The hydroclimatic and ecophysiological basis of cloud forest distributions under current and projected climates

Rafael S. Oliveira*, Cleiton B. Eller, Paulo R. L. Bittencourt, Mark Mulligan

*Corresponding author for this work

Research output: Contribution to journalLiterature reviewpeer-review

92 Citations (Scopus)

Abstract

Background
Tropical montane cloud forests (TMCFs) are characterized by a unique set of biological and hydroclimatic features, including frequent and/or persistent fog, cool temperatures, and high biodiversity and endemism. These forests are one of the most vulnerable ecosystems to climate change given their small geographic range, high endemism and dependence on a rare microclimatic envelope. The frequency of atmospheric water deficits for some TMCFs is likely to increase in the future, but the consequences for the integrity and distribution of these ecosystems are uncertain. In order to investigate plant and ecosystem responses to climate change, we need to know how TMCF species function in response to current climate, which factors shape function and ecology most and how these will change into the future.

Scope
This review focuses on recent advances in ecophysiological research of TMCF plants to establish a link between TMCF hydrometeorological conditions and vegetation distribution, functioning and survival. The hydraulic characteristics of TMCF trees are discussed, together with the prevalence and ecological consequences of foliar uptake of fog water (FWU) in TMCFs, a key process that allows efficient acquisition of water during cloud immersion periods, minimizing water deficits and favouring survival of species prone to drought-induced hydraulic failure.

Conclusions
Fog occurrence is the single most important microclimatic feature affecting the distribution and function of TMCF plants. Plants in TMCFs are very vulnerable to drought (possessing a small hydraulic safety margin), and the presence of fog and FWU minimizes the occurrence of tree water deficits and thus favours the survival of TMCF trees where such deficits may occur. Characterizing the interplay between microclimatic dynamics and plant water relations is key to foster more realistic projections about climate change effects on TMCF functioning and distribution.

Original languageEnglish
Pages (from-to)909-920
Number of pages12
JournalANNALS OF BOTANY
Volume113
Issue number6
DOIs
Publication statusPublished - May 2014

Keywords

  • Tropical montane cloud forest
  • plant water relations
  • drought
  • cavitation
  • fog
  • hydraulic failure
  • ecohydrology
  • foliar water uptake
  • Drimys brasiliensis
  • climate change
  • neotropics
  • LEAF WATER REPELLENCY
  • ISOLATED CUTICULAR MEMBRANES
  • ROOT XYLEM EMBOLISM
  • SEMPERVIRENS D. DON
  • PLANT CUTICLES
  • HYDRAULIC REDISTRIBUTION
  • RAIN-FOREST
  • NIGHTTIME TRANSPIRATION
  • FOLIAR UPTAKE
  • TROPICAL MOUNTAIN

Fingerprint

Dive into the research topics of 'The hydroclimatic and ecophysiological basis of cloud forest distributions under current and projected climates'. Together they form a unique fingerprint.

Cite this