A complex network of interactions controls coexistence and relative abundances in Patagonian grass-shrub steppes.

CIPRIOTTI, P; AGUIAR, M.R.; WIEGAND, T.; PARUELO, J.M.

JOURNAL OF ECOLOGY (PRINT)

WILEY-BLACKWELL PUBLISHING, INC

Lugar: Londres; Año: 2014 vol. 102 p. 766 - 788

0022-0477

1. The coexistence of shrubs and grasses has intrigued ecologists for the past century, and the conundrum ofshrub?grass coexistence is at the core of debates on the functioning of semi-arid ecosystems. Here, we exploredhow the interplay of root competition and facilitation between life-forms at different life stages and demo-graphic bottlenecks controls the long-term coexistence of multiple shrub and grass species in semi-arid Patago-nian steppes.2. We used the spatially explicit and individual-based simulation model DINVEG that integrates the abundantinformation on the semi-arid Patagonian grass?shrub steppes to test six competing hypotheses on the mechanismsthat govern the coexistence and relative abundances of several grass and shrub species. The structurally realisticmodel allows for a direct comparison of model outputs with a wide range of previously collected field data.3. We formulate three competing hypotheses on vertical root overlap between grasses and shrubs (no overlap,partial overlap, full overlap) that were crosses with two hypotheses on asymmetric shrub?grass facilitation (withand without). Each of the six variants of DINVEG were tested in their ability to generate dynamics in accor-dance with detailed field data, and we performed global sensitivity analyses to reveal demographic bottlenecksand controls.4. The hypothesis combining partial vertical root overlap with no facilitation was the most likely hypothesisgiven the data. It created demographic bottlenecks in recruitment and emergence that controlled grass and shrubabundances, respectively, and only this hypothesis generated a situation where grasses controlled shrub abun-dances (by limiting shrub recruitment), but where grass abundance was only weakly controlled by shrubs. Inter-nal water dynamics generated reduced competition of shrubs to neighboured grasses that was sufficient toproduce the observed ring of grasses around shrubs, and most of the parameterizations that approximated theobserved species-specifi c abundances were able to reproduce the observed equilibrated spatial patterns of themature community.5. Synthesis. We found a complex network of mechanisms that controlled growth-form coexistence and relativeabundances in the Patagonian grass-shrub steppe where both, demographic bottlenecks and species interactionsacross life-forms, species and life stages were important. Our study points to alternative mechanisms of shrub?grass coexistence that may play an important role in dry grasslands and steppes where fire and herbivory arenot key drivers and provide an avenue to detect them.