TY  - THES
A1  - Leidinger, Ludwig Klaus Theodor
T1  - How genomic and ecological traits shape island biodiversity - insights from individual-based models
T1  - Einflüsse genomischer und ökologischer Arteigenschaften auf die Biodiversität von Inseln - Erkenntnisse aus individuenbasierten Modellen
N2  - Life on oceanic islands provides a playground and comparably easy\-/studied basis
for the understanding of biodiversity in general. Island biota feature many
fascinating patterns: endemic species, species radiations and species with
peculiar trait syndromes. However, classic and current island biogeography
theory does not yet consider all the factors necessary to explain many of these
patterns. In response to this, there is currently a shift in island biogeography
research to systematically consider species traits and thus gain a more
functional perspective. Despite this recent development, a set of species
characteristics remains largely ignored in island biogeography, namely genomic
traits. Evidence suggests that genomic factors could explain many of the
speciation and adaptation patterns found in nature and thus may be highly
informative to explain the fascinating and iconic phenomena known for oceanic
islands, including species radiations and susceptibility to biotic invasions.

Unfortunately, the current lack of comprehensive meaningful data makes studying
these factors challenging. Even with paleontological data and space-for-time
rationales, data is bound to be incomplete due to the very environmental
processes taking place on oceanic islands, such as land slides and volcanism,
and lacks causal information due to the focus on correlative approaches. As
promising alternative, integrative mechanistic models can explicitly consider
essential underlying eco\-/evolutionary mechanisms. In fact, these models have
shown to be applicable to a variety of different systems and study questions.

In this thesis, I therefore examined present mechanistic island models to
identify how they might be used to address some of the current open questions in
island biodiversity research. Since none of the models simultaneously considered
speciation and adaptation at a genomic level, I developed a new genome- and
niche-explicit, individual-based model. I used this model to address three
different phenomena of island biodiversity: environmental variation, insular
species radiations and species invasions.

Using only a single model I could show that small-bodied species with flexible
genomes are successful under environmental variation, that a complex combination
of dispersal abilities, reproductive strategies and genomic traits affect the
occurrence of species radiations and that invasions are primarily driven by the
intensity of introductions and the trait characteristics of invasive
species. This highlights how the consideration of functional traits can promote
the understanding of some of the understudied phenomena in island biodiversity.

The results presented in this thesis exemplify the generality of integrative
models which are built on first principles. Thus, by applying such models to
various complex study questions, they are able to unveil multiple biodiversity
dynamics and patterns.  The combination of several models such as the one I
developed to an eco\-/evolutionary model ensemble could further help to identify
fundamental eco\-/evolutionary principles. I conclude the thesis with an outlook
on how to use and extend my developed model to investigate geomorphological
dynamics in archipelagos and to allow dynamic genomes, which would further
increase the model's generality.
N2  - Inseln sind nützliche Modellsysteme für das Verständnis von Biodiversität im
Allgemeinen. Dies wird verstärkt durch den Umstand, dass Flora und Fauna auf
Inseln eine Vielzahl einzigartiger Phänomene aufweisen: von endemischen Arten
über Artenradiationen bis hin zu außergewöhnlichen Arteigenschaften. Bisherige
Theorien der Inselbiogeographie berücksichtigen jedoch nicht alle Faktoren, die
nötig wären, um solche Phänomene zu erklären. Derzeitige Bemühungen zielen daher
darauf ab, Arteigenschaften systematisch mit bestehenden Theorien zu vereinen.
Trotz dieser Entwicklung werden genomische Arteigenschaften bislang in solch
einer funktionalen Inselbiogeographie weitestgehend ignoriert, obwohl es
Hinweise darauf gibt, dass genomische Faktoren einige der faszinierenden
Diversifizierungsmuster einschließlich Artenradiationen erklären könnten.

Die Erforschung dieser Faktoren gestaltet sich aufgrund des Mangels an
umfangreichen, aussagekräftigen Daten jedoch als schwierig. Selbst unter
Zuhilfenahme von paläontologischen Daten und substituierten Daten aus
vergleichbaren Systemen lassen sich Unvollständigkeiten in den Daten und das
Problem fehlender Kausalzusammenhänge schwer überwinden. Eine vielversprechende
Alternative stellen mechanistische Modelle dar, von denen einige bereits
für eine Vielzahl von Systemen und Forschungsprojekten eingesetzt wurden.

In dieser Dissertation wurden daher mechanistische Inselmodelle untersucht, um
herauszufinden, inwiefern sich diese für derzeitige offene Fragen in der
Inselbiogeographie eignen würden. Da keines der untersuchten Modelle
gleichzeitig Artbildung and Anpassung unter Berücksichtigung von genomischen
Faktoren abbildet, wurde ein neues genom- und nischenexplizites,
individuenbasiertes Modell entwickelt. Dieses wurde benutzt, um drei
verschiedene Phänomene im Kontext der Inselbiogeographie zu untersuchen: die
Anpassung an Umweltvariation, Artenradiationen und Invasionen durch exotische
Arten.

Mit diesem neuentwickeltem Modell konnte gezeigt werden, dass kleinere
Arten mit flexiblen Genomen unter variablen Umwelteigenschaften erfolgreicher
sind, dass eine komplexe Kombination aus Ausbreitungsfähigkeiten,
Fortpflanzungsstrategien und genomischen Arteigenschaften das Entstehen von
Artenradiationen beeinflussen und dass Invasionen vor allem von der
Einführungsintensität und den Arteigenschaften exotischer Arten getrieben
sind. Diese Ergebnisse demonstrieren, wie die Berücksichtigung funktionaler
Arteigenschaften dabei helfen kann, einige bislang wenig untersuchte Phänomene
der Inselbiogeographie zu verstehen.

Die Ergebnisse dieser Dissertation stehen beispielhaft für die
Allgemeingültigkeit integrativer, auf Grundzusammenhängen aufbauender
Modelle. Dies wird durch die Aufdeckung diverser Biodiversitätsmuster und
-dynamiken im Rahmen der Bearbeitung verschiedener komplexer Fragestellungen
hervorgehoben. Weitere Modelle, wie das hier beschriebene, könnten sogar in
einem Modellensemble kombiniert werden, um öko-evolutionare Grundprinzipien zu
identifizieren. Abschließend wird ein Ausblick auf die Möglichkeit gewährt, das
Modell weiterzunutzen und zu erweitern, um beispielsweise geomorphologische
Archipeldynamiken oder dynamische Genome abzubilden, und damit die
Allgemeingültigkeit des Modells noch zu erweitern.
KW  - Inselbiogeografie
KW  - Simulation
KW  - Biodiversität
KW  - Genetik
KW  - Mikroevolution
KW  - island biogeography
KW  - mechanistic models
KW  - genetic architecture
KW  - eco-evolutionary feedbacks
Y1  - 2020
U6  - http://nbn-resolving.de/urn/resolver.pl?urn:nbn:de:bvb:20-opus-207300
ER  - 
TY  - JOUR
A1  - Schmitt, Jana
A1  - Keller, Andreas
A1  - Nourkami-Tutdibi, Nasenien
A1  - Heisel, Sabrina
A1  - Habel, Nunja
A1  - Leidinger, Petra
A1  - Ludwig, Nicole
A1  - Gessler, Manfred
A1  - Graf, Norbert
A1  - Berthold, Frank
A1  - Lenhof, Hans-Peter
A1  - Meese, Eckart
T1  - Autoantibody Signature Differentiates Wilms Tumor Patients from Neuroblastoma Patients
JF  - PLoS ONE
N2  - Several studies report autoantibody signatures in cancer. The majority of these studies analyzed adult tumors and compared the seroreactivity pattern of tumor patients with the pattern in healthy controls. Here, we compared the autoimmune response in patients with neuroblastoma and patients with Wilms tumor representing two different childhood tumors. We were able to differentiate untreated neuroblastoma patients from untreated Wilms tumor patients with an accuracy of 86.8%, a sensitivity of 87.0% and a specificity of 86.7%. The separation of treated neuroblastoma patients from treated Wilms tumor patients' yielded comparable results with an accuracy of 83.8%. We furthermore identified the antigens that contribute most to the differentiation between both tumor types. The analysis of these antigens revealed that neuroblastoma was considerably more immunogenic than Wilms tumor. The reported antigens have not been found to be relevant for comparative analyses between other tumors and controls. In summary, neuroblastoma appears as a highly immunogenic tumor as demonstrated by the extended number of antigens that separate this tumor from Wilms tumor.
KW  - Heparan-sulfate
KW  - N-Myc
KW  - Serum autoantibodies
KW  - Suppressors EXT1
KW  - Neuro-blastoma
KW  - Allelic loss
KW  - Lung-cancer
KW  - Children
KW  - Amplification
KW  - Therapy
Y1  - 2011
U6  - http://nbn-resolving.de/urn/resolver.pl?urn:nbn:de:bvb:20-opus-133794
VL  - 6
IS  - 12
ER  - 
TY  - JOUR
A1  - Vedder, Daniel
A1  - Leidinger, Ludwig
A1  - Sarmento Cabral, Juliano
T1  - Propagule pressure and an invasion syndrome determine invasion success in a plant community model
JF  - Ecology and Evolution
N2  - The success of species invasions depends on multiple factors, including propagule pressure, disturbance, productivity, and the traits of native and non-native species. While the importance of many of these determinants has already been investigated in relative isolation, they are rarely studied in combination. Here, we address this shortcoming by exploring the effect of the above-listed factors on the success of invasions using an individual-based mechanistic model. This approach enables us to explicitly control environmental factors (temperature as surrogate for productivity, disturbance, and propagule pressure) as well as to monitor whole-community trait distributions of environmental adaptation, mass, and dispersal abilities. We simulated introductions of plant individuals to an oceanic island to assess which factors and species traits contribute to invasion success. We found that the most influential factors were higher propagule pressure and a particular set of traits. This invasion trait syndrome was characterized by a relative similarity in functional traits of invasive to native species, while invasive species had on average higher environmental adaptation, higher body mass, and increased dispersal distances, that is, had greater competitive and dispersive abilities. Our results highlight the importance in management practice of reducing the import of alien species, especially those that display this trait syndrome and come from similar habitats as those being managed.
KW  - community trait analysis
KW  - individual-based modelling
KW  - island plant communities
KW  - propagule pressure
KW  - species invasions
Y1  - 2021
U6  - http://nbn-resolving.de/urn/resolver.pl?urn:nbn:de:bvb:20-opus-259107
VL  - 11
IS  - 23
ER  - 
TY  - JOUR
A1  - Leidinger, Ludwig
A1  - Vedder, Daniel
A1  - Cabral, Juliano Sarmento
T1  - Temporal environmental variation may impose differential selection on both genomic and ecological traits
JF  - Oikos
N2  - The response of populations and species to changing conditions determines how community composition will change functionally, including via trait shifts. Selection from standing variation has been suggested to be more efficient than acquiring new mutations. Yet, studies on community trait composition and trait selection largely focus on phenotypic variation in ecological traits, whereas the underlying genomic traits remain understudied. Using a genome‐explicit, niche‐ and individual‐based model, we address the potential interactions between genomic and ecological traits shaping communities under an environmental selective forcing, namely temporal positively autocorrelated environmental fluctuation. In this model, all ecological traits are explicitly coded by the genome. For our experiments, we initialized 90 replicate communities, each with ca 350 initial species, characterized by random genomic and ecological trait combinations, on a 2D spatially explicit landscape with two orthogonal gradients (temperature and resource use). We exposed each community to two contrasting scenarios: without (i.e. static environments) and with temporal variation. We then analyzed emerging compositions of both genomic and ecological traits at the community, population and genomic levels. Communities in variable environments were species poorer than in static environments, and populations more abundant, whereas genomes had lower genetic linkage, mean genetic variation and a non‐significant tendency towards higher numbers of genes. The surviving genomes (i.e. those selected by variable environments) coded for enhanced environmental tolerance and smaller biomass, which resulted in faster life cycles and thus also in increased potential for evolutionary rescue. Under temporal environmental variation, larger, less linked genomes retained more variation in mean dispersal ability at the population level than at genomic level, whereas the opposite trend emerged for biomass. Our results provide clues to how sexually‐reproducing diploid plant communities might react to variable environments and highlights the importance of genomic traits and their interaction with ecological traits for eco‐evolutionary responses to changing climates.
KW  - environmental variability
KW  - genomic traits
KW  - mechanistic model
KW  - rapid evolution
KW  - standing variation
Y1  - 2021
U6  - http://nbn-resolving.de/urn/resolver.pl?urn:nbn:de:bvb:20-opus-238945
VL  - 130
IS  - 7
SP  - 1100
EP  - 1115
ER  -