TY - THES A1 - Zancolli, Giulia T1 - Amphibian diversity along the slope of Mount Kilimanjaro: from species to genes T1 - Diversität von Amphibien im Höhengradienten des Mount Kilimanjaro: von Arten zu Genen N2 - 1. Since the early nineteenth century describing (and understanding) patterns of distribution of biodiversity across the Earth has represented one of the most significant intellectual challenges to ecologists and biogeographers. Among the most striking patterns of species richness are: the latitudinal and elevational gradients, with peaks in number of species at low latitudes and somewhere at mid altitudes, although other patterns, e.g. declines with increasing elevation, are often observed. Even in highly diverse tropical regions, species richness is not evenly distributed but there are “hotspots” of biodiversity where an exceptional number of species, especially endemics, are concentrated. Unfortunately, such areas are also experiencing dramatic loss of habitat. Among vertebrate taxa, amphibians are facing the most alarming number of extinctions. Habitat destruction, pollution and emergence of infectious diseases such as chytridiomycosis, are causing worldwide population declines. Responses to these drivers can be multidirectional and subtle, i.e. they may not be captured at the species but at the genetic level. Moreover, present patterns of diversity can result from the influence of past geological, climatic and environmental changes. In this study, I used a multidisciplinary and multilevel approach to understand how and to which extent the landscape influences amphibian diversity. Mount Kilimanjaro is an exceptional tropical region where the landscape is rapidly evolving due to land use changes; additionally, there is a broad lack of knowledge of its amphibian fauna. During two rainy seasons in 2011, I recorded anurans from the foothills to 3500 m altitude; in addition, I focused on two river frog species and collected tissue samples for genetic analysis and swabs for detection of chytridiomycosis, the deadly disease caused by Batrachochytrium dendrobatidis (Bd). 2. I analyzed how species richness and composition change with increasing elevation and anthropogenic disturbance. In order to disentangle the observed patterns of species diversity and distribution, I incorporated inferences from historical biogeography and compared the assemblage of Mt. Kilimanjaro and Mt. Meru (both recent volcanoes) with those of the older Eastern Arc Mountains. Species richness decreased with elevation and locally increased in presence of water bodies, but I did not detect effects of either anthropogenic disturbance or vegetation structure on species richness and composition. Moreover, I found a surprisingly low number of forest species. Historical events seem to underlie the current pattern of species distribution; the young age of Mt. Kilimanjaro and the complex biogeographic processes which occurred in East Africa during the last 20 million years prevented montane forest frogs from colonizing the volcano. 3. I focused on the genetic level of biodiversity and investigated how the landscape, i.e. elevation, topographic relief and land cover, influence genetic variation, population structure and gene flow of two ecologically similar and closely related river frog species, namely Amietia angolensis and Amietia wittei. I detected greater genetic differentiation among populations in the highland species (A. wittei) and higher genetic variation in the lowland species (A. angolensis), although genetic diversity was not significantly correlated with elevation. Importantly, human settlements seemed to restrict gene flow in A. angolensis, whereas steep slopes were positively correlated with gene flow in A. wittei. This results show that even ecologically similar species can respond differently to landscape processes and that the spatial configuration of topographic features combined with species-specific biological attributes can affect dispersal and gene flow in disparate ways. 4. River frogs of the genus Amietia seem to be particularly susceptible to chytridiomycosis, showing the highest pathogen load in Kenya and other African countries. In the last study, I collected swab samples from larvae of A. angolensis and A. wittei for Bd detection. Both species resulted Bd-positive. The presence of Bd on Mt. Kilimanjaro has serious implication. For instance, Bd can be transported by footwear of hikers from contaminated water and soil. Tourists visiting Mt. Kilimanjaro may translocate Bd zoospores to other areas such as the nearby Eastern Arc Mts. where endemic and vulnerable species may still be naïve to the fungus and thus suffer of population declines. 5. My study significantly contributed to the knowledge of the amphibian fauna of Mt. Kilimanjaro and of East Africa in general, and it represents a valuable tool for future conservation actions and measures. Finally, it highlights the importance of using a multidisciplinary (i.e. community ecology, historical biogeography, landscape genetics, disease ecology) and multilevel (i.e. community, species, population, gene) approach to disentangle patterns of biodiversity. N2 - Seit Ende des 19. Jahrhunderts ist es eine der größten intellektuellen Herausforderungen für Ökologen und Biogeographen, die Verteilungsmuster der Biodiversität auf der Erde zu beschreiben und letztlich zu verstehen. Zu den auffälligsten Mustern des Artenreichtums gehören die Gradienten, die sich in Abhängigkeit von der geographischer Breite und der Höhe über dem Meeresspiegel ergeben. Dabei treten Maxima der Artenzahl in den niederen Breiten und stellenweise in mittleren Höhenregionen auf; es lassen sich aber auch andere Muster beobachten, z.B. eine Abnahme der Artenzahl mit zunehmender Höhe. Selbst in den hochdiversen Tropen sind Arten nicht gleichmäßig verteilt. So gibt es sog. „hotspots“ der Biodiversität mit einer außergewöhnlich großen Zahl von Arten (meist Endemiten). Gerade diese Regionen sind es, die heute dramatische 1. Seit Ende des 19. Jahrhunderts ist es eine der größten intellektuellen Herausforderungen für Ökologen und Biogeographen, die Verteilungsmuster der Biodiversität auf der Erde zu beschreiben und letztlich zu verstehen. Zu den auffälligsten Mustern des Artenreichtums gehören die Gradienten, die sich in Abhängigkeit von der geographischer Breite und der Höhe über dem Meeresspiegel ergeben. Dabei treten Maxima der Artenzahl in den niederen Breiten und stellenweise in mittleren Höhenregionen auf; es lassen sich aber auch andere Muster beobachten, z.B. eine Abnahme der Artenzahl mit zunehmender Höhe. Selbst in den hochdiversen Tropen sind Arten nicht gleichmäßig verteilt. So gibt es sog. „hotspots“ der Biodiversität mit einer außergewöhnlich großen Zahl von Arten (meist Endemiten). Gerade diese Regionen sind es, die heute dramatische Habitatverluste verzeichnen. Unter den Wirbeltieren sind es die Amphibien, die dabei die höchsten Aussterberaten aufweisen. Ihre Populationen gehen weltweit zurück, wofür neben Lebensraumzerstörung auch Umweltverschmutzung und die Ausbreitung von Infektionskrankheiten, z.B. Chytridiomykose, verantwortlich sind. Reaktionen auf solche Faktoren können vielschichtig sein und fast unmerklich bleiben, was bedeutet, dass sie nicht auf Artniveau, sondern nur auf genetischer Ebene erfasst werden können. Hinzu kommt, dass die aktuellen Muster der Biodiversität auf den Einfluss vergangener Veränderungen hinsichtlich Geologie, Klima und Umwelt zurückgeführt werden können ... KW - Kilimandscharo KW - biodiversity KW - Amphibien KW - Lurche KW - Biodiversität KW - Vielfalt Y1 - 2013 U6 - http://nbn-resolving.de/urn/resolver.pl?urn:nbn:de:bvb:20-opus-91792 ER - TY - JOUR A1 - Peters, Marcell K. A1 - Hemp, Andreas A1 - Appelhans, Tim A1 - Behler, Christina A1 - Classen, Alice A1 - Detsch, Florian A1 - Ensslin, Andreas A1 - Ferger, Stefan W. A1 - Frederiksen, Sara B. A1 - Gebert, Frederike A1 - Haas, Michael A1 - Helbig-Bonitz, Maria A1 - Hemp, Claudia A1 - Kindeketa, William J. A1 - Mwangomo, Ephraim A1 - Ngereza, Christine A1 - Otte, Insa A1 - Röder, Juliane A1 - Rutten, Gemma A1 - Costa, David Schellenberger A1 - Tardanico, Joseph A1 - Zancolli, Giulia A1 - Deckert, Jürgen A1 - Eardley, Connal D. A1 - Peters, Ralph S. A1 - Rödel, Mark-Oliver A1 - Schleuning, Matthias A1 - Ssymank, Axel A1 - Kakengi, Victor A1 - Zhang, Jie A1 - Böhning-Gaese, Katrin A1 - Brandl, Roland A1 - Kalko, Elisabeth K.V. A1 - Kleyer, Michael A1 - Nauss, Thomas A1 - Tschapka, Marco A1 - Fischer, Markus A1 - Steffan-Dewenter, Ingolf T1 - Predictors of elevational biodiversity gradients change from single taxa to the multi-taxa community level JF - Nature Communications N2 - The factors determining gradients of biodiversity are a fundamental yet unresolved topic in ecology. While diversity gradients have been analysed for numerous single taxa, progress towards general explanatory models has been hampered by limitations in the phylogenetic coverage of past studies. By parallel sampling of 25 major plant and animal taxa along a 3.7 km elevational gradient on Mt. Kilimanjaro, we quantify cross-taxon consensus in diversity gradients and evaluate predictors of diversity from single taxa to a multi-taxa community level. While single taxa show complex distribution patterns and respond to different environmental factors, scaling up diversity to the community level leads to an unambiguous support for temperature as the main predictor of species richness in both plants and animals. Our findings illuminate the influence of taxonomic coverage for models of diversity gradients and point to the importance of temperature for diversification and species coexistence in plant and animal communities. KW - community ecology KW - macroecology KW - tropical ecology KW - biodiversity Y1 - 2016 U6 - http://nbn-resolving.de/urn/resolver.pl?urn:nbn:de:bvb:20-opus-169374 VL - 7 ER -