Cell biology
Abstract
Extracellular matrix (ECM) disorder was considered as the result of fibrosis, but it is recently recognized that fibrotic ECM initiates a self-reinforcing circuit and contributes to development of fibrosis. Versican, an ECM component, participates in cell-ECM interaction and ECM regeneration. In pleura, versican is primarily derived from pleural mesothelial cells (PMCs). However, the role and mechanism of versican in pleural fibrosis remained unknown. In this study, versican and versican-mediated pleural viscoelasticity was found elevated in both human and murine pleural fibrotic tissues. Versican knockdown by shRNA prevented increases of viscoelasticity as well as pleural fibrosis. High level of versican and viscoelasticity promoted mesothelial to mesenchymal transition (MesoMT) in PMCs. Mechanistically, increased viscoelasticity induced pleural fibrosis through CD44/USP10/Smad4 mechanotransduction pathway. In conclusion, these results revealed that excessive versican in fibrotic pleural ECM enhanced ECM viscoelasticity, and consequently promoted progression of pleural fibrosis.
Authors
Zi-Heng Jia, Xin-Liang He, Xiao-Lin Cui, Qian Li, Pei-Pei Cheng, Li-Qin Zhao, Shu-Yi Ye, Shi-He Hu, Chen-Yue Lian, He-De Zhang, Li-Mei Liang, Lin-Jie Song, Fan Yu, Liang Xiong, Fei Xiang, Xiaorong Wang, Meng Wang, Xiyong Dai, Hong Ye, Wan-Li Ma
Abstract
Impaired adhesion and differentiation of keratinocytes is a hallmark of several skin diseases, but only some of the factors that regulate these processes have been identified. Here, we studied the role of isoform-rich dermokine – a wound- and tumor-regulated protein – in keratinocytes using a combination of multi-omics and functional approaches. CRISPR/Cas9-induced knockout of dermokine isoforms in human keratinocytes inhibited differentiation of these cells in three-dimensional organotypic skin cultures, which was confirmed by quantitative proteomics. In two-dimensional monocultures, dermokine deficiency affected the proteome and phosphoproteome as revealed by mass spectrometry. We found reduced abundance of differentiation-specific proteins and increased phosphorylation of cell adhesion protein p120 (catenin-δ1). The adhesive strength of dermokine knockout keratinocytes was impaired, which was rescued by p120 knock-down or ROCK inhibition. Finally, we verified the correlation between decreased dermokine expression and increased p120 phosphorylation in human non-healing wounds. These results identify dermokine as regulator of keratinocyte adhesion and differentiation, involving at least in part its effect on p120 phosphorylation and ROCK. Our data point to a function of dermokine in the pathogenesis of chronic wounds.
Authors
Vahap Canbay, Till Wüstemann, Weihua Tian, Tobias A. Beyer, Camilla Reiter Elbæk, Michael Stumpe, Gaetana Restivo, Chatpakorn Christiansen, Anabel Migenda Herranz, Susanne Mailand, Jürg Hafner, Rune Busk Damgaard, Steffen Goletz, Jörn Dengjel, Ulrich auf dem Keller, Chiara Francavilla
Abstract
Lysophosphatidic acid (LPA) is a bioactive lipid that signals through G protein–coupled receptors (LPA1–6) and regulates multiple cellular processes, including fibrosis. Although LPA signaling has been implicated in fibrotic diseases in several organs, its role in skeletal muscle remains unclear. Here, we show that LPA/LPA1 signaling promotes fibrogenesis after sciatic nerve transection. Denervation induces differential expression of LPA signaling axis components and a transient early increase in intramuscular LPA levels. Pharmacological inhibition of LPA1/3 with Ki16425, or genetic deletion of LPA1, reduces extracellular matrix accumulation and expansion of fibro/adipogenic progenitors (FAPs) in denervated muscle. Although LPA blockade suppresses atrophy-related gene expression, it does not fully preserve myofiber size. Mechanistically, denervation increases YAP/TAZ expression, nuclear localization in FAPs, and transcriptional activity, effects that are attenuated by LPA axis inhibition. Furthermore, pharmacological inhibition of YAP/TAZ with verteporfin reduces fibrosis after denervation, supporting their role as critical downstream mediators. Finally, transient denervation activates the LPA axis, promotes muscle fibrosis, reduces axonal density in the sciatic nerve, and increases neuromuscular junction instability, effects reversed by Ki16425. Together, these findings identify the LPA/LPA1/YAP/TAZ pathway as a key driver of denervation-induced muscle fibrosis and a potential therapeutic target in neuromuscular disorders.
Authors
Meilyn Cruz-Soca, Adriana Córdova-Casanova, Jennifer Faundez-Contreras, Nicolás W. Martínez, Francesca Vaccaro-Rivera, Sebastián Bazaes-Astorga, Cristian Gutiérrez-Rojas, Felipe S. Gallardo, Daniela L. Rebolledo, Felipe A. Court, Jerold Chun, Carlos P. Vio, Soledad Matus, Juan Carlos Casar, Enrique Brandan
Abstract
Inactivating NOTCH1 mutations in head and neck squamous cell carcinoma (HNSCC) were described over a decade ago, suggesting a tumorsuppressor function—unlike its oncogenic role in other tumors. Today, much debate persists regarding a putative oncogenic role in HNSCC as well, with reports that NOTCH1 signaling drives tumor growth and a cancerstemcell (CSC) phenotype. In this work, comprehensive experiments unequivocally demonstrate that NOTCH1 is a tumor suppressor in HNSCC regardless of mutation or activation status and that it reduces CSC frequency. We developed a signature of NOTCH1 activation showing the pathway is associated with very early differentiation, an altered tumor microenvironment, and better prognosis. Clarifying whether NOTCH1 occasionally functions as an oncogenic driver in HNSCC is crucial to prognosis and personalized therapy. The results presented unify the field, reconcile conflicting data, and provide critical insights into the biological and clinical significance of NOTCH1, with broader implications in other squamous carcinomas with NOTCH1 mutations.
Authors
Chenfei Huang, Shhyam Moorthy, Qiuli Li, Kazi M. Ahmed, Kalil Saab, Defeng Deng, Jiping Wang, Xiayu Rao, Jiexin Zhang, Yuanxin Xi, Jing Wang, Zhiyi Liu, Noriaki Tanaka, David A. Wheeler, Eve Shinbrot, Rami Saade, Curtis R. Pickering, Tong-Xin Xie, Adel K. El-Naggar, Abdullah A. Osman, Kunal Rai, Patrick A. Zweidler-McKay, John V. Heymach, Lauren A. Byers, Faye M. Johnson, Vlad C. Sandulache, Jeffrey N. Myers, Pedram Yadollahi, Mitchell J. Frederick
Abstract
Short QT syndrome is a heritable arrhythmia disorder linked to sudden cardiac death. We recently identified that individuals with alternating hemiplegia of childhood (AHC), a rare neurodevelopmental disorder, can exhibit shortened corrected QT intervals and elevated risk for ventricular fibrillation. This is especially true for patients with AHC heterozygous for the recurrent ATP1A3-D801N variant, though the underlying cardiac mechanism remains unclear. We hypothesized that the D801N missense impairs Na+/K+-ATPase function, causing Ca2+ overload, shortened action potential duration (APD), and arrhythmias. Using in silico modeling and patient-derived induced pluripotent stem cell cardiomyocytes (iPSC-CMsD801N), we observed shorter APD, elevated intracellular and sarcoplasmic reticulum Ca2+ levels, and delayed afterdepolarizations (DADs) compared with WT. Additionally, increased Ca²+ influx via the Na+/Ca2+ exchanger (NCX1) during depolarization was observed in iPSC-CMsD801N. Simulations and in vitro experiments suggest that reduced ATPase function accelerated inactivation of L-type Ca2+ channels. Pharmacologic inhibition of NCX1 with ORM-10103 normalized APD and reduced DADs. These findings support a Ca2+-mediated mechanism for arrhythmogenesis in ATP1A3-D801N carriers and identify NCX1 as a potential therapeutic target.
Authors
Minu-Tshyeto K. Bidzimou, Padmapriya Muralidharan, Zhushan Zhang, Danyal Raza, Daniel Needs, Bo Sun, Robin M. Perelli, Mary E. Moya-Mendez, P.K. Rakesh Manivannan, Arsen S. Hunanyan, Abbigail Helfer, Christine Q. Simmons, Alfred L. George Jr., Donald M. Bers, Nenad Bursac, Mohamad A. Mikati, Andrew P. Landstrom
Abstract
Supernumerary centrosomes are a hallmark of cancer. To maintain viability, cancer cells cluster these centrosomes during mitosis, enabling bipolar division similar to that of normal cells. Disruption of this centrosome clustering leads to multipolar anaphase and apoptosis (anaphase catastrophe), which selectively eliminates cancer cells harboring supernumerary centrosomes. In this context, because the motor protein KIFC1 contributes to centrosome clustering, we investigated whether targeting of this mechanism through KIFC1 inhibition could be exploited in small-cell lung cancer (SCLC), an aggressive malignancy with limited treatment options and poor prognosis. Through in silico and in vitro analyses, as well as IHC of clinical samples, we found that KIFC1 is overexpressed and that centrosome amplification occurs more frequently in SCLC compared with normal tissues and other cancer types. Pharmacological and genetic inhibition of KIFC1 disrupted the clustering of supernumerary centrosomes, triggered multipolar mitosis, and exerted antineoplastic effects in SCLC cells, with minimal effects on noncancerous cells. These findings were validated and extended in vivo using SCLC xenograft models. Finally, cotargeting KIFC1 and the centrosome duplication regulator PLK4 further enhanced growth suppression in SCLC cells. Together, these results suggest that disrupting centrosome clustering and triggering anaphase catastrophe via KIFC1 inhibition may represent a promising therapeutic strategy for SCLC.
Authors
Natsuki Nakagawa, Minemichi Toda, Akiko Kunita, Masafumi Horie, Masakatsu Tokunaga, Hiroaki Ikushima, Mirei Ka, Takahiro Iida, Manabu Shigeoka, Yukinobu Ito, Takahiro Ando, Kousuke Watanabe, Yasunori Ota, Xi Liu, Ethan Dmitrovsky, Hidenori Kage, Masanori Kawakami
Abstract
At-home blood collection devices (ABCDs) can facilitate study participation for remote and rural cohorts. Previous studies used ABCDs to interrogate samples by proteomics and sequencing approaches. We wanted to address the question of whether this approach could be used to assess live immune cells with high-parameter flow cytometry to enable remote immune monitoring. We first compared blood from standard venipuncture with ABCD blood draws, followed by assessment of the impact of sample shipping on immune cell viability and phenotyping. We found that capillary blood collected with a Tasso+ device and concurrently drawn venipuncture blood samples had highly congruent immune cell composition and phenotype. Shipment of Tasso+ samples via the United States Postal Service altered the myeloid compartment, but T cell numbers, subsets, and phenotypes remained remarkably stable compared with non-shipped samples. Finally, we describe a flow cytometry analysis framework that allowed for direct sample comparison even when samples were stained and analyzed over a time period of 1.5 years. Overall, our data highlight the feasibility of using ABCDs combined with subsequent flow cytometry analysis for remote immune monitoring. Additionally, our study also identifies areas that could be improved to further promote the use of ABCDs for immune monitoring.
Authors
Andrew J. Konecny, Fang Yun Lim, Eva Domenjo-Vila, Erika Lovas, Rachel L. Blazevic, Louise E. Kimball, Michael Boeckh, Alpana Waghmare, Martin Prlic
Abstract
Current treatment protocols for most types of cancers require chemotherapeutic agents that are associated with significant side effects, including chemotherapy-induced peripheral neuropathy (CIPN). Currently, there are no effective CIPN prevention strategies, and current treatment approaches remain limited. The enzyme purine nucleoside phosphorylase (PNPase) actively modulates both oxidative injury and cellular damage. Here, we tested the hypothesis that the signs and symptoms of CIPN are due to a chemotherapy-induced dysregulation of the purine metabolome. We assessed the effect of PNPase inhibition on paclitaxel-induced (PAC-induced) CIPN. Female adult Sprague-Dawley rats were treated with PAC and randomized to oral treatment with either the PNPase inhibitor 8-aminoguanine (8-AG) or its vehicle. Some rats were injected with shRNA against PNPase prior to PAC injections. PAC-treated rats exhibited multiple abnormalities: mechanical allodynia and changes in damaging purines, intraepidermal nerve fiber (IENF) density, and signaling cascades involved in mitochondrial disruption and axonal damage. Inhibition of PNPase improved behavioral function (mechanical allodynia), rescued the loss/damage of IENF, and normalized markers for mitochondrial dysfunction and nerve damage. These findings support the hypothesis that inhibition of PNPase prevented (and potentially reversed) CIPN through several mechanisms that included a reduction in neuronal damage and development of mechanical allodynia.
Authors
Lori A. Birder, Amanda Wolf-Johnston, Jonathan Franks, Mara L.G. Sullivan, Simon C. Watkins, Anthony J. Kanai, Vladimir B. Ritov, Edwin K. Jackson
Abstract
Chronic neuropathic pain is frequently comorbid with anxiety disorders, yet the neural circuits underlying this interaction remain poorly defined. The parafascicular nucleus of the thalamus (PF) integrates nociceptive and affective signals, but its specific regulatory mechanisms in pain-anxiety comorbidity are not well known. Using spared nerve injury (SNI) model mice, we combined viral neural tracing, chemogenetics, pharmacology, and electrophysiology to dissect the locus coeruleus (LC)-PF neural pathway. Viral tracing revealed monosynaptic projections from norepinephrinergic (NEergic) neurons in the dorsal LC to calcium/calmodulin dependent protein kinase IIα (CaMKIIα)- immunopositive neurons within the PF. Chemogenetic inhibition/activation of this pathway were performed in naïve and SNI mice, alongside intra-PF microinjection of the alpha-2 adrenergic receptor (ADRA2) antagonist yohimbine. Behavioral tests assessed mechanical/thermal hypersensitivity and anxiety-like behaviors. Results showed that 92.1% of PF-projecting LC neurons were NEergic, with 70.1% localized dorsally. Chemogenetic inhibition of LCNE-PFCaMKIIα neural pathway significantly alleviated both acute-phase mechanical hypersensitivity (< 7 days post-surgery) and chronic-phase anxiety-like behaviors in SNI mice, while activation of this pathway induced pain sensitization and anxiety-like behaviors in naïve mice. Intra-PF yohimbine reversed SNI-induced allodynia and anxiety-like behaviors. Electrophysiology confirmed yohimbine increased PF neuronal intrinsic excitability. These results suggest that the LCNE-PFCaMKIIα neural pathway promotes neuropathic pain and comorbid anxiety via ADRA2-mediated suppression of PF neuronal activity. Targeted inhibition of this circuit may represent a therapeutic strategy for pain-related affective disorders.
Authors
Zhong-Yi Liu, Fei Li, Li-Ming Liu, Yao-Hua Liu, Jia Li, Zi-Ang Li, Jin Cheng, Tian-Yu Zhao, Hui-Min Tian, Dong-Ning Li, Sha-Sha Tao, Hui Li, Fen-Sheng Huang, Yun-Qing Li
Abstract
Dedifferentiated liposarcoma (DDLS), myxofibrosarcoma (MFS), and undifferentiated pleomorphic sarcoma (UPS) are the most common types of genetically complex sarcoma. There is an urgent need to develop effective targeted therapy for these deadly sarcoma types. Despite their genetic complexity, these sarcomas share genomic alterations causing PI3K/Akt/mTOR and MAPK pathway activation, and both pathways control translation mediated by the RNA helicase eIF4A. We therefore investigated eIF4A inhibition as a therapeutic strategy. The eIF4A inhibitor CR-1-31B effectively suppressed tumor growth and induced apoptosis in DDLS, MFS, and UPS patient-derived cell lines and mouse xenografts. Transcriptome-scale ribosome footprinting identified eIF4A-dependent mRNAs such as the Hippo pathway transcriptional coactivators YAP1 (YAP) and WWTR1 (TAZ). Combined knockdown of YAP and TAZ induced apoptosis in DDLS, MFS, and UPS cell lines, and their ectopic expression partially rescued cells from apoptosis induced by CR-1-31B. Genomic analysis of patient tumors revealed that YAP and WWTR1 were frequently amplified or gained in DDLS, MFS, and UPS and were associated with worse clinical outcomes. Together, our findings identify a new strategy for targeting the Hippo pathway in incurable forms of sarcoma based on inhibition of eIF4A-dependent translation of the key oncogenic transcription factors YAP and TAZ.
Authors
Young-Mi Kim, Prathibha Mohan, Urmila Sehrawat, Evan Seffar, Rafaela Muniz De Queiroz, Kalyani Chadalavada, Nikita Persaud, Tomoyo Okada, Anirudh Kulkarni, Jianan Lin, Nathalie Lailler, Shaleigh Smith, Bhumika Jadeja, Nicholas D. Socci, Zhengqing Ouyang, Hans-Guido Wendel, Samuel Singer
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