More Like this

1. Wild herbivores and cattle have differing effects on postfire herbaceous vegetation recovery in an A frican savanna

   https://doi.org/10.1002/eap.2975  

   Masudi, Sherril_P; Odadi, Wilfred_O; Kimuyu, Duncan_M; Gachuiri, Charles_K; Sensenig, Ryan_L; Young, Truman_P (May 2024, Ecological Applications)

   Abstract Fire and herbivory have profound effects on vegetation in savanna ecosystems, but little is known about how different herbivore groups influence vegetation dynamics after fire. We assessed the separate and combined effects of herbivory by cattle and wild meso‐ and megaherbivores on postfire herbaceous vegetation cover, species richness, and species turnover in a savanna ecosystem in central Kenya. We measured these vegetation attributes for five sampling periods (from 2013 to 2017) in prescribed burns and unburned areas located within a series of replicated long‐term herbivore exclosures that allow six different combinations of cattle and wild meso‐ and megaherbivores (elephants and giraffes). Vegetation cover (grasses, mainly) and species richness were initially reduced by burning but recovered by 15–27 months after fire, suggesting strong resilience to infrequent fire. However, the rates of recovery differed in plots accessible by different wild and domestic herbivore guilds. Wildlife (but not cattle) delayed postfire recovery of grasses, and the absence of wildlife (with or without cattle) delayed recovery of forbs. Herbivory by only cattle increased grass species richness in burned relative to unburned areas. Herbivory by cattle (with or without wildlife), however, reduced forb species richness in burned relative to unburned areas. Herbivory by wild ungulates (but not cattle) increased herbaceous species turnover in burned relative to unburned areas. Megaherbivores had negligible modifying effects on these results. This study demonstrates that savanna ecosystems are remarkably resilient to infrequent fires, but postfire grazing by cattle and wild mesoherbivores exerts different effects on recovery trajectories of herbaceous vegetation. 

   more » « less
2. Synergistic effects of long‐term herbivory and previous fire on fine‐scale heterogeneity of prescribed grassland burns

   https://doi.org/10.1002/ecy.3270  

   Werner, Chhaya M.; Kimuyu, Duncan; Veblen, Kari E.; Sensenig, Ryan L.; LaMalfa, Eric; Young, Truman P. (February 2021, Ecology)

   Abstract Grassland and savanna ecosystems, important for both livelihoods and biodiversity conservation, are strongly affected by ecosystem drivers such as herbivory, fire, and drought. Interactions among fire, herbivores and vegetation produce complex feedbacks in these ecosystems, but these have rarely been studied in the context of fuel continuity and resultant fire heterogeneity. We carried out 36 controlled burns within replicated experimental plots that had allowed differential access by wild and domestic large herbivores since 1995 in a savanna ecosystem in Kenya. Half of these were reburns of plots burned 5 yr previously. We show here that the fine‐scale spatial heterogeneity of fire was greater in plots (1) previously burned, (2) accessible to large herbivores, and especially (3) these two in combination. An additional embedded experiment demonstrated that even small experimental burn‐free patches can have strong positive effects on tree saplings, which experienced less damage during controlled burns and quicker postfire recovery. This work highlights the importance of simultaneously examining the interactions between fire and herbivory on fuel heterogeneity, which can have important impacts on the growth of woody saplings in savanna grasslands. 

   more » « less
3. Disease and fire interact to influence transitions between savanna–forest ecosystems over a multi‐decadal experiment

   https://doi.org/10.1111/ele.13719  

   Pellegrini, Adam F. A.; Hein, Andrew M.; Cavender‐Bares, Jeannine; Montgomery, Rebecca A.; Staver, A. Carla; Silla, Fernando; Hobbie, Sarah E.; Reich, Peter B.; Williams, ed., John (March 2021, Ecology Letters)

   Abstract Global change is shifting disturbance regimes that may rapidly change ecosystems, sometimes causing ecosystems to shift between states. Interactions between disturbances such as fire and disease could have especially severe effects, but experimental tests of multi‐decadal changes in disturbance regimes are rare. Here, we surveyed vegetation for 35 years in a 54‐year fire frequency experiment in a temperate oak savanna–forest ecotone that experienced a recent outbreak of oak wilt. Different fire regimes determined whether plots were savanna or forest by regulating tree abundance (r² = 0.70), but disease rapidly reversed the effect of fire exclusion, increasing mortality by 765% in unburned forests, but causing relatively minor changes in frequently burned savannas. Model simulations demonstrated that disease caused unburned forests to transition towards a unique woodland that was prone to transition to savanna if fire was reintroduced. Consequently, disease–fire interactions could shift ecosystem resilience and biome boundaries as pathogen distributions change. 

   more » « less
4. Herbivore regulation of savanna vegetation: Structural complexity, diversity, and the complexity–diversity relationship

   https://doi.org/10.1002/ecm.1624  

   Coverdale, Tyler C; Boucher, Peter B; Singh, Jenia; Palmer, Todd M; Goheen, Jacob R; Pringle, Robert M; Davies, Andrew B (November 2024, Ecological Monographs)

   Abstract Large mammalian herbivores exert strong top‐down control on plants, which in turn influence most ecological processes. Accordingly, the decline, displacement, or extinction of wild large herbivores in African savannas is expected to alter the physical structure of vegetation, the diversity of plant communities, and downstream ecosystem functions. However, herbivore impacts on vegetation comprise both direct and indirect effects and often depend on herbivore body size and plant type. Understanding how herbivores affect savanna vegetation requires disaggregating the effects of different herbivores and the responses of different plants, as well as accounting for both the structural complexity and composition of plant assemblages. We combined high‐resolution Light Detection and Ranging (LiDAR) with field measurements from size‐selective herbivore exclosures in Kenya to determine how herbivores affect the diversity and physical structure of vegetation, how these impacts vary with body size and plant type, and whether there are predictable associations between plant diversity and structural complexity. Herbivores generally reduced the diversity and abundance of both overstory and understory plants, though the magnitude of these impacts varied substantially as a function of body size and plant type: only megaherbivores (elephants and giraffes) affected tree cover, whereas medium‐ and small‐bodied herbivores had stronger effects on herbaceous diversity and abundance. We also found evidence that herbivores altered the strength and direction of interactions between trees and herbaceous plants, with signatures of facilitation in the presence of herbivores and of competition in their absence. While megaherbivores uniquely affected tree structure, medium‐ and small‐bodied species had stronger (and complementary) effects on metrics of herbaceous vegetation structure. Plant structural responses to herbivore exclusion were species‐specific: of five dominant tree species, just three exhibited significant individual morphological variation across exclosure treatments, and the size class of herbivores responsible for these effects varied across species. Irrespective of exclosure treatment, more species‐rich plant communities were more structurally complex. We conclude that the diversity and architecture of savanna vegetation depend on consumptive and nonconsumptive plant–herbivore interactions; the roles of herbivore diversity, body size, and plant traits in mediating those interactions; and a positive feedback between plant diversity and structural complexity. 

   more » « less
5. Amazonian forest resilience inferred from fire-induced changes in carbon stocks and tree diversity

   https://doi.org/10.1088/1748-9326/ade60d  

   Maracahipes-Santos, Leonardo; Maracahipes, Leandro; Silvério, Divino_Vicente; Macedo, Marcia; Silveiro, Antônio_Carlos; Potter, Nathalia; Paolucci, Lucas_Navarro; Starinchak, Bela; Alencar, Ane; Brando, Paulo (June 2025, Environmental Research Letters)

   Abstract Understanding the resilience of tropical forests to fire is essential for evaluating their dynamics under climate change and increasing land-use pressures. Here, we assess how different fire frequencies and intensities influence tree mortality and carbon dynamics in southeastern Amazonia. Using a replicated randomized block design with 24 plots (40 × 40 m), we applied four treatments: unburned control, one burn in 2016 (B1), two burns in 2013 and 2016 (B2), and two burns with added fuel (B2+) to increase fire intensity. Forest inventories conducted from 2012 to 2024 measured tree mortality, diversity, composition, and aboveground biomass. Fire frequency and intensity significantly increased mortality, particularly among small trees, but impacts on forest structure and productivity were more nuanced. Aboveground biomass declined modestly in burned plots, with the greatest loss in B2+ (13%). Aboveground net primary productivity (ANPP) dropped immediately post-burn, especially in B2 and B2+, and partially recovered by 2022–2024. In contrast, leaf area index (LAI) and litterfall rebounded within a couple of years, suggesting a degree of structural and functional resilience. Species richness and composition remained relatively stable in the years following the first experimental fires, but gradually declined and shifted in B2 and B2+ plots beginning in 2014. These results indicate that the experimental forests’ resilience to low-intensity and infrequent fires can prevent widespread forest collapse, but repeated and intensified burns likely undermine long-term resilience by altering forest structure, composition, and carbon dynamics. With the southeastern Amazon forests projected to burn more often in the coming decades, our results highlight both the vulnerability and recovery potential of these ecosystems. Maintaining ecological integrity and minimizing additional disturbances that influence fuel availability will be critical for sustaining forest functions under future fire regimes. 

   more » « less