Xylem form and function under extreme nutrient limitation: an example from California’s pygmy forest

• Xylem anatomy and function have large implications for plant growth as well as survival during drought, but the impact of nutrient limitation on xylem is not fully understood. This study examines the pygmy forest in California, a plant community that experiences negligible water stress but is seve...

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Bibliographic Details
Published in:The New phytologist 2020-05, Vol.226 (3), p.760-769
Main Authors: Cary, Katharine L., Ranieri, Gina M., Pittermann, Jarmila
Format: Article
Language:English
Subjects:
Acidic soils
California
Cavitation
Cavitation resistance
conduit diameter
Conspecifics
Drought
embolism
Environmental impact
Forests
hydraulic conductivity
Mineral nutrients
Nutrient transport
Nutrients
Plant communities
Plant growth
Plant Leaves
pygmy forest
Sequoia sempervirens (redwood)
Soil
Soil investigations
Soil resistance
Soils
Species
Specific conductivity
Survival
Trees
vulnerability curve
Water
Water stress
Water transport
wood anatomy
Xylem
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Summary:• Xylem anatomy and function have large implications for plant growth as well as survival during drought, but the impact of nutrient limitation on xylem is not fully understood. This study examines the pygmy forest in California, a plant community that experiences negligible water stress but is severely stunted by low-nutrient and acidic soil, to investigate how nutrient limitation affects xylem function. • Thirteen key anatomical and hydraulic traits of stems of four species were compared between pygmy forest plants and nearby conspecifics growing on richer soil. • Resistance to cavitation (P50), a critical trait for predicting survival during drought, had highly species-specific responses: in one species, pygmy plants had a 26% decrease in cavitation resistance compared to higher-nutrient conspecifics, while in another species, pygmy plants had a 56% increase in cavitation resistance. Other traits responded to nutrient limitation more consistently: pygmy plants had smaller xylem conduits and higher leaf-specific conductivity (K L) than conspecific controls. • Edaphic stress, even in the absence of water stress, altered xylem structure and thus had substantial impacts on water transport. Importantly, nutrient limitation shifted cavitation resistance in a species-specific and unpredictable manner; this finding has implications for the assessment of cavitation resistance in other natural systems.
ISSN:0028-646X
1469-8137
DOI:10.1111/nph.16405