570 Biowissenschaften; Biologie
Refine
Year of publication
- 2022 (159) (remove)
Document Type
- Article (102)
- Doctoral Thesis (37)
- Postprint (15)
- Review (2)
- Habilitation Thesis (1)
- Master's Thesis (1)
- Other (1)
Is part of the Bibliography
- yes (159) (remove)
Keywords
- functional traits (7)
- animal personality (5)
- light pollution (5)
- Arabidopsis thaliana (4)
- GPS (4)
- coexistence (4)
- fence ecology (4)
- giving-up density (4)
- ungulate (4)
- veterinary cordon fence (4)
Institute
- Institut für Biochemie und Biologie (159) (remove)
Hitze ist eine bedeutende klimatische Bedingung, die das Wachstum und das Überleben von Pflanzen bedroht. Extreme Temperaturereignisse in der Natur werden gravierender, häufiger, länger anhaltend, was sich nachteilig auf die landwirtschaftliche Produktion auswirkt. Daher ist es wichtig, mehr über die Mechanismen zu erfahren, die zu einer erhöhten Hitzetoleranz bei Pflanzen führen. Um auszuhalten und zu überleben, haben höhere Pflanzen komplexe Mechanismen entwickelt, um auf verschiedene Intensitäten von Hitzestress zu reagieren. Pflanzen haben eine thermische Toleranz, die es ihnen ermöglicht, schnelle und dramatische Temperaturanstiege für eine begrenzte Zeit zu überleben. Pflanzen können auch darauf vorbereitet werden, Hitzestress (HS) zu widerstehen, der ansonsten tödlich wäre, indem man sie kurzen, moderaten und nicht-tödlichen HS (als Priming-Stimulus bezeichnet) aussetzt, bevor sie hohem HS ausgesetzt werden. Eine erworbene Thermotoleranz kann bei Pflanzen unter optimalen Bedingungen lange aufrechterhalten werden, was bedeutet, dass Pflanzen während dieser Zeit Informationen speichern können. Mehrere Studien haben gezeigt, dass sich erworbene Thermotoleranz (Thermopriming) auf die erhöhte Widerstandsfähigkeit von Zellen, Geweben und Organismen gegenüber erhöhten Temperaturen nach vorheriger Hitzeeinwirkung bezieht. Die Aufrechterhaltung der erworbenen Thermotoleranz (Thermomemory) ist mit der Synthese von speziellen Stressproteinen verbunden, die am Zellschutz und der beschleunigten Gewebereparatur beteiligt sind, wie z. B. Hitzeschockproteine (HSPs). Neuere Studien haben eine Beteiligung von Hitzeschockproteinen, z.B. HSP21, in Chloroplasten an der Regulation des Thermogedächtnisses belegt. Als wichtiges Organell ist die mitochondriale Funktion entscheidend für die Reaktion von Pflanzenzellen auf Hitze. Es ist jedoch noch unbekannt, wie die molekulare und physiologische Beteiligung von HSPs an der mitochondrialen Funktion im Thermogedächtnis erfolgt. In unserer Studie haben wir gezeigt, dass Thermopriming Transkript- und Proteinspiegel von zwei mitochondrialen kleinen Hitzeschockproteinen, HSP23.56 (AT5G51440) und HSP23.6 (AT4G25200), induziert, die während der Thermogedächtnisphase 2-3 Tage andauern. Die morphologische Analyse von HSP23.5/6-transgenen Pflanzen zeigte eine HSP23.5/6-Funktionsredundanz bei Hitzestress. Wir zeigten, dass hsp23.5/6-Doppel-Knockout-Pflanzen Anomalien im Thermogedächtnis im Keimlingsstadium aufwiesen und dass reife hsp23.5/6-Pflanzen sowohl mit basaler Thermotoleranz als auch mit Thermogedächtnis empfindlicher sind. Die Wärmebehandlung beeinflusste die Atmungsrate von hsp23.5/6-Keimlingen im Vergleich zu WT signifikant, was auf eine mitochondriale Dysfunktion in Abhängigkeit von HSP23.5 und HSP23.6 hinweist. Darüber hinaus haben wir die Chaperon-Aktivität von HSP23.6 gegenüber dem Modellsubstratprotein Malatdehydrogenase (MDH) in vitro getestet und bestätigt, was darauf hindeutet, dass HSP23.6 möglicherweise zur Aufrechterhaltung der zellulären Lebensfähigkeit beiträgt. Darüber hinaus entdeckten wir ein neues HSP23.6-Clientprotein, CIB22, ein mitochondriales Komplex-I-Untereinheitsprotein. Nach experimentellen Daten (BiFC und Co-IP) interagieren HSP23.6 und CIB22 in Pflanzenzellen. Wir identifizierten auch einen Hitzereaktionsphänotyp in der cib22-Mutante im Vergleich zu WT sowie einen CIB22-Proteinabbau in der hsp23.5/6-Mutante, wenn sie Hitze ausgesetzt wurde. Unsere Ergebnisse legen nahe, dass die beiden mitochondrial lokalisierten
Hitzeschockproteine eine Rolle bei der Thermotoleranz spielen, vermutlich indem sie die mitochondriale Funktion und Struktur beeinflussen. Um neue genetische Komponenten zu identifizieren, die mit dem Thermogedächtnis in Pflanzen verbunden sind, haben wir weiterhin ein Proteom-Profiling von Arabidopsis WT (Col-0) -Keimlingen während des Thermogedächtnisses durchgeführt. Mehrere Zeitpunkte von Priming und Triggerung mit Kontrollen wurden gesammelt und analysiert, um dynamische Proteomänderungen während der Gedächtnisphase in
Arabidopsis-Zellen aufzudecken. Unter den Top-gedächtnis-assoziierten Proteinen entdeckten wir, dass HSP70-4 nach dem Priming signifikant hochreguliert wurde und für die nächsten vier Tage auf hohem Niveau bleibt (mindestens 2-fach erhöht). Durch Analyse ihres Hitzestressverhaltens konnten wir verifizieren, dass HSP70-4 an der 7 Reaktion von Pflanzen auf Hitzestress beteiligt ist. Interessant ist, dass HSP70-4-GFP nach dem Priming zytosolische Foci erzeugt, die für einige Tage während der Erholungsphase bestehen bleiben. Wir schlagen vor, dass der Fokus mit SGs verbunden ist, da Cycloheximid (CHX) GFP-Foci-Signale unterdrückt, wenn sie der Hitze ausgesetzt werden. Diese Ergebnisse weisen auf eine HSP70-4-vermittelte Transkriptions- und Translationssteuerungsverbindung (Modul) während der basalen Thermotoleranz und des Thermogedächtnisses sowie auf ihre potenzielle(n) Rolle(n) bei der Reaktion auf Hitzestress hin.
Zusammenfassend bietet unsere Forschung neue Einblicke in die Rolle von Hitzeschockproteinen bei der Kontrolle der Hitzestresstoleranz und des Gedächtnisses.
Background: In the animal kingdom body size is often linked to dominance and subsequently the standing in social hierarchy. Similarly, human growth has been associated and linked to socioeconomic factors, including one’s social status. This has already been proposed in the early 1900s where data on young German school girls from different social strata have been compared.
Objectives: This paper aims to summarize and analyze these results and make them accessible for non-German speakers. The full English translation of the historic work of Dikanski (Dikanski, 1914) is available as a supplement. Further, this work aims to compare the historical data with modern references, to test three hypotheses: (1) higher social class is positively associated with body height and weight, (2) affluent people from the used historical data match modern references in weight and height and (3) weight distributions are skewed in both modern and historical populations.
Methods: Comparison of historical data from 1914 with WHO and 1980s German data. The data sets, for both body weight and height for 6.0- and 7.0-year-old girls, were fitted onto centile curves and quantile correlation coefficients were calculated.
Results: In historical data social status is positively associated with body height and weight while both are also normally distributed, which marks a significant difference to modern references.
Conclusion: Social status is positively associated with height, signaling social dominance, making children of affluent classes taller. Children from the historical data do not reach the average height of modern children, even under the best environmental conditions. The children of the upper social class were not skewed in weight distribution, although they had the means to become as obese as modern children.
Aim Growth is a multifarious phenomenon that has been studied by nutritionists, economists, paediatric endocrinologists; archaeologists, child psychologists and other experts. Yet, a unifying theory of understanding growth regulation is still lacking. Method Critical review of the literature. Results We summarise evidence linking social competition and its effect on hierarchies in social structures, with the neuronal networks of the ventromedial hypothalamus and body size. The endocrine signalling system regulating growth hormone, Insulin-like-Growth-Factor1 and skeletal growth, is well conserved in the evolution of vertebrata for some 400 million years. The link between size and status permits adaptive plasticity, competitive growth and strategic growth adjustments also in humans. Humans perceive size as a signal of dominance with tallness being favoured and particularly prevalent in the upper social classes. Conclusion Westernised societies are competitive. People are tall, and "open to change." Social values include striving for status and prestige implying socio-economic domination. We consider the transition of political and social values following revolutions and civil wars, as key elements that interact with the evolutionarily conserved neuroendocrine competence for adaptive developmental plasticity, overstimulate the hypothalamic growth regulation and finally lead to the recent historic increases in average height.
The emergence of carbapenemase-producing multi-drug resistant Enterobacteriaceae poses a dramatic, world-wide health risk. Limited treatment options and a lack of easy-to-use methods for the detection of infections with multi-drug resistant bacteria leave the health-care system with a fast-growing challenge. Aptamers are single stranded DNA or RNA molecules that bind to their targets with high affinity and specificity and can therefore serve as outstanding detection probes. However, an effective aptamer selection process is often hampered by non-specific binding. When selections are carried out against recombinant proteins, purification tags (e.g. polyhistidine) serve as attractive side targets, which may impede protein target binding. In this study, aptamer selection was carried out against N-terminally hexa-histidine tagged New Delhi metallo-ss-lactamase 1. After 14 selection rounds binding to polyhistidine was detected rather than to New Delhi metallo-ss-lactamase 1. Hence, the selection strategy was changed. As one aptamer candidate showed remarkable binding affinity to polyhistidine, it was used as a masking probe and selection was restarted from selection round 10. Finally, after three consecutive selection rounds, an aptamer with specific binding properties to New Delhi metallo-ss-lactamase 1 was identified. This aptamer may serve as a much-needed detection probe for New Delhi metallo-ss-lactamase 1 expressing Enterobacteriaceae.
As a critical part of plant immunity, cells that are attacked by pathogens undergo rapid transcriptional reprogramming to minimize virulence. Many bacterial phytopathogens use type III effector (T3E) proteins to interfere with plant defense responses, including this transcriptional reprogramming. Here, we show that Xanthomonas outer protein S (XopS), a T3E of Xanthomonas campestris pv. vesicatoria (Xcv), interacts with and inhibits proteasomal degradation of WRKY40, a transcriptional regulator of defense gene expression. Virus-induced gene silencing of WRKY40 in pepper (Capsicum annuum) enhanced plant tolerance to Xcv infection, indicating that WRKY40 represses immunity. Stabilization of WRKY40 by XopS reduces the expression of its targets, which include salicylic acid-responsive genes and the jasmonic acid signaling repressor JAZ8. Xcv bacteria lacking XopS display significantly reduced virulence when surface inoculated onto susceptible pepper leaves. XopS delivery by Xcv, as well as ectopic expression of XopS in Arabidopsis thaliana or Nicotiana benthamiana, prevented stomatal closure in response to bacteria and biotic elicitors. Silencing WRKY40 in pepper or N. benthamiana abolished XopS's ability to prevent stomatal closure. This suggests that XopS interferes with both preinvasion and apoplastic defense by manipulating WRKY40 stability and downstream gene expression, eventually altering phytohormone crosstalk to promote pathogen proliferation.
Boreal forests cover over half of the global permafrost area and protect underlying permafrost. Boreal forest development, therefore, has an impact on permafrost evolution, especially under a warming climate.
Forest disturbances and changing climate conditions cause vegetation shifts and potentially destabilize the carbon stored within the vegetation and permafrost. Disturbed permafrost-forest ecosystems can develop into a dry or swampy bush- or grasslands, shift toward broadleaf- or evergreen needleleaf-dominated forests, or recover to the pre-disturbance state.
An increase in the number and intensity of fires, as well as intensified logging activities, could lead to a partial or complete ecosystem and permafrost degradation. We study the impact of forest disturbances (logging, surface, and canopy fires) on the thermal and hydrological permafrost conditions and ecosystem resilience.
We use a dynamic multilayer canopy-permafrost model to simulate different scenarios at a study site in eastern Siberia. We implement expected mortality, defoliation, and ground surface changes and analyze the interplay between forest recovery and permafrost. We find that forest loss induces soil drying of up to 44%, leading to lower active layer thicknesses and abrupt or steady decline of a larch forest, depending on disturbance intensity.
Only after surface fires, the most common disturbances, inducing low mortality rates, forests can recover and overpass pre-disturbance leaf area index values. We find that the trajectory of larch forests after surface fires is dependent on the precipitation conditions in the years after the disturbance. Dryer years can drastically change the direction of the larch forest development within the studied period.
Foraging by consumers acts as a biotic filtering mechanism for biodiversity at the trophic level of resources. Variation in foraging behaviour has cascading effects on abundance, diversity, and functional trait composition of the community of resource species. Here we propose diversity at giving-up density (DivGUD), i.e. when foragers quit exploiting a patch, as a novel concept and simple measure quantifying cascading effects at multiple spatial scales. In experimental landscapes with an assemblage of plant seeds, patch residency of wild rodents decreased local alpha-DivGUD (via elevated mortality of species with large seeds) and regional gamma-DivGUD, while dissimilarity among patches in a landscape (beta-DivGUD) increased. By linking theories of adaptive foraging behaviour with community ecology, DivGUD allows to investigate cascading indirect predation effects, e.g. the ecology-of-fear framework, feedbacks between functional trait composition of resource species and consumer communities, and effects of inter-individual differences among foragers on the biodiversity of resource communities.
Biological invasions may result from multiple introductions, which might compensate for reduced gene pools caused by bottleneck events, but could also dilute adaptive processes. A previous common-garden experiment showed heritable latitudinal clines in fitness-related traits in the invasive goldenrod Solidago canadensis in Central Europe. These latitudinal clines remained stable even in plants chemically treated with zebularine to reduce epigenetic variation. However, despite the heritability of traits investigated, genetic isolation-by-distance was non-significant. Utilizing the same specimens, we applied a molecular analysis of (epi)genetic differentiation with standard and methylation-sensitive (MSAP) AFLPs. We tested whether this variation was spatially structured among populations and whether zebularine had altered epigenetic variation. Additionally, we used genome scans to mine for putative outlier loci susceptible to selection processes in the invaded range. Despite the absence of isolation-by-distance, we found spatial genetic neighborhoods among populations and two AFLP clusters differentiating northern and southern Solidago populations. Genetic and epigenetic diversity were significantly correlated, but not linked to phenotypic variation. Hence, no spatial epigenetic patterns were detected along the latitudinal gradient sampled. Applying genome-scan approaches (BAYESCAN, BAYESCENV, RDA, and LFMM), we found 51 genetic and epigenetic loci putatively responding to selection. One of these genetic loci was significantly more frequent in populations at the northern range. Also, one epigenetic locus was more frequent in populations in the southern range, but this pattern was lost under zebularine treatment. Our results point to some genetic, but not epigenetic adaptation processes along a large-scale latitudinal gradient of S. canadensis in its invasive range.
The increasing introduction of non-native plant species may pose a threat to local biodiversity. However, the basis of successful plant invasion is not conclusively understood, especially since these plant species can adapt to the new range within a short period of time despite impoverished genetic diversity of the starting populations. In this context, DNA methylation is considered promising to explain successful adaptation mechanisms in the new habitat. DNA methylation is a heritable variation in gene expression without changing the underlying genetic information. Thus, DNA methylation is considered a so-called epigenetic mechanism, but has been studied in mainly clonally reproducing plant species or genetic model plants. An understanding of this epigenetic mechanism in the context of non-native, predominantly sexually reproducing plant species might help to expand knowledge in biodiversity research on the interaction between plants and their habitats and, based on this, may enable more precise measures in conservation biology.
For my studies, I combined chemical DNA demethylation of field-collected seed material from predominantly sexually reproducing species and rearing offsping under common climatic conditions to examine DNA methylation in an ecological-evolutionary context. The contrast of chemically treated (demethylated) plants, whose variation in DNA methylation was artificially reduced, and untreated control plants of the same species allowed me to study the impact of this mechanism on adaptive trait differentiation and local adaptation. With this experimental background, I conducted three studies examining the effect of DNA methylation in non-native species along a climatic gradient and also between climatically divergent regions.
The first study focused on adaptive trait differentiation in two invasive perennial goldenrod species, Solidago canadensis sensu latu and S. gigantea AITON, along a climate gradient of more than 1000 km in length in Central Europe. I found population differences in flowering timing, plant height, and biomass in the temporally longer-established S. canadensis, but only in the number of regrowing shoots for S. gigantea. While S. canadensis did not show any population structure, I was able to identify three genetic groups along this climatic gradient in S. gigantea. Surprisingly, demethylated plants of both species showed no change in the majority of traits studied. In the subsequent second study, I focused on the longer-established goldenrod species S. canadensis and used molecular analyses to infer spatial epigenetic and genetic population differences in the same specimens from the previous study. I found weak genetic but no epigenetic spatial variation between populations. Additionally, I was able to identify one genetic marker and one epigenetic marker putatively susceptible to selection. However, the results of this study reconfirmed that the epigenetic mechanism of DNA methylation appears to be hardly involved in adaptive processes within the new range in S. canadensis.
Finally, I conducted a third study in which I reciprocally transplanted short-lived plant species between two climatically divergent regions in Germany to investigate local adaptation at the plant family level. For this purpose, I used four plant families (Amaranthaceae, Asteraceae, Plantaginaceae, Solanaceae) and here I additionally compared between non-native and native plant species. Seeds were transplanted to regions with a distance of more than 600 kilometers and had either a temperate-oceanic or a temperate-continental climate. In this study, some species were found to be maladapted to their own local conditions, both in non-native and native plant species alike. In demethylated individuals of the plant species studied, DNA methylation had inconsistent but species-specific effects on survival and biomass production. The results of this study highlight that DNA methylation did not make a substantial contribution to local adaptation in the non-native as well as native species studied.
In summary, my work showed that DNA methylation plays a negligible role in both adaptive trait variation along climatic gradients and local adaptation in non-native plant species that either exhibit a high degree of genetic variation or rely mainly on sexual reproduction with low clonal propagation. I was able to show that the adaptive success of these non-native plant species can hardly be explained by DNA methylation, but could be a possible consequence of multiple introductions, dispersal corridors and meta-population dynamics. Similarly, my results illustrate that the use of plant species that do not predominantly reproduce clonally and are not model plants is essential to characterize the effect size of epigenetic mechanisms in an ecological-evolutionary context.
Transcriptomic dataset for early inflorescence stages of oil palm in response to defoliation stress
(2022)
Oil palm breeding and seed development have been hindered due to the male parent's incapacity to produce male inflorescence as a source of pollen under normal conditions. On the other hand, a young oil palm plantation has a low pollination rate due to a lack of male flowers. These are the common problem of sex ratio in the oil palm industry. Nevertheless, the regulation of sex ratio in oil palm plants is a complex mechanism and remains an open question until now. Researchers have previously used complete defoliation to induce male inflorescences, but the biological and molecular mechanisms underlying this morphological change have yet to be discovered. Here, we present an RNA-seq dataset from three early stages of an oil palm inflorescence under normal conditions and complete defoliation stress. This transcriptomic dataset is a valuable resource to improve our understanding of sex determination mechanisms in oil palm inflorescence.