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Die Tagung "Vom Gehen und von Übergängen in den Künsten" konzipiert und geleitet von Uta Degner und Hildegard Fraueneder, fand am 16. Juni 2023 am Programmbereich "Figurationen des Übergangs" der interuniversitären Einrichtung Wissenschaft und Kunst (Paris Lodron Universität Salzburg / Universität Mozarteum Salzburg) statt. Anhand von konkreten künstlerischen Arbeiten aus den Feldern Literatur, Musik und Kunst wurde das transformative Potential von Übergängen entlang der Fragen nach der Bedeutung von Gerichtetheit oder Richtungslosigkeit beim Gehen, den Beziehungen des sich bewegenden Subjekts und der Umgebung und der Situierung von Wahrnehmung und Reflexion zueinander vorgestellt und diskutiert.
Hintergrund: Amblyopie ist nach Fehlsichtigkeit die häufigste Sehstörung bei Kindern. Sie ist eine wesentliche Ursache für eine lebenslange Minderung der bestkorrigierten Sehschärfe und ist meist unilateral. Eine Asymmetrie in der Qualität des visuellen Eindrucks während der sensiblen Phase führt in der Regel zu einer unzureichenden Entwicklung des binokularen Sehsystems. Die Standardtherapie der Amblyopie besteht aus optimaler optischer Korrektur vorhandener Brechungsfehler und der direkten Okklusion, wobei das funktionsbessere Auge zeitweise mit einem Augenpflaster abgedeckt wird. Bisherige Studien haben gezeigt, dass besonders bei Patienten mit tiefer Amblyopie, die Therapietreue oft mäßig ist. In einigen Fällen kann das amblyope Auge nicht mit der Foveola fixieren. Diese exzentrische Fixation beeinflusst den Therapieerfolg negativ. Unser Ziel war, bei dieser speziellen Patientengruppe die Okklusionsdauer objektiv zu registrieren und deren Auswirkung auf die Visusentwicklung und die Fixationsänderung in Abhängigkeit vom Alter über einen langen Zeitraum zu untersuchen.
Methoden: In unserer prospektiven multizentrischen Pilotstudie untersuchten wir amblyope Kinder mit exzentrischer Fixation im Alter von 3-16 Jahren während 12-monatiger Okklusionsbehandlung. Der Nahvisus wurde mittels Landoltringen und Lea-Symbolen (jeweils Reihenoptotypen) bestimmt. Die Okklusionsdauer wurde kontinuierlich mit einem TheraMon®-Mikrosensor aufgezeichnet, der am Augenpflaster angebracht wurde. Der Fixationsort am Augenhintergrund wurde mit einem direkten Ophthalmoskop bestimmt. Unsere Ziele waren: Evaluierung der Sehfunktion, Therapieadhärenz und Beurteilung des Fixationsortes des amblyopen Auges. Der Anteil des korrigierten Visusdefizits, die Dosis-Wirkungs-Beziehung und die Therapieeffizienz wurden berechnet.
Ergebnisse: In unserer Studie wurden 12 Patienten mit Schiel- und kombinierter Schiel- und Anisometropieamblyopie im Alter von 2,9-12,4 Jahren (im Mittel 6,5 ± 3,4 Jahre) untersucht. Der Anfangsvisus der amblyopen Augen nach 3 Monaten refraktiver Adaptationsphase lag im Mittel bei 1,4 ± 0,4 logMAR (Spannweite 0,9-2,0), und der 5 Führungsaugen bei 0,3 ± 0,3 logMAR (Spannweite -0,1-0,8). Die mittlere interokuläre Visusdifferenz (IOVAD, Visusunterschied zwischen dem amblyopen Auge und dem Führungsauge) zu Beginn betrug im Mittel 1,1 ± 0,4 log Einheiten (Spannweite 0,5-1,8). Die verschriebene Okklusionsdauer lag im Median bei 7,7 Stunden/Tag (Spannweite 6,6-9,9), die tatsächlich erreichte bei 5,2 Stunden/Tag (Spannweite 0,7-9,7). Nach 12 Monaten betrug die mediane Visusbesserung der amblyopen Augen 0,6 log Einheiten (Spannweite 0-1,6), die mediane IOVAD 0,3 log Einheiten (Spannweite 0-1,8). Multiple Regressionsanalyse mit Rückwärtselimination zeigte, dass sowohl das Alter (p=0,0002) als auch die Okklusionsdosis (p=0,046) signifikante Einflussfaktoren für den Visusanstieg waren. Kinder unter 4 Jahren zeigten das beste Ansprechen mit der niedrigsten Rest-IOVAD (Median 0,1 log Einheiten, Spannweite 0-0,3). Die Effizienzberechnung ergab eine Visusbesserung von etwa einer log Visusstufe pro 100 Stunden Okklusion in den ersten zwei Monaten und einer halben log Visusstufe nach 6 Monaten. Die Therapieeffizienz nahm mit zunehmendem Alter ab (p = 0,01). Trotz einer gewissen Visusbesserung auch bei Patienten im Alter von ≥8 Jahren (Median 0,4 log Einheiten), zeigten diese eine geringere Therapieadhärenz sowie -effizienz (mediane Rest-IOVAD 0,8 log Einheiten). Zentrale Fixation wurde von 9 Patienten nach im Median 3 Monaten erreicht (Spannweite 1-4 Monate). Drei Patienten (>6 Jahre) erreichten keine zentrale Fixation.
Schlussfolgerung: Amblyopie mit exzentrischer Fixation stellt auch bei guter Adhärenz eine Herausforderung für den Therapieerfolg dar. Unsere Studie zeigte erstmals prospektive quantitative Daten basierend auf elektronischer Erfassung der Okklusion bei dieser seltenen Patientengruppe. Es konnte die deutliche Abnahme der Therapieeffizienz mit zunehmendem Alter gezeigt werden. Die Visusbesserung wurde viel stärker vom Alter als von der Okklusionsdosis beeinflusst. Nur Kinder, die zum Okklusionsbeginn jünger als 4 Jahre waren, konnten im Studienzeitraum in ihren amblyopen Augen eine für ihr Alter annähernd normale Sehschärfe und eine IOVAD <0,2 log Einheiten erreichen. Demzufolge sind, trotz möglicher geringer Visusbesserung auch bei älteren Patienten, eine frühzeitige Diagnose und Therapie dieser Patientengruppe unerlässlich für den Therapieerfolg.
Förderung: bereitgestellt durch den Forschungspreis des Vereins „Augenstern e.V.“
Lattice strains of appropriate symmetry have served as an excellent tool to explore the interaction of superconductivity in the iron-based superconductors with nematic and stripe spin-density wave (SSDW) order, which are both closely tied to an orthorhombic distortion. In this work, we contribute to a broader understanding of the coupling of strain to superconductivity and competing normal-state orders by studying CaKFe4As4 under large, in-plane strains of B1g and B2g symmetry. In contrast to the majority of iron-based superconductors, pure CaKFe4As4 exhibits superconductivity with relatively high transition temperature of Tc∼35 K in proximity of a non-collinear, tetragonal, hedgehog spin-vortex crystal (SVC) order. Through experiments, we demonstrate an anisotropic in-plane strain response of Tc, which is reminiscent of the behavior of other pnictides with nematicity. However, our calculations suggest that in CaKFe4As4, this anisotropic response correlates with the one of the SVC fluctuations, highlighting the close interrelation of magnetism and high-Tc superconductivity. By suggesting moderate B2g strains as an effective parameter to change the stability of SVC and SSDW, we outline a pathway to a unified phase diagram of iron-based superconductivity.
Mitochondrial RNA granules (MRGs) are membraneless, highly specialized compartments that play an essential role in the post-transcriptional regulation of mitochondrial gene expression. This regulation is crucial for maintaining energy production, controlling metabolic functions and ensuring homeostasis in cells. Dysregulation of mitochondrial genes has been linked to various human diseases, including neurodegenerative and metabolic disorders as well as certain types of cancer.
MRGs are composed of different RNA species, including mitochondrial precursor RNA (pre-RNA), mature tRNAs, rRNAs and mRNAs complexed with multiple proteins involved in RNA processing and mitoribosome assembly. However, despite the significance of MRGs, their protein composition, structural organization, stability and dynamics during stress conditions remain elusive. In the study reported here, I adopted a three-step approach to address the aforementioned fundamental issues.
First and foremost, I identified the protein composition of MRGs and unveiled their architectural complexity. To characterize the MRG proteome, I applied the cutting-edge TurboID-based proximity labeling approach combined with quantitative mass spectrometry. Proximity labeling was conducted on 20 distinct MRG-associated human proteins, resulting in the identification of more than 1,700 protein-protein interactions. This expansive dataset enabled me to create a comprehensive network, providing valuable insights into both the (sub)architecture as well as the core structure of MRGs in-depth.
Secondly, I investigated the spatio-temporal dynamics of MRGs under various mitochondrial stress conditions. To monitor the morphological alterations and compositional changes of MRGs, I utilized time-resolved confocal fluorescence microscopy and proteomics, respectively. In this analysis, I applied IMT1, the first specific inhibitor that selectively targets mitochondrial transcription. Using this methodology, I pinpointed precise conditions that triggered MRGs’ disassembly during stress, followed by their reassembly when nascent RNA production was restored. The results of this examination elucidate that MRGs are highly dynamic and stress adaptive structures, capable of rapid dissolution and reassembly, a process closely connected to mitochondrial transcription.
Thirdly, I aimed to explore the impact of RNA turnover on MRGs’ integrity during stress, employing confocal fluorescence microscopy and quantitative real-time PCR. I observed that depletion of MRG proteins associated with RNA degradation counteracts MRGs’ disassembly under stress conditions, a phenomenon attributed to the accumulation of double-stranded RNA (dsRNA). These results emphasize the critical role of pre-RNA turnover in maintaining MRG integrity and reveal that MRGs can be stabilized by dsRNA.
Taken together, the comprehensive investigation reported in this thesis has substantially broadened and deepened our understanding of MRGs’ complexity. By identifying their molecular structure and dynamics, I have gained significant insights into the fundamental characteristics and biological functions of MRGs in cellular processes. This knowledge contributes to the identification of disease-related pathways linked to mitochondrial gene expression and may inspire future studies to develop novel therapeutic approaches.
Background: Multiple studies have focused on medical and pharmacological treatments and outcome predictors of patients with status epilepticus (SE). However, a sufficient understanding of recurrent episodes of SE is lacking. Therefore, we reviewed recurrent SE episodes to investigate their clinical characteristics and outcomes in patients with relapses.
Methods: In this retrospective, multicenter study, we reviewed recurrent SE patient data covering 2011 to 2017 from the university hospitals of Frankfurt and Marburg, Germany. Clinical characteristics and outcome variables were compared among the first and subsequent SE episodes using a standardized form for data collection.
Results: We identified 120 recurrent SE episodes in 80 patients (10.2% of all 1177 episodes). The mean age at the first SE episode was 62.2 years (median 66.5; SD 19.3; range 21–91), and 42 of these patients were male (52.5%). A mean of 262.4 days passed between the first and the second episode. Tonic–clonic seizure semiology and a cerebrovascular disease etiology were predominant in initial and recurrent episodes. After subsequent episodes, patients showed increased disability as indicated by the modified Rankin Scale (mRS), and 9 out of 80 patients died during the second episode (11.3%). Increases in refractory and super-refractory SE (RSE and SRSE, respectively) were noted during the second episode, and the occurrence of a non-refractory SE (NRSE) during the first SE episode did not necessarily provide a protective marker for subsequent non-refractory episodes. An increase in the use of intravenous-available anti-seizure medication (ASM) was observed in the treatment of SE patients. Patients were discharged from hospital with a mean of 2.8 ± 1.0 ASMs after the second SE episode and 2.1 ± 1.2 ASMs after the first episode. Levetiracetam was the most common ASM used before admission and on discharge for SE patients.
Conclusions: This retrospective, multicenter study used the mRS to demonstrate worsened outcomes of patients at consecutive SE episodes. ASM accumulations after subsequent SE episodes were registered over the study period. The study results underline the necessity for improved clinical follow-ups and outpatient care to reduce the health care burden from recurrent SE episodes.
This work aimed to investigate the regulation and activity of 5-lipoxygenase (5-LO), the central enzyme in leukotriene biosynthesis, in two colorectal cancer cell lines. The leukotriene pathway is positively correlated with the progression of several solid malignancies; however, factors regulating 5-LO expression and activity in tumors are poorly understood.
Cancer development, as well as cancer progression, are strongly dependent on the tumor microenvironment. In the conventional monolayer culture of cancer cell lines, cell-matrix and cell-cell interactions present in native tumors are absent. Furthermore, it is already known that various colon cancer cell lines dysregulate several important signaling pathways due to 3D growth. Therefore, the expression of the leukotriene cascade in HT-29 and HCT-116 colorectal cancer cells was investigated within a three-dimensional context using multicellular tumor spheroids to mimic a more physiological environment compared to conventional cell culture. Especially the expression of 5-LO, cPLA2α, and LTA4 hydrolase was altered due to threedimensional (3D) cell growth, which was investigated by qPCR and Western blot analysis. High cellular density in monolayer cultures led to similar results. The observed 5-LO upregulation was found inversely correlated with cell proliferation, determined by cell cycle analysis, and activation of PI3K/mTORC-2- and MEK-1/ERK-dependent pathways, determined using pharmacological pathway inhibition, stable shRNA knockdown cell lines, and analysis via qPCR and Western blot analysis. Following, the transcription factor E2F1 and its target gene MYBL2 were identified to play a role in the repression of 5-LO during cell proliferation. For this purpose, several stable MYBL2 over-expression and ALOX5 reporter cell lines were prepared and analyzed. Since 5-LO was already identified as a direct p53 target gene, the influence of p53, which is variably expressed in the cell lines (HT-29, p53 R273H mut; HCT-116 p53 wt; HCT-116 p53 KO), was investigated as well. Furthermore, HCT-116 cells carrying a p53 knockout were investigated. The PI3K/mTORC-2- and MEK-1/ERK-dependent suppression of 5-LO was also found in tumor cells from other origins (Capan-2, Caco-2, MCF-7), which was determined using pharmacological pathway inhibition and following analysis via qPCR. This suggests that the identified mechanism might apply to other tumor entities as well.
5-LO activity was previously described as attenuated in HT-29 and HCT-116 cells compared to polymorphonuclear leukocytes, which express a highly active 5-LO. However, the present study showed that the enzyme activity is indeed low but inducible in HT-29 and HCT-116 cells. Of note, the general lipid mediator profile and the mediator concentrations were comparable to those of M2 macrophages. Finally, the analysis of substrate availability in HT-29 and HCT-116 cells revealed a vast difference between formed metabolite concentrations and supplemented fatty acid concentrations, indicating that the substrates are either transformed into lipoxygenase-independent metabolites or are esterified into the cellular membrane.
In summary, the data presented in this work demonstrate that 5-LO expression and activity are tightly regulated in HT-29 and HCT-116 cells and fine-tuned due to environmental conditions. The cells suppress 5-LO during proliferation but upregulate the expression and activity of the enzyme under cellular stress-triggering conditions. This implies a possible role of 5-LO in manipulating the tumor stroma to support a tumor-promoting microenvironment.
Bioactive small molecules are used in many research areas as important tools to uncover biological pathways, interpret phenotypic changes, deconvolute protein functions and explore new therapeutic strategies in disease relevant cellular model systems. To unlock the full potential of these small molecules and to ensure reliability of results obtained in cellular assays, it is crucial to understand the properties of these small molecules. These properties encompass their activity and potency on their designated target(s), their selectivity towards unintended off-targets and their phenotypic effects in a cellular system. Approved drugs often engage with multiple targets, which can be beneficial for some applications such as treatment of cancer where several pathways need to be inhibited for treatment efficacy. However, targeting multiple key proteins in diverse pathways also increases the possibility for unspecific or unwanted side effects. For many drugs the entire target space that they modulate is not known. This makes it difficult to use these drugs for target deconvolution or functional assays with the aim to understand the underlying biological processes. In contrast to drugs, for mechanistic studies, a good alternative are chemical tool compounds so called chemical probes that are usually exclusively selective as well as chemogenomic compounds, that inhibit several targets but have narrow selectivity profiles. Because they are mechanistic tools, chemical tool compounds must meet stringent quality criteria and they are therefore well characterized in terms of their potency, selectivity and cellular on-target activity. To ensure that an observed phenotypic effect caused by a compound can be attributed to the described target(s), it is essential to study also properties of chemical tools leading to unspecific cellular effects. There are a variety of unspecific effects that can be caused by physiochemical compound properties that can interfere with phenotypic assays as well as functional compound evaluations. One of these effects is low solubility causing toxicity or intrinsic fluorescence potentially interfering with assay readouts. But unanticipated cellular responses can also arise from unspecific binding, accumulation in cellular compartments or damage caused to organelles such as mitochondria or the cytoskeleton that can result in the induction of diverse forms of cell death.
In this study, we investigated the influence of a variety of small molecules on distinct cell states, by establishing and validating high-content imaging assays, which we called Multiplex assay. This assay portfolio enabled us to detect different cellular responses using diverse fluorescent reporters, such as the influence of a compound on cell viability, induction of cell death programs and modulation of the cell cycle. Additionally, general compound properties such as precipitation and intrinsic fluorescence were simultaneously detected. The assay is adaptable to assess other cellular properties of interest, such as mitochondrial health, changes in cytoskeletal morphology or phospholipidosis. A significant advantage of the assay is that we are using live cells, so we can capture dynamic cellular changes and fluctuations that can be crucial for the understanding of cellular responses.
Background and purpose: In patients with epilepsies of structural origin, brain atrophy and pathological alterations of the tissue microstructure extending beyond the putative epileptogenic lesion have been reported. However, in patients without any evidence of epileptogenic lesions on diagnostic magnetic resonance imaging (MRI), impairment of the brain microstructure has been scarcely elucidated. Using multiparametric quantitative (q) magnetic resonance imaging MRI, we aimed to investigate diffuse impairment of the microstructural tissue integrity in MRI-negative focal epilepsy patients.
Methods: 27 MRI-negative patients with focal epilepsy (mean age 33.1 ± 14.2 years) and 27 matched healthy control subjects underwent multiparametric qMRI including T1, T2, and PD mapping at 3 T. After tissue segmentation based on synthetic anatomies, mean qMRI parameter values were extracted from the cerebral cortex, the white matter (WM) and the deep gray matter (GM) and compared between patients and control subjects. Apart from calculating mean values for the qMRI parameters across the respective compartments, voxel-wise analyses were performed for each tissue class.
Results: There were no significant differences for mean values of quantitative T1, T2, and PD obtained from the cortex, the WM and the deep GM between the groups. Furthermore, the voxel-wise analyses did not reveal any clusters indicating significant differences between patients and control subjects for the qMRI parameters in the respective compartments.
Conclusions: Based on the employed methodology, no indication for an impairment of the cerebral microstructural tissue integrity in MRI-negative patients with focal epilepsy was found in this study. Further research will be necessary to identify relevant factors and mechanisms contributing to microstructural brain tissue damage in various subgroups of patients with epilepsy.
The hippocampal-dependent memory system and striatal-dependent memory system modulate reinforcement learning depending on feedback timing in adults, but their contributions during development remain unclear. In a 2-year longitudinal study, 6-to-7-year-old children performed a reinforcement learning task in which they received feedback immediately or with a short delay following their response. Children’s learning was found to be sensitive to feedback timing modulations in their reaction time and inverse temperature parameter, which quantifies value-guided decision-making. They showed longitudinal improvements towards more optimal value-based learning, and their hippocampal volume showed protracted maturation. Better delayed model-derived learning covaried with larger hippocampal volume longitudinally, in line with the adult literature. In contrast, a larger striatal volume in children was associated with both better immediate and delayed model-derived learning longitudinally. These findings show, for the first time, an early hippocampal contribution to the dynamic development of reinforcement learning in middle childhood, with neurally less differentiated and more cooperative memory systems than in adults.