@phdthesis{Hippel2024,
  author    = {Hippel, Barbara von},
  title     = {Long-term bacteria-fungi-plant associations in permafrost soils inferred from palaeometagenomics},
  doi       = {10.25932/publishup-63600},
  url       = {http://nbn-resolving.de/urn:nbn:de:kobv:517-opus4-636009},
  school      = {Universit{\"a}t Potsdam},
  pages     = {xii, 198},
  year      = {2024},
  abstract  = {The arctic is warming 2 - 4 times faster than the global average, resulting in a strong feedback on northern ecosystems such as boreal forests, which cover a vast area of the high northern latitudes. With ongoing global warming, the treeline subsequently migrates northwards into tundra areas. The consequences of turning ecosystems are complex: on the one hand, boreal forests are storing large amounts of global terrestrial carbon and act as a carbon sink, dragging carbon dioxide out of the global carbon cycle, suggesting an enhanced carbon uptake with increased tree cover. On the other hand, with the establishment of trees, the albedo effect of tundra decreases, leading to enhanced soil warming. Meanwhile, permafrost thaws, releasing large amounts of previously stored carbon into the atmosphere. So far, mainly vegetation dynamics have been assessed when studying the impact of warming onto ecosystems. Most land plants are living in close symbiosis with bacterial and fungal communities, sustaining their growth in nutrient poor habitats. However, the impact of climate change on these subsoil communities alongside changing vegetation cover remains poorly understood. Therefore, a better understanding of soil community dynamics on multi millennial timescales is inevitable when addressing the development of entire ecosystems. Unravelling long-term cross-kingdom dependencies between plant, fungi, and bacteria is not only a milestone for the assessment of warming on boreal ecosystems. On top, it also is the basis for agriculture strategies to sustain society with sufficient food in a future warming world. The first objective of this thesis was to assess ancient DNA as a proxy for reconstructing the soil microbiome (Manuscripts I, II, III, IV). Research findings across these projects enable a comprehensive new insight into the relationships of soil microorganisms to the surrounding vegetation. First, this was achieved by establishing (Manuscript I) and applying (Manuscript II) a primer pair for the selective amplification of ancient fungal DNA from lake sediment samples with the metabarcoding approach. To assess fungal and plant co-variation, the selected primer combination (ITS67, 5.8S) amplifying the ITS1 region was applied on samples from five boreal and arctic lakes. The obtained data showed that the establishment of fungal communities is impacted by warming as the functional ecological groups are shifting. Yeast and saprotroph dominance during the Late Glacial declined with warming, while the abundance of mycorrhizae and parasites increased with warming. The overall species richness was also alternating. The results were compared to shotgun sequencing data reconstructing fungi and bacteria (Manuscripts III, IV), yielding overall comparable results to the metabarcoding approach. Nonetheless, the comparison also pointed out a bias in the metabarcoding, potentially due to varying ITS lengths or copy numbers per genome. The second objective was to trace fungus-plant interaction changes over time (Manuscripts II, III). To address this, metabarcoding targeting the ITS1 region for fungi and the chloroplast P6 loop for plants for the selective DNA amplification was applied (Manuscript II). Further, shotgun sequencing data was compared to the metabarcoding results (Manuscript III). Overall, the results between the metabarcoding and the shotgun approaches were comparable, though a bias in the metabarcoding was assumed. We demonstrated that fungal shifts were coinciding with changes in the vegetation. Yeast and lichen were mainly dominant during the Late Glacial with tundra vegetation, while warming in the Holocene lead to the expansion of boreal forests with increasing mycorrhizae and parasite abundance. Aside, we highlighted that Pinaceae establishment is dependent on mycorrhizal fungi such as Suillineae, Inocybaceae, or Hyaloscypha species also on long-term scales. The third objective of the thesis was to assess soil community development on a temporal gradient (Manuscripts III, IV). Shotgun sequencing was applied on sediment samples from the northern Siberian lake Lama and the soil microbial community dynamics compared to ecosystem turnover. Alongside, podzolization processes from basaltic bedrock were recovered (Manuscript III). Additionally, the recovered soil microbiome was compared to shotgun data from granite and sandstone catchments (Manuscript IV, Appendix). We assessed if the establishment of the soil microbiome is dependent on the plant taxon and as such comparable between multiple geographic locations or if the community establishment is driven by abiotic soil properties and as such the bedrock area. We showed that the development of soil communities is to a great extent driven by the vegetation changes and temperature variation, while time only plays a minor role. The analyses showed general ecological similarities especially between the granite and basalt locations, while the microbiome on species-level was rather site-specific. A greater number of correlated soil taxa was detected for deep-rooting boreal taxa in comparison to grasses with shallower roots. Additionally, differences between herbaceous taxa of the late Glacial compared to taxa of the Holocene were revealed. With this thesis, I demonstrate the necessity to investigate subsoil community dynamics on millennial time scales as it enables further understanding of long-term ecosystem as well as soil development processes and such plant establishment. Further, I trace long-term processes leading to podzolization which supports the development of applied carbon capture strategies under future global warming.},
  language  = {en}
}
@phdthesis{Grewe2016,
  author    = {Grewe, Sina},
  title     = {Hydro- and biogeochemical investigations of lake sediments in the Kenyan Rift Valley},
  url       = {http://nbn-resolving.de/urn:nbn:de:kobv:517-opus4-98342},
  school      = {Universit{\"a}t Potsdam},
  pages     = {110},
  year      = {2016},
  abstract  = {Die Seen im kenianischen Riftsystem bieten die einmalige Gelegenheit eine große Bandbreite an hydrochemischen Umweltbedingungen zu studieren, die von S{\"u}ßwasserseen bis hin zu hochsalinen und alkalinen Seen reichen. Da wenig {\"u}ber die hydro- und biogeochemischen Bedingungen in den darunterliegenden Seesedimenten bekannt ist, war es das Ziel dieser Arbeit, bereits existierende Datens{\"a}tze mit Daten aus der Porenwasser- und Biomarker-Analyse zu erweitern. Zus{\"a}tzlich wurden reduzierte Schwefelkomponenten und Sulfatreduktionsraten in den Sedimenten bestimmt. Mit den neu gewonnenen Daten wurde der anthropogene und mikrobielle Einfluss auf die Seesedimente untersucht sowie der Einfluss der Wasserchemie auf den Abbau und den Erhalt von organischem Material im Sediment. Zu den untersuchten Seen geh{\"o}rten: Logipi, Eight (ein kleiner Kratersee in der Region Kangirinyang), Baringo, Bogoria, Naivasha, Oloiden und Sonachi. Die Biomarker-Zusammensetzungen in den untersuchten Seesedimenten waren {\"a}hnlich; allerdings gab es einige Unterschiede zwischen den salinen Seen und den S{\"u}ßwasserseen. Einer dieser Unterschiede war das Vorkommen eines mit β-Carotin verwandten Molek{\"u}ls, das nur in den salinen Seen gefunden wurde. Dieses Molek{\"u}l stammt wahrscheinlich von Cyanobakterien, Einzellern die in großer Anzahl in salinen Seen vorkommen. In den beiden S{\"u}ßwasserseen wurde Stigmasterol gefunden, ein f{\"u}r S{\"u}ßwasseralgen charakteristisches Sterol. In dieser Studie hat sich gezeigt, dass Bogoria und Sonachi f{\"u}r Umweltrekonstruktionen mit Biomarkern besonders gut geeignet sind, da die Abwesenheit von Sauerstoff an deren Seegr{\"u}nden den Abbau von organischem Material verlangsamt. Andere Seen, wie zum Beispiel Naivasha, sind aufgrund des großen anthropogenen Einflusses weniger gut f{\"u}r solche Rekonstruktionen geeignet. Die Biomarker-Analyse bot jedoch die M{\"o}glichkeit, den menschlichen Einfluss auf den See zu studieren. Desweiteren zeigte diese Studie, dass sich Horizonte mit einem hohen Anteil an elementarem Schwefel als temporale Marker nutzen lassen. Diese Horizonte wurden zu einer Zeit abgelagert, als die Wasserpegel sehr niedrig waren. Der Schwefel wurde von Mikroorganismen abgelagert, die zu anoxygener Photosynthese oder Sulfidoxidation f{\"a}hig sind.},
  language  = {en}
}
@phdthesis{Ambili2012,
  author    = {Ambili, Anoop},
  title     = {Lake sediments as climate and tectonic archives in the Indian summer monsoon domain},
  url       = {http://nbn-resolving.de/urn:nbn:de:kobv:517-opus-64799},
  school      = {Universit{\"a}t Potsdam},
  year      = {2012},
  abstract  = {The Indian summer monsoon (ISM) is one of the largest climate systems on earth and impacts the livelihood of nearly 40\% of the world's population. Despite dedicated efforts, a comprehensive picture of monsoon variability has proved elusive largely due to the absence of long term high resolution records, spatial inhomogeneity of the monsoon precipitation, and the complex forcing mechanisms (solar insolation, internal teleconnections for e.g., El Ni{\~n}o-Southern Oscillation, tropical-midlatitude interactions). My work aims to improve the understanding of monsoon variability through generation of long term high resolution palaeoclimate data from climatically sensitive regions in the ISM and westerlies domain. To achieve this aim I have (i) identified proxies (sedimentological, geochemical, isotopic, and mineralogical) that are sensitive to environmental changes; (ii) used the identified proxies to generate long term palaeoclimate data from two climatically sensitive regions, one in NW Himalayas (transitional westerlies and ISM domain in the Spiti valley and one in the core monsoon zone (Lonar lake) in central India); (iii) undertaken a regional overview to generate "snapshots" of selected time slices; and (iv) interpreted the spatial precipitation anomalies in terms of those caused by modern teleconnections. This approach must be considered only as the first step towards identifying the past teleconnections as the boundary conditions in the past were significantly different from today and would have impacted the precipitation anomalies. As the Spiti valley is located in the in the active tectonic orogen of Himalayas, it was essential to understand the role of regional tectonics to make valid interpretations of catchment erosion and detrital influx into the lake. My approach of using integrated structural/morphometric and geomorphic signatures provided clear evidence for active tectonics in this area and demonstrated the suitability of these lacustrine sediments as palaleoseismic archives. The investigations on the lacustrine outcrops in Spiti valley also provided information on changes in seasonality of precipitation and occurrence of frequent and intense periods (ca. 6.8-6.1 cal ka BP) of detrital influx indicating extreme hydrological events in the past. Regional comparison for this time slice indicates a possible extended "break-monsoon like" mode for the monsoon that favors enhanced precipitation over the Tibetan plateau, Himalayas and their foothills. My studies on surface sediments from Lonar lake helped to identify environmentally sensitive proxies which could also be used to interpret palaeodata obtained from a ca. 10m long core raised from the lake in 2008. The core encompasses the entire Holocene and is the first well dated (by 14C) archive from the core monsoon zone of central India. My identification of authigenic evaporite gaylussite crystals within the core sediments provided evidence of exceptionally drier conditions during 4.7-3.9 and 2.0-0.5 cal ka BP. Additionally, isotopic investigations on these crystals provided information on eutrophication, stratification, and carbon cycling processes in the lake.},
  language  = {en}
}