Cell Signaling Mechanisms Research Articles

TRPC6 Channel Regulates Airway Remodeling in Chronic Obstructive Pulmonary Disease Causing Right Heart Failure.

The role of the canonical transient receptor potential 6 (TRPC6) channel in chronic obstructive pulmonary disease (COPD) remains poorly understood at the mechanistic level. Objects: This study aims to investigate the involvement of TRPC6 in COPD and its signaling mechanisms in human airway smooth muscle cells (HASMCs). Methods and Results: The study found that mRNA and protein expression of TRPC6 increased in cultured HASMCs that were incubated with nicotine, as measured by reverse transcription quantitative polymerase chain reaction and Western blot analysis. Nicotine treatment significantly enhanced TRPC6 transcriptional activity in HASMCs through nuclear factor (NF)-κB, as demonstrated by co-immunoprecipitation and electrophoretic mobility shift assays. Furthermore, miR-135a/b-5p was shown to downregulate TRPC6 expression in HASMCs at the mRNA and protein levels, as confirmed by luciferase reporter assays. Immunohistochemistry assays in a mouse model of cigarette-induced airway remodeling revealed a significant increase in smooth muscle (SM) cell proliferation and SM layer mass. Conclusion: These findings suggest that nicotine exposure increases HASMC proliferation and migration through NF-κB signaling, and that cigarette smoke inhalation causes airway SM layer remodeling via altered TRPC6-induced Ca2+ influx, which is abolished by miR-135a/b-5p both in vitro and invivo. Antioxid. Redox Signal. 00, 000-000.

CITRULLINATED AND MALONDIALDEHYDE-ACETALDEHYDE MODIFIED FIBRINOGEN ACTIVATES MACROPHAGES AND PROMOTES PROFIBROTIC RESPONSES IN HUMAN LUNG FIBROBLASTS.

The objective of this study was to assess fibrinogen (FIB) co-modified with citrulline (CIT) and/or malondialdehyde-acetaldehyde (MAA) initiates macrophage-fibroblast interactions leading to extracellular matrix (ECM) deposition that characterizes rheumatoid arthritis-associated interstitial lung disease (RA-ILD). Macrophages (Mϕ) were stimulated with native-FIB, FIB-CIT, FIB-MAA or FIB-MAA-CIT. Supernatants (SN) (Mϕ-SN [U-937-derived] or MϕP-SN [PBMC-derived]) or direct antigens were co-incubated with human lung fibroblasts (HLFs). Gene expression was examined using RT-PCR. ECM deposition was quantified using immunohistochemistry and Western blot; cell signaling mechanisms were delineated. PDGF-BB and TGF- were measured in macrophage supernatants and inhibition studies performed using Su16f and SB431542, respectively. HLF gene expression of CD36, COL6A3, MMP-9, MMP-10, MMP-12 was increased following stimulations with Mϕ-SN generated from modified FIB but not from direct antigens. HLF stimulated with MϕP-SNFIB-MAA-CIT derived from RA-ILD patients resulted in 4- to 30-fold increases in COL6A3 and MMP12 expression; up-regulation was greater in HLFs stimulated with MϕP-SN derived from RA-ILD vs. controls. HLF exposure to Mϕ-SNFIB-MAA-CIT increased types I/VI collagen deposition vs. all other Mϕ-SN groups and was greater than FIB-MAA-CIT stimulation. PDGF-BB and TGF- signaling had the highest concentrations identified in Mϕ-SNFIB-MAA-CIT and MϕP-SNFIB-MAA-CIT, particularly from RA-ILD-derived cells. PDGF-BB and TGF- inhibitors, alone and in combination, significantly reduced HLF-mediated ECM deposition from Mϕ-SN stimulations. These results show that co-modified fibrinogen activates macrophages to produce PDGF-BB and TGF-β that promotes an aggressive HLF phenotype characterized increased ECM deposition. These results suggest that targeting CIT and/or MAA modifications or downstream cellular signals could represent novel approaches to RA-ILD treatment.

Plasmodium falciparum protein phosphatase PP7 is required for early ring-stage development.

Plasmodium falciparum causes malaria and is responsible for more than 600,000 deaths each year. Although effective drugs are available to treat disease, the spread of drug-resistant parasites endangers their future efficacy. It is hoped that a better understanding of the biology of malaria parasites will help us to discover new drugs to tackle the resistance problem. Our work is focused on the cell signaling mechanisms that control the development of the parasite throughout its complex life cycle. All signal transduction pathways are ultimately regulated by reversible protein phosphorylation by protein kinase and protein phosphatase enzymes. In this study, we investigate the function of calcium-dependent protein phosphatase PP7 and show that it is essential for the development of ring-stage parasites following the invasion of human erythrocytes. Our results contribute to the understanding of the erythrocytic stages of the parasite life cycle that cause malaria pathology.

An integrative proteotranscriptomics approach reveals new ADAM9 substrates and downstream pathways.

Membrane protein shedding is a key regulatory mechanism for cell signaling and adhesion, and dysregulated shedding is associated with diseases. Many membrane proteases can catalyze shedding, but the substrate spectra and downstream targets of these "sheddases" remain largely elusive. While secretomics-based methods have been applied to the systematic identification of sheddase substrates, these methods are not always effective and do not provide much information on downstream targets. Here we developed an integrative proteotranscriptomics approach to uncover the transcriptional and post-transcriptional targets of the disintegrin metalloproteinase ADAM9, a sheddase that has been implicated in solid tumors, autoimmunity, inflammatory diseases and COVID-19. This systematic approach revealed signaling pathways downstream of ADAM9, including the oncogenic mTOR and tumor suppressor FOXO pathways. We further identified several direct and indirect substrates for ADAM9, which may mediate the pathophysiological roles of ADAM9 in various diseases. Of note, some of these substrates are difficult to detect by secretomics. This new approach can be applied to other sheddases to systematically identify their substrates and targets.

Nanocarriers for Controlled Drug Delivery A convergence of Polymer and Nanochemistry

Regarding improving the quality of health care strategies and other fields based on nanoscale technology, nanotechnology has been recognized as the most prevalent and commercially invented technology. In the near future, the pharmaceutical and biotechnology industries are likely to undergo significant changes due to the widespread adoption of nanoscale technology in drug delivery systems, that uses the polymeric nanoparticles that Polymeric nanoparticles have been extensively studied as particulate carriers in the pharmaceutical and medical fields, because they show promise as drug delivery systems as a result of their controlled- and sustained-release properties, subcellular size, and biocompatibility with tissue and cells. Several methods used for preparation of polymeric nanoparticles and after preparation of them they are most important particles that used in encapsulation of drugs such as PLGA, PLA, chitosan are used as encapsulation of anticancer drugs and antihormonal and antimalarial drugs and increase their release rates and also, they are used in field of dentistry and oral systems that are used in some diseases that cause infections, the use of polymeric nanoparticles with antibacterial drugs lead to decrease the infections . To achieve efficient drug delivery, it is important to understand the interactions of nanomaterials with the biological environment, targeting cell-surface receptors, drug release, multiple drug administration, stability of therapeutic agents and molecular mechanisms of cell signaling involved in pathobiology of the disease under consideration.

Warming triggers stomatal opening by enhancement ofphotosynthesis and ensuing guard cell CO2 sensing,whereashigher temperatures induce a photosynthesis-uncoupled response.

Plants integrate environmental stimuli to optimize photosynthesis vs water loss by controlling stomatal apertures. However, stomatal responses to temperature elevation and the underlying molecular genetic mechanisms remain less studied. We developed an approach for clamping leaf-to-air vapor pressure difference (VPDleaf) to fixed values, and recorded robust reversible warming-induced stomatal opening in intact plants. We analyzed stomatal temperature responses of mutants impaired in guard cell signaling pathways for blue light, abscisic acid (ABA), CO2, and the temperature-sensitive proteins, Phytochrome B (phyB) and EARLY-FLOWERING-3 (ELF3). We confirmed that phot1-5/phot2-1 leaves lacking blue-light photoreceptors showed partially reduced warming-induced stomatal opening. Furthermore, ABA-biosynthesis, phyB, and ELF3 were not essential for the stomatal warming response. Strikingly, Arabidopsis (dicot) and Brachypodium distachyon (monocot) mutants lacking guard cell CO2 sensors and signaling mechanisms, including ht1, mpk12/mpk4-gc, and cbc1/cbc2 abolished the stomatal warming response, suggesting a conserved mechanism across diverse plant lineages. Moreover, warming rapidly stimulated photosynthesis, resulting in a reduction in intercellular (CO2). Interestingly, further enhancing heat stress caused stomatal opening uncoupled from photosynthesis. We provide genetic and physiological evidence that the stomatal warming response is triggered by increased CO2 assimilation and stomatal CO2 sensing. Additionally, increasing heat stress functions via a distinct photosynthesis-uncoupled stomatal openingpathway.

Medullins A-H, Sesquiterpenes from Perenniporia medulla-panis, and Their Cellular Signaling Mechanism in HDF Cells.

A chemical investigation of an ethyl acetate-soluble layer in the culture broth of Perenniporia medulla-panis resulted in the isolation of eight novel sesquiterpenes conjugated Gly (1), l-Val (2), l-Ala (3), l-Tyr (4), l-Thr (5), l-Ile (6), l-Leu (7), and l-Phe (8). Elucidation of their structures was performed through comprehensive spectroscopic analysis. The absolute configuration of the sesquiterpene skeleton was ascertained using modified Mosher's methods. The configurations of the amino acid units in compounds 2-8 were identified through acid hydrolysis followed by LC-MS analysis employing Marfey's method. Compounds 1-3 and 5-8 showed significant regulating effect on MAP kinase activity (p-ERK and p-JNK) in human diploid fibroblast (HDF) cells.

The effect of CGRP and SP and the cell signaling dialogue between sensory neurons and endothelial cells

Increasing evidences demonstrate the role of sensory innervation in bone metabolism, remodeling and repair, however neurovascular coupling in bone is rarely studied. Using microfluidic devices as an indirect co-culture model to mimic in vitro the physiological scenario of innervation, our group demonstrated that sensory neurons (SNs) were able to regulate the extracellular matrix remodeling by endothelial cells (ECs), in particular through sensory neuropeptides, i.e. calcitonin gene-related peptide (CGRP) and substance P (SP). Nonetheless, still little is known about the cell signaling pathways and mechanism of action in neurovascular coupling. Here, in order to characterize the communication between SNs and ECs at molecular level, we evaluated the effect of SNs and the neuropeptides CGRP and SP on ECs. We focused on different pathways known to play a role on endothelial functions: calcium signaling, p38 and Erk1/2; the control of signal propagation through Cx43; and endothelial functions through the production of nitric oxide (NO). The effect of SNs was evaluated on ECs Ca2+ influx, the expression of Cx43, endothelial nitric oxide synthase (eNOS) and nitric oxide (NO) production, p38, ERK1/2 as well as their phosphorylated forms. In addition, the role of CGRP and SP were either analyzed using respective antagonists in the co-culture model, or by adding directly on the ECs monocultures. We show that capsaicin-stimulated SNs induce increased Ca2+ influx in ECs. SNs stimulate the increase of NO production in ECs, probably involving a decrease in the inhibitory eNOS T495 phosphorylation site. The neuropeptide CGRP, produced by SNs, seems to be one of the mediators of this effect in ECs since NO production is decreased in the presence of CGRP antagonist in the co-culture of ECs and SNs, and increased when ECs are stimulated with synthetic CGRP. Taken together, our results suggest that SNs play an important role in the control of the endothelial cell functions through CGRP production and NO signaling pathway.

Evolution and development of the conduction system in the vertebrate heart: a role for hemodynamics and the epicardium.

Development of the heart is a very intricate and multiplex process as it involves not only the three spatial dimensions but also the fourth or time dimension. Over time, the heart of an embryo needs to adapt its function to serve the increasing complexity of differentiation and growth towards adulthood. It becomes even more perplexing by expanding time into millions of years, allocating related species in the tree of life. As the evolution of soft tissues can hardly be studied, we have to rely on comparative embryology, supported heavily by genetic and molecular approaches. These techniques provide insight into relationships, not only between species, but also between cell populations, signaling mechanisms, molecular interactions and physical factors such as hemodynamics. Heart development depends on differentiation of a mesodermal cell population that - in more derived taxa - continues in segmentation of the first and second heart field. These fields deliver not only the cardiomyocytes, forming the three-dimensionally looping cardiac tube as a basis for the chambered heart, but also the enveloping epicardium. The synchronized beating of the heart is then organized by the conduction system. In this Review, the epicardium is introduced as an important player in cardiac differentiation, including the conduction system.

Focal adhesion kinase regulates tendon cell mechanoresponse and physiological tendon development.

Tendons enable locomotion by transmitting high tensile mechanical forces between muscle and bone via their dense extracellular matrix (ECM). The application of extrinsic mechanical stimuli via muscle contraction is necessary to regulate healthy tendon function. Specifically, applied physiological levels of mechanical loading elicit an anabolic tendon cell response, while decreased mechanical loading evokes a degradative tendon state. Although the tendon response to mechanical stimuli has implications in disease pathogenesis and clinical treatment strategies, the cell signaling mechanisms by which tendon cells sense and respond to mechanical stimuli within the native tendon ECM remain largely unknown. Therefore, we explored the role of cell-ECM adhesions in regulating tendon cell mechanotransduction by perturbing the genetic expression and signaling activity of focal adhesion kinase (FAK) through both invitro and invivo approaches. We determined that FAK regulates tendon cell spreading behavior and focal adhesion morphology, nuclear deformation in response to applied mechanical strain, and mechanosensitive gene expression. In addition, our data reveal that FAK signaling plays an essential role in invivo tendon development and postnatal growth, as FAK-knockout mouse tendons demonstrated reduced tendon size, altered mechanical properties, differences in cellular composition, and reduced maturity of the deposited ECM. These data provide a foundational understanding of the role of FAK signaling as a critical regulator of insitu tendon cell mechanotransduction. Importantly, an increased understanding of tendon cell mechanotransductive mechanisms may inform clinical practice as well as lead to the discovery of diagnostic and/or therapeutic molecular targets.

Ventilator-induced diaphragm dysfunction: phenomenology and mechanism(s) of pathogenesis.

Mechanical ventilation (MV) is used to support ventilation and pulmonary gas exchange in patients during critical illness and surgery. Although MV is a life-saving intervention for patients in respiratory failure, an unintended side-effect of MV is the rapid development of diaphragmatic atrophy and contractile dysfunction. This MV-induced diaphragmatic weakness is labelled as 'ventilator-induced diaphragm dysfunction' (VIDD). VIDD is an important clinical problem because diaphragmatic weakness is a risk factor for the failure to wean patients from MV. Indeed, the inability to remove patients from ventilator support results in prolonged hospitalization and increased morbidity and mortality. The pathogenesis of VIDD has been extensively investigated, revealing that increased mitochondrial production of reactive oxygen species within diaphragm muscle fibres promotes a cascade of redox-regulated signalling events leading to both accelerated proteolysis and depressed protein synthesis. Together, these events promote the rapid development of diaphragmatic atrophy and contractile dysfunction. This review highlights the MV-induced changes in the structure/function of diaphragm muscle and discusses the cell-signalling mechanisms responsible for the pathogenesis of VIDD. This report concludes with a discussion of potential therapeutic opportunities to prevent VIDD and suggestions for future research in this exciting field.

Anti-Allergic and Anti-Inflammatory Signaling Mechanisms of Natural Compounds/Extracts in In Vitro System of RBL-2H3 Cell: A Systematic Review.

Various extracts are tested for anti-allergic or anti-inflammatory properties on in vitro models. RBL-2H3 cells are widely used in allergic or immunological studies. FCεRI and its downstream signaling cascades, such as MAPK, NF-κB, and JAK/STAT signaling pathways, are important allergic or inflammatory signaling mechanisms in mast and basophil cells. This systematic review aims to study common signaling pathways of the anti-allergic or anti-inflammatory compounds on RBL-2H3 cells. We selected the relevant research articles published after 2015 from the PubMed, Scopus, Science Direct and Web of Science databases. The risk of bias of the studies was assessed based on the modified CONSORT checklist for in vitro studies. The cell lines, treatments, assay, primary findings, and signaling pathways on RBL-2H3 cells were extracted to synthesize the results. Thirty-eight articles were included, and FCεRI and its downstream pathways, such as Lyn, Sky, PLCγ, and MAPK, were commonly studied. Moreover, the JAK/STAT pathway was a potential signaling mechanism in RBL-2H3 cells. However, the findings based on RBL-2H3 cells needed to be tested along with human mast cells to confirm its relevance to human health. In conclusion, a single plant extract may act as an anti-inflammatory reagent in RBL-2H3 cells via multiple signaling pathways besides the MAPK signaling pathway.

Pathogenesis of cardiovascular diseases: effects of mitochondrial CF6 on endothelial cell function.

Cardiovascular disease (CVD) stands as a predominant global cause of morbidity and mortality, necessitating effective and cost-efficient therapies for cardiovascular risk reduction. Mitochondrial coupling factor 6 (CF6), identified as a novel proatherogenic peptide, emerges as a significant risk factor in endothelial dysfunction development, correlating with CVD severity. CF6 expression can be heightened by CVD risk factors like mechanical force, hypoxia, or high glucose stimuli through the NF-κB pathway. Many studies have explored the CF6-CVD relationship, revealing elevated plasma CF6 levels in essential hypertension, atherosclerotic cardiovascular disease (ASCVD), stroke, and preeclampsia patients. CF6 acts as a vasoactive and proatherogenic peptide in CVD, inducing intracellular acidosis in vascular endothelial cells, inhibiting nitric oxide (NO) and prostacyclin generation, increasing blood pressure, and producing proatherogenic molecules, significantly contributing to CVD development. CF6 induces an imbalance in endothelium-dependent factors, including NO, prostacyclin, and asymmetric dimethylarginine (ADMA), promoting vasoconstriction, vascular remodeling, thrombosis, and insulin resistance, possibly via C-src Ca2+ and PRMT-1/DDAH-2-ADMA-NO pathways. This review offers a comprehensive exploration of CF6 in the context of CVD, providing mechanistic insights into its role in processes impacting CVD, with a focus on CF6 functions, intracellular signaling, and regulatory mechanisms in vascular endothelial cells.

Perivascular NOTCH3+ Stem Cells Drive Meningioma Tumorigenesis and Resistance to Radiotherapy.

Meningiomas are the most common primary intracranial tumors. Treatments for patients with meningiomas are limited to surgery and radiotherapy, and systemic therapies remain ineffective or experimental. Resistance to radiotherapy is common in high-grade meningiomas and the cell types and signaling mechanisms that drive meningioma tumorigenesis and resistance to radiotherapy are incompletely understood. Here, we report that NOTCH3 drives meningioma tumorigenesis and resistance to radiotherapy and find that perivascular NOTCH3+ stem cells are conserved across meningiomas from humans, dogs, and mice. Integrating single-cell transcriptomics with lineage tracing and imaging approaches in genetically engineered mouse models and xenografts, we show NOTCH3 drives tumor-initiating capacity, cell proliferation, angiogenesis, and resistance to radiotherapy to increase meningioma growth and reduce survival. To translate these findings to patients, we show that an antibody stabilizing the extracellular negative regulatory region of NOTCH3 blocks meningioma tumorigenesis and sensitizes meningiomas to radiotherapy, reducing tumor growth and improving survival. Significance: There are no effective systemic therapies to treat meningiomas, and meningioma stem cells are poorly understood. Here, we report perivascular NOTCH3+ stem cells to drive meningioma tumorigenesis and resistance to radiotherapy. Our results identify a conserved mechanism and a therapeutic vulnerability to treat meningiomas that are resistant to standard interventions.

Xenohormetic Phytochemicals Inhibit Neovascularization in Microphysiological Models of Vasculogenesis and Tumor Angiogenesis.

Xenohormesis proposes that phytochemicals produced to combat stressors in the host plant exert biochemical effects in animal cells lacking cognate receptors. Xenohormetic phytochemicals such as flavonoids and phytoalexins modulate a range of human cell signaling mechanisms but functional correlations with human pathophysiology are lacking. Here, potent inhibitory effects of grapefruit-derived Naringenin (Nar) and soybean-derived Glyceollins (Gly) in human microphysiological models of bulk tissue vasculogenesis and tumor angiogenesis are reported. Despite this interference of vascular morphogenesis, Nar and Gly are not cytotoxic to endothelial cells and do not prevent cell cycle entry. The anti-vasculogenic effects of Glyceollin are significantly more potent in sex-matched female (XX) models. Nar and Gly do not decrease viability or expression of proangiogenic genes in triple negative breast cancer (TNBC) cell spheroids, suggesting that inhibition of sprouting angiogenesis by Nar and Gly in a MPS model of the (TNBC) microenvironment are mediated via direct effects in endothelial cells. The study supports further research of Naringenin and Glyceollin as health-promoting agents with special attention to mechanisms of action in vascular endothelial cells and the role of biological sex, which can improve the understanding of dietary nutrition and the pharmacology of phytochemical preparations.

A stretchable, electroconductive tissue adhesive for the treatment of neural injury.

Successfulnerve repair using bioadhesive hydrogels demands minimizing tissue-material interfacial mechanical mismatch to reduce immune responses and scar tissue formation. Furthermore, it is crucial to maintain the bioelectrical stimulation-mediated cell-signaling mechanism to overcome communication barriers within injured nerve tissues. Therefore, engineering bioadhesives for neural tissue regeneration necessitates the integration of electroconductive properties with tissue-like biomechanics. In this study, we propose a stretchable bioadhesive based on a custom-designed chemically modified elastin-like polypeptides (ELPs) and a choline-based bioionic liquid (Bio-IL), providing an electroconductive microenvironment to reconnect damaged nerve tissue. The stretchability akin to native neural tissue was achieved by incorporating hydrophobic ELP pockets, and a robust tissue adhesion was obtained due to multi-mode tissue-material interactions through covalent and noncovalent bonding at the tissue interface. Adhesion tests revealed adhesive strength ~10 times higherthan commercially available tissue adhesive, Evicel®. Furthermore, the engineered hydrogel supported in vitro viability and proliferation of human glial cells. We also evaluated the biodegradability and biocompatibility of the engineered bioadhesive in vivo using a rat subcutaneous implantation model, which demonstrated facile tissue infiltration and minimal immune response. The outlined functionalities empower the engineered elastic and electroconductive adhesive hydrogel to effectively enable sutureless surgical sealing of neural injuries and promote tissue regeneration.

Lighting ATR/Chk1 by mesoscale TopBP1 condensates

Biomolecular condensation has gained considerable attention as a fundamental mechanism in cell signaling and various biological processes. A recent study by Egger et al. provides valuable insights into the constituents of topoisomerase IIβ binding protein 1 (TopBP1) condensates and sheds light on the mechanism of Chk1 activation by ataxia telangiectasia-mutated and Rad3-related (ATR) at the interface of these condensates.

Gedunin modulates cellular growth and apoptosis in glioblastoma cell lines.

Glioblastomas are characterized by aggressive behavior. Surgery, radiotherapy, and alkylating agents, including temozolomide are the most common treatment options for glioblastoma. Often, conventional therapies fail to treat these tumors since they develop drug resistance. There is a need for newer agents to combat this deadly tumor. Natural products such as gedunin have shown efficacy in several human diseases. A comprehensive study of gedunin, an heat shock protein (HSP)90 inhibitor, has not been thoroughly investigated in glioblastoma cell lines with different genetic modifications. A key objective of this study was to determine how gedunin affects the biological and signaling mechanisms in glioblastoma cells, and to determine how those mechanisms affect the proliferation and apoptosis of glioblastoma cells. The viability potentials of gedunin were tested using MTT, cell counts, and wound healing assays. Gedunin's effects on glioma cells were further validated using LDH and colony formation assays. In addition, we investigated the survival and apoptotic molecular signaling targets perturbed by gedunin using Western blot analysis and flow cytometry. Our results show that there was a reduction in cell viability and inhibition of wound healing in the cells tested. Western blot analysis of the gene expression data revealed genes such as EGFR and mTOR/Akt/NF kappa B to be associated with gedunin sensitivity. Gedunin treatment induced apoptosis by cleaving poly ADP-ribose polymerase, activating caspases, and downregulating BCL-xL. Based on these results, gedunin suppressed cell growth and HSP client proteins, resulting in apoptosis in glioblastoma cell lines. Our data provide in vitro support for the anticancer activity of gedunin in glioma cells by downregulating cancer survival proteins.

A New Cell Type in Pulmonary Veins

Pulmonary veins (PVs) carry oxygenated blood from lungs back to the heart and may play an important role in preventing blood backflow from the left atrium. Previous studies show that large PVs exhibit spontaneously pulsatile contractions in cardiomyocyte-like manner. However, the contractions of small PVs have not been investigated. We hypothesized that Ca2+ signaling mechanisms in the myocytes mediate small PV contractions. Small, 4th-order PVs from C57BL6 mice were obtained and imaged. Pressurized PVs showed ryanodine receptor-dependent Ca2+ signals and spontaneous contractions. Light sheet fluorescence microscopy and immunostaining showed the expression of troponin C, a cardiomyocyte marker, in the myocyte layer of small PVs, which was not observed in the pulmonary arteries, vena cava, or mesenteric veins. Based on these results, we termed these cells cardiomyocyte-like (CML) cells. In the study of mice with Myh11 Cre-driven tdTomato expression, Myh11 expression was observed in CML cells in small PVs, which was not seen in the smooth muscle cells (SMC) of small PAs. Endothelial protrusions crossing the connective tissue layer into the CML layer were also observed in PVs. Previous studies showed PV remodeling in pulmonary hypertension (PH), and impaired Ca2+ signaling in PAs contribute to higher pulmonary arterial pressure in PH. We further hypothesized that ryanodine receptor (RyR) Ca2+ signals in CML cells are impaired in PH. Results show that RyR Ca2+ signaling was reduced in CML cells of PH mice (injected with Su5416, subjected to chronic hypoxic conditions). Overall, our findings identify a new cell type in small PVs. Moreover, our data show that RyR Ca2+ signals in CML cells underlie spontaneous contractions in small PV, and are impaired in PH. We propose that RyR signaling mechanisms in CML cells may be possible targets for therapy in pulmonary vascular disorders. This work was supported by funding from the National Institute of Health to Swapnil Sonkusare (R01:HL146914, R01:HL157407). This is the full abstract presented at the American Physiology Summit 2024 meeting and is only available in HTML format. There are no additional versions or additional content available for this abstract. Physiology was not involved in the peer review process.

Shear Stress Induces Morphology Changes in Human Lung Microvascular Endothelial Cells via Calcium Influx

Introduction: The pulmonary vascular endothelium is in contact with laminar blood flow, resulting in a physiologic degree of shear stress exerted on endothelial cells (ECs). In vitro cell culture of ECs is typically performed under static conditions, leading to underappreciation of the impact of shear stress. Calcium signaling is among the most ubiquitous cell signaling mechanisms, and changes in intracellular calcium concentration ([Ca2+]i) have been linked to shear stress. The impact of shear stress on human lung microvascular endothelial cell (hLMVEC) morphology and cell signaling is not well described. We hypothesized that hLMVECs exposed to shear stress would undergo Ca2+-dependent morphologic changes. Methods: The effect of shear stress on [Ca2+]i was first tested using ratiometric measurement. Early passage (p≤8) primary hLMVECs from three unique donor lots were plated in gelatin-coated Ibidi 0.2 uM depth plates for 16 h, then incubated with the calcium indicator Fura-2 AM for 1 h. Measurement of [Ca2+]i was obtained over 15 minutes under static and physiologic shear stress (0 and 12 dyn/cm2, respectively), using validated flow rates from the Ibidi system. Measured [Ca2+]i was compared between cells treated vehicle or an inhibitor of the mechanosensitive Ca2+-permeable channel TRPV4 (HC-067047). HC treatment was for 1 h prior to and throughout the duration of shear exposure. Morphology changes were then assessed in hLMVECs from the same three cell lots grown in standard 6-well plates; one plate kept in static culture, while another was exposed to 24 h of 12 dyn/cm2 shear stress using an orbital shaker. Treatments in each plate were control, vehicle, and HC. Representative photos of each well were taken at 0 h and at 24 h. Average ratios of shortest to longest dimensions from 30 cells/field were measured using ImageJ and compared between treatments and shear conditions. A 2-way ANOVA with post-test was used to test for statistically significant changes in morphology. Results: Shear stress increased [Ca2+]i within 15 minutes, and both baseline [Ca2+]i and observed change in response to shear stress were decreased by TRPV4 inhibition with HC. Morphologic changes were observed after exposure to shear stress on microscopic examination, with cells grown in static culture having typical cobblestone appearance and shear-adapted cells having an elongated, spindle like appearance aligned in the direction of flow. The calculated ratio (shortest to longest dimension) of all wells at 0 h was ~0.70 with no significant differences between groups. 24 h of shear stress caused a nearly 80% decrease in ratio compared to static culture in untreated cells (p<0.05), with a decrease of only 30% in HC-treated cells after 24 h of shear (p<0.05). Conclusions: Exposure to shear stress at physiological levels results in a rapid increase [Ca2+]i through mechanosensitive, Ca2+-permeable TRPV4 channels as well as notable morphologic changes to hLMVECs with prolonged exposure to shear stress that appear to be mediated in large part by TRPV4. Further investigation into the impact of shear stress on hLMVECs is warranted to elucidate biochemical pathways and other downstream functional consequences of increased [Ca2+]i. NIH-T32HL007534. This is the full abstract presented at the American Physiology Summit 2024 meeting and is only available in HTML format. There are no additional versions or additional content available for this abstract. Physiology was not involved in the peer review process.