Arun Singh Ramesh scite author profile

Arun Singh Ramesh

2Publications

2Citation Statements Received

137Citation Statements Given

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Temperature, nutrient availability, and species traits interact to shape elevation responses of Australian tropical trees

Ramesh¹,

Cheesman²,

Flores‐Moreno³

et al. 2023

Front. For. Glob. Change

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Elevation gradients provide natural laboratories for investigating tropical tree ecophysiology in the context of climate warming. Previously observed trends with increasing elevation include decreasing stem diameter growth rates (GR), increasing leaf mass per area (LMA), higher root-to-shoot ratios (R:S), increasing leaf δ13C, and decreasing leaf δ15N. These patterns could be driven by decreases in temperature, lower soil nutrient availability, changes in species composition, or a combination thereof. We investigated whether these patterns hold within the genus Flindersia (Rutaceae) along an elevation gradient (0–1,600 m) in the Australian Wet Tropics. Flindersia species are relatively abundant and are important contributors to biomass in these forests. Next, we conducted a glasshouse experiment to better understand the effects of temperature, soil nutrient availability, and species on growth, biomass allocation, and leaf isotopic composition. In the field, GR and δ15N decreased, whereas LMA and δ13C increased with elevation, consistent with observations on other continents. Soil C:N ratio also increased and soil δ15N decreased with increasing elevation, consistent with decreasing nutrient availability. In the glasshouse, relative growth rates (RGR) of the two lowland Flindersia species responded more strongly to temperature than did those of the two upland species. Interestingly, leaf δ13C displayed an opposite relationship with temperature in the glasshouse compared with that observed in the field, indicating the importance of covarying drivers in the field. Leaf δ15N increased in nutrient-rich compared to nutrient-poor soil in the glasshouse, like the trend in the field. There was a significant interaction for δ15N between temperature and species; upland species showed a steeper increase in leaf δ15N with temperature than lowland species. This could indicate more flexibility in nitrogen acquisition in lowland compared to upland species with warming. The distinguishing feature of a mountaintop restricted Flindersia species in the glasshouse was a very high R:S ratio in nutrient-poor soil at low temperatures, conditions approximating the mountaintop environment. Our results suggest that species traits interact with temperature and nutrient availability to drive observed elevation patterns. Capturing this complexity in models will be challenging but is important for making realistic predictions of tropical tree responses to global warming.

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Are Tropical Mountaintop Trees Constrained in Their Distributions by Physiological Limitations? Thermal Adaptation and Acclimation to Climate Change

Ramesh¹,

Cheesman²,

Crayn³

et al. 2022

Proc. R. Soc. Qld.

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Habitat suitability for most tree species restricted to the wet tropical mountaintops of Australia is predicted to decline with climate change. This is especially concerning because no a vailable alternative habitat exists for species to migrate, and their growth responses to warming are understudied. We present a study investigating the effects of warming on an ecologically important taxon, Flindersia spp., distributed across an elevation gradient in the Australian Wet Tropics. We test: (a) whether tropical mountaintop tree species are constrained in their distributions by physiological limitations to their thermal environment; and (b) whether species display an ability to adapt and/or acclimate to future warming. We first explored trends in species' in situ adaptation by studying leaf traits among congeners paired with environmental variables, and then evaluated plant physiological and growth responses under experimental soil nutrients and growth temperatures. We found that field trends in fundamental leaf traits with elevation were strongly driven by climate -decreasing temperatures, increasing soil moisture content and decreasing soil nutrient availability -and under experimental growth conditions showed increasing growth under warmer conditions, but then either declined or did not significantly change for upland and mountaintop species under resource-rich conditions. These modifications were associated with limitations in their photosynthetic biochemistry and selection of pathways favouring either growth or defence under resource-poor conditions. Our research findings have implications for conservation of these species in these fragile ecosystems under future warming.

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