@phdthesis{Frank2019, author = {Frank, Erik Thomas}, title = {Behavioral adaptations in the foraging behaviour of \(Megaponera\) \(analis\)}, url = {http://nbn-resolving.de/urn:nbn:de:bvb:20-opus-156544}, school = {Universit{\"a}t W{\"u}rzburg}, year = {2019}, abstract = {An efficient foraging strategy is one of the most important traits for the fitness of animals. The theory of optimal foraging tries to predict foraging behaviour through the overarching question: how animals should forage so as to minimize costs while maximizing profits? Social insects, having occupied nearly every natural niche through widely different strategies, offer themselves as an ideal group to study how well optimal foraging theory can explain their behaviour and success. Specialization often leads to unique adaptations in morphology and behaviour. I therefore decided to investigate the behaviour of Megaponera analis. This ponerine ant species is specialized on hunting only termites of the subfamily Macrotermitinae at their foraging sites. Their foraging behaviour is regulated by a handful of individual scouts (10-20) that search for termite foraging sites before returning to the nest to recruit a large number of nestmates (200-500 ants). These ants then follow the scout in a column formation to the termites and after the hunt return together to the nest, these raids occur two to five times per day. Predators of highly defensive prey likely develop cost reducing adaptations. The evolutionary arms race between termites and ants led to various defensive mechanisms in termites, e.g. a caste specialized in fighting predators. As M. analis incurs high injury/mortality risks when preying on termites, some risk mitigating adaptations have evolved. I show that a unique rescue behaviour in M. analis, consisting of injured nestmates being carried back to the nest, reduces combat mortality. These injured ants "call for help" with pheromones present in their mandibular gland reservoirs. A model accounting for this rescue behaviour identifies the drivers favouring its evolution and estimates that rescuing allows for maintaining a 29\% larger colony size. Heavily injured ants that lost too many legs during the fight on the other hand are not helped. Interestingly, this was regulated not by the helper but by the uncooperativeness of the injured ant. I further observed treatment of the injury by nestmates inside the nest through intense allogrooming directly at the wound. Lack of treatment increased mortality from 10\% to 80\% within 24 hours, with the cause of death most likely being infections. Collective decision-making is one of the main mechanisms in social insects through which foraging is regulated. However, individual decision-making can also play an important role, depending on the type of foraging behaviour. In M. analis only a handful of individuals (the scouts) hold all the valuable information about foraging sites. I therefore looked at predictions made by optimal foraging theory to better understand the interplay between collective and individual decision-making in this obligate group-raiding predator. I found a clear positive relation between raid size and termite abundance at the foraging site. Furthermore, selectivity of the food source increased with distance. The confirmation of optimal foraging theory suggests that individual scouts must be the main driver behind raid size, choice and raiding behaviour. Therefore most central place foraging behaviours in M. analis were not achieved by collective decisions but rather by individual decisions of scout ants. Thus, 1\% of the colony (10-20 scouts) decided the fate and foraging efficiency of the remaining 99\%. Division of labour is one of the main reasons for the success of social insects. Worker polymorphism, age polyethism and work division in more primitive ants, like the ponerines, remain mostly unexplored though. Since M. analis specializes on a defensive prey, adaptations to reduce their foraging costs can be expected. I found that the work division, task allocation and column-formation during the hunt were much more sophisticated than was previously thought. The column-formation was remarkably stable, with the same ants resuming similar positions in subsequent raids and front ants even returning to their positions if displaced in the same raid. Most of the raid tasks were not executed by predetermined members of the raid but were filled out as need arose during the hunt, with a clear preference for larger ants to conduct most tasks. I show that specialization towards a highly defensive prey can lead to very unique adaptations in the foraging behaviour of a species. I explored experimentally the adaptive value of rescue behaviour focused on injured nestmates in social insects. This was not only limited to selective rescuing of lightly injured individuals by carrying them back (thus reducing predation risk) but moreover includes a differentiated treatment inside the nest. These observations will help to improve our understanding of the evolution of rescue behaviour in animals. I further show that most optimal foraging predictions are fulfilled and regulated by a handful of individuals in M. analis. Lastly, I propose that the continuous allometric size polymorphism in M. analis allows for greater flexibility in task allocation, necessary due to the unpredictability of task requirements in an irregular system such as hunting termites in groups. All of my observations help to further understand how a group-hunting predator should forage so as to minimize costs while maximizing profits.}, subject = {Stechameisen}, language = {en} } @phdthesis{BergmannBueno2021, author = {Bergmann Bueno, Amauri}, title = {Ecophysiological adaptations of cuticular water permeability of plants to hot arid biomes}, doi = {10.25972/OPUS-16783}, url = {http://nbn-resolving.de/urn:nbn:de:bvb:20-opus-167832}, school = {Universit{\"a}t W{\"u}rzburg}, year = {2021}, abstract = {Arid environments cover almost one-third of the land over the world. Plant life in hot arid regions is prone to the water shortage and associated high temperatures. Drought-stressed plants close the stomata to reduce water loss. Under such conditions, the remaining water loss exclusively happens across the plant cuticle. The cuticular water permeability equals the minimum and inevitable water loss from the epidermal cells to the atmosphere under maximally stomatal closure. Thus, low cuticular water permeability is primordial for plant survival and viability under limited water source. The assumption that non-succulent xerophytes retard water loss due to the secretion of a heavier cuticle is often found in the literature. Intuitively, this seems to be plausible, but few studies have been conducted to evaluate the cuticular permeability of xerophilous plants. In chapter one, we investigated whether the cuticular permeability of Quercus coccifera L. grown in the aridest Mediterranean-subtype climate is indeed lower than that of individuals grown under temperate climate conditions. Also, the cuticular wax chemical compositions of plants grown in both habitats were qualitatively and quantitatively analysed by gas-chromatography. In few words, our findings showed that although the cuticular wax deposition increased in plants under Mediterranean climate, the cuticular permeability remained unaltered, regardless of habitat. The associated high temperatures in arid regions can drastically increase the cuticular water permeability. Thereby, the thermal stability of the cuticular transpirational barrier is decisive for safeguarding non-succulent xerophytes against desiccation. The successful adaptation of plants to hot deserts might be based on finding different solutions to cope with water and heat stresses. Water-saver plants close the stomata before the leaf water potential drastically changes in order to prevent damage, whereas water-spender plants reduce the leaf water potential by opening the stomata, which allow them to extract water from the deep soil to compensate the high water loss by stomatal transpiration. In chapter two, we compare the thermal stability of the cuticular transpiration barrier of the desert water-saver Phoenix dactylifera L. and the water-spender Citrullus colocynthis (L.) Schrad. In short, the temperature-dependent increase of the cuticular permeability of P. dactylifera was linear over the whole temperature range (25-50°C), while that of C. colocynthis was biphasic with a steep increase at temperatures ≥ 40°C. This drastic increase of cuticular permeability indicates a thermally induced breakdown of the C. colocynthis cuticular transpiration barrier, which does not occur in P. dactylifera. We further discussed how the specific chemical composition of the cutin and cuticular waxes might contribute to the pronounced thermal resistance of the P. dactylifera cuticular transpiration barrier. A multitude of morpho and physiological modifications, including photosynthetic thermal tolerance and traits related to water balance, led to the successful plant colonisation of hot arid regions over the globe. High evaporative demand and elevated temperatures very often go along together, thereby constraining the plant life in arid environments. In chapter 3, we surveyed cuticular permeability, leaf thermal tolerance, and cuticular wax chemical composition of 14 non-succulent plant species native from some of the hottest and driest biomes in South-America, Europe, and Asia. Our findings showed that xerophilous flowering plants present high variability for cuticular permeability and leaf thermal tolerance, but both physiological features could not be associated with the species original habitat. We also provide substantial evidence that non-succulent xerophytes with more efficient cuticular transpirational barrier have higher leaf thermal tolerance, which might indicate a potential coevolution of these features in hot arid biomes. We further discussed the efficiency of the cuticular transpiration barrier in function to the cuticular wax chemical composition in the general discussion section.}, subject = {Plant cuticle}, language = {en} } @phdthesis{CastilloCajas2020, author = {Castillo Cajas, Ruth}, title = {Evolution and diversity of cuticular hydrocarbon profiles of cuckoo wasps}, doi = {10.25972/OPUS-17341}, url = {http://nbn-resolving.de/urn:nbn:de:bvb:20-opus-173418}, school = {Universit{\"a}t W{\"u}rzburg}, year = {2020}, abstract = {Cuticular hydrocarbons (CHC) abound on the surface of arthropods. In spite of their simple structure (molecules of carbon and hydrogen atoms), they provide pivotal functions in insects: their hydrophobic properties confer the insects a means to regulate water balance and avoid desiccation, whereas their diversity has enhanced their use as signals and cues in a wide range of communication and recognition processes. Although the study of CHC in insects over the past two decades has provided great insight into the wide range of functions they play, there is still a gap in understanding how they diversify and evolve. In this thesis, I have used members of the family Chrysididae to explore patterns of diversification of CHC. Most of the species of cuckoo wasps in this study are specialized parasitoids or kleptoparasites of mainly solitary hymenopteran hosts. Other hosts of the family include butterflies or stick insects. Cuckoo wasps are a particular interesting model to study the evolution of cuticular hydrocarbons because of their chemical adaptations that allow them to remain unrecognized by their hosts. Chemical insignificance (the reduction of the total amount of CHC on the cuticle) and chemical mimicry (the de novo production of CHC profiles resembling those of their female host) have been described in some representatives of the family and unpublished evidence suggests chemical deception is widespread in Chrysididae (Chapter 2). Nonetheless, to trace the evolution of any trait of interest, a reliable phylogenetic reconstruction of the family is required. Therefore, the first study of this thesis constitutes the largest and to-date most reliable phylogenetic reconstruction of the family Chrysididae, which includes representatives of 186 species of cuckoo wasps. While the results of this phylogenetic reconstruction are consistent with previous ideas on the relationships of subfamilies and tribes, it shows the existence of several non-monophyletic genera (Chapter 3). CHC are involved in intraspecific recognition, often acting as contact sex pheromones. Nevertheless, it is not yet understood to what extent CHC profiles differ between the two sexes and whether some compound classes are more prevalent in one or the other sex. So far, no comparison of CHC profiles of males and females has been done for more than a dozen of related species. In Chapter 4, I describe and compare CHC profiles of females and males of 58 species of cuckoo wasps in order to evaluate whether and to what extent CHC profiles of these species differ between the sexes. I demonstrated that CHC profiles of cuckoo wasps are frequently (more than 90\% of the species analyzed) and strongly dimorphic (both sexes of a given species tend to produce very different CHC compounds). Methyl-branched compounds tend to be more prevalent in males (especially dimethyl-branched compounds) and unsaturated compounds prevail in females. Moreover, a sex-specific pattern in the distribution of the double bond position of alkenes was evident: internal double bond positions (> 11) occur predominantly in males, whereas alkenes with the doubl{\´e} bond at position 9 were more abundant and frequent in females (Chapter4). In Chapter5, I investigated how CHC profiles of cuckoo wasps differ across species. Are CHC profiles of cuckoo wasps species-specific, enabling their use as cues for species recognition? How do CHC profiles resemble phylogenetic relatedness? In Chapter 5, I try to answer these questions by comparing CHC profiles of 59 species of cuckoo wasps. CHC profiles of cuckoo wasps are shown to be species (and sex-) specific. I show that CHC profiles are useful as a complementary tool to help delimiting taxonomically difficult sibling species. Moreover, the evaluation of CHC profiles of five commonly occurring species within a genus, showed little or no geographical variation. However, CHC profiles of closely related species may differ strongly among each other, not being useful to track the evolutionary history of species (Chapter 5). Sexual selection is generally credited for generating striking sexual dimorphism by causing changes in male traits. Most often, sexual selection has a stronger effect on males, who compete for access to and may be selected by females, thus male traits may rapidly evolve. Nevertheless, in cuckoo wasps, it appears that it is the female sex the one evolving faster changes, with females of very closely related species showing extremely divergent profiles. One plausible reason for this disparity is that natural selection acting on female's CHC profiles may be stronger than sexual selection on males (Chapter 6). Since females of cuckoo wasps are most probably engaged in an evolutionary arms race with their female hosts, CHC profiles of female cuckoo wasps are likely rapidly evolving, thus explaining part of the strong observed sexual dimorphism of CHC (Chapter 6). In fact, Chapter 7 shows evidence of a possible ongoing evolutionary arms race between five cuckoo wasps of the genus Hedychrum and their hosts. Hedychrum species parasitize either Coleoptera-hunting or Hymenoptera-hunting digger wasps. Since the coleopteran prey of the former digger wasps is naturally better protected against fungus infestation, these wasps do not embalm their prey with alkene-enriched secretions as do the Hymenoptera-hunting digger wasps. Thus, Coleoptera-hunting digger wasps can apparently diversify their profiles to escape chemical mimicry. Interestingly, only female cuckoo wasps of these hosts have started producing the same compound classes and even the same CHC compounds as those of their hosts. Male cuckoo wasps, however retain an alkene-enriched CHC profile that reflects the molecular phylogeny of the genus (Chapter 7). Whereas, a larger number of parasite-host comparisons may be needed to further conclude that an arms race between cuckoo wasps and their hosts is capable of generating sexual dimorphism of cuckoo wasps, this thesis constitutes the first effort towards this, providing a starting point for further studies. Finally, I provide some methodological tools that may help in speeding up the sometimes cumbersome process of analyzing and identifying CHC profiles. One of the most time-demanding steps in the processing of CHC data is the alignment of CHC chromatograms. This process is often done manually, because alignment programs are mostly designed for metabolomics or are just recently being developed. I analyzed CHC profiles using a combined approach with two freely available programs. I used AMDIS (Automated Mass Spectral Deconvolution and Identification System, http://chemdata.nist.gov/mass-spc/amdis/) to deconvolute and automatically identify all CHC of interest present in a chromatogram. I then developed a series of R scripts to correct for potential, unavoidable errors while processing CHC chromatograms with AMDIS. Chapter 8 explains this procedure. In the next chapter, I developed a program that helps in the identification of one commonly occurring class of hydrocarbons. The limited number of linear alkanes (only one per carbon atom) and their characteristic diagnostic ion allows a rapid and unambigous identification of these substances. In opposition, unsaturated and methyl-branched compounds are more difficult to identify, as a result of the much larger diversity of existing compounds. To identify unsaturated compounds a derivatization is necessary to determine the position of the double bond. Methyl-branched alkanes, however can be identified from the original chromatogram if their diagnostic ions are known. Nonetheless, polymethyl-branched alkanes (e.g., compounds with two or more methyl groups along the chain) are often difficult to identify, because they may appear in mixes (e.g., 3,7 diMeC27 and 3,9 diMeC27), and tables containing the diagnostic ions are not easily available. Therefore, I developed a program that creates a table with all possiblemethyl-branched compounds containing up to 4 methyl groups, and that provides their diagnostic ions and a calculated retention index. This may allow a much faster identification of the methyl-branched compound a researcher is dealing with, without having to lose time in the tedious calculations by hand. The program is able to correctly identify, or at least, greatly reduce the number of possible options for the identification of an unknown methyl-branched compound. Thus, using this tool, most methyl-branched compounds can be readily identified (Chapter 9). This thesis ends with a general discussion (Chapter 10). Overall, this work provides a comprehensive overview of the diversity of cuticular hydrocarbons of cuckoo wasps. The analyses presented here shed light on the emergence and evolution of interspecific diversity and intraspecific sexual dimorphism of CHC profiles. In addition, two technical methods have been developed that could greatly facilitate the CHC analysis of insects.}, language = {en} } @phdthesis{Lehenberger2022, author = {Lehenberger, Maximilian}, title = {Ecology and Evolution of symbiotic microbial communities in fungus farming ambrosia beetles}, publisher = {Fungal Ecology, Frontiers in Microbiology, Deutsche Gesellschaft f{\"u}r allgemeine und angewandte Entomologie}, doi = {10.25972/OPUS-24154}, url = {http://nbn-resolving.de/urn:nbn:de:bvb:20-opus-241546}, school = {Universit{\"a}t W{\"u}rzburg}, year = {2022}, abstract = {Within my PhD project I gained several novel insights into the poorly investigated symbiotic world of fungus farming ambrosia beetles and their bark beetle ancestors, where I especially focused on physiological interactions and capabilities of associated fungal symbionts. Here, (i) I could confirm the association of mutualistic Phialophoropsis fungi with the ambrosia beetle genus Trypodendron and found hints for a possible new Phialophoropsis species in T. signatum and T. domesticum. Moreover, I could show that mutualistic fungi of Trypodendron ambrosia beetles are able to decompose major woody polysaccharides such as cellulose and xylan. Additionally, (ii) I provided the first images using micro-computed tomography (µCT) of the formerly unknown structure of the mycetangium of Trypodendron leave. (iii) I could confirm a general tolerance towards ethanol in mutualistic ambrosia beetle fungi, while antagonistic fungi as well as most examined fungal bark beetle associates (e.g. possibly tree-defense detoxifying species) were highly sensitive to even low concentrations of ethanol. Further, (iv) I found that natural galleries of ambrosia beetles are highly enriched with several biologically important elements (such as N, P, S, K, Mg) compared to the surrounding woody tissue and suggest that mutualistic fungi are translocating and concentrating elements from the immediate surrounding xylem to the beetles galleries. Furthermore, (v) I could show that various fungi associated with bark and ambrosia beetles (mutualists, possibly beneficial symbionts) are emitting several volatile organic compounds mostly within aliphatic and aromatic alcohols and esters, while non-mutualistic and free living species were generally emitting a lower number and amount of volatiles. Finally, especially bark and ambrosia beetle fungi were found to incorporate several amino acids, from which some are especially important for the production of certain volatile organic compounds. Amino acid content also indicated a higher nutritional value for certain species. Here, I propose that especially volatile organic compounds are widespread key players in maintaining various symbioses between fungi and beetles, as already proven by a recent study on the bark beetle Ips typographus (as well as for some other bark beetle-fungus symbioses, see summary in Kandasamy et al. 2016) and also suggested for ambrosia beetles.}, language = {en} } @phdthesis{Riemens2023, author = {Riemens, Renzo J. M.}, title = {Neuroepigenomics in Alzheimer's disease: The single cell ADds}, isbn = {978-94-6423-524-1}, doi = {10.25972/OPUS-25457}, url = {http://nbn-resolving.de/urn:nbn:de:bvb:20-opus-254574}, school = {Universit{\"a}t W{\"u}rzburg}, year = {2023}, abstract = {Die Forschung, die in dieser Arbeit zusammengestellt wird, kann in zwei Teile geteilt werden. Der erste Teil, bestehend aus vier Kapiteln, konzentriert sich auf die Rolle der epigenetischen Dysregulation in der {\"A}tiopathophysiologie der sporadischen Alzheimer-Krankheit (sAD). Neben Einblicken in die neuesten Entwicklungen in neuroepigenomischen Studien zu dieser Krankheit geht der erste Teil der Arbeit auch auf verbleibende Herausforderungen ein und gibt einen Ausblick auf m{\"o}gliche Entwicklungen auf diesem Gebiet. Der zweite Teil, der drei weitere Kapitel umfasst, konzentriert sich auf die Anwendung von auf induzierten pluripotenten Stammzellen (iPSC) basierenden Krankheitsmodellen f{\"u}r das Studium der AD, einschließlich, aber nicht beschr{\"a}nkt auf mechanistische Studien zur epigenetischen Dysregulation unter Verwendung dieser Plattform. Neben der Skizzierung der bisherigen Forschung mit iPSC-basierten Modellen f{\"u}r sAD gibt der zweite Teil der Arbeit auch Einblicke in die Gewinnung krankheitsrelevanter Nervenkulturen auf Basis der gezielten Differenzierung von iPSCs und beinhaltet dar{\"u}ber hinaus einen experimentellen Ansatz f{\"u}r den Aufbau eines solchen Modellsystems.}, subject = {Epigenetik}, language = {en} } @phdthesis{Becker2020, author = {Becker, Mira Caroline}, title = {Principles of olfactory-visual integration to form a common percept in honeybees}, doi = {10.25972/OPUS-19919}, url = {http://nbn-resolving.de/urn:nbn:de:bvb:20-opus-199190}, school = {Universit{\"a}t W{\"u}rzburg}, year = {2020}, abstract = {The honeybee is a well studied and important organism in neuroethology. The possibility to train them with a classical conditioning paradigm and their miniature brain provide a perfect requisite to investigate the neuronal principles of learning and memory. Honeybees use visual and olfactory cues to detect flowers during their foraging trips. Hence, the reward association of a nectar source is a multi-modal construct, which has at least two major components - olfactory and visual cues. It is still an open question, how both sensory components are converged in the mushroom body, which represent the multi-modal integration centre of the honeybee brain. The main goal of this study, is to investigate the processing of multiple modalities and how a reward association is formed. This includes, how and wether both sensory modalities interfere during learning. Thus, in this study stimulation with UV, blue and green light was used to evoke distinct photoreceptor activities in the compound eye. Furthermore, three different odours (Geraniol, Citronellol and Farnesol) were used. These stimuli were tested in three different experimental series. The first experiment involved classical differential conditioning of the single modalities - odour and colour. Honeybees showed high learning performances in differentiating olfactory stimuli and also reliable responses for visual conditioning. Furthermore, a temporal discrepancy in the stimulus length for best learning in the olfatcoty and visual cues was found. In the second series, it was tested how multi-modal compounds are perceived. This includes, unique cues (configural processing) or the sum of the single components of a compound (elemen- tal processing). This was tested by combining single odour components with monochromatic light in a positive (PP) and negative patterning (NP) experiment. During PP, the olfactory- visual compound was rewarded, whereas the single components were unrewarded. In contrast, during NP the single components were reinforced, but the compound was not. In addition, the ability to distinguish between two different light stimuli presented as a part of an olfactory-visual compound with the same odour component during acquisition was tested. In a memory test, the light stimuli were presented again as a compound and in addition as the single components. The results revealed that bees used elemental processing with compounds containing green and blue light. In contrast, when UV light was presented the bees used configural processing. Finally, a third experiment was conducted at the neuronal level. Multi-unit recordings were established to provide a suitable method to analyse extrinsic neurons at the mushroom body output region, the so called ventral lobe of the pedunculus. Here, three different odours (Geran- iol, Farnesol and Citronellol), two colours (green and blue) and two combined stimuli (colour + odour) were chosen as stimuli, to search for possible variations in processing stimuli with different modalities. Two units could be detected that responded mainly to visual stimuli.}, language = {en} } @phdthesis{Kumar2024, author = {Kumar, Manish}, title = {Structural and compositional effects on tree-water relation}, doi = {10.25972/OPUS-32624}, url = {http://nbn-resolving.de/urn:nbn:de:bvb:20-opus-326245}, school = {Universit{\"a}t W{\"u}rzburg}, year = {2024}, abstract = {Forests are essential sources of tangible and intangible benefits, but global climate change associated with recurrent extreme drought episodes severely affects forest productivity due to extensive tree die-back. On that, it appeals to an urgency for large-scale reforestation efforts to mitigate the impact of climate change worldwide; however, there is a lack of understanding of drought-effect on sapling growth and survival mechanisms. It is also challenging to anticipate how long trees can survive and when they succumb to drought. Hence, to ensure success of reforestation programs and sustainable forest productivity, it is essential to identify drought-resistant saplings. For that, profound knowledge of hydraulic characteristics is needed. To achieve this, the study was split into two phases which seek to address (1) how the hydraulic and anatomical traits influence the sapling's growth rate under drought stress. (2) how plant water potential regulation and physiological traits are linked to species' water use strategies and their drought tolerance. The dissertation is assembled of two study campaigns carried out on saplings at the Chair of Botany II, University of W{\"u}rzburg, Germany. The first study involved three ecologically important temperate broadleaved tree species — saplings of 18-month (Acer pseudoplatanus, Betula pendula, and Sorbus aucuparia) — grown from seeds in contrasting conditions (inside a greenhouse and outside), with the latter being subjected to severe natural heat waves. In the second study, two additional temperate species (Fagus sylvatica and Tilia cordata) were added. The drying-out event was conducted using a randomised blocked design by monitoring plant water status in a climate-controlled chamber and a greenhouse. In campaign I, I present the result based on analysed data of 82 plants of temperate deciduous species and address the juvenile growth rate trade-off with xylem safety-efficiency. Our results indicate biomass production varies considerably due to the contrasted growing environment. High hydraulic efficiency is necessary for increased biomass production, while safety-efficiency traits are decoupled and species-specific. Furthermore, productivity was linked considerably to xylem safety without revealing a well-defined pattern among species. Moreover, plasticity in traits differed between stressed and non-stressed plants. For example, safety-related characteristics were more static than efficiency-related traits, which had higher intra-specific variation. Moreover, we recorded anatomical and leaf traits adjustments in response to a stress condition, but consistency among species is lacking. In campaign II, I combined different ways to estimate the degree of isohydry based on water potential regulation and connected the iso-anisohydric spectrum (i.e., hydroscape area, HSA) to hydraulic traits to elucidate actual plant performance during drought. We analysed plant water potential regulation (Ψpd and Ψmd) and stomatal conductance of 28-29 month saplings of five species. I used a linear mixed modelling approach that allowed to control individual variations to describe the water potential regulation and tested different conceptual definitions of isohydricity. The combined methods allowed us to estimate species' relative degree of isohydry. Further, we examined the traits coordination, including hydraulic safety margin, HSM; embolism resistance, P88; turgor loss, Ψtlp; stomata closure, Ps90; capacitance, C; cuticular conductance, gmin, to determine time to hydraulic failure (Thf). Thf is the cumulative effect of time to stomata closure (Tsc) and time after stomatal closure to catastrophic hydraulic failure (Tcrit). Our results show the species' HSA matches their stomatal stringency, which confirms the relationship between stomatal response and leaf water potential decline. Species that close stomata at lower water potential notably had a larger HSA. Isohydric behaviour was mostly associated with leaf hydraulic traits and poorly to xylem safety traits. Species' degree of isohydry was also unrelated to the species' time to death during drying-out experiments. This supports the notion that isohydry behaviours are linked to water use rather than drought survival strategies. Further, consistent with our assumptions, more isohydric species had larger internal water storage and lost their leaf turgor at less negative water potentials. Counter to our expectations, neither embolism resistance nor the associated hydraulic safety margins were related to metrics of isohydry. Instead, our results indicate traits associated with plant drought response to cluster along two largely independent axes of variation (i.e., stomatal stringency and xylem safety). Furthermore, on the temporal progression of plant drought responses, stomatal closure is critical in coordinating various traits to determine species' hydraulic strategies. Desiccation avoidance strategy was linked to Tsc and coordinated traits response of Ps90, Ψtlp, and HSA, whereas desiccation tolerance was related to Tcrit and traits such as lower P88 value, high HSM, and lower gmin. Notably, the shoot capacitance (C) is crucial in Thf and exhibits dichotomous behaviour linked to both Tsc and Tcrit. In conclusion, knowledge of growth rate trade-offs with xylem safety-efficiency combined with traits linked to species' hydraulic strategies along the isohydry could substantially enhance our ability to identify drought-resistant saplings to ensure the success of reforestation programs and predicting sensitivity to drought for achieving sustainable forest ecosystems.}, subject = {Wachstumsrate}, language = {en} }