New computer model helps to better understand species diversity in rainforests
Based on a media release from ETH Zurich
Leipzig, Zurich. Using a new mechanistic model of evolution on Earth, researchers at German Centre for Integrative Biodiversity Research (iDiv) and ETH Zurich can now better explain why the rainforests of Africa are home to fewer species than the tropical forests of South America and Southeast Asia. The key to high species diversity lies in how dynamically the continents have evolved over time.
Tropical rainforests are the most biodiverse habitats on Earth. They are home to a huge number of different plants, animals, fungi and other organisms. These forests are primarily spread over three continents, concentrated in the Amazon Basin in South America, the Congo Basin in Central Africa, and the vast archipelago of Southeast Asia. One might assume that all tropical rainforests are about equally diverse due to their stable warm and humid climate and their geographical location around the equator – but this is not the case. Compared to South America and Southeast Asia, the number of species in Africa's humid tropical forests is significantly lower for many groups of organisms.
Palms with few species
A good illustration of this uneven distribution – what researchers refer to as the pantropical diversity disparity (PDD) – is palm trees: "Of the 2,500 species worldwide, 1,200 occur in the Southeast Asian region and 800 in the tropical forests of South America, but only 66 in African rainforests. Why this should be so is debated among biodiversity researchers", explains co-author Dr Renske Onstein, Head of Junior Research Group Evolution and Adaptation at iDiv.
There is some evidence that the current climate is the cause of the lower species diversity in Africa's tropical forests. The climate in Africa's tropical belt is drier and cooler than that in Southeast Asia and South America. Other evidence suggests that the different environmental and tectonic histories of the three tropical forest regions over tens of millions of years had an impact on the differing levels of biodiversity. Such environmental changes include, for example, the formation of mountains, islands, or arid and desert areas. However, it is difficult to distinguish between the two factors of current climate and environmental history.
Mountain building brings up diversity
Researchers from iDiv and ETH Zurich have now investigated this question with the help of a new computer model called "gen3sis". "The model allows us to simulate the evolution and diversification of species over many millions of years," explains Dr Oskar Hagen, who developed the model as part of his doctoral thesis which was supervised by Prof. Loïc Pellissier, Professor of Landscape Ecology at ETH Zurich.
The researchers conclude that the current climate is not the main reason why biodiversity is lower in the rainforests of Africa. Rather, biodiversity has emerged from the dynamics of mountain building and climate change. The results of the historical simulations largely coincide with the patterns of biodiversity distribution observable today.
One factor in particular is crucial to high biodiversity on a continent: geological dynamics. Active plate tectonics promote both the formation of mountains, such as the Andes in South America, and the emergence of archipelagos, as in Southeast Asia. These two processes result in many new ecological niches, which in turn give rise to numerous new species. Africa's rainforest belt, on the other hand, has had less tectonic activity over the past 110 million years. It is also relatively small because it is bordered by drylands in the north and south, limiting its spread. "Species from humid regions can hardly adapt to the dry conditions of the surrounding drylands," Pellissier points out.
Geologically vibrant continents produce higher biodiversity
The "gen3sis" model developed by ETH researchers was only recently presented in the journal PLoS Biology. It is a mechanistic model in which the primary constraints such as geology and climate are represented together with biological mechanisms and from which biodiversity patterns can materialise. To simulate the emergence of biodiversity, the most important processes to integrate into the model are ecology (i.e. each species has its own limited ecological niche), evolution, speciation and dispersal.
"With our model, we can show how complex geological, climatic and biological processes interact and how different biodiversity patterns emerge," Hagen says. By building their model on these basic evolutionary mechanisms, the researchers can simulate species diversity without having to input (distribution) data for each individual species. However, the model requires data on the geological dynamics of the continents under consideration, as well as humidity and temperatures from climate reconstructions.
The researchers are now refining the model and running simulations to understand the emergence of biodiversity in other species-rich regions, such as the mountains of western China. The model's code and the palaeoenvironmental reconstructions are open source. All interested evolutionary and biodiversity researchers can use it to study the formation of biodiversity in different regions of the world.
Original publication:
(Researchers with iDiv affiliation bold)
Hagen, O., Skeels, A., Onstein, R., Jetz, W., Pellissier, L. (2021): Earth history events shaped the evolution of uneven biodiversity across tropical moist forests. Proc Natl Acad Sci USA October 5, 2021 118 (40) e2026347118; doi: 10.1073/pnas.2026347118call_made
Hagen, O., Flück, B., Fopp, F., Cabral, J. S., Hartig, F., Pontarp, M., et al. (2021): gen3sis: A general engine for eco-evolutionary simulations of the processes that shape Earth's biodiversity. PLoS Biol 19(7): e3001340. doi: 10.1371/journal.pbio.3001340call_made
