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Molecular oxygen (O2) is essential for numerous metabolic processes. Not surprisingly, hypoxia and the resulting adaptations play a pivotal role in pathophysiology, e.g., in cancer or in inflammatory diseases. Of note, myeloid cells are known to accumulate in hypoxic regions such as tumor cores or rheumatoid arthritis joints and may contribute to disease progression. While most studies so far concentrated on transcriptional adaptation by the hypoxia-inducible factors (HIF) 1 and 2 under short term hypoxia, prolonged oxygen deprivation and alternative post-transcriptional regulation are rather poorly investigated.
Consequently, the aim of the study was to generate a comprehensive overview of mRNA de novo synthesis and degradation and its contribution to total mRNA changes in monocytic cells in the course of hypoxia.
To this end, I used thiol-linked alkylation for the metabolic sequencing of RNA (SLAM-Seq) to characterize RNA dynamics under hypoxia. Specifically, I labeled monocytic THP-1 cells under normoxia (N), acute hypoxia (AH; 8 h 1% O2), or chronic hypoxia (CH; 72 h 1% O2) with 4-thiouridine (4sU), which allows for transcriptome-wide identification of de novo synthesized mRNAs and estimation of their half-lives. Total mRNA expression analyses revealed that most changes occurred under CH. Considering that HIF accumulation and resulting transcriptional regulation was shown to decline again under CH, I further analyzed the impact of RNA stability on gene expression. I observed a global reduction in RNA half-lives under hypoxia, indicative for the attenuation of energy-consuming protein synthesis upon oxygen deprivation. Moreover, I observed a subgroup of hypoxic destabilized transcripts with resulting decreased mRNA expression under CH, which consisted of 59 nuclear-encoded mitochondrial mRNAs. This might prevent futile production of new mitochondria under conditions, where mitochondria are even actively degraded to prevent production of detrimental reactive oxygen species.
While stability-regulated transcripts were mainly destabilized under hypoxia, the vast majority of differentially de novo synthesized transcripts were upregulated.
Functional analyses revealed not only hypoxia, but also cholesterol homeostasis and inflammatory response as top enriched terms, corroborating findings on total mRNA level. Focusing on hypoxia-altered cholesterol metabolism, I observed an 9 accumulation of early and a decrease in late cholesterol precursors, which are separated by several oxygen-dependent enzymatic steps. Although total cholesterol levels were only slightly reduced, my data indicate locally lowered endoplasmic reticulum (ER) cholesterol levels under hypoxia, which cause feedback activation of the ER cholesterol-sensing transcription factor sterol regulatory element-binding protein 2 (SREBP2) and induction of cholesterol biosynthesis enzymes. Interestingly, a broad range of interferon-stimulated genes (ISGs), mainly known for their antiviral function, was also induced under hypoxia with similar kinetics as SREBP2 targets, suggesting an immunometabolic crosstalk. While the availability of certain cholesterol biosynthesis intermediates as well as a direct involvement of SREBP2 seemed rather unlikely to cause hypoxic ISG induction, changes in intracellular cholesterol distribution appeared crucial for the hypoxic induction of chemokine-ISGs. Mechanistically, I found that MyD88-dependent toll-like receptor 4 (TLR4) signaling contributes to enhanced hypoxic ISG induction, likely sensitized by changes in cholesterol dynamics. Importantly, hypoxia amplified induction of chemokine-ISGs in monocytes upon treatment with severe acute respiratory syndrome coronavirus type 2 (SARS-CoV-2) spike protein via TLR4 similarly as after addition of infectious virus, which might contribute to systemic inflammation in hypoxemic patients with severe coronavirus disease-2019 (COVID-19).
Taken together, I comprehensively analyzed RNA dynamics in hypoxic monocytes. Specifically, I identified RNA stability as a modulating mechanism to limit production of mitochondria under oxygen-restricted conditions. Moreover, I characterized the immunometabolic crosstalk between disturbed cholesterol homeostasis and spontaneous induction of interferon (IFN)-signaling in hypoxic monocytes, which might contribute to systemic inflammation in severe cases of COVID-19.
Acute and chronic inflammation play a pivotal role in various diseases, such as rheumatoid arthritis, atherosclerosis, bacterial as well as viral infections and therefore are an everyday-challenge in clinical practice. In this context, biologically active products of the cyclooxygenases and the prostanoid synthases, e.g. prostaglandins, critically contribute to various aspects of the inflammatory response in almost every tissue of the body. Emerging evidence over the past decades has demonstrated that these mediators are not only responsible for a pro-inflammatory response, but also show anti-inflammatory and pro-resolving properties. The relevance of biologically active lipids in this context is strengthened by the clinical efficacy of nonsteroidal anti-inflammatory drugs (NSAIDs), e.g. Aspirin®, which block the biosynthesis of the mediators via the cyclooxygenase (COX) enzymes. Notably, microsomal prostaglandin E synthase-1 (mPGES-1)-derived prostaglandin E2 (PGE2) is a well-studied, functionally versatile PG, which promotes its effects via specific G protein-coupled receptors (GPCRs). Activation of these receptors elicits an internal signal transduction cascade, including activation of the adenylyl cyclase (AC). Active AC contributes to an elevated intracellular cyclic adenosine monophosphate (cAMP) level, which in turn activates the transcription factor cAMP response element-binding protein (CREB) via phosphorylation.
While the role of PGE2 in the inflammatory context has been well-documented in previous literature, relatively little is known about CREB-dependent transcriptional changes in inflammation. Therefore, the aim of this study was to investigate the effect of mPGES-1-derived PGE2 on CREB-mediated transcriptional changes specifically in murine wild-type (WT) and mPGES-1 knock-out (KO) macrophages in an inflammatory context. To address this issue, bone marrow-derived macrophages (BMDMs) were treated with either the bacterial cell wall component lipopolysaccharide (LPS) in combination with interferon-γ (IFN-γ) or the yeast extract zymosan. To analyze effects on CREB activation we determined protein expression profiles of relevant PGE2-synthesizing enzymes, i.e. COX-2 and mPGES-1, as well as activity of the downstream transcription factor CREB. The activity of mPGES-1 was simultaneously determined by the analysis of the prostanoid kinetics. Under these experimental conditions we showed that COX-2 is strongly induced, and we also observed elevated activated CREB levels in WT as well as in mPGES-1 KO macrophages. Further, both LPS+IFN-γ and zymosan increased expression of mPGES-1 in WT but not in mPGES-1-deficient macrophages. These findings go in hand with largely similar alterations in the PGD2, TXB2, PGF2α profiles in WT and mPGES-1 KO macrophages upon stimulation. Of note, an elevated PGE2 production was also observed in mPGES-1-deficient macrophages at later stages upon inflammatory conditions. Subsequently, potential CREB-regulated targets were identified in macrophages upon inflammatory stimuli after 16 h by chromatin immunoprecipitation (ChIP) followed by Next-Generation-Sequencing (NGS). Surprisingly, despite equal levels of pCREB the characterization of CREB binding sites revealed different targetome profiles between WT and mPGES-1 KO macrophages. Specifically, the fatty acid metabolic processes-associated targets appeared to be selectively lost in mPGES-1-deficient vs. WT macrophages. We further validated one of those targets, i.e. the endoplasmic reticulum lipid raft-associated protein 1 (Erlin1), at the mRNA expression level, which indeed was differentially transcribed in response to different PGE2 synthesizing conditions.
Mechanistically, CREB is a well-characterized phosphorylation-dependent transcription factor in cell survival, proliferation, differentiation, and immune responses. Yet, our understanding of the functions of CREB in inflammation, specifically with respect to its activation by PGE2, is insufficient. Due to its biological relevance in inflammation it clearly requires additional studies to shed light on the details of CREB activation in macrophages to provide possibilities of therapeutic interventions.
Krebs ist und wird voraussichtlich auch in näherer Zukunft eine der häufigsten Todesursachen weltweit bleiben. Trotz vielversprechenden Fortschritten in Therapeutik und Diagnostik bedarf es noch weiterer Forschung, um die vielfältigen molekularen Mechanismen zu entschlüsseln, welche dem Verlauf von malignen Tumorerkrankungen bestimmen und zu beeinflussen vermögen. Das RNA-Bindeprotein Hu antigen R (HuR) reguliert Genexpression auf posttranskriptioneller Ebene, indem es durch Bindung an Ziel mRNAs Einfluss auf deren Abbau, Lokalisation oder Translationseffizienz nimmt. Darüber hinaus zeigte sich in den letzten Jahren, dass HuR diese Prozesse auch indirekt durch Interaktion mit regulatorischen RNAs beeinflusst. In Krebszellen lässt sich häufig eine erhöhte Aktivität von HuR beobachten, welche in Verbindung mit verschiedenen tumorigenen Prozessen gebracht wird. Unter anderem trägt HuR zur Deregulation des Zellzyklus bei, indem es die Expression der Cycline A2, B1, D1 und E1 erhöht. Weiterhin unterstützt HuR das Tumorwachstum durch Regulation von proangiogenen Faktoren wie VEGF, IL8 und COX2. Da HuR generell eine prominente Rolle bei der Regulation von Immunantworten, sowohl in Immunzellen selbst als auch in solidem Gewebe einnimmt, wurde HuR in der Vergangenheit häufig auch mit der Ausbildung des inflammatorischen Tumormikromilieus in Verbindung gebracht, jedoch ist die Datenlage in dieser Hinsicht bis heute uneindeutig. Obwohl eine Großzahl an Zytokinen und inflammatorischen Faktoren prinzipiell als HuR Zielgene beschrieben sind, gibt es nur für die wenigsten dieser Proteine entsprechende Untersuchungen in Tumorzellen.
Ziel dieser Arbeit war es, den Einfluss von HuR in Tumoren auf die Rekrutierung von Makrophagen zu evaluieren. Hierfür bot sich als in vitro Modell die Brustkrebszelllinie MCF-7 an, da diese unter entsprechenden Kultivierungsbedingungen dreidimensionale Sphäroide bildet. Solch ein Sphäroidmodell bietet sich als Kompromiss zwischen der klassischen zweidimensionalen Zellkultur an, welche zwar höchst artifiziell, jedoch leicht zu handhaben und zu kontrollieren ist, und den physiologischeren, aber gleichzeitig experimentell unzugänglicheren und speziesfremden Tiermodellen. Mittels lentiviraler Transduktion wurde ein small hairpin RNA (shRNA) vermittelter stabiler Knockdown von HuR in MCF-7 erzielt, welcher zu vermindertem Zellwachstum führte, jedoch keinen weiteren Einfluss auf die Bildung von Sphäroiden hatte. Um die initiale Suche nach HuR-regulierten, potenziell relevanten Faktoren möglichst breit und unvoreingenommen zu halten, wurde die Expression von 174 Zytokinen in Wildtyp- und HuR-knockdown Sphäroiden mittels eines Protein Arrays untersucht. Überraschenderweise zeigte der Großteil der veränderten Proteins einen negativen Zusammenhang mit HuR, welches eigentlich eher als positiv regulierendes Protein beschrieben ist. Bemerkenswerterweise befand sich unter den mit am stärksten regulierten Faktoren das Chemokin CCL5 (auch RANTES genannt), welches einerseits als einer der beiden zentralen Faktoren für die Makrophageninfiltration in Brustkrebs gilt, andererseits bisher noch nicht in Verbindung mit HuR gebracht wurde.
Im Folgenden untersuchte ich zuerst den mechanistischen Hintergrund dieser Regulation. Da diese sich auch in adhärenten Zellrasen zeigte, wechselte ich für die entsprechenden Experimente zu zweidimensionaler Zellkultur. Eine negative regulatorische Funktion von HuR wird meist in Verbindung mit verminderter Translation von Zielfaktoren gebracht. Da die mRNA Level von CCL5 dem Effekt auf Proteinebene entsprachen, konnten entsprechende Mechanismen als Grund für die veränderten CCL5 Level ausgeschlossen werden. Desweiteren blieb die mRNA Stabilität ungeachtet der HuR Level konstant; dabei zeigte sich zudem, dass mRNA Abbau generell keinen relevanten Einfluss auf die Expression von CCL5 in MCF-7 hatte. Da diese Ergebnisse auf eine transkriptionelle Regulation hindeuteten, untersuchte ich im Folgenden den Einfluss von HuR auf die Promoteraktivität von CCL5. Hierfür isolierte ich zunächst die CCL5-Promoterregion aus genomischer DNA von MCF-7 Zellen und inserierte diese dann in einen zuvor promoterlosen Luciferase-Expressionsvektor. In den folgenden Reporteranalysen zeigte sich, dass HuR tatsächlich einen negativen Einfluss auf die Promoteraktivität von CCL5 ausübt. Durch sukzessive Verkürzung ließ sich der entscheidende DNA-Bereich auf die letzten 140 Nukleotide vor dem Transkriptionsstartpunkt eingrenzen. Dieser Bereich enthält vier prominente und sehr gut charakterisierte regulatorische Abschnitte: zwei benachbarte NF-κB Bindestellen sowie je ein Interferon-stimulated Response Element (ISRE) und ein C/EBPβ Erkennungsmotiv. Während das C/EBP Element keine funktionelle Relevanz in den Reporteranalysen hatte, reduzierte sich durch Deletion sowohl der ISRE als auch der NF-κB Elemente die Promoteraktivität um mehr als 50%, allerdings nur im ISRE-Deletionskonstrukt unter Nivellierung des HuR-abhängigen Unterschiedes. Somit ließ sich der Einfluss von HuR auf die CCL5 Promoteraktivität vollständig und ausschließlich auf das ISRE zurückführen. Im Gegensatz zu dem in Tumorzellen häufig basal überaktiven NF-κB Signalweg sind die kanonischen, ISRE-assoziierten Typ I Interferon Signalkaskaden und ihre vermittelnden Transkriptionsfaktoren, die sogenannten Interferon Regulatory Factors (IRFs) nicht konstitutiv überaktiviert. Eine Sonderstellung nehmen dabei die Faktoren IRF1 und IRF2 ein, da sie, für Proteine abseits der Stimulus-getriebenen ISRE-Interferon Achse, auch als konstitutive Transkriptionsfaktoren beschrieben sind, wobei IRF2 in diesem Kontext als IRF1-Antagonist und somit Transkriptionsrepressor fungiert. Überraschenderweise ließ sich mittels Chromatin Immunopräzipitation eine Assoziation von IRF1 mit dem CCL5 Promoter nur in Wildtyp-, jedoch nicht in HuR-knockdown Zellen nachweisen. Im Gegensatz dazu ergaben mRNA Expressionsanalysen der Tumor-relevanten IRFs, dass die CCL5 Induktion in HuR-depletierten Zellen mit einer allgemeinen, jedoch niedrigschwelligen Erhöhung von Typ I Interferon-assoziierten Signalen einhergeht. Interessanterweise korrelierte Interferon β zwar mit CCL5 auf mRNA Ebene, jedoch hatte eine Blockade des Interferon-α/β Rezeptors in HuR-depletierten Zellen keinen akuten Effekt auf CCL5. Umgekehrt zeigte sich auch keine erhöhten CCL5 Level in Wildtypzellen unter Kokultur mit HuR-knockdown Zellen, wie es bei parakriner Induktion durch Interferon β zu erwarten wäre. Ebenso konnte alternatives ISRE Signaling durch einen Komplex aus unphosphoryliertem Stat1 und IRF9, wie es in vitro unter länger anhaltender Niedriglevel Exposition mit Interferon β beobachtet wurde, ausgeschlossen werden. Um sicher zu stellen, dass diese Erhöhung kein sequenzabhängiges off-target Artefakt ist, wie es in der Vergangenheit für einzelne small hairpin RNAs (shRNAs) beobachtet wurde, wurde eine entsprechende Aktivierung von IRF3 und damit des IRF3/IRF7 Aktivierungsweges untersucht und ausgeschlossen. Zusätzlich konnte durch Tests unterschiedlicher shRNA Sequenzen sowie Zellsysteme demonstriert werden, dass die CCL5 Aktivierung tatsächlich ein spezifischer und in einer größeren Bandbreite an Krebszelllinien unterschiedlicher Herkunft, darunter Brust- und Lungenkarzinom, Glioblastom- sowie Melanom- Zelllinien, reproduzierbarer Effekt von HuR-Defizienz ist.
Da CCL5 als eines der zentralen Chemokine bei der Rekrutierung von Monozyten/Makrophagen in Tumore beschrieben ist, stellte sich die Frage, ob HuR mit diesem Vorgang in Verbindung zu bringen ist. Brusttumore weisen oft eine hohe Zahl von Tumor-assoziierten Makrophagen auf, welche von eingewanderten Blutmonozyten abstammen. Ein Einfluss von HuR auf diesen Vorgang in vitro konnte mittels einer Kokultur von Sphäroiden mit zuvor frisch aus Humanblut isolierten Primärmonozyten nachgewiesen werden. Hierbei wiesen HuR-knockdown Sphäroide trotz ihres geringeren Durchmessers eine erhöhte Anzahl von Monozyten/Makrophagen auf. Da sich in diesen Zellen weder Proliferation noch relevante Apoptose zeigte, ließ sich die erhöhte Anzahl auf verstärkte Einwanderung in das Sphäroid zurückführen. Hierbei erwies sich der direkte Zellkontakt zwischen Monozyten und Tumorzellen als erforderlich, da Monozyten keine unterschiedliche Chemotaxis gegenüber entsprechenden Sphäroidüberständen zeigten. Dass die erhöhte Infiltration in HuR-defizienten Sphäroiden tatsächlich auf CCL5 zurückzuführen ist, konnte in Kokulturexperimenten durch Inhibierung von CCL5 gezeigt werden. Unterstütztend wurde ein Zusammenhang zwischen HuR, CCL5 und Tumor assoziierten Makrophagen in silico unter Zuhilfenahme des TCGA Datensets für Estrogenrezeptor-positive Brusttumore untersucht. Im Einklang mit meinen Ergebnissen zeigte sich eine negative Korrelation zwischen HuR und CCL5. Außerdem ließ sich ein negativer Zusammenhang zwischen HuR und einer Makrophagensignatur feststellen, während CCL5 wie erwartet mit dieser Signatur positiv korrelierte.
Zusammenfassend zeigte sich in dieser Arbeit, dass HuR eine Rolle bei der zellulären Zusammensetzung des inflammatorischen Tumor-Mikromilieus spielt. Der Verlust von HuR in Tumorzellen führte zu einer erhöhten Expression des Chemokins CCL5. Dies ließ sich in Brust- und Lungenkarzinom-, Glioblastom- sowie Melanom- Zelllinien beobachten. In Brustkrebszellen zeigte sich, dass diese Regulation auf verstärkte Transkription, vermittelt durch ein ISRE innerhalb des CCL5 Promoters, zurückzuführen ist. Funktionell konnte die erhöhte CCL5 Produktion in HuR-defizienten Tumorsphäroiden in Verbindung mit verstärkter Infiltration von Monozyten/Makrophagen gebracht werden. Unterstützend zeigte sich auch bei einer in silico Analyse von Estrogenrezeptor-positiven Brusttumoren eine negative Korrelation zwischen HuR und CCL5, was mit einer entsprechend veränderten Makrophagensignatur einherging. Im Hinblick auf derzeit diskutierte Ansätze, das Wachstum von Tumoren mittels HuR Blockade zu inhibieren, sind meine Ergebnisse potenziell von therapeutischer Relevanz. Basierend auf meiner Arbeit sollte dabei in zukünftigen Studien näher untersucht werden, wie sich Inhibierung von HuR in Tumoren auf die Zusammensetzung und Funktion des Tumormikromilieus auswirkt und daraus resultierende Effekte auf das Tumorwachstum in Relation zu der allgemein wachstumsfördernden Rolle von HuR in Tumorzellen gesetzt werden.
Obesity is considered as a type of chronic inflammation. It enhances the risk of developing cardiovascular disease, diabetes, and some cancers. The key players in the induction of inflammation in adipose tissue are macrophages. However the mechanism of macrophage activation in obese fat tissue is still not fully understood. Elevated level of saturated fatty acids in adipose tissue promotes inflammation and insulin resistance. Exposure of macrophages to saturated fatty acids stimulates pro-inflammatory c-Jun N-terminal kinase (JNK), nuclear factor kappa B (NF-kB) signaling, and production of pro-inflammatory cytokines, such as IL-6, IL-8, IL-1β, and TNFα. Palmitate is a major saturated free fatty acid released by adipocytes. It activates inflammatory pathways through Toll-like receptors (TLR) 2 and 4, provokes endoplasmic reticulum (ER) stress and increases levels of diacylglycerols (DAGs) and ceramides. Saturated fatty acids also affect cellular oxidative metabolism. Thus, mitochondrial fatty acid oxidation reduces ER-stress and expression of inflammatory cytokines in palmitate-treated macrophages. On the other hand mitochondrial reactive oxygen species (ROS) promote palmitate-mediated pro-inflammatory cytokine production. Recently, mitochondrial functions were linked to their morphology. Mitochondrial fission has been reported in β-cells and myocytes in response to high levels of glucose and free fatty acids, and was associated with disruption of mitochondrial functions, increased ROS level, and cell death. The aim of this study was to investigate the role of mitochondrial fragmentation in palmitate-induced inflammation in human macrophages. In our settings fatty acids, independently of their saturation, affected mitochondrial morphology. Mixtures of long chain saturated and unsaturated fatty acids as well as triglyceride-rich lipoprotein lipolysis products promoted mitochondrial fission. Mitochondrial fragmentation in palmitate-treated macrophages revealed a time- and concentration-dependent character, and was reversible upon palmitate removal. This observation, together with unaltered levels of mitochondrial protein and DNA content, and intact mitochondrial respiration, suggested that mitochondria were not damaged and were functionally active. Mechanistically, palmitate-induced mitochondrial fragmentation was not regulated by ER stress or loss of mitochondrial membrane potential. However, inhibition of palmitate incorporation into mitochondrial membrane phospholipids decreased mitochondrial fragmentation. Other approach to prevent mitochondrial fission was the inhibition of dynamin-related protein 1 (DRP1) activity, which drives mitochondrial fission by forming ring- like structures around mitochondria and constricting mitochondrial membranes. Palmitate altered mitochondrial membrane lipid composition and promoted DRP1-oligomerization. The inhibition of palmitate-induced mitochondrial fragmentation enhanced mitochondrial ROS production, c-Jun phosphorylation, and upregulated expression of pro-inflammatory cytokines. Taken together, these results suggest that mitochondrial fragmentation is a protective mechanism attenuating palmitate-induced inflammatory responses. Future experiments will be required to investigate the role of mitochondrial fragmentation in obesity-associated diseases in vivo.
Disturbances in lipid metabolism are responsible for many chronic disorders, such as type 2 diabetes and atherosclerosis. Regulation of lipid metabolism occurs by activated transcription factors peroxisome proliferator-activated receptor δ (PPARδ) and liver X receptor α (LXRα) mediating transcription of different target genes involved in regulation of fatty acid uptake and oxidation or cellular cholesterol homeostasis. This is especially relevant for the macrophages, since pathways regulated by PPARδ and LXRα affect foam cell formation, a process driving the progression of atherosclerotic lesion. AMP-activated protein kinase (AMPK) plays a central role in energy homeostasis in every type of eukaryotic cell, but its role in human macrophages, particularly with regard to lipid metabolism, is not precisely defined yet. Thus, I investigated the impact of AMPK activity on PPARδ and LXRα and the expression of their target genes involved in fatty acid oxidation (FAO) and cholesterol metabolism.
As PPARδ has been described as a potential target for prevention and treatment of several disorders and AMPK as interesting drug target for diabetes and metabolic syndrome, the aim of the first part of my studies was to investigate their interaction in primary human macrophages. Completing the first challenge successfully, I was able to establish a lentiviral transduction system for constitutively active AMPK (consisting of a truncated catalytic AMPKα1 subunit bearing an activating T198D mutation) in primary human macrophages.
Using genome-wide microarray analysis of gene expression, I demonstrate FAO as the strongest affected pathway during combined AMPKα1 overexpression and PPARδ activation.
The most influenced genes were validated by quantitative PCR as well as by Western analysis. I found that AMPK increases the expression of FAO-associated genes targeted by PPARδ. Corroborating the results obtained using AMPKα1 overexpression, PPARδ target gene expression was increased not only by PPARδ agonist GW501516, but also by pharmacological allosteric AMPK activator A-769662. Additional enhancement of target gene mRNA expression was achieved upon co-activation of PPARδ and AMPK. Silencing PPARδ expression increased basal expression of target genes, confirming the repressive nature of ligand-free PPARδ, abolishing the increased target gene expression upon AMPK or PPARδ activation. Measurements of triglyceride contents of human macrophages incubated with VLDL following PPARδ activation demonstrated a reduction of intracellular triglyceride accumulation in cells, which may reflect the enhancement of fat catabolism.
In the second part of my studies, I concentrated on the regulation of cholesterol transporter ATP-binding cassette transporter A1 (ABCA1) expression by AMPK. ABCA1 facilitates
cholesterol efflux from macrophages thus, preventing atherosclerosis progression. For the first time, AMPK implication in the regulation of the ABCA1 pathway could be presented. Both AMPK overexpression and activation lead to significantly increased ABCA1 expression, whereas AMPKα1 knock-down strongly reduced this effect. Besides, I was able to prove an enhanced activity of ABCA1 during AMPK activation in human THP-1 macrophages by measuring cholesterol efflux into apolipoprotein AI-containing medium.
Previous findings showed regulation of ABCA1 by LXRα. I confirmed these results by silencing experiments indicating an essential role of LXRα in ABCA1 regulation pathway.
Here, ABCA1 mRNA as well as protein expression were positively mediated by LXRα. LXRα activation elevated ABCA1 levels, whereas its silencing down-regulated this effect.
Interestingly, ABCA1 was found to be regulated only by LXRα and not through LXRα. At the same time, knock-down of PPARδ, -γ or -δ, which may be also involved in the regulation of LXR/ABCA1 axis, did not influence the activation of ABCA1 expression by an AMPK activator. To confirm that LXRE on Abca1 promoter is essential for ABCA1 regulation, I performed luciferase reporter assay using constructs based on Abca1 promoter with or without LXRE mutation. Mutation of LXRE abolished reporter activity, whereas AMPK activation increased luciferase activity of wild-type LXRE construct. Furthermore, I demonstrate AMPK-dependent LXRα binding to the LXRE site of Abca1 promoter using the method of chromatin immunoprecipitation. AMPK activation significantly increased, whereas silencing of AMPK significantly attenuated LXRα binding, indicating AMPK as one of the most important regulators of ABCA1 expression.
In summary, I provided an evidence for AMPK involvement into lipid and cholesterol metabolism in human macrophages showing the regulation of PPARδ and LXRα target genes. The understanding of AMPK and PPARδ interaction allows the development of new approaches for treatment of metabolic syndrome and related diseases. Increased FAO during the activation of both proteins may exhibit better therapeutic benefit. On the other hand, I have shown the impact of AMPK activation on ABCA1 via LXRα up-regulation leading to increased cholesterol efflux in human macrophages for the first time. These findings thus may impact future improving of anti-atherosclerosis therapies.
Immune cells are key players in several physiological and pathophysiological events such as acute and chronic inflammation, atherosclerosis and cancer. Especially in acute inflammation, macrophages are indispensable for the switch from the acute inflammatory phase to the resolution phase. Not only the phagocytosis of apoptotic cells, but especially the surrounding cytokines and mediators are able to switch macrophage polarization from inflammatory- to anti-inflammatory phenotypes. Within this cytokine environment, sphingosine-1-phosphate (S1P) plays an important role for immune cell activation, polarization and migration.
Tumor development usually follows predictable paths where tumor cells acquire common characteristics and features known as the hallmarks of cancer. Recently, additional characteristics have been added to these hallmarks since solid tumors are composed of a very heterogeneous population of transformed, formerly normal tissue cells and stromal cells, e.g. immune cells and fibroblasts. Compelling evidence suggests that stromal cells and tumor cells maintain a symbiotic relationship to build up the tumor microenvironment and to fuel tumor growth. In cancer therapies, common features of tumors such as unrestricted cell growth, suppression of immunological responses, and the ability to form new blood vessels (angiogenesis) have emerged as the main targets of interest. The lipid mediator prostaglandin E2 (PGE2) is known to promote all these features and thus, is connected to cancer progression in general. Its synthesis is triggered in response to stress factors or during inflammation. Inducible PGE2 production relies on the enzymes cyclooxygenase 2 (COX-2) and microsomal prostanglandin E synthase 1 (mPGES-1), which are simultaneously expressed in response to a variety of different stimuli and are functionally coupled. Inhibition of COX-2 with non-steroidal antiinflammatory drugs (NSAIDs) for cancer treatment is, however, limited by cardiovascular risks, since selective COX-2 inhibition disrupts the prostacyclin/thromboxane balance. Therefore targeting mPGES-1 downstream of COX-2 for PGE2 inhibition was evaluated in this work in different steps of carcinogenesis. Knockdown of mPGES-1 in DU145 prostate cancer cells revealed that the mPGES-1 status did not affect growth of monolayer tumor cells, but significantly impaired 3D growth of multi-cellular tumor spheroids (MCTS). Spheroid formation induced COX-2 in DU145 and other prostate cancer spheroids. High levels of PGE2 were detected in supernatants of DU145 MCTS as opposed to monolayer DU145 cells. Pharmacological inhibition of COX-2 and mPGES-1 confirmed the pivotal role of PGE2 for DU145 MCTS growth. Besides promoting spheroid growth, MCTS-derived PGE2 also inhibited cytotoxic T lymphocyte (CTL) activation. When investigating the mechanisms of COX-2 induction during spheroid formation, the typical tumor microenvironmental factors such as glucose deprivation, hypoxia or tumor cell apoptosis failed to enhance COX-2. Interestingly, when interfering with apoptosis in DU145 spheroids, the pan-caspase inhibitor Z-VAD-FMK triggered a Summary 12 shift towards necrosis, thus enhancing COX-2 expression. Coculturing viable DU145 monolayer cells with isolated heat-shocked-treated necrotic DU145 cells, but not with necrotic cell supernatants, induced COX-2 and PGE2, confirming the impact of necrosis for MCTS growth and CTL inhibition. As mentioned, in vivo tumors are very heterogenous mixtures of tumor cells and stromal cells e.g. immune cells. Hence, the interaction of the immune system with tumors was investigated in further experiments. When coculturing MCF-7 breast cancer spheroids with human peripheral blood mononuclear cells (PBMCs), only low levels of PGE2 were detected, since MCF-7 cells did not upregulate COX-2 during spheroid formation and did not induce PGE2 production by PBMCs. Under inflammatory conditions, by adding the toll-like receptor 4 (TLR4) agonist lipopolysaccharide (LPS) to cocultures, PGE2 production was triggered, spheroid sizes were reduced, and numbers of high levels of granzyme B expressing (GrBhi) CTLs were increased, while CD80 expression by tumor-associated phagocytes was also elevated. Inhibition of CD80 but not CD86 diminished numbers of GrBhi CTLs and attenuated spheroid lysis. To determine the role of ctivation-induced PGE2 production, use of the COX-2 inhibitor celecoxib and the experimental mPGES-1 inhibitor C3 further increased CD80 expression. Addition of PGE2, the prostaglandin E2 (EP2) receptor agonist butaprost, and the phosphodiesterase 4 (PDE4) inhibitor rolipram reduced LPS/C3-triggered CD80 expression, confirming the impact of COX- 2/mPGES-1-derived PGE2 on shaping phagocyte phenotypes in an EP2/cAMP-dependent manner. In a spontaneous breast cancer model (MMTV-PyMT), mPGES-1-deficiency significantly delayed tumor growth in mice, confirming an overall protumorigenic role of mPGES-1 in breast cancer development in vivo. However in tumors of mPGES-1-/- mice, tumor-infiltrating phagocytes expressed low levels of CD80 similar to their wildtype counterparts. These data suggest that the immunosuppressive microenvironment does not allow for immunostimulatory effects by mPGES-1 inhibition without an activating stimulus. Evidences in this study recommend the application of mPGES-1 inhibitors for treating cancer diseases, since mPGES-1 promotes tumor growth in multiple steps of carcinogenesis, ranging from well-characterized effects of tumor cell growth to immune suppression of CTL activity and phagocyte polarization. Regarding the latter, blunting PGE2 during immune activation may limit the tumor-favoring features of inflammation and improve the efficiency of TLR4 based immune therapies.
Hepatocellular carcinoma (HCC) is the fifth most common malignant tumor and third leading cause of cancer-related death worldwide. Most cases arise as a consequence of underlying liver disease, e.g. developed from chronic hepatitis B or C infectionsalcohol abuse or obesity, and are most often associated with liver cirrhosis. Hypoxiand the hypoxia inducible factors (HIF)-1α and -2α promote tumor progression of HCC, not only affecting tumor cell proliferation and invasion, but also angiogenesis and lymphangiogenesis and thus, increasing the risk of metastasis.
HCC is characterized as one of the most vascularized solid tumors. While HIF-1α and HIF-2α are frequently up-regulated in HCC only HIF-2α is correlated with high patientlethality. HIF-dependent regulation of HCC angiogenesis is controversially discussed.VEGFA, for example, as the most prominent factor inducing tumor angiogenesis represents not only a HIF-1 target, but also a HIF-2 target gene in HCC. This questions whether both isoforms have overlapping functions in regulating the angiogenic switch in HCC.
Besides angiogenesis also tumor-associated lymphangiogenesis significantly influences patient survival in HCC. Lymphatic spread is an important clinical determinant for the prognosis of HCC, but little is known how lymphangiogenesis is controlled in this context. To date, mainly HIF-1α was positively correlated with olymphatic invasion and metastasis in HCC, while a defined role of HIF-2α is missing. Thus, although HIF-1α and HIF-2α are structurally alike and regulate overlapping but not identical sets of target genes, they promote highly divergent outcomes in cancer progression and may even have counteracting roles. The aim of my work was to characterize the specific role of HIF-1α and HIF-2α in the angiogenic switch and lymphangiogenesis induction during HCC development.
Therefore, I created a stable knockdown of HIF-1α and HIF-2α in HepG2 cells and generated cocultures of HepG2 spheroids and embryonic bodies derived from embryonic mouse stem cells as an in vitro tumor model mimicking the cancer microenvironment to analyze which HIF isoform has key regulatory functions in HCC (lymph)angiogenesis. In cocultures with a HIF-2α knockdown angiogenesis was attenuated but lymphangiogenesis increased, while the knockdown of HIF-1α was without effect. Microarray analysis identified plasminogen activator inhibitor 1 (PAI-1)and insulin-like growth factor binding protein 1 (IGFBP1) as HIF-2 target genes.However, prominent angiogenic and lymphangiogenic factors such as VEGFs, PDGFB, ANG and their receptors were not regulated in a HIF-dependent manner. As PAI-1 was linked to angiogenesis in literature and IGF-signaling, which is negatively regulated by IGFBP-1, was correlated with lymphangiogenesis, I decided to investigate their HIF-2α-dependent influence on HCC (lymph)angiogenesis. The knockdown of PAI-1 in HepG2 cells also lowered angiogenesis in PAI-1k/d cocultures similar to the HIF-2α k/d phenotype. PAI-1 as the potent inhibitor of tPA and uPA, both inducing the conversion of plasminogen to plasmin, also inhibits plasmin directly. Therefore, I assumed an increase of plasmin in HIF-2α k/d and PAI-1 k/d cocultures as a result of the reduced PAI-1 levels. Blocking plasmin with aprotinin in HIF-2α k/d cocultures restored angioge nesis, suggesting that HIF-2α increases PAI-1 to lower concentrations of active plasmin, thereby supporting angiogenesis. In further experiments I could exclude PAI-1 to reduce angiogenesis by inducing plasmin-mediated apoptosis of differentiating stem cells in PAI-1 k/d and HIF-2α k/d cocultures, but demonstrated an increase of VEGFA165 degradation in these cocultures, suggesting plasmin-catalyzed proteolysis of VEGF as an additional layer of regulation required to explain the angiogenic phenotype. Besides the pivotal role of PAI-1 in angiogenesis I also investigated its potentialinfluence in lymphangiogenesis. Indeed, the knockdown of PAI-1 reduced lymphaticstructures and implied an important but opposing role in lymphangiogenesis comparedto induced lymphangiogenesis in HIF-2α k/d cocultures. However, blocking plasmin again with aprotinin in HIF-2α k/d cocultures restored lymphangiogenesis to the level of control virus, which indicates a divergent lymphangiogenic role of plasmin in PAI-1 k/d and HIF-2α k/d cocultures, possibly because of other essential pathways masking the lymphangiogenic effects of PAI-1 in HIF-2α k/d cocultures.
HIF-2α resulting in reduced IGFBP1 expression induced the differentiation of stem cells toward a lymphatic cell type and significantly enhanced the assembly of human dermal lymphatic endothelial cells into tubes. These data point the first time to an important impact of HIF-2 in the regulatin of lymphangiogenesis in vitro by inducing IGFBP1 and thus, scavenging IGF-1. Furthermore, matrigel plug assays to investigate the in vivorelevance of these observations confirmed HIF-2α as a crucial factor in the regulation of lymphangiogenesis in vivo
In conclusion, this work provides evidence that HIF-2α is a key regulator of angiogenesis and lymphangiogenesis in HCC by regulating PAI-1 and IGFBP1. HIF-2α positively influences the angiogenic switch via PAI-1 and negatively affects lymphangiogenesis via IGFBP1 expression. Targeting HIF-2α in HCC to reduce tumor angiogenesis should be approached carefully, as it might be overcome by induced lymphangiogenesis and metastasis.
In the absence of apparent mutations, alteration of gene expression patterns represents the key mechanism by which normal cells evolve to cancer cells.
Gene expression is tightly regulated by posttranscriptional processes. Within this context, RNA-binding proteins (RBPs) represent fundamental factors, since they control mechanisms, such as mRNA-stabilization, -translation and -degradation. Human antigen R (HuR) was among the first RBPs that have been directly associated to carcinogenesis. HuR modulates the stability and translation of mRNAs which encode proteins facilitating various ‘hallmarks of cancer’, namely proliferation, evasion of growth suppression, angiogenesis, cell death resistance, invasion and metastasis. Furthermore, it is well established that tumor-promoting inflammation contributes to tumorigenesis. In this process, monocytes are attracted to the site of the tumor and educated towards a tumor-promoting macrophage phenotype. While HuR has been extensively studied in various tumor cell types, little is known about HuR in hepatocellular carcinoma (HCC). Thus, the aim of my work was to characterize the contribution of HuR to the development of cancer characteristics in HCC. I was particularly interested to investigate if HuR facilitates tumor-promoting inflammation, since a role for HuR has not been described in this context. To this end, I depleted HuR in HepG2 cells (HuR k/d) and used a co-culture model of HepG2 tumor spheroids and infiltrating monocytes to study the impact of HuR on the tumor microenvironment. I could show that depletion of HuR resulted in the reduction of cell numbers. Additionally, the expression of proliferation marker KI-67 and proto-oncogene c-Myc was reduced, supporting a proliferative role of HuR. Furthermore, exposure to cytotoxic staurosporine elevated apoptosis in HuR k/d cells compared to control cells. Concomitantly, the expression of the anti-apoptotic mediator B-cell lymphoma protein-2 (Bcl-2) was markedly reduced in the HuR k/d cells, pointing to an involvement of HuR in cell survival processes.
Accordingly, a pro-survival function of HuR was also observed in tumor spheroids, since HuR k/d spheroids exhibited a larger necrotic core region at earlier time points and showed elevated numbers of dead cells compared to control (Ctr.) spheroids. Interestingly, HuR k/d spheroids isplayed reduced numbers of infiltrated macrophages, suggesting that HuR contributes to a tumor-promoting, inflammatory microenvironment by recruiting monocytes/macrophages to the tumor site. Aiming at identifying HuR-regulated factors responsible for the recruitment of monocytes, I found reduced levels of the chemokine interleukin 8 (IL-8) in supernatants of HuR k/d spheroids, supporting a critical involvement of HuR in the chemoattraction of monocytes. Analyzing supernatants of co-cultures of macrophages and HuR k/d or Ctr. spheroids revealed additional differences in chemokine secretion patterns. Interestingly, protein levels of many chemokines were elevated in co-cultures of HuR k/d spheroids compared to control co-cultures. Albeit enhanced chemokine secretion was observed, less monocytes are recruited into HuR k/d spheroids, further underlining the necessity of HuR in cancer related monocyte/macrophage attraction and infiltration. Differences between chemokine profiles of mono- and co-cultured spheroids could be attributable to changes in spheroid-derived chemokines as a result of the crosstalk with the immune cells. Provided the chemokines originate from monocytes/macrophages, the different secretion patterns suggest that HuR contributes to the modulation of the functional phenotype of infiltrated macrophages, since the tumorenvironment is critically involved in the shaping of macrophage phenotypes. Regions of low-oxygen (hypoxia) represent another critical feature of tumors. Therefore, I next analyzed the impact of HuR on the hypoxic response. Loss of HuR attenuated hypoxia-inducible factor (HIF) 2α expression after exposure to hypoxia, while HIF-1α protein levels remained unaltered. Considering previous results of our group, showing that HIF-2α depletion (HIF-2α k/d) resulted in the enhanced expression of HIF-1α protein, I aimed to determine the involvement of HuR in the compensatory upregulation of HIF-1α protein in HIF-2α k/d cells. I could demonstrate that not only total HuR protein levels, but specifically cytoplasmic HuR was elevated in HIF-2α depleted cells pointing to enhanced HuR activity. Silencing HuR in HIF-2α deficient cells attenuated enhanced HIF-1α protein expression, thus confirming a direct role of HuR in the compensatory upregulation of HIF-1α. This as also reflected on HIF-1α target gene expression. I further investigated the mechanism underlying the compensatory HIF-1α expression in HIF-2α deficient cells. Analyzing HIF-1α mRNA expression, I excluded enhanced HIF1-α transcription and stability to account for elevated HIF-1α expression in HIF-2α k/d cells. HIF-1α promoter activity assays confirmed the mRNA data. Furthermore, HIF-1α protein half-life was not elevated in HIF-2α k/d cells compared to control cells, indicating that HIF-1α protein stability is not altered in HIF-2α k/d cells. Analysis of the association of HIF-1α with the translational machinery using polysomal fractionation finally revealed an increased istribution of HIF-1α mRNA in the heavier polysomal fractions in HIF-2α k/d cells compared to control cells. Since augmented ribosome occupancy is an indicator for more efficient translation, I propose enhanced HIF-1α translation as underlying principle of the compensatory increase in HIF-1α protein levels in HIF-2α k/d cells. In summary, my results demonstrate that HuR is critical for the development of cancer characteristics in HCC. Future work analyzing the impact of HuR on tumor-promoting inflammation, specifically macrophage attraction and activation could provide new trategies to inhibit macrophage-driven tumor progression. Furthermore, I provide evidence that HuR contributes to the hypoxic response by regulating the expression of HIF-1α and HIF-2α. Targeting single HIF-isoforms for tumor therapy should be carefully considered, because of their compensatory regulation when one α-subunit is depleted. Thus, therapeutic strategies targeting factors such as HuR that control both α-subunits and at the same time prevent compensation might be more promising.