@phdthesis{Naseri2018,
  author    = {Naseri, Gita},
  title     = {Plant-derived transcription factors and their application for synthetic biology approaches in Saccharomyces cerevisiae},
  doi       = {10.25932/publishup-42151},
  url       = {http://nbn-resolving.de/urn:nbn:de:kobv:517-opus4-421514},
  school      = {Universit{\"a}t Potsdam},
  pages     = {187},
  year      = {2018},
  abstract  = {Bereits seit 9000 Jahren verwendet die Menschheit die B{\"a}ckerhefe Saccharomyces cerevisiae f{\"u}r das Brauen von Bier, aber erst seit 150 Jahren wissen wir, dass es sich bei diesem unerm{\"u}dlichen Helfer im Brauprozess um einzellige, lebende Organismen handelt. Und die B{\"a}ckerhefe kann noch viel mehr. Im Rahmen des Forschungsgebietes der Synthetischen Biologie soll unter anderem die B{\"a}ckerhefe als innovatives Werkzeug f{\"u}r die biobasierte Herstellung verschiedenster Substanzen etabliert werden. Zu diesen Substanzen z{\"a}hlen unter anderem Feinchemikalien, Biokraftstoffe und Biopolymere sowie pharmakologisch und medizinisch interessante Pflanzenstoffe. Damit diese verschiedensten Substanzen in der B{\"a}ckerhefe hergestellt werden k{\"o}nnen, m{\"u}ssen große Mengen an Produktionsinformationen zum Beispiel aus Pflanzen in die Hefezellen {\"u}bertragen werden. Dar{\"u}ber hinaus m{\"u}ssen die neu eingebrachten Biosynthesewege reguliert und kontrolliert in den Zellen ablaufen. Auch Optimierungsprozesse zur Erh{\"o}hung der Produktivit{\"a}t sind notwendig. F{\"u}r alle diese Arbeitsschritte mangelt es bis heute an anwendungsbereiten Technologien und umfassenden Plattformen. Daher wurden im Rahmen dieser Doktorarbeit verschiedene Technologien und Plattformen zur Informations{\"u}bertragung, Regulation und Prozessoptimierung geplant und erzeugt. F{\"u}r die Konstruktion von Biosynthesewegen in der B{\"a}ckerhefe wurde als erstes eine Plattform aus neuartigen Regulatoren und Kontrollelementen auf der Basis pflanzlicher Kontrollelemente generiert und charakterisiert. Im zweiten Schritt erfolgte die Entwicklung einer Technologie zur kombinatorischen Verwendung der Regulatoren in der Planung und Optimierung von Biosynthesewegen (COMPASS). Abschließend wurde eine Technologie f{\"u}r die Prozessoptimierung der ver{\"a}nderten Hefezellen entwickelt (CapRedit). Die Leistungsf{\"a}higkeit der entwickelten Plattformen und Technologien wurde durch eine Optimierung der Produktion von Carotenoiden (Beta-Carotin und Beta-Ionon) und Flavonoiden (Naringenin) in Hefezellen nachgewiesen. Die im Rahmen der Arbeit etablierten neuartigen Plattformen und innovativen Technologien sind ein wertvoller Grundbaustein f{\"u}r die Erweiterung der Nutzbarkeit der B{\"a}ckerhefe. Sie erm{\"o}glichen den Einsatz der Hefezellen in kosteneffizienten Produktionswegen und alternativen chemischen Wertsch{\"o}pfungsketten. Dadurch k{\"o}nnen zum Beispiel Biokraftstoffe und pharmakologisch interessante Pflanzenstoffe unter Verwendung von nachwachsenden Rohstoffen, Reststoffen und Nebenprodukten hergestellt werden. Dar{\"u}ber hinaus ergeben sich Anwendungsm{\"o}glichkeiten zur Bodensanierung und Wasseraufbereitung.},
  language  = {en}
}
@phdthesis{Lawas2018,
  author    = {Lawas, Lovely Mae F.},
  title     = {Molecular characterization of rice exposed to heat and drought stress at flowering and early grain filling},
  pages     = {VII, 150},
  year      = {2018},
  language  = {en}
}
@phdthesis{Albers2018,
  author    = {Albers, Philip},
  title     = {Funktionelle Charakterisierung des bakteriellen Typ-III Effektorproteins HopZ1a in Nicotiana benthamiana},
  school      = {Universit{\"a}t Potsdam},
  pages     = {viii, 134},
  year      = {2018},
  abstract  = {Um das Immunsystem der Pflanze zu manipulieren translozieren gram-negative pathogene Bakterien Typ-III Effektorproteine (T3E) {\"u}ber ein Typ-III Sekretionssystem (T3SS) in die pflanzliche Wirtszelle. Dort lokalisieren T3Es in verschiedenen subzellul{\"a}ren Kompartimenten, wo sie Zielproteine modifizieren und so die Infektion beg{\"u}nstigen. HopZ1a, ein T3E des Pflanzenpathogens Pseudomonas syringae pv. syringae, ist eine Acetyltransferase und lokalisiert {\"u}ber ein Myristolierungsmotiv an der Plasmamembran der Wirtszelle. Obwohl gezeigt wurde, dass HopZ1a die fr{\"u}he Signalweiterleitung an der Plasmamembran st{\"o}rt, wurde bisher kein mit der Plasmamembran assoziiertes Zielprotein f{\"u}r diesen T3E identifiziert. Um bisher unbekannte HopZ1a-Zieleproteine zu identifizieren wurde im Vorfeld dieser Arbeit eine Hefe-Zwei-Hybrid-Durchmusterung mit einer cDNA-Bibliothek aus Tabak durchgef{\"u}hrt, wobei ein nicht n{\"a}her charakterisiertes Remorin als Interaktor gefunden wurde. Bei dem Remorin handelt es sich um einen Vertreter der Gruppe 4 der Remorin-Familie, weshalb es in NbREM4 umbenannt wurde. Durch den Einsatz verschiedener Interaktionsstudien konnte demonstriert werden, dass HopZ1a mit NbREM4 in Hefe, in vitro und in planta wechselwirkt. Es wurde ferner deutlich, dass HopZ1a auf spezifische Weise mit dem konservierten C-Terminus von NbREM4 interagiert, das Remorin jedoch in vitro nicht acetyliert. Analysen mittels BiFC haben zudem ergeben, dass NbREM4 in Homodimeren an der Plasmamembran lokalisiert, wo auch die Interaktion mit HopZ1a stattfindet. Eine funktionelle Charakterisierung von NbREM4 ergab, dass das Remorin eine spezifische Rolle im Immunsystem der Pflanze einnimmt. Die transiente Expression in N. benthamiana induziert die Expression von Abwehrgenen sowie einen ver{\"a}nderten Blattph{\"a}notyp. In A. thaliana wird HopZ1a {\"u}ber das Decoy ZED1 und das R-Protein ZAR1 erkannt, was zur Ausl{\"o}sung einer starken Hypersensitiven Antwort (HR von hypersensitive response) f{\"u}hrt. Es konnte im Rahmen dieser Arbeit gezeigt werden, dass ZAR1 in N. benthamiana konserviert ist, NbREM4 jedoch nicht in der ETI als Decoy fungiert. Mit Hilfe einer Hefe-Zwei-Hybrid-Durchmusterung mit NbZAR1 als K{\"o}der konnten zwei Proteine, die Catalase CAT1 und der Protonenpumpeninteraktor PPI1, als Interaktoren von NbZAR1 identifiziert werden, welche m{\"o}glicherweise in der Regulation der HR eine Rolle spielen. Aus Voruntersuchungen war bekannt, dass NbREM4 mit weiteren, nicht n{\"a}her charakterisierten Proteinen aus Tabak interagieren k{\"o}nnte. Eine phylogenetische Einordnung hat gezeigt, dass es sich um die bekannte Immun-Kinase PBS1 sowie zwei E3-Ubiquitin-Ligasen, NbSINA1 und NbSINAL3, handelt. PBS1 interagiert mit NbREM4 an der Plasmamembran und phosphoryliert das Remorin innerhalb des intrinsisch ungeordneten N-Terminus. Mittels Massenspektrometrie konnten die Serine an Position 64 und 65 innerhalb der Aminos{\"a}uresequenz von NbREM4 als PBS1-abh{\"a}ngige Phosphorylierungsstellen identifiziert wurden. NbSINA1 und NbSINAL3 besitzen in vitro Ubiquitinierungsaktivit{\"a}t, bilden Homo- und Heterodimere und interagieren ebenfalls mit dem N-terminalen Teil von NbREM4, wobei sie das Remorin in vitro nicht ubiquitinieren. Aus den in dieser Arbeit gewonnenen Ergebnissen l{\"a}sst sich ableiten, dass der bakterielle T3E HopZ1a gezielt mit dem Tabak-Remorin NbREM4 an der Plasmamembran interagiert und {\"u}ber einen noch unbekannten Mechanismus mit dem Immunsystem der Pflanze interferiert, wobei NbREM4 m{\"o}glicherweise eine Rolle als Adapter- oder Ankerprotein zukommt, {\"u}ber welches HopZ1a mit weiteren Immunkomponenten interagiert. NbREM4 ist Teil eines gr{\"o}ßeren Immunnetzwerkes, zu welchem die bekannte Immun-Kinase PBS1 und zwei E3-Ubiquitin-Ligasen geh{\"o}ren. Mit NbREM4 konnte damit erstmalig ein membranst{\"a}ndiges Protein mit einer Funktion im Immunsystem der Pflanze als Zielprotein von HopZ1a identifiziert werden.},
  language  = {de}
}
@phdthesis{Meyer2018,
  author    = {Meyer, Susann},
  title     = {Wirkung und Wirkungsweise von Ectoin auf DNA-Molek{\"u}le},
  school      = {Universit{\"a}t Potsdam},
  pages     = {103},
  year      = {2018},
  language  = {de}
}
@phdthesis{Fer2018,
  author    = {Fer, Istem},
  title     = {Modeling past, present and future climate induced vegetation changes in East Africa},
  doi       = {10.25932/publishup-42777},
  url       = {http://nbn-resolving.de/urn:nbn:de:kobv:517-opus4-427777},
  school      = {Universit{\"a}t Potsdam},
  pages     = {xxii, 156},
  year      = {2018},
  abstract  = {Ostafrika ist ein nat{\"u}rliches Labor: Durch ein Studium seiner einzigartigen geologischen und biologischen Geschichte lassen sich unsere Theorien und Modelle {\"u}berpr{\"u}fen und verbessern. Ein Studium seiner Gegenwart und seiner Zukunft wiederum hilft uns dabei, die global bedeutende Artenvielfalt und die {\"o}kosystemaren Dienstleistungen Ostafrikas zu sch{\"u}tzen. Eine zentrale Rolle spielt dabei spielt die ostafrikanische Vegetation, deren Dynamiken in dieser Dissertation durch Computersimulationen quantifiziert werden sollen. {\"U}ber Computersimulationen lassen sich fr{\"u}here Rahmenbedingungen reproduzieren, Voraussagen treffen oder Simulationsexperimente durchf{\"u}hren, die durch Feldforschung nicht m{\"o}glich w{\"a}ren. Zuallererst muss jedoch ihre Leistungsf{\"a}higkeit {\"u}berpr{\"u}ft werden. Die von dem Modell anhand der heutigen Inputs gelieferten Ergebnisse stimmten weitgehend mit heutigen Beobachtungen ostafrikanischer Vegetation {\"u}berein. Als n{\"a}chstes wurde die fr{\"u}here Vegetation simuliert, f{\"u}r die fossile Pollen-Daten zum Abgleich vorliegen. {\"U}ber Computermodelle lassen sich Wissensl{\"u}cken zwischen Standorten {\"u}berbr{\"u}cken, bei denen wir {\"u}ber fossile Pollen-Daten verf{\"u}gen, sodass ein vollst{\"a}ndigeres Bild der Vergangenheit entsteht. Zus{\"a}tzlich validiert wurde die Leistungsf{\"a}higkeit des Modells durch die hohe {\"U}bereinstimmung zwischen Modell und Pollen-Daten, wo sie im Raum {\"u}berlappen. Nachdem das Modell getestet und f{\"u}r die Region validiert war, konnte eine der seit langem offenen Fragen {\"u}ber die ostafrikanische Vegetation angegangen werden, n{\"a}mlich wie Ostafrika seines Tropenwaldes verlustig gehen konnte. In den Tropen wird die heutige Vegetation weltweit haupts{\"a}chlich von W{\"a}ldern dominiert, mit Ausnahme der Tropengebiete Ostafrikas, wo W{\"a}lder nur noch stellenweise an der K{\"u}ste und im Hochland vorkommen. Durch eine Reihe von Simulationsexperimenten konnte aufgezeigt werden, unter welchen Bedingungen jene Waldgebiete fr{\"u}her zusammenhingen und schließlich fragmentiert wurden. Die Studie hat erwiesen, wie empfindlich die ostafrikanische Vegetation f{\"u}r die Klimaschwankungen ist, die durch den k{\"u}nftigen Klimawandel zu erwarten sind. Weitere Auswirkungen auf das ostafrikanische Klima ergeben sich aus dem El Ni{\~n}o/Southern Oscillation-Ph{\"a}nomen (ENSO), das aus Temperaturfluktuationen zwischen dem Ozean und der Atmosph{\"a}re herr{\"u}hrt und k{\"u}nftig an Intensit{\"a}t zunehmen d{\"u}rfte. Die derzeitigen Klimamodelle sind allerdings noch nicht gut genug beim Erfassen solcher Ereignismuster. In einer Studie wurde der Einfluss des ENSO-Ph{\"a}nomens auf die ostafrikanische Vegetation quantifiziert und dabei aufgezeigt, wie sehr sich die k{\"u}nftige Vegetation von den heute simulierten Ergebnissen unterscheiden k{\"o}nnte, bei denen der genaue ENSO-Beitrag nicht ber{\"u}cksichtigt werden kann. Bei der Berechnung der k{\"u}nftigen weltweiten CO2-Bilanz und den zu treffenden Entscheidungen stellt dies einen zus{\"a}tzlichen Unsicherheitsfaktor dar.},
  language  = {en}
}
@phdthesis{Ullmann2018,
  author    = {Ullmann, Wiebke},
  title     = {Understanding animal movement behaviour in dynamic agricultural landscapes},
  doi       = {10.25932/publishup-42715},
  url       = {http://nbn-resolving.de/urn:nbn:de:kobv:517-opus4-427153},
  school      = {Universit{\"a}t Potsdam},
  pages     = {vii, 183},
  year      = {2018},
  abstract  = {The movement of organisms has formed our planet like few other processes. Movements shape populations, communities, entire ecosystems, and guarantee fundamental ecosystem functions and services, like seed dispersal and pollination. Global, regional and local anthropogenic impacts influence animal movements across ecosystems all around the world. In particular, land-use modification, like habitat loss and fragmentation disrupt movements between habitats with profound consequences, from increased disease transmissions to reduced species richness and abundance. However, neither the influence of anthropogenic change on animal movement processes nor the resulting effects on ecosystems are well understood. Therefore, we need a coherent understanding of organismal movement processes and their underlying mechanisms to predict and prevent altered animal movements and their consequences for ecosystem functions. In this thesis I aim at understanding the influence of anthropogenically caused land-use change on animal movement processes and their underlying mechanisms. In particular, I am interested in the synergistic influence of large-scale landscape structure and fine-scale habitat features on basic-level movement behaviours (e.g. the daily amount of time spend running, foraging, and resting) and their emerging higher-level movements (home range formation). Based on my findings, I identify the likely consequences of altered animal movements that lead to the loss of species richness and abundances. The study system of my thesis are hares in agricultural landscapes. European brown hares (Lepus europaeus) are perfectly suited to study animal movements in agricultural landscapes, as hares are hermerophiles and prefer open habitats. They have historically thrived in agricultural landscapes, but their numbers are in decline. Agricultural areas are undergoing strong land-use changes due to increasing food demand and fast developing agricultural technologies. They are already the largest land-use class, covering 38\% of the world's terrestrial surface. To consider the relevance of a given landscape structure for animal movement behaviour I selected two differently structured agricultural landscapes - a simple landscape in Northern Germany with large fields and few landscape elements (e.g. hedges and tree stands), and a complex landscape in Southern Germany with small fields and many landscape elements. I applied GPS devices (hourly fixes) with internal high-resolution accelerometers (4 min samples) to track hares, receiving an almost continuous observation of the animals' behaviours via acceleration analyses. I used the spatial and behavioural information in combination with remote sensing data (normalized difference vegetation index, or NDVI, a proxy for resource availability), generating an almost complete idea of what the animal was doing when, why and where. Apart from landscape structure (represented by the two differently structured study areas), I specifically tested whether the following fine-scale habitat features influence animal movements: resource, agricultural management events, habitat diversity, and habitat structure. My results show that, irrespective of the movement process or mechanism and the type of fine-scale habitat features, landscape structure was the overarching variable influencing hare movement behaviour. High resource variability forces hares to enlarge their home ranges, but only in the simple and not in the complex landscape. Agricultural management events result in home range shifts in both landscapes, but force hares to increase their home ranges only in the simple landscape. Also the preference of habitat patches with low vegetation and the avoidance of high vegetation, was stronger in the simple landscape. High and dense crop fields restricted hare movements temporarily to very local and small habitat patch remnants. Such insuperable barriers can separate habitat patches that were previously connected by mobile links. Hence, the transport of nutrients and genetic material is temporarily disrupted. This mechanism is also working on a global scale, as human induced changes from habitat loss and fragmentation to expanding monocultures cause a reduction in animal movements worldwide. The mechanisms behind those findings show that higher-level movements, like increasing home ranges, emerge from underlying basic-level movements, like the behavioural modes. An increasing landscape simplicity first acts on the behavioural modes, i.e. hares run and forage more, but have less time to rest. Hence, the emergence of increased home range sizes in simple landscapes is based on an increased proportion of time running and foraging, largely due to longer travelling times between distant habitats and scarce resource items in the landscape. This relationship was especially strong during the reproductive phase, demonstrating the importance of high-quality habitat for reproduction and the need to keep up self-maintenance first, in low quality areas. These changes in movement behaviour may release a cascade of processes that start with more time being allocated to running and foraging, resulting into an increased energy expenditure and may lead to a decline in individual fitness. A decrease in individual fitness and reproductive output will ultimately affect population viability leading to local extinctions. In conclusion, I show that landscape structure has one of the most important effects on hare movement behaviour. Synergistic effects of landscape structure, and fine-scale habitat features, first affect and modify basic-level movement behaviours, that can scales up to altered higher-level movements and may even lead to the decline of species richness and abundances, and the disruption of ecosystem functions. Understanding the connection between movement mechanisms and processes can help to predict and prevent anthropogenically induced changes in movement behaviour. With regard to the paramount importance of landscape structure, I strongly recommend to decrease the size of agricultural fields and increase crop diversity. On the small-scale, conservation policies should assure the year round provision of areas with low vegetation height and high quality forage. This could be done by generating wildflower strips and additional (semi-) natural habitat patches. This will not only help to increase the populations of European brown hares and other farmland species, but also ensure and protects the continuity of mobile links and their intrinsic value for sustaining important ecosystem functions and services.},
  language  = {en}
}
@phdthesis{Bergholz2018,
  author    = {Bergholz, Kolja},
  title     = {Trait-based understanding of plant species distributions along environmental gradients},
  doi       = {10.25932/publishup-42634},
  url       = {http://nbn-resolving.de/urn:nbn:de:kobv:517-opus4-426341},
  school      = {Universit{\"a}t Potsdam},
  pages     = {128},
  year      = {2018},
  abstract  = {For more than two centuries, plant ecologists have aimed to understand how environmental gradients and biotic interactions shape the distribution and co-occurrence of plant species. In recent years, functional trait-based approaches have been increasingly used to predict patterns of species co-occurrence and species distributions along environmental gradients (trait-environment relationships). Functional traits are measurable properties at the individual level that correlate well with important processes. Thus, they allow us to identify general patterns by synthesizing studies across specific taxonomic compositions, thereby fostering our understanding of the underlying processes of species assembly. However, the importance of specific processes have been shown to be highly dependent on the spatial scale under consideration. In particular, it remains uncertain which mechanisms drive species assembly and allow for plant species coexistence at smaller, more local spatial scales. Furthermore, there is still no consensus on how particular environmental gradients affect the trait composition of plant communities. For example, increasing drought because of climate change is predicted to be a main threat to plant diversity, although it remains unclear which traits of species respond to increasing aridity. Similarly, there is conflicting evidence of how soil fertilization affects the traits related to establishment ability (e.g., seed mass). In this cumulative dissertation, I present three empirical trait-based studies that investigate specific research questions in order to improve our understanding of species distributions along environmental gradients. In the first case study, I analyze how annual species assemble at the local scale and how environmental heterogeneity affects different facets of biodiversity—i.e. taxonomic, functional, and phylogenetic diversity—at different spatial scales. The study was conducted in a semi-arid environment at the transition zone between desert and Mediterranean ecosystems that features a sharp precipitation gradient (Israel). Different null model analyses revealed strong support for environmentally driven species assembly at the local scale, since species with similar traits tended to co-occur and shared high abundances within microsites (trait convergence). A phylogenetic approach, which assumes that closely related species are functionally more similar to each other than distantly related ones, partly supported these results. However, I observed that species abundances within microsites were, surprisingly, more evenly distributed across the phylogenetic tree than expected (phylogenetic overdispersion). Furthermore, I showed that environmental heterogeneity has a positive effect on diversity, which was higher on functional than on taxonomic diversity and increased with spatial scale. The results of this case study indicate that environmental heterogeneity may act as a stabilizing factor to maintain species diversity at local scales, since it influenced species distribution according to their traits and positively influenced diversity. All results were constant along the precipitation gradient. In the second case study (same study system as case study one), I explore the trait responses of two Mediterranean annuals (Geropogon hybridus and Crupina crupinastrum) along a precipitation gradient that is comparable to the maximum changes in precipitation predicted to occur by the end of this century (i.e., -30\%). The heterocarpic G. hybridus showed strong trends in seed traits, suggesting that dispersal ability increased with aridity. By contrast, the homocarpic C. crupinastrum showed only a decrease in plant height as aridity increased, while leaf traits of both species showed no consistent pattern along the precipitation gradient. Furthermore, variance decomposition of traits revealed that most of the trait variation observed in the study system was actually found within populations. I conclude that trait responses towards aridity are highly species-specific and that the amount of precipitation is not the most striking environmental factor at this particular scale. In the third case study, I assess how soil fertilization mediates—directly by increased nutrient addition and indirectly by increased competition—the effect of seed mass on establishment ability. For this experiment, I used 22 species differing in seed mass from dry grasslands in northeastern Germany and analyzed the interacting effects of seed mass with nutrient availability and competition on four key components of seedling establishment: seedling emergence, time of seedling emergence, seedling survival, and seedling growth. (Time of) seedling emergence was not affected by seed mass. However, I observed that the positive effect of seed mass on seedling survival is lowered under conditions of high nutrient availability, whereas the positive effect of seed mass on seedling growth was only reduced by competition. Based on these findings, I developed a conceptual model of how seed mass should change along a soil fertility gradient in order to reconcile conflicting findings from the literature. In this model, seed mass shows a U-shaped pattern along the soil fertility gradient as a result of changing nutrient availability and competition. Overall, the three case studies highlight the role of environmental factors on species distribution and co-occurrence. Moreover, the findings of this thesis indicate that spatial heterogeneity at local scales may act as a stabilizing factor that allows species with different traits to coexist. In the concluding discussion, I critically debate intraspecific trait variability in plant community ecology, the use of phylogenetic relationships and easily measured key functional traits as a proxy for species' niches. Finally, I offer my outlook for the future of functional plant community research.},
  language  = {en}
}
@phdthesis{Zhang2018,
  author    = {Zhang, Yunming},
  title     = {Understanding the functional specialization of poly(A) polymerases in Arabidopsis thaliana},
  school      = {Universit{\"a}t Potsdam},
  pages     = {131},
  year      = {2018},
  language  = {de}
}
@phdthesis{Lehmann2018,
  author    = {Lehmann, Andreas},
  title     = {Variability in human life history traits},
  school      = {Universit{\"a}t Potsdam},
  pages     = {110},
  year      = {2018},
  language  = {de}
}
@phdthesis{Schwahn2018,
  author    = {Schwahn, Kevin},
  title     = {Data driven approaches to infer the regulatory mechanism shaping and constraining levels of metabolites in metabolic networks},
  doi       = {10.25932/publishup-42324},
  url       = {http://nbn-resolving.de/urn:nbn:de:kobv:517-opus4-423240},
  school      = {Universit{\"a}t Potsdam},
  pages     = {109},
  year      = {2018},
  abstract  = {Systems biology aims at investigating biological systems in its entirety by gathering and analyzing large-scale data sets about the underlying components. Computational systems biology approaches use these large-scale data sets to create models at different scales and cellular levels. In addition, it is concerned with generating and testing hypotheses about biological processes. However, such approaches are inevitably leading to computational challenges due to the high dimensionality of the data and the differences in the dimension of data from different cellular layers. This thesis focuses on the investigation and development of computational approaches to analyze metabolite profiles in the context of cellular networks. This leads to determining what aspects of the network functionality are reflected in the metabolite levels. With these methods at hand, this thesis aims to answer three questions: (1) how observability of biological systems is manifested in metabolite profiles and if it can be used for phenotypical comparisons; (2) how to identify couplings of reaction rates from metabolic profiles alone; and (3) which regulatory mechanism that affect metabolite levels can be distinguished by integrating transcriptomics and metabolomics read-outs. I showed that sensor metabolites, identified by an approach from observability theory, are more correlated to each other than non-sensors. The greater correlations between sensor metabolites were detected both with publicly available metabolite profiles and synthetic data simulated from a medium-scale kinetic model. I demonstrated through robustness analysis that correlation was due to the position of the sensor metabolites in the network and persisted irrespectively of the experimental conditions. Sensor metabolites are therefore potential candidates for phenotypical comparisons between conditions through targeted metabolic analysis. Furthermore, I demonstrated that the coupling of metabolic reaction rates can be investigated from a purely data-driven perspective, assuming that metabolic reactions can be described by mass action kinetics. Employing metabolite profiles from domesticated and wild wheat and tomato species, I showed that the process of domestication is associated with a loss of regulatory control on the level of reaction rate coupling. I also found that the same metabolic pathways in Arabidopsis thaliana and Escherichia coli exhibit differences in the number of reaction rate couplings. I designed a novel method for the identification and categorization of transcriptional effects on metabolism by combining data on gene expression and metabolite levels. The approach determines the partial correlation of metabolites with control by the principal components of the transcript levels. The principle components contain the majority of the transcriptomic information allowing to partial out the effect of the transcriptional layer from the metabolite profiles. Depending whether the correlation between metabolites persists upon controlling for the effect of the transcriptional layer, the approach allows us to group metabolite pairs into being associated due to post-transcriptional or transcriptional regulation, respectively. I showed that the classification of metabolite pairs into those that are associated due to transcriptional or post-transcriptional regulation are in agreement with existing literature and findings from a Bayesian inference approach. The approaches developed, implemented, and investigated in this thesis open novel ways to jointly study metabolomics and transcriptomics data as well as to place metabolic profiles in the network context. The results from these approaches have the potential to provide further insights into the regulatory machinery in a biological system.},
  language  = {en}
}