphorylation and functional potentiation of Piezo1. The mutant mice show activity-dependent elevation of blood pressure and compromised exercise endurance, resembling endothelial-specific Piezo1 knockout mice. Taken together, we identify the major PKA and PKC phosphorylation site in Piezo1 and demonstrate its contribution to Piezo1-mediated physiological functions.

Chelerythrine inhibits NR2B NMDA receptor independent of PKC activity

N-methyl-d-aspartate receptors (NMDARs), the ligand ion glutamate receptor channels, mediate major excitatory neurotransmission in central nervous system (CNS). They highly express in CNS and involve in multiple physiological processes. Many studies implicated that NMDAR plays a crucial role in number of neurological disorders, including ischemia, dementia, and pain, indicating its potential as a therapeutic target for treatments. Chelerythrine (CHE) is a benzo-phenanthridine alkaloid extracted from Chelidonium majus with many biological activities including anti-inflammatory, anticancer effect, and antidiabetic effect. But the mechanism of CHE is not well understood. The aim of this study was to investigate the effect of CHE on the NMDAR. The results demonstrated that CHE effectively suppressed NMDA-induced currents in primary cultured cortical neurons. To elucidate the underlying mechanism, we expressed NMDARs in HEK293T cells and found that CHE and some of its structural analogues inhibited NMDAR currents and facilitated the desensitization of GluN2B NMDARs. Notably, these effects were independent of protein kinase C activity, suggesting that the effect of CHE on GluN2B-containing NMDAR may occur through a mechanism of directly interaction with NMDAR. Moreover, the inhibitory effect of CHE on GluN2B NMDARs is pH-dependent. Molecular docking prediction in conjunction with mutagenesis analysis revealed that the M3 α-helical segment of the NMDAR in close proximity to the GluN2B Thr647 amino acid plays an important role in CHE inhibition of GluN2B. This study revealed a novel function of CHE and its structural analogues in inhibiting the NMDARs and promoting GluN2B-mediated desensitization by obstructing the receptor at the channel pore region.

Mycobacterium avium inhibits protein kinase C and MARCKS phosphorylation in human cystic fibrosis and non-cystic fibrosis cells.

In cystic fibrosis (CF), there is abnormal translocation and function of the cystic fibrosis transmembrane conductance regulator (CFTR) and an upregulation of the epithelial sodium channel (ENaC). This leads to hyperabsorption of sodium and fluid from the airway, dehydrated mucus, and an increased risk of respiratory infections. In this study, we performed a proteomic assessment of differentially regulated proteins from CF and non-CF small airway epithelial cells (SAEC) that are sensitive to Mycobacterium avium. CF SAEC and normal non-CF SAEC were infected with M. avium before the cells were harvested for protein. Protein kinase C (PKC) activity was greater in the CF cells compared to the non-CF cells, but the activity was significantly attenuated in both cell types after infection with M. avium compared to vehicle. Western blot and densitometric analysis showed a significant increase in cathepsin B protein expression in M. avium infected CF cells. Myristoylated alanine rich C-kinase substrate (MARCKS) protein was one of several differentially expressed proteins between the groups that was identified by mass spectrometry-based proteomics. Total MARCKS protein expression was greater in CF cells compared to non-CF cells. Phosphorylation of MARCKS at serine 163 was also greater in CF cells compared to non-CF cells after treating both groups of cells with M. avium. Taken together, MARCKS protein is upregulated in CF cells and there is decreased phosphorylation of the protein due to a decrease in PKC activity and presumably increased cathepsin B mediated proteolysis of the protein after M. avium infection.

Sensitive fluorescent biosensor reveals differential subcellular regulation of PKC.

The protein kinase C (PKC) family of serine and threonine kinases, consisting of three distinctly regulated subfamilies, has been established as critical for various cellular functions. However, how PKC enzymes are regulated at different subcellular locations, particularly at emerging signaling hubs, is unclear. Here we present a sensitive excitation ratiometric C kinase activity reporter (ExRai-CKAR2) that enables the detection of minute changes (equivalent to 0.2% of maximum stimulation) in subcellular PKC activity. Using ExRai-CKAR2 with an enhanced diacylglycerol (DAG) biosensor, we uncover that G-protein-coupled receptor stimulation triggers sustained PKC activity at the endoplasmic reticulum and lysosomes, differentially mediated by Ca2+-sensitive conventional PKC and DAG-sensitive novel PKC, respectively. The high sensitivity of ExRai-CKAR2, targeted to either the cytosol or partitioning defective complexes, further enabled us to detect previously inaccessible endogenous atypical PKC activity in three-dimensional organoids. Taken together, ExRai-CKAR2 is a powerful tool for interrogating PKC regulation in response to physiological stimuli.

Protein kinase C (PKC) inhibitor Calphostin C activates PKC in a light-dependent manner at high concentrations via the production of singlet oxygen

Calphostin C (Cal-C) is a protein kinase C (PKC) inhibitor that binds to its C1 domain. The aim of the present study was to elucidate the action of Cal-C in addition to PKC inhibition. First, we confirmed that Cal-C at low concentrations (<200 nM) inhibit phorbol ester-induced PKC translocation and G-protein-coupled receptor (GPCR)-mediated PKC activation. Cal-C at higher concentrations (>2 μM) increased intracellular calcium ion concentrations ([Ca2+]i) in a concentration-dependent manner. The origin of this increase is the mobilization of the endoplasmic reticulum (ER), which does not involve GPCR or ryanodine receptors. Cal-C at high concentrations also cause structural changes in the ER, such as the formation of vacuoles and aggregates, and calcium leakage from the ER. At 2 μM, Cal-C translocated a calcium-sensitive PKCα. Studies using a C-kinase activity reporter and a myristoylated alanine-rich protein kinase C substrate fused with green fluorescent protein (GFP) have also revealed that Cal-C at high concentrations activate PKC in living cells. Additionally, the PKC-activating effects of Cal-C were light-dependent. Finally, studies using Si-DMA, an indicator of singlet oxygen, showed that Cal-C at high concentrations generated singlet oxygen, causing structural changes in the ER and leakage of calcium into the cytosol, which triggered PKC activation. This study confirms the novel action of Cal-C, solely considered a PKC inhibitor. Cal-C acted as a PKC inhibitor at low concentrations and a PKC activator at high concentrations by generating singlet oxygen in a light-dependent manner, suggesting that Cal-C can be used in photodynamic therapy.

Phenylephrine Enhances the Mitogenic Effect of S-Allyl-L-cysteine on Primary Cultured Hepatocytes through Protein Kinase C-Induced B-Raf Phosphorylation.

The co-mitogenic effects of the α1-adrenoceptor agonist phenylephrine on S-allyl-L-cysteine (SAC)-induced hepatocyte proliferation were examined in primary cultures of adult rat hepatocytes. The combination of phenylephrine (10-10-10-6 M) and SAC (10-6 M) exhibited a significant dose-dependent increase in the number of hepatocyte nuclei and viable cells compared to SAC alone. This combination also increased the progression of hepatocyte nuclei into the S-phase. The potentiating effect of phenylephrine on SAC-induced cell proliferation was counteracted by prazosin (an α1-adrenergic receptor antagonist) and GF109203X (selective protein kinase C (PKC) inhibitor). In addition, PMA (direct PKC activator) potentiated the proliferative effects of SAC similarly to phenylephrine. In essence, these findings suggest that PKC activity plays a crucial role in enhancing SAC-induced cell proliferation. Moreover, the effects of phenylephrine on SAC-induced Ras activity, Raf phosphorylation, and extracellular signal-regulated kinase 2 (ERK2) phosphorylation were investigated. Phenylephrine (or PMA) in combination with SAC did not augment Ras activity, but further increased ERK2 phosphorylation and its upstream B-Raf phosphorylation. These results indicate that PKC activation, triggered by stimulating adrenergic α1 receptors, further amplifies SAC-induced cell proliferation through enhanced ERK2 phosphorylation via increased B-Raf-specific phosphorylation in primary cultured hepatocytes.

An Ingenane-Type Diterpene from Euphorbia kansui Promoted Cell Apoptosis and Macrophage Polarization via the Regulation of PKC Signaling Pathways.

Euphorbia kansui, a toxic Chinese medicine used for more than 2000 years, has the effect of "purging water to promote drinking" and "reducing swelling and dispersing modules". Diterpenes and triterpenes are the main bioactive components of E. kansui. Among them, ingenane-type diterpenes have multiple biological activities as a protein kinase C δ (PKC-δ) activator, which have previously been shown to promote anti-proliferative and pro-apoptotic effects in several human cancer cell lines. However, the activation of PKC subsequently promoted the survival of macrophages. Recently, we found that 13-hydroxyingenol-3-(2,3-dimethylbutanoate)-13-dodecanoate (compound A) from E. kansui showed dual bioactivity, including the inhibition of tumor-cell-line proliferation and regulation of macrophage polarization. This study identifies the possible mechanism of compound A in regulating the polarization state of macrophages, by regulating PKC-δ-extracellular signal regulated kinases (ERK) signaling pathways to exert anti-tumor immunity effects in vitro, which might provide a new treatment method from the perspective of immune cell regulation.

NADPH oxidase 1/4 dual inhibitor setanaxib suppresses platelet activation and thrombus formation

AimsThe production of reactive oxygen species (ROS) by NADPH oxidase (NOX) is able to induce platelet activation, making NOX a promising target for antiplatelet therapy. In this study, we examined the effects of setanaxib, a dual NOX1/4 inhibitor, on human platelet function and ROS-related signaling pathways. Materials and methodsIn collagen-stimulated human platelets, aggregometry, assessment of ROS and Ca2+, immunoblotting, ELISA, flow cytometry, platelet adhesion assay, and assessment of mouse arterial thrombosis were performed in this study. Key findingsSetanaxib inhibited both intracellular and extracellular ROS production in collagen-activated platelets. Additionally, setanaxib significantly inhibited collagen-induced platelet aggregation, P-selectin exposure from α-granule release, and ATP release from dense granules. Setanaxib blocked the specific tyrosine phosphorylation-mediated activation of Syk, LAT, Vav1, and Btk within collagen receptor signaling pathways, leading to reduced activation of PLCγ2, PKC, and Ca2+ mobilization. Setanaxib also inhibited collagen-induced activation of integrin αIIbβ3, which is linked to increased cGMP levels and VASP phosphorylation. Furthermore, setanaxib suppressed collagen-induced p38 MAPK activation, resulting in decreased phosphorylation of cytosolic PLA2 and reduced TXA2 generation. Setanaxib also inhibited ERK5 activation, affecting the exposure of procoagulant phosphatidylserine. Setanaxib reduced thrombus formation under shear conditions by preventing platelet adhesion to collagen. Finally, in vivo administration of setanaxib in animal models led to the inhibition of arterial thrombosis. SignificanceThis study is the first to show that setanaxib suppresses ROS generation, platelet activation, and collagen-induced thrombus formation, suggesting its potential use in treating thrombotic or cardiovascular diseases.

Filamin A regulates platelet shape change and contractile force generation via phosphorylation of the myosin light chain.

Platelets are critical mediators of hemostasis and thrombosis. Platelets circulate as discs in their resting form but change shape rapidly upon activation by vascular damage and/or soluble agonists such as thrombin. Platelet shape change is driven by a dynamic remodeling of the actin cytoskeleton. Actin filaments interact with the protein myosin, which is phosphorylated on the myosin light chain (MLC) upon platelet activation. Actin-myosin interactions trigger contraction of the actin cytoskeleton, which drives platelet spreading and contractile force generation. Filamin A (FLNA) is an actin cross-linking protein that stabilizes the attachment between subcortical actin filaments and the cell membrane. In addition, FLNA binds multiple proteins and serves as a critical intracellular signaling scaffold. Here, we used platelets from mice with a megakaryocyte/platelet-specific deletion of FLNA to investigate the role of FLNA in regulating platelet shape change. Relative to controls, FLNA-null platelets exhibited defects in stress fiber formation, contractile force generation, and MLC phosphorylation in response to thrombin stimulation. Blockade of Rho kinase (ROCK) and protein kinase C (PKC) with the inhibitors Y27632 and bisindolylmaleimide (BIM), respectively, also attenuated MLC phosphorylation; our data further indicate that ROCK and PKC promote MLC phosphorylation through independent pathways. Notably, the activity of both ROCK and PKC was diminished in the FLNA-deficient platelets. We conclude that FLNA regulates thrombin-induced MLC phosphorylation and platelet contraction, in a ROCK- and PKC-dependent manner.

A high-performance genetically encoded sensor for cellular imaging of PKC activity in vivo.

We report a genetically encoded fluorescence lifetime sensor for protein kinase C (PKC) activity, named CKAR3, based on Förster resonance energy transfer. CKAR3 exhibits a 10-fold increased dynamic range compared to its parental sensors and enables in vivo imaging of PKC activity during animal behavior. Our results reveal robust PKC activity in a sparse neuronal subset in the motor cortex during locomotion, in part mediated by muscarinic acetylcholine receptors.

Teleocidin B-4, a PKC Activator, Upregulates Hypoxia-Inducible Factor 1 (HIF-1) Activity by Promoting the Accumulation of HIF-1α Protein via the PKCα/mTORC Signaling Pathway.

Hypoxia-inducible factor 1 (HIF-1) signaling is upregulated in an oxygen-dependent manner under hypoxic conditions. Activation of HIF-1 signaling increases the expression of HIF-1 target genes involved in cell survival, proliferation, and angiogenesis. Therefore, compounds that activate HIF-1 signaling have therapeutic potential in ischemic diseases. Screening for compounds that activate HIF-1 activity identified a microbial metabolite, teleocidin B-4, a PKC activator. Other PKC activators, such as TPA and 10-Me-Aplog-1, also activated HIF-1 activity. PKC activators induced HIF-1α protein accumulation through PKCα/mTORC activation. These results suggest that PKC activators without tumor-promoting activity have potential as therapeutic agents via HIF-1 target gene activation.