The need to decipher plant drought stress along the
soil-plant-atmosphere continuum
- Andreas Schweiger,
- Telse Zimmermann,
- Christian Poll,
- Sven Marhan,
- Vincent Leyrer,
- Bernd Berauer
Abstract
Lacking comparability among rainfall manipulation studies is still a
major limiting factor for generalizations in ecological climate change
impact research. A common framework for studying ecological drought
effects is urgently needed to foster advances in ecological
understanding the effects of drought. In this synthesis, we argue, that
the soil-plant-atmosphere continuum, describing the flow of water from
the soil through the plant to the atmosphere, can serve as a holistic
concept of drought in rainfall manipulation experiments which allows for
the reconciliation experimental drought ecology. Using experimental
data, we show that investigations of leaf water potential in combination
with edaphic and atmospheric drought -- as the three main components of
the soil-plant-atmosphere-continuum -- are key to understand the effect
of drought stress on plants. Based on a systematic literature survey, we
show that especially plant and atmospheric based drought quantifications
are strongly underrepresented and integrative assessments of all three
components are almost absent in current experimental literature. Based
on our observations we argue, that studying dynamics of plant water
status in the framework of the soil-plant-atmosphere-continuum can
foster comparability of different studies conducted in different
ecosystems and with different plant species and can facilitate
extrapolation to other systems, species or future climates.