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Bei der Behandlung solider Tumoren spielen systemisch verabreichte Chemotherapeutika eine wich- tige Rolle. Allerdings akkumulieren diese Therapeutika besser in normalem Gewebe als in Tumoren. Als Ursache für diesen unzureichenden Transport von Medikamenten in den Tumor wurde bisher vor allem die dysfunktionale Tumorvaskulatur diskutiert. Diese befindet sich in einem chaotischen und unreifen Zustand ohne ausreichende Bedeckung der Gefäße mit stabilisierenden Perizyten. Aus dem Zustand der Vaskulatur resultierend erreichen Medikamente den Tumor nur in geringem Ausmaß und werden dort heterogen verteilt. Als Grund für den Zustand der Vaskulatur wur- de ein großer Überschuss an pro-angiogenetischen Faktoren im Tumor ausgemacht. Durch eine anti-angiogenetische Behandlung konnte in präklinischen Modellen für einen gewissen Zeitraum die Tumorvaskulatur „normalisiert“ werden. Dies zeichnete sich vor allem durch Veränderung von zwei wichtigen Parametern für die Medikamenteneinbringung aus: zum Einen kommt es zu einer Reduktion der Gefäßdichte. Zum Anderen zu einer Reifung der Blutgefäße. In einem Teil von Pati- enten scheint dabei der Effekt der Gefäßverbesserung zu überwiegen und es kann eine verbesserte Perfusion detektiert werden. Mutmaßlich führt dies auch zu einer verbesserten Einbringung von Therapeutika in den Tumor und so zu einer erhöhten Effizienz der Therapie. In einem weiteren Teil der Patienten scheint jedoch der Effekt der Gefäßreduktion zu überwiegen und die detektierte Perfusion im Tumor wird durch die Behandlung verringert.
Das in dieser Arbeit verwendete MT6-Fibrosarkom-Modell reagierte auf eine anti-angiogenetische Therapie nicht mit einer sonst in murinen Modellen beobachteten Wachstumsreduktion. Die- se ermöglichte eine so bisher nicht mögliche Untersuchung der sekundären Effekte einer anti- angiogenetischen Therapie wie die Medikamenteneinbringung in den Tumor. Die Vaskulatur in MT6-Tumoren zeigte dabei nach einer anti-angiogenetischen Vorbehandlung, die erwarteten Merk-male einer „normalisierten“ Vaskulatur wie eine Reduktion der Gefäßdichte bei gleichzeitiger Rei- fung der verbleibenden Gefäße. Dies führte jedoch nicht zu einer verbesserten Effizienz einer subsequenten Chemotherapie. Durch Vergleich mit einem weiteren Tumor-Modell, dem 4T1-Modell für ein metastasierendes Mammakarzinom, konnten signifikante Unterschiede im Gefäßbild beider Modelle ausgeschlossen werden. Durch mikroskopische Methoden konnte dabei beobachtet werden, dass die Diffusion von Medikamenten aus den Blutgefäßen des MT6-Modells im Vergleich zum 4T1-Modell verringert war. Weitere Untersuchungen deuten auf eine Differenz in der Qualität der extrazellulären Matrix der verwendeten Tumor-Modelle. Durch mRNA-Expressionsanalysen konnte die Enzymfamilie der Lysyloxidasen als mögliche Ursache für diesen Diffusionsunterschied identi- fiziert werden. Lysyloxidasen katalysieren vor allem die Quervernetzung von Proteinen der Extra- zellulärmatrix. Im Weiteren konnte gezeigt werden, dass die Quervernetzung von Matrixproteinen durch Lysyloxidasen ursächlich für die Diffusions-Inhibierung kleiner Moleküle wie das Chemo- therapeutikum Doxorubicin sein kann. Durch spezifische Inhibition der Lysyloxidasen mittels des Inhibitors βAPN konnte diese Diffusions-Inhibition sowohl in vitro als auch im MT6-Tumor-Modell nahezu vollständig verhindert werden. Die hohe Aktivität von Lysyloxidasen im MT6-Modell stell- te allerdings kein Alleinstellungsmerkmal dieses Modells dar. In weiteren Untersuchungen konnte gezeigt werden, dass Lysyloxidasen in einer Vielzahl von murinen und humanen Tumorzelllinien überexprimiert wird. Die Inhibition von Lysyloxidasen durch βAPN konnte dabei in allen unter- suchten Modellen die Einbringung von Medikamenten in den Tumor erhöhen und könnte so eine sinnvolle adjuvante Maßnahme zur Verbesserung bestehender Chemotherapien darstellen.
Supplement-free induction of cellular differentiation and polarization solely through the topography of materials is an auspicious strategy but has so far significantly lagged behind the efficiency and intensity of media-supplementation-based protocols. Consistent with the idea that 3D structural motifs in the extracellular matrix possess immunomodulatory capacity as part of the natural healing process, it is found in this study that human-monocyte-derived macrophages show a strong M2a-like prohealing polarization when cultured on type I rat-tail collagen fibers but not on collagen I films. Therefore, it is hypothesized that highly aligned nanofibrils also of synthetic polymers, if packed into larger bundles in 3D topographical biomimetic similarity to native collagen I, would induce a localized macrophage polarization. For the automated fabrication of such bundles in a 3D printing manner, the strategy of “melt electrofibrillation” is pioneered by the integration of flow-directed polymer phase separation into melt electrowriting and subsequent selective dissolution of the matrix polymer postprocessing. This process yields nanofiber bundles with a remarkable structural similarity to native collagen I fibers, particularly for medical-grade poly(ε-caprolactone). These biomimetic fibrillar structures indeed induce a pronounced elongation of human-monocyte-derived macrophages and unprecedentedly trigger their M2-like polarization similar in efficacy as interleukin-4 treatment.
Primary open-angle glaucoma (POAG) is a leading cause of blindness due to chronic degeneration of retinal ganglion cells and their optic nerve axons. It is associated with disturbed regulation of intraocular pressure, elevated intraocular levels of TGF-β2, aberrant extracellular matrix (ECM) deposition and increased outflow resistance in the trabecular meshwork (TM). The mechanisms underlying these changes are not fully understood. Cell-matrix interactions have a decisive role in TM maintenance and it has been suggested that TGF-β-induced inhibition of matrix metalloproteases may drive aberrant ECM deposition in POAG. Invadopodia and podosomes (invadosomes) are distinct sites of cell-matrix interaction and localized matrix-metalloprotease (MMP) activity. Here, we report on the effects of TGF-β2 on invadosomes in human trabecular meshwork cells. Human TM (HTM) cells were derived from donor tissue and pretreated with vehicle or TGF-β2 (2 ng/ml) for 3d. Invadosomes were studied in ECM degradation assays, protein expression and MMP-2 activity were assessed by western blot and zymography and ECM protein transcription was detected by RT-qPCR. HTM cells spontaneously formed podosomes and invadopodia as detected by colocalization of Grb2 or Nck1 to sites of gelatinolysis. Pretreatment with TGF-β2 enhanced invadosomal proteolysis and zymographic MMP-2 activity as well as MMP-2, TIMP-2 and PAI-1 levels in HTM cell culture supernatants. Rho-kinase inhibition by H1152 blocked the effects of TGF-β2. Concomitant transcription of fibronectin and collagens-1, -4 and -6 was increased by TGF-β2 and fibrillar fibronectin deposits were observed in areas of invadosomal ECM remodelling. In contrast to a current hypothesis, our data indicate that TGF-β2 induces an active ECM remodelling process in TM cells, characterized by concurrent increases in localized ECM digestion and ECM expression, rather than a mere buildup of material due to a lack of degradation. Invadosomal cell adhesion and signaling may thus have a role in POAG pathophysiology.
When aiming at cell‐based therapies in osteoarthritis (OA), proinflammatory conditions mediated by cytokines such as IL‐1β need to be considered. In recent studies, the phytoalexin resveratrol (RSV) has exhibited potent anti‐inflammatory properties. However, long‐term effects on 3D cartilaginous constructs under inflammatory conditions with regard to tissue quality, especially extracellular matrix (ECM) composition, have remained unexplored. Therefore, we employed long‐term model cultures for cell‐based therapies in an in vitro OA environment and evaluated effects of RSV. Pellet constructs made from expanded porcine articular chondrocytes were cultured with either IL‐1β (1–10 ng/ml) or RSV (50 μM) alone, or a cotreatment with both agents. Treatments were applied for 14 days, either directly after pellet formation or after a preculture period of 7 days. Culture with IL‐1β (10 ng/ml) decreased pellet size and DNA amount and severely compromised glycosaminoglycan (GAG) and collagen content. Cotreatment with RSV distinctly counteracted the proinflammatory catabolism and led to partial rescue of the ECM composition in both culture systems, with especially strong effects on GAG. Marked MMP13 expression was detected in IL‐1β‐treated pellets, but none upon RSV cotreatment. Expression of collagen type I was increased upon IL‐1β treatment and still observed when adding RSV, whereas collagen type X, indicating hypertrophy, was detected exclusively in pellets treated with RSV alone. In conclusion, RSV can counteract IL‐1β‐mediated degradation and distinctly improve cartilaginous ECM deposition in 3D long‐term inflammatory cultures. Nevertheless, potential hypertrophic effects should be taken into account when considering RSV as cotreatment for articular cartilage repair techniques.
Articular cartilage is an exceptional connective tissue which by a network of fibrillar collagen and glycosaminoglycan (GAG) molecules allows both low- friction articulation and distribution of loads to the subchondral bone (Armiento et al., 2018, Ulrich-Vinther et al., 2003). Because of its very limited ability to self-repair, chondral defects following traumatic injury increase the risk for secondary osteoarthritis (OA) (Muthuri et al., 2011). Still, current OA treatments such as common nonsteroidal anti-inflammatory drugs (NSAIDs) and joint replacement primarily address end-stage symptoms (Tonge et al., 2014). As low-grade inflammation plays a pivotal role in the pathogenesis of OA (Robinson et al., 2016), there is a strong demand for novel therapeutic concepts, such as integrating application of anti-inflammatory agents into cartilage cell- based therapies in order to effectively treat OA affected joints in early disease stages. The polyphenolic phytoalexin resveratrol (RSV), found in the skin of red grapes, berries, and peanuts, has been shown to have effective anti-inflammatory properties (Shen et al., 2012). However, its long-term effects on 3D chondrocyte constructs cultured in an inflammatory environment with regard to tissue quality have remained unexplored so far. Therefore, in this study, pellets made from expanded porcine articular chondrocytes were cultured for 14 days with either the pro-inflammatory cytokine interleukin-1β (IL-1β) (1 - 10 ng/ml) or RSV (50 μM) alone, or a co-treatment with both agents. Constructs treated with chondrocyte medium only served as control. Treatment with IL-1β at 10 ng/ml resulted in a significantly smaller pellet size and reduced DNA content. However, RSV counteracted the IL-1β-induced decrease and significantly enhanced diameter and DNA content. Also, in terms of GAG deposition, treatment with IL-1β at 10 ng/ml resulted in a tremendous depletion of absolute GAG content and GAG/DNA. Again, RSV co-treatment counteracted the inflammatory stimulus and led to a partial recovery of GAG content. Histological analysis utilizing safranin-O staining confirmed these findings. Marked expression of the cartilage-degrading enzyme matrix metalloproteinase 13 (MMP13) was detected in IL-1β-treated pellets, but none upon RSV co- treatment. Moreover, co-treatment of IL-1β-challenged constructs with RSV significantly increased absolute collagen content. However, under non- inflammatory conditions, RSV induced gene expression and protein accumulation of collagen type X, a marker for undesirable hypertrophy. Taken together, in the present thesis, RSV was demonstrated to elicit marked beneficial effects on the extracellular matrix composition of 3D cartilaginous constructs in long-term inflammatory culture in vitro, but also induced hypertrophy under non-inflammatory conditions. Based on these findings, further experiments examining multiple concentrations of RSV under various inflammatory conditions appear desirable concerning potential therapeutic applicability in OA.
The process of tumor invasion requires degradation of extracellular matrix by proteolytic enzymes. Cancer cells form protrusive invadopodia, which produce and release matrix metalloproteinases (MMPs) to degrade the basement membrane thereby enabling metastasis. We investigated the effect of LASP1, a newly identified protein in invadopodia, on expression, secretion and activation of MMPs in invasive breast tumor cell lines.
By analyzing microarray data of in-house generated control and LASP1-depleted MDA-MB-231 breast cancer cells, we observed downregulation of MMP1, -3 and -9 upon LASP1 depletion. This was confirmed by Western blot analysis. Conversely, rescue experiments restored in part MMP expression and secretion. The regulatory effect of LASP1 on MMP expression was also observed in BT-20 breast cancer cells as well as in prostate and bladder cancer cell lines.
In line with bioinformatic FunRich analysis of our data, which mapped a high regulation of transcription factors by LASP1, public microarray data analysis detected a correlation between high LASP1 expression and enhanced c-Fos levels, a protein that is part of the transcription factor AP-1 and known to regulate MMP expression. Compatibly, in luciferase reporter assays, AP-1 showed a decreased transcriptional activity after LASP1 knockdown.
Zymography assays and Western blot analysis revealed an additional promotion of MMP secretion into the extracellular matrix by LASP1, thus, most likely, altering the microenvironment during cancer progression.
The newly identified role of LASP1 in regulating matrix degradation by affecting MMP transcription and secretion elucidated the migratory potential of LASP1 overexpressing aggressive tumor cells in earlier studies.
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).
Non-contact, Label-free Monitoring of Cells and Extracellular Matrix using Raman Spectroscopy
(2012)
Non-destructive, non-contact and label-free technologies to monitor cell and tissue cultures are needed in the field of biomedical research.1-5 However, currently available routine methods require processing steps and alter sample integrity. Raman spectroscopy is a fast method that enables the measurement of biological samples without the need for further processing steps. This laser-based technology detects the inelastic scattering of monochromatic light.6 As every chemical vibration is assigned to a specific Raman band (wavenumber in cm-1), each biological sample features a typical spectral pattern due to their inherent biochemical composition.7-9 Within Raman spectra, the peak intensities correlate with the amount of the present molecular bonds.1 Similarities and differences of the spectral data sets can be detected by employing a multivariate analysis (e.g. principal component analysis (PCA)).10
Here, we perform Raman spectroscopy of living cells and native tissues. Cells are either seeded on glass bottom dishes or kept in suspension under normal cell culture conditions (37 °C, 5% CO2) before measurement. Native tissues are dissected and stored in phosphate buffered saline (PBS) at 4 °C prior measurements. Depending on our experimental set up, we then either focused on the cell nucleus or extracellular matrix (ECM) proteins such as elastin and collagen. For all studies, a minimum of 30 cells or 30 random points of interest within the ECM are measured. Data processing steps included background subtraction and normalization.
Cell culture models are helpful tools to study inflammatory diseases, like rheumatoid arthritis (RA), osteoarthritis (OA), arteriosclerosis or asthma, which are linked to increased matrix metalloproteinase (MMP) activity. Such cell culture models often focus on the secretion of cytokines and growth factors or the direct effects of disease on tissue destruction. Even though the crucial role of MMPs in inflammatory diseases is known, the results of MMP studies are contradictious and the use of MMPs as biomarkers is inconsistent. MMPs play an important role in disease pathology, as they are involved in elastin degradation in the walls of alveoli in chronic obstructive pulmonary disease (COPD), tumor angiogenesis and metastasis and in cartilage and bone degradation in arthropathies. In RA and OA MMPs are secreted by osteocytes, synoviocytes, and by infiltrating immune cells in response to the increased concentration of inflammatory mediators, like growth factors and cytokines. MMPs are zinc and calcium-dependent proteinases and play an important role in physiological and pathological extracellular matrix (ECM) turn over. Their substrate specificity gives them the ability to degrade all major ECM components, like aggrecan, elastin, gelatin, fibronectin and all types of collagen even the triple helix of collagen monomers. The ECM consists of two large three-dimensional cross-linked macromolecule classes: one are fibrous proteins, like collagen and elastin fibers that are responsible for ECM’s structure, tensile strength, resiliency, reversible extensibility, and deformability and the second class is comprised of proteoglycans composed of glycosaminoglycan (GAG) chains covalently attached to protein cores that are multifunctionally involved in signaling pathways and cell interactions. ECM is present within all tissues and organs and changes in ECM structure contribute to pathogenesis, e.g. wounded and fibrotic tissue, COPD or tumours.
This thesis primarily focuses on the development of a diagnostic peptide system, that enables to gain information on MMP activity from ECM by deploying the isobaric mass encoding strategy. The core element of the developed system is an isotopically labelled peptide sequence (mass tag), that is released in response to elevated levels of MMPs and allows multiplexed detection in tandem mass spectrometry (LC-MS/MS). The mass reporters possess a modular structure with different functionalities. C-terminal either a transglutaminase (TG) recognition sequence or a high molecular weight polyethylene glycol (PEG) moiety was attached to immobilize the mass reporters covalently or physically at the injection site. The following matrix metalloproteinase substrate sequence (MSS) is incorporated in two different versions with different sensitivity to MMPs. The MSS were applied in pairs for relative quantification consisting of the cleavable version synthesized with natural L-amino acids and the non-cleavable D-amino acid variant. The mass tag was synthesized with isotopically labelled amino acids and is separated from the MSS by a UV light-sensitive molecule. N-terminal the mass tag is followed by a tobacco etch virus protease (TEV) sensitive sequence, that is responsible to separate the mass tag from the affinity tag, which was either the Strep-tag II sequence or biotin and were added for purification purposes.
Chapter 1 presents a step-by-step protocol on how to design a mass tag family allowing for multiplexed analysis by LC-MS/MS. The multiplexing is achieved by developing an isobar mass tag family with four family members, which are chromatographically indistinguishable, but due to the mass encoding principles they fragment in distinct y-type ions with a mass difference of 1 or 2 Da each in MS2. Furthermore, it is explained how to covalently attach the mass reporter peptides onto ECM by the activated calcium-catalyzed blood coagulation transglutaminase factor XIII (FXIIIa). The lysine of mass reporter’s TG sequence (D-domain of insulin-like growth factor-I (IGF-I)) and a glutamine in fibronectin are covalently crosslinked by FXIIIa and build an isopeptide bond. Elevated levels of MMP release the mass reporters from ECM by recognizing the inter-positioned MSS.
The designed mass reporters were able to monitor enzyme activity in an in vitro setting with cell-derived ECM, which was shown in Chapter 2. The modular structured mass reporters were investigated in a proof of concept study. First, the different modules were characterized in terms of their MMP responsiveness and their sensitivity to TEV protease and UV light. Then the FXIIIa-mediated coupling reaction was detailed and the successful coupling on ECM was visualized by an immunosorbent assay or confocal laser scanning microscopy. Finally, the immobilized mass reporters on ECM were incubated with MMP-9 to investigate their multiplexing ability of MMP activity. The cleaved mass reporter fragments were purified in three steps and mass tags were analyzed as mix of all four in LC-MS/MS.
Chapter 3 describes the change from an immobilizing system as seen in chapter 1 and 2 to a soluble enzyme activity monitoring system that was applied in an osteoarthritic mouse model. Instead of the immobilizing TG sequence the C-terminal MMS was extended with two amino acids where one holds an azide moiety to perform a strain-promoted azide-alkyne cycloaddition to a high molecular weight dibenzocyclooctyne-polyethylene glycol (DBCO-PEG), which was chosen to retain the mass reporters at the injection site. Furthermore, the N-terminal affinity tag was extended with a 2.5 kDa PEG chain to increase the half-life of the mass reporter peptides after MMP release. The systems biocompatibility was proved but its enzyme monitoring ability in an in vivo setting could not be analyzed as samples degraded during shipping resulting from the Chinese customs blocking transport to Germany.
In summary the diagnostic peptide system was developed in two variants. The immobilized version one from chapter 1 and 2 was designed to be covalently attached to ECM by the transglutaminase-mediated cross-linking reaction. In an in vitro setting the functionality of the mass reporter system for the detection of MMP activity was successfully verified. The second variant comprises of a soluble mass reporter system that was tested in an OA mouse model and showed biocompatibility. With these two designed systems this thesis provides a flexible platform based on multiplexed analysis with mass-encoded peptides to characterize cell culture models regarding their MMP activity, to deploy cell-derived ECM as endogenous depot scaffold and to develop a mass tag family that enables simultaneous detection of at least four mass tags.
Zellmigration ist essentiell für die Invasion und Metastasierung maligner Tumore. Neben der Bewegung von Einzelzellen zeigen Tumore sowohl epithe¬lialen als auch mesenchymalen Ursprungs auch kollektive Migration und Invasion multizellulärer Zellverbände, die sich unter Beibehaltung von Zell-Zell-Adhäsionen koordiniert als Gruppe bewegen. Ziel der Arbeit war, primäre humane Melanomexplantate mittels organotypischer Kultur in 3D Kollagenmatrices einzusetzen, um mittels Zeit-raffermikroskopie und experimentellen Blockadestrategien die zellulären und molekularen Grundlagen kollektiver Migration darzustellen, insbesondere die Bedeutung von Zell-Matrix-Interaktionen und Integrinen. In 3D Explantatkulturen bildeten primäre Melanomexplantate reproduzierbar Invasionszonen und sich ablösende und kollektiv wandernde Zellcluster aus. Diese zeichneten sich durch eine ausgeprägte Polarität mit motiler Vorderfront mit zugartig reorientierten Kollagenfasern und nachgezogenem hinteren Teil der Gruppen aus, vergleichbar der Asymmetrie haptokinetisch migrierender Fibroblasten. β1 Integrine zeigten ein heterogenes Verteilungsmuster mit Fokalisierung an Zell-Matrix-Interaktionen vor allem an der Vorderfront und linearer Anordnung entlang der Zell-Zell-Grenzen. Adhäsionsblockierende anti- β1 Integrin-Antikörper bewirkten nahezu vollständige Hemmung der kollektiven Migration, mit Verlust der Zellgruppenpolarität und Migrationspersistenz. Nach Integrinblockade zerfielen Zellverbände infolge Loslösung von Einzelzellen, die sich mittels β1 Integrin-unabhängiger, amöboider Migration durch die Kollagenmatrix bewegten. Der Übergang von β1 Integrin-abhängiger, kollektiver Migration zu amöboider Einzelzellwanderung (kollektiv-amöboide Transition) ist ein Beispiel für die Plastizität von Tumorzellwanderung, die in Anpassung an das Milieu einen Wechsel der Migrationsstrategie erlaubt. Die Plastizität der Tumorzellmigration muss bei der Entwicklung therapeutischer Konzepte, die auf Hemmung von Tumorinvasion und -metastasierung abzielen, berücksichtigt werden.
Diabetes mellitus is an incurable, metabolic disease, which is associated with severe long-term complications. The in vitro generation of pancreatic β-cells from human induced pluripotent stem cells (hiPSCs) represent a promising strategy for a curative therapy of diabetes mellitus. However, current differentiation strategies largely fail to produce functional β-cells in vitro and require an additional in vivo transplantation to achieve terminal maturation. Previous studies demonstrated a beneficial effect of the extracellular matrix (ECM) on the survival and sustained function of adult, isolated islets of Langerhans. This raises the question whether organ-specific cell-ECM interactions might represent the missing link driving the final stage of β-cell development. In order to address this issue, this study investigated the impact of the pancreas ECM on in vitro β-cell differentiation and its use for the establishment of a pancreatic endocrine organ model.
To this purpose, a pancreas-specific ECM scaffolds (PanMa) was derived from porcine pancreata using whole organ decellularization with Sodium Deoxycholate. In a first step, the generated PanMa was thoroughly characterized using (immuno-) histological stainings, scanning electron microscopy and DNA quantification as well as perfusion and recellularization experiments with endothelial cells. Based on these data, a scoring system (PancScore) for a standardized PanMa generation was developed. Next, the generated PanMa was tested for the presence of tissue-specific ECM features. Therefore, the biophysical and physico-structural characteristics, such as rigidity, porosity and hygroscopy were analyzed using rheological measurements, particle diffusion analyses as well as a water evaporation assay and compared to the properties of ECM scaffolds derived from porcine small intestine (SISser) and lung (LungMa) to examine organ-specific scaffold cues. Following the thorough scaffold characterization, the impact of the PanMa on pluripotency and early development of hiPSC was studied. To this purpose, gene and protein expression of hiPSCs during maintenance culture and spontaneous differentiation on the PanMa were assessed. In a next step, the impact of the PanMa on the pancreatic endocrine differentiation of hiPSCs was tested. Therefore, the PanMa was used as a liquid media supplement or as a solid scaffold during the directed differentiation of hiPSC towards either pancreatic hormone-expressing cells (Rezania et al. 2012; Rezania et al. 2014) or maturing β-cells (Rezania et al. 2014). The impact of the PanMa on the generated cells was examined by gene expression analysis, immunohistochemical staining of important stage markers, as well as glucose stimulated insulin secretion assays. In a last part of this study, the potential of the PanMa for the prolonged culture of hiPSC derived endocrine cells for the establishment of an in vitro organ model of the endocrine pancreas was examined. Therefore, a PanMa-derived hydrogel was generated and used for the encapsulation and culture of hiPSC-derived hormone-expressing cells (HECs). The influence of the PanMa-hydrogel culture was analyzed on gene, protein and functional level by gene expression analysis, immunohistochemical stainings and glucose stimulated insulin secretion.
Whole organ decellularization resulted in the generation of an acellular PanMa scaffold, with low amounts of residual DNA and a preserved ECM micro- and ultrastructure, including important ECM components, such as collagen I, III and IV. Furthermore, the PanMa maintained an intact vessel system and was verified as cytocompatible as demonstrated by the successful recellularization of the arterial system with human endothelial cells. In comparison to SISser and LungMa, the PanMa was characterized as a relative soft, hygroscopic scaffold with a collagen-fiber based structure. Furthermore, the findings indicate that the ECM-specific properties have a relevant effect on the stem cell character and early multi-lineage decisions of hiPSCs. In this regard, maintenance of hiPSCs on the PanMa resulted in a slightly changed expression of pluripotency genes (OCT4, SOX2 and NANOG) and a weak immunohistochemical signal for NANOG protein, indicating a PanMa-dependent impact on hiPSC pluripotency. Strikingly, this presumption was corroborated by the finding that culture on the PanMa promoted an endodermal development of hiPSCs during spontaneous differentiation. In line with that, pancreatic differentiation of hiPSC on both the PanMa and SISser resulted in a significant decrease of glucagon and somatostatin gene expression as well as an unaltered insulin expression, suggesting an ECM-driven suppression of the development of non β-cell endocrine cells. However, this change did not result in an improved glucose stimulated insulin secretion of the generated HECs. Moreover, use of the PanMa as a hydrogel allowed prolonged culture of these cells in a defined culture system. HECs were viable after 21 days of culture, however already showed an altered islet morphology as well as a slightly decreased glucose stimulated insulin secretion.
Altogether, this study demonstrates a relevant biological effect of tissue specific ECM cues on the in vitro differentiation of hiPSCs. More specifically, the data indicate an involvement of the ECM in the endocrine commitment of hiPSC-derived pancreatic cells during directed differentiation highlighting the ECM as an important regulator of pancreatic development. Collectively, these findings emphasize the relevance of the ECM for the fabrication of functional hiPSC-derived cell types and suggest a much stronger consideration of organ specific ECM cues for tissue engineering approaches as well as clinical translation in regenerative medicine.
Development of predictable in vitro tumor models is a challenging task due to the enormous complexity of tumors in vivo. The closer the resemblance of these models to human tumor characteristics, the more suitable they are for drug-development and –testing. In the present study, we generated a complex 3D lung tumor test system based on acellular rat lungs. A decellularization protocol was established preserving the architecture, important ECM components and the basement membrane of the lung. Human lung tumor cells cultured on the scaffold formed cluster and exhibited an up-regulation of the carcinoma-associated marker mucin1 as well as a reduced proliferation rate compared to respective 2D culture. Additionally, employing functional imaging with 2-deoxy-2-[\(^{18}\)F]fluoro-D-glucose positron emission tomography (FDG-PET) these tumor cell cluster could be detected and tracked over time. This approach allowed monitoring of a targeted tyrosine kinase inhibitor treatment in the in vitro lung tumor model non-destructively. Surprisingly, FDG-PET assessment of single tumor cell cluster on the same scaffold exhibited differences in their response to therapy, indicating heterogeneity in the lung tumor model. In conclusion, our complex lung tumor test system features important characteristics of tumors and its microenvironment and allows monitoring of tumor growth and -metabolism in combination with functional imaging. In longitudinal studies, new therapeutic approaches and their long-term effects can be evaluated to adapt treatment regimes in future.
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).
In the last years it became evident that many cytokines do not only bind to their specific cell surface receptors but also interact with components of the extracellular matrix. Mainly in Drosophila, several enzymes were identified, that are involved in glycosaminoglycan synthesis. Mutations in these enzymes mostly result in disturbances of several signaling pathways like hedgehog, wingless, FGF or dpp. In most cases it was, due to these pleiotropic effects, not possible to examine the relevance of matrix interactions for single pathways. The aim of this work was to examine the relevance of matrix interactions for the TGF-ß superfamily member DPP. Based on the fact that DPP is highly homologous to human BMP-2, the basic N-terminus of mature DPP was mutated, which has been shown to contain a heparin-binding site in BMP-2. Thus, a wildtype variant (D-MYC), a deletion variant (D-DEL), which lacked the whole basic part of the N-terminus and a duplication variant (D-DUP), which contained a second copy of the basic core moitiv, were generated. In order to characterise the variants biochemically, they were expressed in E.coli and refolded in a bioactive form. In chicken limbbud assay, the deletion variant was much more active than the wildtype variant, comparable to data of BMP-2. By means of biacore mesurements with the immobilised ectodomain of the high affinity type I receptor thick veins, it could be demonstrated, that the variants differ only in matrix binding and not in their receptor affinity. Different matrix binding was shown by Heparin FPLC. The biological relevance of the matrix interaction of DPP was examined in transgenic flies. To allow expression of the different variants under the control of various Gal4 driver lines, they were cloned behind an UAS-promoter site. In early tracheal development, a strong dependence of DPP signaling on matrix binding was observed. While ectopic expression of the deletion variant caused only minor defects, the branching pattern was strongly disturbed by overexpression of wildtype and duplication variant. Ubiquitous expression of the variants in the wing imaginal disc caused overproliferation of the disc and expansion of the omb target gene expression. The extent of phenotypes correlated with the matrix binding ability of the variants. Corresponding disturbances of the wing vein pattern was observed in adult flies. By the crossing of different dpp allels, transheterozygous animals were created, that lack dpp only in imaginal discs. Expression of the variants under the control of a suitable dpp-Gal4 driver line revealed insights into the biological relevance of matrix binding on DPP gradient formation and specific target gene activation in wing imaginal discs. It was shown, that all variants were able to generate a functional DPP gradient with correct expression of the target genes omb and spalt. Again a correlation between extent of target gene domains and matrix binding ability of the corresponding variants was found. Thus by mutating the N-terminus of DPP, it could be shown that this is responsible for DPP`s matrix interaction. Also the relevance of matrix binding of DPP in different tissues was examined. It turned out, that the reorganisation of tracheal branching by DPP strongly depends on matrix interactions wheras the establishing of a gradient in wing imaginal discs depends only gradually on matrix interactions. Based on these data a model for the action of DPP/TGFßs as morphogens was established. While a deletion of matrix binding leads to a decrease in specific bioactivity of the cytokine, the latter is increased by additional matrix binding sites.
Solid tumors are complex organ-like structures that consist not only of tumor cells but also of vasculature, extracellular matrix (ECM), stromal, and immune cells. Often, this tumor microenvironment (TME) comprises the larger part of the overall tumor mass. Like the other components of the TME, the ECM in solid tumors differs significantly from that in normal organs. Intratumoral signaling, transport mechanisms, metabolisms, oxygenation, and immunogenicity are strongly affected if not controlled by the ECM. Exerting this regulatory control, the ECM does not only influence malignancy and growth of the tumor but also its response toward therapy. Understanding the particularities of the ECM in solid tumor is necessary to develop approaches to interfere with its negative effect. In this review, we will also highlight the current understanding of the physical, cellular, and molecular mechanisms by which the pathological tumor ECM affects the efficiency of radio-, chemo-, and immunotherapy. Finally, we will discuss the various strategies to target and modify the tumor ECM and how they could be utilized to improve response to therapy.
Background: Tumor necrosis factor-like weak inducer of apoptosis (TWEAK) and its receptor fibroblast growth factorinducible 14 (Fn14) are upregulated after myocardial infarction (MI) in both humans and mice. They modulate inflammation and the extracellular matrix, and could therefore be important for healing and remodeling after MI. However, the function of TWEAK after MI remains poorly defined.
Methods and results: Following ligation of the left coronary artery, mice were injected twice per week with a recombinant human serum albumin conjugated variant of TWEAK (HSA-Flag-TWEAK), mimicking the activity of soluble TWEAK. Treatment with HSA-Flag-TWEAK resulted in significantly increased mortality in comparison to the placebo group due to myocardial rupture. Infarct size, extracellular matrix remodeling, and apoptosis rates were not different after MI. However, HSA-Flag-TWEAK treatment increased infiltration of proinflammatory cells into the myocardium. Accordingly, depletion of neutrophils prevented cardiac ruptures without modulating all-cause mortality.
Conclusion: Treatment of mice with HSA-Flag-TWEAK induces myocardial healing defects after experimental MI. This is mediated by an exaggerated neutrophil infiltration into the myocardium.
Die Anpassung des Aktinzytoskeletts an extrazelluläre Gewebsstrukturen ist Voraussetzung für die Interaktion mit der extrazellulären Matrix und für die Zellbewegung, einschließlich der Invasion und Metastasierung von Tumorzellen. Wir untersuchten bei invasiven B16/F1 GFP-Aktin Mausmelanomzellen, ob und wie sich Zellform, Art und Effizienz der Bewegung an physikalisch unterschiedlich beschaffene kollagenöse Umgebungen anpassen: 1) mit Kollagen-Monomeren beschichtete 2D Objektträger, 2) 2D Oberfläche einer fibrillären Kollagenmatrix und 3) Zellen, die in einer 3D Kollagenmatrix eingebettet waren. Zur Darstellung des Aktinzytoskeletts wurden Zellen eingesetzt, die GFP-Aktin Fusionsprotein exprimierten, und mittels Zeitraffer-Videomikroskopie und Konfokalmikroskopie untersucht. Im direkten Vergleich waren Struktur und Dynamik des Aktinzytoskelett wie auch Zellform und Art der Migration unterschiedlich in den verschiedenen Umgebungen. Auf 2D planer Oberfläche erfolgte eine rasche Adhäsion und Abflachung der Zellen (Spreading) mit nachfolgender Migration mit Bildung fokaler Adhäsionszonen, in die kabelartige Aktinstrukturen (Stress fibers) einstrahlten. Dagegen entwickelte sich in 3D Kollagenmatrices eine spindelförmige, fibroblastenähnliche Zellform (mesenchymal) mit zylindrischen fingerförmigen vorderen Pseudopodien, die Zug der Zelle nach vorne bewirken und hochdynamisches polymeres Aktin, nicht jedoch Stress Fibers enthielten. Eine ähnliche Zellform und Struktur des Zytoskeletts entwickelte sich in Zellen auf 2D fibrillärem Kollagen. Die Kontaktfindung und Migrationseffizienz auf oder in fibrillären Matrices war im Vergleich zu 2D kollagenbeschichteter Oberfläche erschwert, die Migrationseffizienz verringert. In Kontrollversuchen wurden Migration und polarisierte Bildung von Aktindynamik durch Inhibitoren des Aktinzytoskeletts (Cytochalasin D, Latrunculin B, Jasplakinolide) stark gehemmt. Diese Befunde zeigen , dass die Struktur und Dynamik des Aktinzytoskeletts sowie die Art der Migration in Tumorzellen stärker als bisher angenommen durch die umgebende Kollagenstruktur bestimmt wird. Während 3D Kollagenmatrices in vivo ähnliche bipolare Zytoskelettstruktur fördern, müssen Abflachung der Zellen mit Bildung von Stress Fibers als spezifische Charakteristika von 2D Modellen angesehen werden.
The mechanisms underlying the cellular response to extracellular matrices (ECMs) that consist of multiple adhesive ligands are still poorly understood. Here, we address this topic by monitoring specific cellular responses to two different extracellular adhesion molecules – the main integrin ligand fibronectin and galectin-8, a lectin that binds β-galactoside residues − as well as to mixtures of the two proteins. Compared with cell spreading on fibronectin, cell spreading on galectin-8-coated substrates resulted in increased projected cell area, more-pronounced extension of filopodia and, yet, the inability to form focal adhesions and stress fibers. These differences can be partially reversed by experimental manipulations of small G-proteins of the Rho family and their downstream targets, such as formins, the Arp2/3 complex and Rho kinase. We also show that the physical adhesion of cells to galectin-8 was stronger than adhesion to fibronectin. Notably, galectin-8 and fibronectin differently regulate cell spreading and focal adhesion formation, yet act synergistically to upregulate the number and length of filopodia. The physiological significance of the coherent cellular response to a molecularly complex matrix is discussed.
This article has an associated First Person interview with the first author of the paper.
Background
Fibrosis poses a substantial setback in regenerative medicine. Histopathologically, fibrosis is an excessive accumulation of collagen affected by myofibroblasts and this can occur in any tissue that is exposed to chronic injury or insult. Transforming growth factor (TGF)-β1, a crucial mediator of fibrosis, drives differentiation of fibroblasts into myofibroblasts. These cells exhibit α-smooth muscle actin (α-SMA) and synthesize high amounts of collagen I, the major extracellular matrix (ECM) component of fibrosis. While hormones stimulate cells in a pulsatile manner, little is known about cellular response kinetics upon growth factor impact. We therefore studied the effects of short TGF-β1 pulses in terms of the induction and maintenance of the myofibroblast phenotype.
Results
Twenty-four hours after a single 30 min TGF-β1 pulse, transcription of fibrogenic genes was upregulated, but subsided 7 days later. In parallel, collagen I secretion rate and α-SMA presence were elevated for 7 days. A second pulse 24 h later extended the duration of effects to 14 days. We could not establish epigenetic changes on fibrogenic target genes to explain the long-lasting effects. However, ECM deposited under singly pulsed TGF-β1 was able to induce myofibroblast features in previously untreated fibroblasts. Dependent on the age of the ECM (1 day versus 7 days’ formation time), this property was diminished. Vice versa, myofibroblasts were cultured on fibroblast ECM and cells observed to express reduced (in comparison with myofibroblasts) levels of collagen I.
Conclusions
We demonstrated that short TGF-β1 pulses can exert long-lasting effects on fibroblasts by changing their microenvironment, thus leaving an imprint and creating a reciprocal feed-back loop. Therefore, the ECM might act as mid-term memory for pathobiochemical events. We would expect this microenvironmental memory to be dependent on matrix turnover and, as such, to be erasable. Our findings contribute to the current understanding of fibroblast induction and maintenance, and have bearing on the development of antifibrotic drugs.
Biofabrication, including printing technologies, has emerged as a powerful approach to the design of disease models, such as in cancer research. In breast cancer, adipose tissue has been acknowledged as an important part of the tumor microenvironment favoring tumor progression. Therefore, in this study, a 3D-printed breast cancer model for facilitating investigations into cancer cell-adipocyte interaction was developed. First, we focused on the printability of human adipose-derived stromal cell (ASC) spheroids in an extrusion-based bioprinting setup and the adipogenic differentiation within printed spheroids into adipose microtissues. The printing process was optimized in terms of spheroid viability and homogeneous spheroid distribution in a hyaluronic acid-based bioink. Adipogenic differentiation after printing was demonstrated by lipid accumulation, expression of adipogenic marker genes, and an adipogenic ECM profile. Subsequently, a breast cancer cell (MDA-MB-231) compartment was printed onto the adipose tissue constructs. After nine days of co-culture, we observed a cancer cell-induced reduction of the lipid content and a remodeling of the ECM within the adipose tissues, with increased fibronectin, collagen I and collagen VI expression. Together, our data demonstrate that 3D-printed breast cancer-adipose tissue models can recapitulate important aspects of the complex cell–cell and cell–matrix interplay within the tumor-stroma microenvironment