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The trace elements zinc and manganese are essential for human health, especially due to their enzymatic and protein stabilizing functions. If these elements are ingested in amounts exceeding the requirements, regulatory processes for maintaining their physiological concentrations (homeostasis) can be disturbed. Those homeostatic dysregulations can cause severe health effects including the emergence of neurodegenerative disorders such as Parkinson’s disease (PD). The concentrations of essential trace elements also change during the aging process. However, the relations of cause and consequence between increased manganese and zinc uptake and its influence on the aging process and the emergence of the aging-associated PD are still rarely understood. This doctoral thesis therefore aimed to investigate the influence of a nutritive zinc and/or manganese oversupply on the metal homeostasis during the aging process. For that, the model organism Caenorhabditis elegans (C. elegans) was applied. This nematode suits well as an aging and PD model due to properties such as its short life cycle and its completely sequenced, genetically amenable genome. Different protocols for the propagation of zinc- and/or manganese-supplemented young, middle-aged and aged C. elegans were established. Therefore, wildtypes, as well as genetically modified worm strains modeling inheritable forms of parkinsonism were applied. To identify homeostatic and neurological alterations, the nematodes were investigated with different methods including the analysis of total metal contents via inductively-coupled plasma tandem mass spectrometry, a specific probe-based method for quantifying labile zinc, survival assays, gene expression analysis as well as fluorescence microscopy for the identification and quantification of dopaminergic neurodegeneration.. During aging, the levels of iron, as well as zinc and manganese increased.. Furthermore, the simultaneous oversupply with zinc and manganese increased the total zinc and manganese contents to a higher extend than the single metal supplementation. In this relation the C. elegans metallothionein 1 (MTL-1) was identified as an important regulator of metal homeostasis. The total zinc content and the concentration of labile zinc were age-dependently, but differently regulated. This elucidates the importance of distinguishing these parameters as two independent biomarkers for the zinc status. Not the metal oversupply, but aging increased the levels of dopaminergic neurodegeneration. Additionally, nearly all these results yielded differences in the aging-dependent regulation of trace element homeostasis between wildtypes and PD models. This confirms that an increased zinc and manganese intake can influence the aging process as well as parkinsonism by altering homeostasis although the underlying mechanisms need to be clarified in further studies.
Systemic inflammation is a hallmark of cancer cachexia. Among tumor-host interactions, the white adipose tissue (WAT) is an important contributor to inflammation as it suffers morphological reorganization and lipolysis, releasing free fatty acids (FA), bioactive lipid mediators (LM) and pro-inflammatory cytokines, which accentuate the activation of pro-inflammatory signaling pathways and the recruitment of immune cells to the tissue. This project aimed to investigate which inflammatory factors are involved in the local adipose tissue inflammation and what is the influence of such factors upon enzymes involved in FA or LM metabolism in healthy individuals (Control), weight stable gastro-intestinal cancer patients (WSC) and cachectic cancer patients (CC). The results demonstrated that the inflammatory signature of systemic inflammation is different from local adipose tissue inflammation. The systemic inflammation of the cachectic cancer patients was characterized by higher levels of circulating saturated fatty acids (SFA), tumor-necrosis-factor-α (TNF-α), interleukins IL-6, IL-8 and CRP while levels of polyunsaturated fatty acids (PUFAs), especially n3-PUFAs, were lower in CC than in the other groups. In vitro and in adipose tissue explants, pro-inflammatory cytokines and SFAs were shown to increase the chemokines IL-8 and CXCL10 that were found to be augmented in adipose tissue inflammation in CC which was more profound in the visceral adipose tissue (VAT) than in subcutaneous adipose tissue (SAT). Systemic inflammation was negatively associated with the expression of PUFA synthesizing enzymes, though gene and protein expression did hardly differ between groups. The effects of inflammatory factors on enzymes in the whole tissue could have been masked by differentiated modulation of the diverse cell types in the same tissue. In vitro experiments showed that the expression of FA-modifying enzymes such as desaturases and elongases in adipocytes and macrophages was regulated into opposing directions by TNF-α, IL-6, LPS or palmitate. The higher plasma concentration of the pro-resolving LM resolvin D1 in CC cannot compensate the overall inflammatory status and the results indicate that inflammatory cytokines interfere with synthesis pathways of pro-resolving LM. In summary, the data revealed a complex inter-tissue and inter-cellular crosstalk mediated by pro-inflammatory cytokines and lipid compounds enhancing inflammation in cancer cachexia by feed-forward mechanisms.
Microbiota analyses of patients suffering from various diseases suggest a beneficial role of Akkermansia muciniphila in the maintenance of health, whereas several studies in animal models of intestinal inflammation report that this organism may aggravate inflammation. Therefore, it is important to clarify under which circumstances A. muciniphila exerts negative effects in the intestine of its host.
The previously reported observation that A. muciniphila aggravates acute intestinal inflammation in the Salmonella enterica serovar Typhimurium infection mouse model colonized with a simplified human intestinal microbiota was investigated in this study. To unravel the underlying mechanism that led to the observed phenomenon, the time course of events following the infection was analyzed. In mice colonized with a simplified human intestinal microbiota, Salmonella infection induced clear signs of intestinal inflammation three days post infection. The inflammatory response was similar in mice colonized with A. muciniphila before Salmonella infection. These observations were independent of the time when colonization with the simplified human intestinal microbiota occurred, right after birth or only after weaning, and contradict the previous report.
To find out whether A. muciniphila influences the development of chronic intestinal inflammation in a genetically predisposed host, mono-associated interleukin-10-deficient (Il10-/-) mice, Il10-/- mice dual-associated with A. muciniphila and colitogenic Escherichia coli NC101, as well as Il10-/- mice associated with A. muciniphila and a simplified human intestinal microbiota were compared to the respective mice without A. muciniphila. The data clearly show that in these gnotobiotic Il10-/- mice, A. muciniphila neither induces intestinal inflammation itself nor modulates it after induction by a colitogenic bacterium or by a simplified human intestinal microbiota.
The experiments lead to the conclusion that the promotion of intestinal inflammation is not an intrinsic feature of this bacterium. The results of this study encourage the proposed use of A. muciniphila for the prevention or treatment of metabolic disorders.
The development of type 2 diabetes (T2D) is driven by genetic as well as life style factors. However, even genetically identical female NZO mice on a high-fat diet show a broad variation in T2D onset. The main objective of this study was to elucidate and investigate early epigenetic determinants of type 2 diabetes. Prior to other experiments, early fat content of the liver (<55.2 HU) in combination with blood glucose concentrations (>8.8 mM) were evaluated as best predictors of diabetes in NZO females. Then, DNA methylome and transcriptome were profiled to identify molecular pathophysiological changes in the liver before diabetes onset. The major finding of this thesis is that alterations in the hepatic DNA methylome precede diabetes onset. Of particular interest were 702 differentially methylated regions (DMRs), of which 506 DMRs had genic localization. These inter-individual DMRs were enriched by fivefold in the KEGG pathway type 2 diabetes mellitus, independent of the level of gene expression, demonstrating an epigenetic predisposition toward diabetes. Interestingly, among the list of hepatic DMRs, eleven DMRs were associated with known imprinted genes in the mouse genome. Thereby, six DMRs (Nap1l5, Mest, Plagl1, Gnas, Grb10 and Slc38a4) localized to imprinting control regions, including five iDMRs that exhibited hypermethylation in livers of diabetes-prone mice. This suggests that gain of DNA methylation in multiple loci of the paternal alleles has unfavourable metabolic consequences for the offspring. Further, the comparative liver transcriptome analysis demonstrated differences in expression levels of 1492 genes related to metabolically relevant pathways, such as citrate cycle and fatty acid metabolism. The integration of hepatic transcriptome and DNA methylome indicated that 449 differentially expressed genes were potentially regulated by DNA methylation, including genes implicated in insulin signaling. In addition, liver transcriptomic profiling of diabetes-resistant and diabetes-prone mice revealed a potential transcriptional dysregulation of 17 hepatokines, in particular Hamp. The hepatic expression of Hamp was decreased by 52% in diabetes-prone mice, on account of an increase in DNA methylation of promoter CpG-118. Hence, HAMP protein levels were lower in mice prone to develop diabetes, which correlated to higher liver triglyceride levels.. In sum, the identified DNA methylation changes appear to collectively favor the initiation and progression of diabetes in female NZO mice. In near future, epigenetic biomarkers are likely to contribute to improved diagnosis for T2D.
The impact of collagen modifications by methylglyoxal on fibroblast function and the role in aging
(2016)
Aging is a complex process characterized by several factors, including loss of genetic and epigenetic information, accumulation of chronic oxidative stress, protein damage and aggregates and it is becoming an emergent drug target. Therefore, it is the utmost importance to study aging and agerelated diseases, to provide treatments to develop a healthy aging process. Skeletal muscle is one of the earliest tissues affected by age-related changes with progressive loss of muscle mass and function from 30 years old, effect known as sarcopenia. Several studies have shown the accumulation of protein aggregates in different animal models, as well as in humans, suggesting impaired proteostasis, a hallmark of aging, especially regarding degradation systems. Thus, different publications have explored the role of the main proteolytic systems in skeletal muscle from rodents and humans, like ubiquitin proteasomal system (UPS) and autophagy lysosomal system (ALS), however with contradictory results. Yet, most of the published studies are performed in muscles that comprise more than one fiber type, that means, muscles composed by slow and fast fibers. These fiber types, exhibit different metabolism and contraction speed; the slow fibers or type I display an oxidative metabolism, while fast fibers function towards a glycolytic metabolism ranging from fast oxidative to fast glycolytic fibers. To this extent, the aim of this thesis sought to understand on how aging impacts both fiber types not only regarding proteostasis but also at a metabolome and transcriptome network levels. Therefore, the first part of this thesis, presents the differences between slow oxidative (from Soleus muscle) and fast glycolytic fibers (Extensor digitorum longus, EDL) in terms of degradation systems and how they cope with oxidative stress during aging, while the second part explores the differences between young and old EDL muscle transcriptome and metabolome, unraveling molecular features. More specifically, the results from the present work show that slow oxidative muscle performs better at maintaining the function of UPS and ALS during aging than EDL muscle, which is clearly affected, accounting for the decline in the catalytic activity rates and accumulation of autophagy-related proteins. Strinkingly, transcriptome and metabolome analyses reveal that fast glycolytic muscle evidences significant downregulation of mitochondrial related processes and damaged mitochondria morphology during aging, despite of having a lower oxidative metabolism compared to oxidative fibers. Moreover, predictive analyses reveal a negative association between aged EDL gene signature and lifespan extending interventions such as caloric restriction (CR). Although, CR intervention does not alter the levels of mitochondrial markers in aged EDL muscle, it can reverse the higher mRNA levels of muscle damage markers. Together, the results from this thesis give new insights about how different metabolic muscle fibers cope with age-related changes and why fast glycolytic fibers are more susceptible to aging than slow oxidative fibers.
Sex-specific differences in the regulation of body weight dynamics and adipose tissue metabolism
(2014)
Eine Störung des Leberstoffwechsels durch die Ausbildung einer Insulinresistenz kann zu Folgeerkrankungen wie der nicht alkoholischen Fettlebererkrankung (NAFLD) bis hin zur Steatohepatitis (NASH) und zur Entwicklung eines Diabetes Typ II führen. Am Krankheitsverlauf sind residente (Kupfferzellen) sowie infiltrierende Makrophagen beteiligt, die durch inflammatorische Stimuli aktiviert werden und zur Progression von Lebererkrankungen führen können. Im Rahmen dieser Arbeit wurde die Rolle von mPGES1-abhängig gebildetem Prostaglandin E2 (PGE2) an der Modulation von aktivierten Lebermakrophagen untersucht. Dazu wurden Kupfferzellen und Peritonealmakrophagen (als Modell für infiltrierende Makrophagen) aus Wildtyp und mPGES1-defizienten Mäusen isoliert. Beide Makrophagenpopulationen wurden in Zellkulturversuchen mit Lipopolysacchariden (LPS) aktiviert und auf ihre PGE2-Synthese, Genexpression und Sekretion von verschiedenen Cytokinen hin untersucht. Die beiden Makrophagenpopulationen unterschieden sich hinsichtlich der PGE2-Synthese bei mPGSE1-Defizienz. Während bei Peritonealmakrophagen die LPS-abhängige PGE2-Synthese bei Abwesenheit der mPGES1 fast vollständig reprimiert war, war bei Kupfferzellen nur eine 25%ige Abnahme zu verzeichnen. Die postulierte selbstverstärkende Rückkopplungsschleife von PGE2 im Hinblick auf seine eigene Synthese konnte in isolierten Peritonealmakrophagen, nicht jedoch in Kupfferzellen, bestätigt werden. In Kupfferzellen führte exogenes PGE2 ferner zu einer Repression von den pro-inflammatorischen Cytokinen TNFα und IL-1β und für endogenes PGE2 konnte in diesem Zelltyp kein Effekt festgestellt werden. In Peritonealmakrophagen konnte hingegen auch für endogenes PGE2 eine reprimierende Wirkung auf die Expression von TNFα beobachtet werden. Das ist eventuell auf eine höhere Sensitivität gegenüber PGE2 von Peritonealmakrophagen im Vergleich zu Kupfferzellen zurückzuführen. PGE2 wirkte unter den gewählten Versuchsbedingungen in vitro somit eher anti-inflammatorisch. Cholesterolkristalle induzierten in Kupfferzellen die Expression der PGE2-synthetisierenden Enzyme und verschiedener pro-inflammatorische Cytokine. Sie könnten somit zu einer Progression von NAFL zu NASH beitragen. Die Daten aus dieser Arbeit deuten darauf hin, dass PGE2 im Rahmen von entzündlichen Leberveränderungen eine eher protektive Wirkung im Hinblick auf die Progression von NAFLD und Insulinresistenz haben könnte.
Pannexin 1
(2022)
Hypoxic pulmonary vasoconstriction is an active alveolar hypoxia-caused physiological response redirecting pulmonary blood flow from poorly ventilated areas to better oxygenated lung regions in order to optimize oxygen supply. However, the signaling pathways underlying this pulmonary vascular response remain an area under investigation. In the present study I investigated the functional relevance of Pannexin 1 (Panx1)-mediated ATP release in hypoxic pulmonary vasoconstriction and chronic hypoxic pulmonary hypertension using murine isolated perfused lungs, chronic hypoxic mice, and pulmonary artery smooth muscle cell culture. In isolated mouse lungs, switch to hypoxic gas induced a marked increase in pulmonary artery pressure. Pharmacological inhibition of Panx1 using probenecid, Panx1 specific inhibitory peptide (10Panx1) or spironolactone as well as genetic deletion of Panx1 in smooth muscle cells diminished hypoxic pulmonary vasoconstriction in isolated perfused mouse lungs. Fura-2 imaging revealed a reduced Ca2+ response to hypoxia in pulmonary artery smooth muscle cells treated with spironolactone or 10Panx1. Although these findings suggested an important role of Panx1 in HPV, neither smooth muscle cell nor endothelial cell specific genetic deletion of Panx1 prevented the development of pulmonary hypertension in chronic hypoxic mice. Surprisingly, hypoxia did not induce ATP release and inhibition of purinergic receptors or ATP degradation by ATPase failed to decrease the pulmonary vasoconstriction response to hypoxia in isolated perfused mouse lungs. However, Panx1 antagonism as well as TRPV4 inhibition prevented the hypoxia-induced increase in intracellular Ca2+ concentration in pulmonary artery smooth muscle cells in an additive manner suggesting that Panx1 might modulate intracellular Ca2+ signaling independently of the ATP-P2-TRPV4 signaling axis. In line with this assumption, overexpression of Panx1 in HeLa cells increased intracellular Ca2+ concentrations in response to acute hypoxia. Conclusion: In this study I identifiy Panx1 as novel regulator of HPV.. Yet, the role of Panx1 was not attributable to the release of ATP and downstream P2 signaling pathways or activation of TRPV4 but rathter relates to a role of Panx1 as indirect or direct modulator of the Ca2+ response to hypoxia in PASMCs. Genetic deletion of Panx1 did not influence the development of chronic hypoxic pulmonary hypertension in mice.