TY - JOUR A1 - Nanda, Indrajit A1 - Steinlein, Claus A1 - Haaf, Thomas A1 - Buhl, Eva M. A1 - Grimm, Domink G. A1 - Friedman, Scott L. A1 - Meurer, Steffen K. A1 - Schröder, Sarah K. A1 - Weiskirchen, Ralf T1 - Genetic characterization of rat hepatic stellate cell line HSC-T6 for in vitro cell line authentication JF - Cells N2 - Immortalized hepatic stellate cells (HSCs) established from mouse, rat, and humans are valuable in vitro models for the biomedical investigation of liver biology. These cell lines are homogenous, thereby providing consistent and reproducible results. They grow more robustly than primary HSCs and provide an unlimited supply of proteins or nucleic acids for biochemical studies. Moreover, they can overcome ethical concerns associated with the use of animal and human tissue and allow for fostering of the 3R principle of replacement, reduction, and refinement proposed in 1959 by William M. S. Russell and Rex L. Burch. Nevertheless, working with continuous cell lines also has some disadvantages. In particular, there are ample examples in which genetic drift and cell misidentification has led to invalid data. Therefore, many journals and granting agencies now recommend proper cell line authentication. We herein describe the genetic characterization of the rat HSC line HSC-T6, which was introduced as a new in vitro model for the study of retinoid metabolism. The consensus chromosome markers, outlined primarily through multicolor spectral karyotyping (SKY), demonstrate that apart from the large derivative chromosome 1 (RNO1), at least two additional chromosomes (RNO4 and RNO7) are found to be in three copies in all metaphases. Additionally, we have defined a short tandem repeat (STR) profile for HSC-T6, including 31 species-specific markers. The typical features of these cells have been further determined by electron microscopy, Western blotting, and Rhodamine-Phalloidin staining. Finally, we have analyzed the transcriptome of HSC-T6 cells by mRNA sequencing (mRNA-Seq) using next generation sequencing (NGS). KW - liver KW - extracellular matrix KW - hepatic stellate cell KW - myofibroblast KW - fibrosis KW - in vitro model KW - SKY analysis KW - phalloidin stain KW - next generation sequencing KW - STR profile Y1 - 2022 U6 - http://nbn-resolving.de/urn/resolver.pl?urn:nbn:de:bvb:20-opus-275178 SN - 2073-4409 VL - 11 IS - 11 ER - TY - JOUR A1 - Zimny, Sebastian A1 - Koob, Dennis A1 - Li, Jingguo A1 - Wimmer, Ralf A1 - Schiergens, Tobias A1 - Nagel, Jutta A1 - Reiter, Florian Paul A1 - Denk, Gerald A1 - Hohenester, Simon T1 - Hydrophobic bile salts induce pro-fibrogenic proliferation of hepatic stellate cells through PI3K p110 alpha signaling JF - Cells N2 - Bile salts accumulating during cholestatic liver disease are believed to promote liver fibrosis. We have recently shown that chenodeoxycholate (CDC) induces expansion of hepatic stellate cells (HSCs) in vivo, thereby promoting liver fibrosis. Mechanisms underlying bile salt-induced fibrogenesis remain elusive. We aimed to characterize the effects of different bile salts on HSC biology and investigated underlying signaling pathways. Murine HSCs (mHSCs) were stimulated with hydrophilic and hydrophobic bile salts. Proliferation, cell mass, collagen deposition, and activation of signaling pathways were determined. Activation of the human HSC cell line LX 2 was assessed by quantification of α-smooth muscle actin (αSMA) expression. Phosphatidyl-inositol-3-kinase (PI3K)-dependent signaling was inhibited both pharmacologically and by siRNA. CDC, the most abundant bile salt accumulating in human cholestasis, but no other bile salt tested, induced Protein kinase B (PKB) phosphorylation and promoted HSC proliferation and subsequent collagen deposition. Pharmacological inhibition of the upstream target PI3K-inhibited activation of PKB and pro-fibrogenic proliferation of HSCs. The PI3K p110α-specific inhibitor Alpelisib and siRNA-mediated knockdown of p110α ameliorated pro-fibrogenic activation of mHSC and LX 2 cells, respectively. In summary, pro-fibrogenic signaling in mHSCs is selectively induced by CDC. PI3K p110α may be a potential therapeutic target for the inhibition of bile salt-induced fibrogenesis in cholestasis. KW - cholestasis KW - HSC KW - myofibroblast KW - chenodeoxycholate KW - phosphatidyl-inositol-3-kinase p110 alpha KW - Alpelisib KW - liver fibrosis Y1 - 2022 U6 - http://nbn-resolving.de/urn/resolver.pl?urn:nbn:de:bvb:20-opus-281806 SN - 2073-4409 VL - 11 IS - 15 ER - TY - JOUR A1 - Nanda, Indrajit A1 - Schröder, Sarah K. A1 - Steinlein, Claus A1 - Haaf, Thomas A1 - Buhl, Eva M. A1 - Grimm, Domink G. A1 - Weiskirchen, Ralf T1 - Rat hepatic stellate cell line CFSC-2G: genetic markers and short tandem repeat profile useful for cell line authentication JF - Cells N2 - Hepatic stellate cells (HSCs) are also known as lipocytes, fat-storing cells, perisinusoidal cells, or Ito cells. These liver-specific mesenchymal cells represent about 5% to 8% of all liver cells, playing a key role in maintaining the microenvironment of the hepatic sinusoid. Upon chronic liver injury or in primary culture, these cells become activated and transdifferentiate into a contractile phenotype, i.e., the myofibroblast, capable of producing and secreting large quantities of extracellular matrix compounds. Based on their central role in the initiation and progression of chronic liver diseases, cultured HSCs are valuable in vitro tools to study molecular and cellular aspects of liver diseases. However, the isolation of these cells requires special equipment, trained personnel, and in some cases needs approval from respective authorities. To overcome these limitations, several immortalized HSC lines were established. One of these cell lines is CFSC, which was originally established from cirrhotic rat livers induced by carbon tetrachloride. First introduced in 1991, this cell line and derivatives thereof (i.e., CFSC-2G, CFSC-3H, CFSC-5H, and CFSC-8B) are now used in many laboratories as an established in vitro HSC model. We here describe molecular features that are suitable for cell authentication. Importantly, chromosome banding and multicolor spectral karyotyping (SKY) analysis demonstrate that the CFSC-2G genome has accumulated extensive chromosome rearrangements and most chromosomes exist in multiple copies producing a pseudo-triploid karyotype. Furthermore, our study documents a defined short tandem repeat (STR) profile including 31 species-specific markers, and a list of genes expressed in CFSC-2G established by bulk mRNA next-generation sequencing (NGS). KW - liver KW - extracellular matrix KW - hepatic stellate cell KW - myofibroblast KW - fibrosis KW - stress fibers KW - spectral karyotyping KW - rhodamine–phalloidin stain KW - next-generation sequencing KW - STR profile Y1 - 2022 U6 - http://nbn-resolving.de/urn/resolver.pl?urn:nbn:de:bvb:20-opus-288067 SN - 2073-4409 VL - 11 IS - 18 ER - TY - THES A1 - Aue, Annemarie T1 - Lokalisation und Bedeutung der NO-sensitiven Guanylyl-Cyclase bei der Lungenfibrose in der Maus T1 - Localization and importance of NO-sensitive guanylyl cyclase in a murine model of lung fibrosis N2 - Die im Rahmen dieser Arbeit behandelten Fragestellungen vermitteln neue Kenntnisse über die Pathogenese der Lungenfibrose auf zellulärer Ebene. Bei der Lungenfibrose handelt es sich um eine chronische Erkrankung, die durch eine initiale Inflammation und das Auftreten von Myofibroblasten gekennzeichnet ist. Die Myofibroblasten führen zu einer vermehrten Produktion von EZM, was in einer Zerstörung der Lungenarchitektur, Narbenbildung und folglich einem verminderten Gasaustausch resultiert. Eine modulatorische Rolle von Stickstoffmonoxid (NO) bei der Entwicklung der Lungenfibrose wird vermutet, dennoch sind die Effektorzellen in der Lunge noch nicht bekannt. Daher wurde im ersten Teil dieser Arbeit die Lokalisation des NO-Rezeptors, der NO-sensitiven Guanylyl-Cyclase (NO-GC), in der Lunge untersucht. Dazu wurden Knockout-Mäuse generiert, bei denen die NO-GC global (GCKO) oder Perizyten-spezifisch (PDGFRβ-GCKO, SMMHC-GCKO, NG2-GCKO und SMMHC/NG2-GCKO) deletiert ist. Zudem wurden tdTomato-Reportermäuse verwendet, die das Fluoreszenzprotein unter Kontrolle eines spezifischen Reporters exprimieren (PDGFRβ/tomato, SMMHC/tomato, NG2/tomato, FoxD1/tomato und Tie2/tomato). In der Lunge sind Perizyten der NO-GC-exprimierende Zelltyp. Durch Immunhistochemie konnten zudem zwei verschiedene Subpopulationen von NO-GC-exprimierenden Perizyten identifiziert werden: Eine große Population an SMMHC/PDGFRβ-positiven Perizyten und eine kleine Population an NG2/PDGFRβ-positiven Perizyten. Im zweiten Teil dieser Arbeit wurde die Funktion der NO-GC während der Bleomycin-induzierten Lungenfibrose untersucht. Bleomycin führt zu einer fibrotischen Antwort in allen Genotypen, was durch ein erhöhtes Lungengewicht und einen erhöhten Kollagengehalt deutlich wird. Der Schweregrad der Lungenverletzung ist in NO-GC-defizienten Mäusen größer als in Anwesenheit der NO-GC. Dies deutet auf eine Rolle der NO-GC bei der Bleomycin-induzierten Lungenfibrose hin. Während der Entstehung der Lungenfibrose kommt es zur Bildung von Myofibroblasten, die als die Schlüsselzellen der Wundheilung und fibrotischer Prozesse bezeichnet werden. Diese Zellen kommen unter physiologischen Bedingungen kaum vor und ihre Herkunft ist nach wie vor nicht eindeutig geklärt. Da Perizyten als mögliche Vorläuferzellen betrachtet werden, wurde Lineage Tracing von Perizyten durchgeführt. Erstmals wurden zwei verschiedene Myofibroblasten-Subtypen durch die Expression von NO-GC unterschieden: (1) NO-GC-positive Myofibroblasten, die in der Alveolarwand lokalisiert sind und von Perizyten abstammen und (2) NO-GC-negative Myofibroblasten, die sich innerhalb der Alveolen befinden, deren Ursprung jedoch nicht Perizyten sind. Diese Myofibroblasten zeigen jedoch eine de novo-Synthese von PDGFRβ. Durch Lineage Tracing-Versuche sowie immunhistochemische Analysen können Perizyten, Endothelzellen und Fibrozyten als Vorläuferzellen ausgeschlossen werden. Die Ursprungszelle der intra-alveolären Myofibroblasten ist somit bislang nicht identifiziert. Im letzten Teil der Arbeit wurde die Rolle der an der Lungenfibrose beteiligten Zelltypen näher untersucht. Dazu wurde die Auflösung der reversiblen Bleomycin-induzierten Lungenschäden betrachtet. Der Verlust der beiden Myofibroblasten-Subtypen weist darauf hin, dass sie zwar die Effektorzellen der Wundheilungsreaktion, jedoch nicht an der Entstehung der chronisch manifesten Fibrose beteiligt sind. Perizyten proliferieren in Folge der Gabe von Bleomycin und sind vermehrt im Lungenparenchym auch nach Auflösung der Bleomycin-induzierten Lungenverletzung vorzufinden. Diese Ergebnisse führen zu der Annahme, dass es sich hierbei um die Effektorzellen der chronisch manifesten Lungenfibrose handelt, die durch eine Verdickung der Alveolarwand gekennzeichnet ist. Um die zellulären Mechanismen der Lungenfibrose umfassend aufzuklären, müssen weitere Untersuchungen an irreversiblen Fibrosemodellen folgen, die auch die chronischen Charakteristiken der Erkrankung berücksichtigen. N2 - This project provides new insights into the pathogenesis of pulmonary fibrosis on the cellular level. Pulmonary fibrosis is a chronic disease characterized by signs of inflammation and the appearance of myofibroblasts that are responsible for excessive production of extracellular matrix (ECM). This leads to destroyed lung architecture, scar formation and reduced gas exchange. A modulatory role of nitric oxide (NO) in the development of pulmonary fibrosis has been proposed. However, the effector cells in the lung are remain elusive. The first part of the thesis focused on the localization of NO-sensitive guanylyl cyclase (NO-GC) in lung. Pericytes are the major NO-GC-expressing cell type in lung. Knock-out mice were generated lacking NO-GC globally (GCKO) as well as pericyte-specific GCKO mice (PDGFRβ-GCKO, SMMHC-GCKO, NG2-GCKO und SMMHC/NG2-GCKO). In addition, reporter mice were used that express tdTomato following cre-mediated recombination (PDGFRβ/tomato, SMMHC/tomato, NG2/tomato, FoxD1/tomato und Tie2/tomato). Immunohistochemical analysis shows the existence of two subpopulations of pericytes expressing NO-GC in lung: SMMHC/PDGFRβ-positive pericytes and a smaller subpopulation of NG2/PDGFRβ-positive pericytes. In the second part of the thesis, the role of NO-GC during bleomycin-induced lung injury was investigated. Bleomycin led to a fibrotic response in all genotypes as seen by an increase of lung weight and collagen content. Severity of lung injury in NO-GC-deficient mice was greater compared to wild type (WT) mice following instillation of bleomycin. These results indicate a possible role of NO-GC during bleomycin-induced lung injury. The development of pulmonary fibrosis is characterized by the formation of myofibroblasts that are known to be key players of wound healing and fibrotic processes. These cells do not occur under physiological conditions and their origin is still under debate. Lineage tracing of pericytes showed that NO-GC-expression allows to differentiate interstitial from intra-alveolar myofibroblasts: (1) NO-GC-positive, pericyte-derived myofibroblasts located in the alveolar wall and (2) NO-GC-negative, intra-alveolar myofibroblasts that are not derived from pericytes but, surprisingly, show de novo-expression of PDGFRβ after injury. The precursor cell type of intra-alveolar myofibroblasts is not identified yet. Pericytes, endothelial cells and fibrocytes do not transdifferentiate into myofibroblasts. Investigation of different cell types during resolution of lung fibrosis showed the disappearance of both types of myofibroblast. NO-GC-expressing pericytes that proliferate following administration of bleomycin are still present in an increased number. These results implicate a major role of myofibroblasts during wound healing responses but pericytes could be the effectors of chronic and manifest pulmonary fibrosis that is characterized by thickening of the alveolar wall. For a further understanding of the cellular mechanisms during pulmonary fibrosis investigations on irreversible models of fibrosis need to be performed. KW - Lungenfibrose KW - Guanylatcyclase KW - Myofibroblast KW - Perizyt KW - NO-sensitive Guanylyl-Cyclase KW - Bleomycin KW - Pulmonary fibrosis KW - NO-sensitive guanylyl cyclase KW - myofibroblast KW - pericyte KW - bleomycin Y1 - 2019 U6 - http://nbn-resolving.de/urn/resolver.pl?urn:nbn:de:bvb:20-opus-176710 ER -