Your search keyword '"Muellner-Riehl, A.N."' showing total 5 results

1. Deep phylogeographic splits and limited mixing by sea surface currents govern genetic population structure in the mangrove genus Lumnitzera (Combretaceae) across the Indonesian Archipelago

Author

Manurung, J., Rojas Andrés, B.M., Barratt, C.D., Schnitzler, J., Jönsson, B.F., Susanti, R., Durka, Walter, Muellner-Riehl, A.N., Manurung, J., Rojas Andrés, B.M., Barratt, C.D., Schnitzler, J., Jönsson, B.F., Susanti, R., Durka, Walter, and Muellner-Riehl, A.N.

Abstract

The Indonesian Archipelago accommodates the largest mangrove area in Southeast Asia and possesses the world's richest composition of mangrove species. The archipelago comprises areas of the biogeographic regions Sunda and Wallacea, separated by Wallace's line. We used the true mangrove species Lumnitzera littorea and L. racemosa as a study case for understanding the effects of phylogeographic history, sea surface currents and geographical distance on genetic diversity and genetic structure. We sampled 14 populations of L. littorea (N = 106) and 21 populations of L. racemosa (N = 152) from Indonesia. We utilized 3,442 biallelic SNP loci genotyped with the ddRADseq approach. We assessed genetic diversity, genetic structure, and effective dispersal of the populations, and related them to geographical distance and sea surface currents. Our study revealed low levels of genetic variation at population level in Lumnitzera. Pronounced genetic differentiation between populations indicated two phylogroups in both species. While in L. littorea the two phylogroups were largely separated by Wallace's line, L. racemosa showed a northwest vs. southeast pattern with strong mixture in Wallacea. Our findings provide novel insights into the phylogeography of the mangrove genus Lumnitzera and the role of sea surface currents in the Indonesian Archipelago.

Published

2022

2. Climate change will disproportionally affect the most genetically diverse lineages of a widespread African tree species

Author

Lyam, P.T., Duque-Lazo, J., Hauenschild, F., Schnitzler, J., Muellner-Riehl, A.N., Greve, M., Ndangalasi, H., Myburgh, A., Durka, Walter, Lyam, P.T., Duque-Lazo, J., Hauenschild, F., Schnitzler, J., Muellner-Riehl, A.N., Greve, M., Ndangalasi, H., Myburgh, A., and Durka, Walter

Abstract

Global climate change is proceeding at an alarming rate with major ecological and genetic consequences for biodiversity, particularly in drylands. The response of species to climate change may differ between intraspecific genetic groups, with major implications for conservation. We used molecular data from 10 nuclear and two chloroplast genomes to identify phylogeographic groups within 746 individuals from 29 populations of Senegalia senegal, a savannah tree species in sub-Saharan Africa. Three phylogroups are identified corresponding to Sudano-Sahelian, Zambezian and Southern African biogeographic regions in West, East and Southern Africa. Genetic diversity was highest in Southern and Zambesian and lowest in the Sudano-Sahelian phylogroups. Using species distribution modeling, we infer highly divergent future distributions of the phylogroups under three climate change scenarios. Climate change will lead to severe reductions of distribution area of the genetically diverse Zambezian (− 41–− 54%) and Southern (− 63–− 82%) phylogroups, but to an increase for the genetically depauperate Sudano-Sahelian (+ 7– + 26%) phylogroups. This study improves our understanding of the impact of climate change on the future distribution of this species. This knowledge is particularly useful for biodiversity management as the conservation of genetic resources needs to be considered in complementary strategies of in-situ conservation and assisted migration.

Published

2022

3. Structure of chimpanzee gut microbiomes across tropical Africa

Author

Bueno de Mesquita, C.P., Nichols, L.M., Gebert, M.J., Vanderburgh, C., Bocksberger, G., Lester, J.D., Kalan, A.K., Dieguez, P., McCarthy, M.S., Agbor, A., Álvarez Varona, P., Ayimisin, A.E., Bessone, M., Chancellor, R., Cohen, H., Coupland, C., Deschner, T., Egbe, V.E., Goedmakers, A., Granjon, A.-C., Grueter, C.C., Head, J., Hernandez-Aguilar, R.A., Jeffery, K.J., Jones, S., Kadam, P., Kaiser, M., Lapuente, J., Larson, B., Marrocoli, S., Morgan, D., Mugerwa, B., Mulindahabi, F., Neil, E., Niyigaba, P., Pacheco, L., Piel, A.K., Robbins, M.M., Rundus, A., Sanz, C.M., Sciaky, L., Sheil, D., Sommer, V., Stewart, F.A., Ton, E., van Schijndel, J., Vergnes, V., Wessling, E.G., Wittig, R.M., Ginath Yuh, Y., Yurkiw, K., Zuberbühler, K., Gogarten, J.F., Heintz-Buschart, Anna, Muellner-Riehl, A.N., Boesch, C., Kühl, H.S., Fierer, N., Arandjelovic, M., Dunn, R.R., Bueno de Mesquita, C.P., Nichols, L.M., Gebert, M.J., Vanderburgh, C., Bocksberger, G., Lester, J.D., Kalan, A.K., Dieguez, P., McCarthy, M.S., Agbor, A., Álvarez Varona, P., Ayimisin, A.E., Bessone, M., Chancellor, R., Cohen, H., Coupland, C., Deschner, T., Egbe, V.E., Goedmakers, A., Granjon, A.-C., Grueter, C.C., Head, J., Hernandez-Aguilar, R.A., Jeffery, K.J., Jones, S., Kadam, P., Kaiser, M., Lapuente, J., Larson, B., Marrocoli, S., Morgan, D., Mugerwa, B., Mulindahabi, F., Neil, E., Niyigaba, P., Pacheco, L., Piel, A.K., Robbins, M.M., Rundus, A., Sanz, C.M., Sciaky, L., Sheil, D., Sommer, V., Stewart, F.A., Ton, E., van Schijndel, J., Vergnes, V., Wessling, E.G., Wittig, R.M., Ginath Yuh, Y., Yurkiw, K., Zuberbühler, K., Gogarten, J.F., Heintz-Buschart, Anna, Muellner-Riehl, A.N., Boesch, C., Kühl, H.S., Fierer, N., Arandjelovic, M., and Dunn, R.R.

Abstract

Understanding variation in host-associated microbial communities is important given the relevance of microbiomes to host physiology and health. Using 560 fecal samples collected from wild chimpanzees (Pan troglodytes) across their range, we assessed how geography, genetics, climate, vegetation, and diet relate to gut microbial community structure (prokaryotes, eukaryotic parasites) at multiple spatial scales. We observed a high degree of regional specificity in the microbiome composition, which was associated with host genetics, available plant foods, and potentially with cultural differences in tool use, which affect diet. Genetic differences drove community composition at large scales, while vegetation and potentially tool use drove within-region differences, likely due to their influence on diet. Unlike industrialized human populations in the United States, where regional differences in the gut microbiome are undetectable, chimpanzee gut microbiomes are far more variable across space, suggesting that technological developments have decoupled humans from their local environments, obscuring regional differences that could have been important during human evolution.

Published

2021

4. Genetic diversity and distribution of Senegalia senegal (L.) Britton under climate change scenarios in West Africa

Author

Lyam, P.T., Duque-Lazo, J., Durka, Walter, Hauenschild, F., Schnitzler, J., Michalak, I., Ogundipe, O.T., Muellner-Riehl, A.N., Lyam, P.T., Duque-Lazo, J., Durka, Walter, Hauenschild, F., Schnitzler, J., Michalak, I., Ogundipe, O.T., and Muellner-Riehl, A.N.

Abstract

Climate change is predicted to impact species’ genetic diversity and distribution. We used Senegalia senegal (L.) Britton, an economically important species distributed in the Sudano-Sahelian savannah belt of West Africa, to investigate the impact of climate change on intraspecific genetic diversity and distribution. We used ten nuclear and two plastid microsatellite markers to assess genetic variation, population structure and differentiation across thirteen sites in West Africa. We projected suitable range, and potential impact of climate change on genetic diversity using a maximum entropy approach, under four different climate change scenarios. We found higher genetic and haplotype diversity at both nuclear and plastid markers than previously reported. Genetic differentiation was strong for chloroplast and moderate for the nuclear genome. Both genomes indicated three spatially structured genetic groups. The distribution of Senegalia senegal is strongly correlated with extractable nitrogen, coarse fragments, soil organic carbon stock, precipitation of warmest and coldest quarter and mean temperature of driest quarter. We predicted 40.96 to 6.34 per cent of the current distribution to favourably support the species’ ecological requirements under future climate scenarios. Our results suggest that climate change is going to affect the population genetic structure of Senegalia senegal, and that patterns of genetic diversity are going to influence the species’ adaptive response to climate change. Our study contributes to the growing evidence predicting the loss of economically relevant plants in West Africa in the next decades due to climate change.

Published

2018

5. Evolutionary radiations in the species-rich mountain genus Saxifraga L

Author

Ebersbach, J., Schnitzler, J., Favre, A., and Muellner-Riehl, A.N.

Subjects

Evolutionary radiations, Geography, Evolution, diversification rates, Climate Change, Saxifragaceae, alpine habitats, Saxifraga, key innovations, Tibet, Biological Evolution, QH359-425, Hengduan Mountains, Phylogeny, Research Article

Abstract

Background A large number of taxa have undergone evolutionary radiations in mountainous areas, rendering alpine systems particularly suitable to study the extrinsic and intrinsic factors that have shaped diversification patterns in plants. The species-rich genus Saxifraga L. is widely distributed throughout the Northern Hemisphere, with high species numbers in the regions adjacent to the Qinghai-Tibet Plateau (QTP) in particular the Hengduan Mountains and the Himalayas. Using a dataset of 297 taxa (representing at least 60% of extant Saxifraga species), we explored the variation of infrageneric diversification rates. In addition, we used state-dependent speciation and extinction models to test the effects of geographic distribution in the Hengduan Mountains and the entire QTP region as well as of two morphological traits (cushion habit and specialized lime-secreting glands, so-called hydathodes) on the diversification of this genus. Results We detected two to three rate shifts across the Saxifraga phylogeny and two of these shifts led to radiations within two large subclades of Saxifraga, sect. Ciliatae Haworth subsect. Hirculoideae Engl. & Irmsch. and sect. Porphyrion Tausch subsect. Kabschia Engl. GEOSSE analyses showed that presence in the Hengduan Mountains had a positive effect on diversification across Saxifraga. Influence of these mountains was strongest in Saxifraga sect. Ciliatae subsect. Hirculoideae given its pronounced distribution there, and thus the radiation in this group can be classified at least partially as geographic. In contrast, the evolution of the cushion life form and lime-secreting hydathodes had positive effects on diversification only in selected Saxifraga sections, including sect. Porphyrion subsect. Kabschia. We therefore argue that radiation in this group was likely adaptive. Conclusions Our study underlines the complexity of processes and factors underpinning plant radiations: Even in closely related lineages occupying the same life zone, shifts in diversification are not necessarily governed by similar factors. In conclusion, alpine plant radiations result from a complex interaction among geographical settings and/or climatic modifications providing key opportunities for diversification as well as the evolution of key innovations. Electronic supplementary material The online version of this article (doi:10.1186/s12862-017-0967-2) contains supplementary material, which is available to authorized users.

Published

2017