Moisture rivals temperature in limiting photosynthesis by trees establishing beyond their cold-edge range limit under ambient and warmed conditions

Climate change is altering plant species distributions globally, and warming is expected to promote uphill shifts in mountain trees. However, at many cold-edge range limits, such as alpine treelines in the western United States, tree establishment may be colimited by low temperature and low moisture...

Full description

Saved in:
Bibliographic Details
Published in:The New phytologist 2015-09, Vol.207 (4), p.1005-1014
Main Authors: Moyes, Andrew B., Germino, Matthew J., Kueppers, Lara M.
Format: Article
Language:English
Subjects:
abiotic stress
alpine treeline
Assimilation
Climate change
Cold Temperature
Colorado
Data lines
Drying
Forest soils
Gases - metabolism
Growing season
Humidity
Low temperature
Microclimate
Microclimates
Mountains
photoinhibition
Photosynthesis
Photosystem II Protein Complex - metabolism
Pine trees
Pinus - physiology
Pinus flexilis
Plant species
Provenance
Response functions
Seasons
Seedlings
Seedlings - physiology
Soil - chemistry
Soil heating
Soil moisture
Soil temperature regimes
Soil water
source limitation
species distribution
Temperature measurement
Timberlines
Time Factors
Treeline
Trees
Trees - physiology
water potential
Citations: Items that this one cites
Items that cite this one
Online Access:Get full text
Tags: Add Tag
No Tags, Be the first to tag this record!
Description
Summary:Climate change is altering plant species distributions globally, and warming is expected to promote uphill shifts in mountain trees. However, at many cold-edge range limits, such as alpine treelines in the western United States, tree establishment may be colimited by low temperature and low moisture, making recruitment patterns with warming difficult to predict. We measured response functions linking carbon (C) assimilation and temperature- and moisture-related microclimatic factors for limber pine (Pinus flexilis) seedlings growing in a heating × watering experiment within and above the alpine treeline. We then extrapolated these response functions using observed microclimate conditions to estimate the net effects of warming and associated soil drying on C assimilation across an entire growing season. Moisture and temperature limitations were each estimated to reduce potential growing season C gain from a theoretical upper limit by 15–30% (c. 50% combined). Warming above current treeline conditions provided relatively little benefit to modeled net assimilation, whereas assimilation was sensitive to either wetter or drier conditions. Summer precipitation may be at least as important as temperature in constraining C gain by establishing subalpine trees at and above current alpine treelines as seasonally dry subalpine and alpine ecosystems continue to warm.
ISSN:0028-646X
1469-8137
DOI:10.1111/nph.13422