Institutes
Refine
Year of publication
Document Type
- Doctoral Thesis (62) (remove)
Language
- English (62) (remove)
Has Fulltext
- yes (62)
Is part of the Bibliography
- no (62)
Keywords
- Macrophages (2)
- fMRI (2)
- ACKR (1)
- ADHD (1)
- ADHS (1)
- Allosteric inhibition (1)
- Aurora kinase (1)
- B cell differentiation (1)
- BMI (1)
- Bentall operation (1)
Institute
- Medizin (62)
- Biowissenschaften (1)
Type 1 diabetes (T1D) is precipitated by the autoimmune destruction of the insulin-producing beta-cells in the pancreatic islets of Langerhans. Chemokines have been identified as major conductors of the islet infiltration by autoaggressive leukocytes, including antigen-presenting cells and islet autoantigen-specific T cells. We have previously generated a roadmap of the gene expression in the islet microenvironment during T1D in a mouse model and found that most of the chemokine axes are chronically upregulated during T1D. We focused our attention on CXCL10/CXCR3, CCL5/CCR5, CXCL16/CCR6, CX3CL1/CX3CR1, and XCL1/XCR1. First, we found that the absence of CCR6 and of CX3CR1 diminished T1D incidence in a mouse model for T1D. Further, the XCL1/XCR1 chemokine axis is of particular interest, since XCR1 is exclusively expressed on convention dendritic cells type 1 (cDC1) that excel by their high capacity for T cell activation. Here we demonstrate that cDC1 expressing XCR1 are present in and around the islets of patients with T1D and of islet-autoantibody positive individuals. Further, in an inducible mouse model for T1D, we show that XCL1 plays an important role in the attraction of highly potent dendritic cells expressing XCR1 to the islets. XCL1-deficient mice display a diminished infiltration of XCR1+ cDC1 and subsequently also a reduced magnitude and activity of islet autoantigen-specific T cells. XCR1-deficient mice display a reduced magnitude and activity of islet autoantigen-specific T cells. A 3D-visualization of the entire pancreas reveals that both XCL1-deficient mice and XCR1-deficient mice indeed maintain most of their functional islets after induction of the disease. Thus, the absence of XCL1 results in a profound decrease in T1D incidence. The XCR1-deficiency also reduces T1D incidence, even if in a less drastic way compared to XCL1-deficiency. An interference with the XCL1/XCR1 chemokine axis might constitute a novel target for the therapy for T1D.
Throughout the entire life, new neurons of the granule cell type (GCs) are continu-ously generated in the mammalian hippocampal dentate gyrus (DG). As a part of the limbic system, the hippocampus is concerned with spatial and declarative memory for-mation. Increasing evidence exists, that adult born granule cells (ABGCs) play an im-portant role in this process. An especially critical period, when these ABGCs are 4-6 weeks old, has come into the focus of research. It is during this specific time-span that the ABGCs express enhanced excitability and synaptic plasticity as well as a lowered threshold for the induction of long term potentiation (LTP), a mechanism associated to learning and memory formation.
This study investigates the time course and dynamics of synaptic integration in ABGCs and mature GCs together with which differences exist between them at various cell ages. Furthermore, spine plasticity following high frequency stimulation (HFS) is analysed focusing on a critical phase of enhanced excitability in 4-5 week old ABGCs.
In this thesis, two approaches at studying the synaptic integration and structural plas-ticity of ABGCs in rats were investigated. This work was performed on fixed brain ma-terial that was provided by two laboratories that performed the in vivo labelling, stimu-lation procedures and brain fixation. In the first project, 6, 12 and 35 weeks old XdU-labelled ABGCs were studied. Adult rats were exposed to an enriched environment and received unilateral intrahippocampal delta burst stimulation (DBS) and LTP induction. The ABGCs and a control population of mature GCs were immunohistologically ana-lysed for Egr1 (early growth response 1) expression. Egr1 is an immediate early gene (IEG), expressed after LTP induction and marks neuronal excitation.
It was found, that unilateral stimulation of the perforant path of the hippocampus re-sults in an increase of Egr1 expression in ABGCs of both hemispheres. It could be shown that the enhanced expression intensity of Egr1 in ABGCs is not a usual state of young GCs but a reaction to DBS. ABGCs from unstimulated control animals and mature GCs expressed lower levels of Egr1. Interestingly, the stimulation induced a similar degree of Egr1 expression intensity in all ABGC age groups. Furthermore, it was found that young ABGC from the infrapyramidal dentate gyrus (DG) express a higher excita-bility than those from the suprapyramidal DG.
In the second project, fixed brain sections were analysed. They stemmed from rat brains containing 28 and 35 day old ABGC that had been transfected with intrahippo-campal RV-GFP (retroviral-green fluorescent protein) injections and had received uni-lateral high frequency stimulation of the medial perforant path in vivo. Nuclear Egr1 expression intensity was analysed in a cell specific manner. Dendritic spine size was measured in the inner-, middle- and outer molecular layer (IML, MML, OML). It was found that in ABGC, stimulation induced Egr1 expression increase is lower than in ma-ture GC. Following HFS, a significant homosynaptic spine enlargement was observed in the MML indicating homosynaptic LTP, while heterosynaptic spine shrinkage was found in the adjacent IML and OML. The latter corresponds to heterosynaptic long term depression (LTD). Homosynaptic plasticity describes an input-specific potentiation of synapses that received direct activation. The weakening of synapses not stimulated dur-ing homosynaptic potentiation is oppositely coined heterosynaptic plasticity1.
A positive correlation between an increase in nuclear Egr1 expression intensity and spine enlargement due to homosynaptic plasticity induced by HFS could be shown. Concomitant heterosynaptic plasticity, as indicated by spine shrinkage was observed. Spine shrinkage in the IML and OML showed a negative correlation to a decrease in Egr1 intensity.
Taken together, the results provide detailed information on the gradual integration of ABGC with ongoing maturation. Cell specific proof for homo- and heterosynaptic plas-ticity following HFS was found in the critical period of synaptic integration of ABGCs.
Glioblastoma multiforme accounts for more than 80% of all malignant gliomas in adults and a minor fraction of new annual cases occurs in children. In the last decades, research shed light onto the molecular patterns underlying human malignancies which resulted in a better understanding of the disease and finally an improved long term survival for cancer patients. However, malignancies of the central nervous system and especially glioblastomas are still related to poor outcomes with median survivals of less than 6 months despite extensive surgery, chemotherapy and radiation. Hence, a better understanding of the molecular mechanism driving and sustaining cancerous mutations in glioblastomas is crucial for the development of targeted therapies. Apoptosis, a form of programmed cell death, is an important feature of eukaryotic cells and crucial for the maintenance of multicellular homeostasis. Because apoptosis is a highly complex and tightly regulated signaling pathway, resisting apoptotic stimuli and avoiding cell death is a hallmark of the cancerous transformation of cells. Hence, targeting molecular structures to reestablish apoptotic signaling in tumor cells is a promising approach for the treatment of malignancies. Smac mimetics are a group of small molecular protein inhibitors that structurally derive from an intracellular protein termed Smac and selectively block Inhibitor of apoptosis (IAP) proteins, which are often aberrantly expressed in cancer. Several studies confirmed the antitumoral effects of Smac mimetics in different human malignancies, including glioblastoma, and give rationales for the development of potent Smac mimetics and Smac mimetic-based combination protocols. This study investigates the antitumoral activity of the bivalent Smac mimetic BV6 in combination with Interferon α. Latter is a well characterized cytokine with an essential role in immunity, cell differentiation and apoptosis. This study further aims to address the molecular mechanisms underlying the antitumoral activity of the combination treatment by using well established molecular cell death assays, flow cytometry, western blot analysis, genetic approaches and selective pharmacological inhibition. Since different Smac mimetics and Smac mimetic-based combination therapies are currently under clinical evaluations, findings of this study may have broad implications for the application of Smac mimetics as clinical cancer therapeutics.
The genetic mutation of the coagulation factor VIII (fVIII) results in a defective or missing protein, leading to a malfunctioning blood coagulation. The resulting disease is called hemophilia A. Depending on the severity of the mutation, affected patients experience an increased risk of pathologic bleeding after minor trauma or even sudden bleeding events. Substitution therapies with extrinsic fVIII exist using plasmatic or recombinant fVIII products. Due to an insufficient immune tolerance towards substituted fVIII, about 30 % of patients develop allogenic neutralizing antibodies (inhibitors) against substituted fVIII products. The gold standard of treating inhibitors is the immune tolerance induction (ITI), where patients are given frequent, high doses of fVIII to induce an immune tolerance. ITI therapy fails in about 30 % of patients. Mechanisms of action of ITI are part of research, as insufficient knowledge about mechanisms and prognostic factors complicate treatment. For example, the development of anti-idiotypic antibodies, which occur naturally as a regulatory mechanism of the immune system, are being studied. Such anti-idiotypes have been detected in immunoglobuline preparations and in patients after successful ITI.
Inhibitors interfere with fVIII function in coagulation by binding functional epitopes within fVIII domains. Inhibitors against the A2 and C2 domain are predominantly found, however also the C1 domain has been shown to be highly immunogenic in some patients. The polyclonality of inhibitors aggravates the understanding and treatment of these. The present project therefore focusses on the selection of synthetic anti-idiotypic antibodies to target inhibitors in patients. The phage display method was applied to, for one, isolate anti-idiotypic single chain variable fragments (scFvs) specific against human polyclonal anti-fVIII antibodies and second against two C1 domain-specific inhibitory monoclonal antibodies (mAbs).
In the first project, anti-fVIII antibodies were purified from human plasma to serve as target molecules. A previous project showed that using full plasma as a target did not yield anti-idiotypic antibodies from phage display. For the purification, protein A chromatography and fVIII coupled Affi Gel® chromatography were applied. The isolated antibodies were next used as targets for the selection of anti-idiotypic scFvs. Analysis revealed that none of the selected phages solely bound the anti-fVIII antibody target. Consequently, the test protocol was modified, which resulted in a reduction of unspecific binders. Yet, no target-specific binders were isolated from phage pools. Reason for this may have been the high diversity of the polyclonal antibody target and the limited diversity of the phage libraries.
The aim of the second project, was the selection and characterization of scFvs, that target the paratopes of C1 domain-specific mAbs GMA8011 and LE2E9. From a therapeutic viewpoint, the preparation of an anti-idiotypic antibody pool, tailored to each patient’s inhibitor population, could help neutralize inhibitors in patients. Ultimately, one GMA8011-specific scFv-carrying phage clone (H2C1) and two specifics to LE2E9 (H3G7, H3F10) were isolated. In further experiments, only the GMA8011-specific scFv showed competitive behavior in presence of fVIII, pointing towards an anti-idiotypic binding to the inhibitor paratope. The LE2E9-specific scFvs did not prevent binding of the inhibitor to fVIII. Hence, no anti-idiotypic behavior could be determined. For further characterization, selected scFvs were genetically fused to Fc antibody fragments and recombinantly produced. In this antibody format, all three scFvs showed concentration dependent binding to the target and the isotype control. The binding specificity to the target, observed in phage context, could not be reproduced. Competition experiments with fVIII confirmed that none of the scFvs bound the paratope of their target inhibitor.
The selection of anti-idiotypic scFvs from phage display libraries proves to be effortful. Polyclonal anti-fVIII antibodies purified from hemophilic plasma appear to be unsuitable as a target for phage display, likely due to the high diversity of the target molecules. Furthermore, the preparation of an individualized anti-idiotypic pools for patients by selecting scFvs against single inhibitory mAbs proves to be difficult. The selection of scFvs against anti-C1 inhibitors GMA8011 and LE2E9 produced three promising scFv-carrying phages. However, analysis could not detect anti-idiotypic behavior. Further research with inhibitors, monoclonal and polyclonal, and anti-idiotypic antibodies should be performed to bring better insight into the highly complex paratope-epitope interaction.
Cancer is the major cause of death besides cardiovascular disease. Leukaemia represents the most prevalent malignancy in children with a frequency of 30 % and is one of the ten leading types of cancer in adults. Philadelphia Chromosome-positive B-ALL (Ph+ B-ALL) is driven by the cytogenetic aberration of the reciprocal chromosomal translocation t(9;22)(q34;q11) leading to the formation of the Philadelphia chromosome with a BCR-ABL1 fusion gene. This fusion gene encodes a BCR-ABL1 oncoprotein which is characterized by a constitutively enhanced tyrosine kinase activity promoting amplified proliferation, differentiation arrest and resistance to cell death. Ph+ B-ALL is considered the most aggressive ALL subtype with a long-term survival rate in the range of only 30 % despite intensive standard of care including chemotherapy in combination with a tyrosine kinase inhibitor (TKI) followed by allogeneic stem cell transplantation after remission for clinically fit patients.
The efficacy of chemotherapy has long been mainly attributed to tumour cell toxicity while immune modulating effects have been overlooked, especially in light of known immunosuppressive properties. Accumulative evidence, however, emphasizes the ability of chemotherapeutic agents, including TKIs, to normalise or re-educate a dysfunctional tumour microenvironment (TME) resulting in enhanced anti-tumour immunity. One of the underlying mechanisms of immune modulation is the induction of immunogenic cell death (ICD). ICD is an anti-tumour agent-induced cell death modality determined by the capacity to convert cancer cells into anti-cancer vaccines. The induction of ICD relies on the release of damage-associated molecular patterns (DAMPs) from dying tumour cells succumbing to ICD. Translocation of CALR to the cell surface, extracellular secretion of ATP and release of HMGB1 from the nucleus are key hallmarks of ICD that mediate anti-tumour immunity upon binding to antigen presenting cells resulting in a tumour antigen-specific immune response. Besides these molecular determinants, ICD is functionally defined by the inhibition of tumour growth in a vaccination assay in which mice are injected with tumour cells exposed to the potential ICD inducer in-vitro and then re-challenged with live tumour cells of the same cancer type. Both molecular and functional criteria determine the gold standard approach to assess ICD. By increasing the immunogenicity of cancer cells, ICD contributes to the restoration of immunosurveillance as an essential feature of tumour rejection, which is clinically reflected by improved therapeutic efficacy and disease outcome in patients. Therefore, identifying novel ICD inducers is an objective of interest in the context of cancer therapy.
In respect of these considerations, the aim addressed in the present work is the examination of the second-generation TKI Nilotinib for the ability to induce ICD. The thesis is set in the context of the group's research on the role of Gas6/TAM signalling within the TME regarding the pathogenesis of acute leukaemia. In in-vivo experiments of our research group it has been consistently observed that the use of Nilotinib enhances the anti-leukaemic immunity mediated by a deletion of Gas6. Against the background of increasing importance of chemotherapeutic agents as potent modulators of a dysregulated TME, it was hypothesized that Nilotinib may synergize with a Gas6-deficient environment by inducing ICD in Ph+ B-ALL cells.
In growth inhibition and Annexin V/Propidium iodide cell death assays Nilotinib was shown to induce cell death in concentration-dependent manner that occurs bimodally in terms of cell death modality ranging between apoptosis and necrosis. By ICD marker analysis, comprising flow-cytometric detection of CALR exposure, chemoluminescence-based ATP measurement and immunoblotting for HMGB1, it was found that Nilotinib-induced cell death is not accompanied by CALR exposure and ATP secretion, but is associated with the release of HMGB1. In macrophages co-culture experiments with Nilotinib-treated leukaemic cells, no relevant shift in terms of macrophages activation and polarisation was observed in either a juxtacrine or paracrine setup. In consistency with the results obtained in the in-vitro experiments, Nilotinib was not potent to elicit a protective immune response in mice within a vaccination assay.
Conclusively, Nilotinib was identified to not qualify as bona fide ICD inducer. The role of Nilotinib-induced cell death and HMGB1 release are proposed as objective for further investigation concerning the synergistic interplay between Nilotinib and a Gas6-deficient environment. Efforts addressing exploration and optimisation of the immunological potential of chemotherapeutic agents are a promising approach aimed at providing cancer patients with the best possible treatment in future.
Abdominal aortic aneurysm (AAA) is the most common type of aortic aneurysm, which is defined as a dilation of the abdominal aorta over 3.0 cm or more. Surgical repair is the golden standard for the treatment of AAA, in which open surgical repair (OSR) and endovascular aneurysm repair (EVAR) are the main approaches. Technically speaking, the lesion segment of aueurysm is completely replaced by a graft during OSR, while in EVAR, the lesion is insulated by a stentgraft. EVAR is a less invasive treatment than OSR and shows a lower early mortality rate, although the long-term advantages of EVAR over OSR remain inconclusive.
Endoleak, especially the type II endoleak (T2EL), is a common complication after EVAR. According to research, 16-28% of the patients develop a T2EL after EVAR, and it accounts for nearly three in four of all types of endoleaks. Around 30-50% of the T2EL resolved spontaneously during the follow-up, however, it still causes a secondary intervention in many patients. Therefore, it is critical to monitor endoleaks after repair.
Patent aortic branches in the stent-overlapped area and vasa vasorum have been identified as potential sources of blood flow in T2EL. However, the mechanisms of biological changes or remodeling of the aneurysm sac after the repair are still not clear, but they have been considered to play an important role in the development of endoleaks. Unfortunately, it is impossible to obtain a tissue sample of the aortic wall in patients who underwent EVAR.
MicroRNAs (miRNAs) are a class of small single-stranded non-coding RNAs that inhibit the expression of target message RNA (mRNA). miR-29b/29c, miR-155, and miR-15a are miRNAs associated with regulating extracellular matrix (ECM) components, inflammation, and proliferation, respectively. All four miRNAs have been identified as biomarkers of AAA, not only in aneurysm tissue but also extracellular as circulating miRNAs. However, it is still unknown whether they can reflect the biological changes after AAA repair. Thus, we conducted a prospective study to investigate the changes in expression of circulating miR-29b, miR-29c, miR-155, and miR-15a before (T0), 3 days (T1), and 3 months (T2) after AAA repair.
A total of 39 patients were recruited for this study, 17 of whom were repaired by OSR and 22 of whom were repaired by EVAR. Four patients failed the T2 follow-up due to the Covid-19 pandemic. No significant changes were found in the expression of miR-29b, miR-29c, miR-155, and miR-15a. There were also no obvious differences between OSR and EVAR. However, the T1 expression of miR-15a was significantly lower in patients without endoleak after EVAR than in those who developed endoleak after EVAR and those who were repaired by OSR. Unfortunately, these differences did not persist to the T2 follow-up, and no other differences were found among these patients.
In summary, miR-15a is a miRNA that significantly changes in AAA patients. This study demonstrates that the expression of circulating miR-15a is lower in patients without endoleak three days after EVAR, compared to those who had endoleak after EVAR and those who underwent OSR. The results suggest that miR-15a might be involved in the early aortic remodeling after EVAR as an indicator of endoleak.
Facial expression recognition is linked to clinical and neurofunctional differences in autism
(2022)
Background: Difficulties in social communication are a defining clinical feature of autism. However, the underlying neurobiological heterogeneity has impeded targeted therapies, and requires new approaches to identifying clinically relevant bio-behavioural subgroups. In the largest autism cohort to date, we comprehensively examined difficulties in facial expression recognition, a key process in social communication, as a bio-behavioural stratification biomarker, and validated them against clinical features and neurofunctional responses.
Methods: Between 255 and 488 participants aged 6-30 years with autism, typical development and/or mild intellectual disability completed the Karolinska Directed Emotional Faces task, the Reading the Mind in the Eyes Task and/or the Films Expression Task. We first examined mean-group differences on each test. Then we used a novel intersection approach that compares two centroid and connectivity-based clustering methods to derive subgroups based on the combined performance across the three tasks. Measures and subgroups were then related to clinical features and neurofunctional differences measured using fMRI during a fearful face-matching task.
Results: We found significant mean-group differences on each expression recognition test. However, cluster analyses showed that these were driven by a low-performing autistic subgroup (~30% of autistic individuals who performed below 2SDs of the neurotypical mean on at least one test), while a larger subgroup (~70%) performed within 1SD on at least 2 tests. The low-performing subgroup also had on average significantly more social-communication difficulties and lower activation in the amygdala and fusiform gyrus than the high-performing subgroup.
Limitations: Findings of autism expression recognition subgroups and their characteristics require independent replication. This is currently not possible, as there is no other existing data set that includes all relevant measures. However, we demonstrated high internal robustness (91.6%) of findings between two clustering methods with fundamentally different assumptions, which is a critical pre-condition for independent replication.
Conclusions: We identified a subgroup of autistic individuals with expression recognition difficulties and showed that this related to clinical and neurobiological characteristics. If replicated, expression recognition may serve as bio-behavioural stratification biomarker and aid in the development of targeted interventions for a subgroup of autistic individuals.
After entorhinal deafferentiation of the hippocampal dentate gyrus a reinnervation of the denervated neurons by axon collaterals can be observed. This process takes place in a matter of weeks. However, the overall functional effect on the hippocampal network is still unclear.
In an effort to investigate this effect of axonal sprouting on the neuronal network of the dentate gyrus we compared the electrophysiological response of the dentate gyrus after electric stimulation in wild-type mice (WT mice) with a normal post-lesion sprouting, with genetically modified mice with an overexpression of the growth-protein CAP23 (cytoskeleton-associated protein 23). CAP23 overexpressing mice (CAP23tg mice) are known to have an enhanced axonal growth and sprouting after lesion.
The mice (both the WT as well as the CAP23tg mice) were deeply anesthetized and a lesion of the perforant path was induced stereotactically with a wire knife. After that the mice were permitted to survive for 4-6 weeks for partial reinnervation of the dentate gyrus before they were again operated and evoked potentials were measured (extracellular recordings of evoked potentials in the dentate gyrus). Non-lesioned litter-mate mice were taken as reference. The sprouting and the correct position of the electrodes was confirmed histologically.
For electrophysiological investigation we assessed laminar profiles and calculated a current-source density (CSD). In lesioned CAP23tg mice compared to lesioned WT mice this CSD-analysis revealed a significant enhancement of the current sink in the area of deafferentiation (outer molecular layer) and a significant excitation in the granule-cell layer.
Our results show that axonal sprouting seems to enhance the excitability of granule-cells. Thus, even if an enhanced axonal sprouting might accelerate the reinnervation of denervated dendrites after lesion, but it also leads to posttraumatic hyperexcitability of the neuronal network. In a therapeutic approach of fascilitating axonal sprouting this hyperexcitability has to be taken into consideration.
Cancer is one of the leading causes of death across all countries and its diagnosis still yields fear for the affected patient. Although treatment of cancer has made marvelous progress compared to the agents available thirty years ago, a cure for cancer, however, is still a distant prospect. Modern therapy still is a burden for many patients due to heavy side effects. With the development of agents targeting specific molecular targets on cancer cells, a new field of cancer therapy was opened and a small success story in the history of cancer began.
Aurora kinases represent a relatively new target in cancer therapy. The kinase is a essential part of mitosis and cell cycle progression and its overexpression has been shown to be related to many kinds of malignancies. Allosteric inhibition of a kinase is an increasing pre-clinical approach not yet established in the treatment of patients. In this thesis, we combine allostery with another innovative approach that is drug repurposing. If repurposed, a drug can be permitted to fast track drug admission to clinical trials.
I set up a screening of 1280 FDA approved drugs to identify small molecule compounds that affect the binding of Aurora kinase A and its main physiologic binding partner, TPX2. Further, I characterized the positive hits in vitro for their capabilities to displace TPX2 from Aurora A, to inhibit Aurora kinase activity, to thermally stabilize the protein and performed assays to determine their dissociation constant. Last but not least, I tested the compounds in cells for their effect on the cell viability and cell cycle via flow cytometry. Comparing the hit-compounds with controls I found that ATP-competitive AurA inhibitor MLN 8237 strongly displaces the interaction of Aurora A with TPX2.
Summarized, we identified eight hit compounds allosterically affecting Aurora A, but no compound proved to be active in all assays. Just one compound, PS 731, identified in another screening performed by our group and further characterized in this thesis remains interesting, especially when put in context with recent publications released in the time between the start of experiments for this thesis and its finalization.
Identification of translationally deregulated proteins during inflammation-associated tumorigenesis
(2012)
The translation of mRNAs into proteins is an elaborate and highly regulated process. Translational regulation primarily takes place at the level of initiation. During initation the eukaryotic initiation factors (eIFs) form a complex that binds to the 5’end of the mRNA to scan for a start codon. Once recognized, the ribosome is recruited to the mRNA and protein synthesis starts. Initiation of translation can basically occur via two distinct mechanisms, i.e. cap-dependent and cap-independent that is mediated via internal ribosome entry sites (IRESs). The former is mediated by a 5’cap structure composed of a 7-methylguanylate which is added to every mRNA during transcription and recruits the initiation complex. IRES-dependent translation involves elements within the 5’untranslated region (UTR) of the mRNA that mostly bind IRES trans-acting factors (ITAFs) which associate either with the initiation complex or with the ribosome itself and consequently allow for internal initiation of translation.
During tumorigenesis the demand for proteins is increased due to rapid cell growth, which consequently requires enhanced translation. Many factors that regulate translation are overexpressed in tumors. Moreover, signaling pathways that trigger translation or further hyperactivated by the surrounding tumor microenvironment. This environment is largely generated by infiltration of immune cells such as macrophages that secrete cytokines and other mediators to promote tumorigenesis. As the effects of inflammatory conditions on the translation of specific targets are only poorly characterized, my study aimed at identifying translationally deregulated targets during inflammation-associated tumorigenesis.
For this purpose, I cocultured MCF7 breast tumor cells with conditioned medium of activated monocyte-derived U937 macrophages (CM). Polysome profiling and microarray analysis identified 42 targets to be regulated at the level of translation. The results were validated by quantitative PCR and one target - early growth response 2 (EGR2) - was chosen for in depth analysis of the mechanism leading to its enhanced translation.
In order to identify upstream signaling molecules causing enhanced EGR2 protein synthesis the cytokine profile of CM was analyzed and the impact of several cytokines on EGR2 translation was examined. Preincubation of CM with neutralizing antibodies revealed that lowering interleukin 6 (IL-6) had only little effect, whereas depletion of IL 1β significantly reduced EGR2 translation. This finding was corroborated by the fact that treatment with recombinant IL-1β enhanced EGR2 translation to virtually the same extend as CM. Further experiments revealed that this effect was mediated via the p38-MAPK signaling cascade.
Interestingly, I observed that the mTOR inhibitor rapamycin, which reduces cap-dependent translation, specifically stimulated EGR2 translation. This result argued for an IRES-dependent mechanism that might account for EGR2 translation. The use of bicistronic reporter assays verified this hypothesis. In line with the above mentioned results, CM, IL-1β and p38-MAPK induced EGR2-IRES activity.
Since IRESs commonly require ITAFs to mediate translation initiation, the binding of proteins to the 5’UTR was analyzed using mass spectrometry. Among others, several previously described ITAFs, such as polypyrimidine tract-binding protein (PTB) and heterogeneous nuclear ribonucleoprotein A1 (hnRNP-A1) were identified to directly bind to the EGR2-5’UTR. Furthermore, overexpression of hnRNP-A1 enhanced EGR2-IRES activity whereas a dominant negative form of hnRNP-A1 significantly decreased it, thus, showing its importance for EGR2 translation.
In summary, my data provide evidence that EGR2 expression can be controlled by IRES-dependent translational regulation, which is responsive to an inflammatory environment. The identified mechanism may not be exclusive for one target but might be representative for gene expression regulation mechanisms during tumorigenesis. This is of special interest for the treatment of cancer patients and development of more specific therapies to reduce tumor outcome.