We found a match
Your institution may have access to this item. Find your institution then sign in to continue.
- Title
Factors controlling drought resistance in grapevine (Vitis vinifera, chardonnay): application of a new microCT method to assess functional embolism resistance.
- Authors
Pratt, R. Brandon; Castro, Viridiana; Fickle, Jaycie C.; Madsen, Angela; Jacobsen, Anna L.
- Abstract
Premise: Quantifying resistance to embolism in woody plants is important for understanding their drought response. Methods to accurately quantify resistance to embolism continue to be debated. Methods: We used a new microCT‐based approach that quantifies embolized conduits and also analyzes conductive conduits by using an x‐ray‐dense, iodine‐rich tracer that moves though the vascular system and can easily be observed in microCT images. Many previous microCT studies assumed that all conduits were initially conductive, which may not be the case if there are developing or occluded conduits. We compared microCT results to a standard benchtop dehydration method and a centrifuge method. During dehydration, we measured gas exchange and quantified water potential at mortality. Results: Our microCT curves agreed with previously published microCT curves from the same greenhouse‐grown cultivar. We found a significant difference in embolism estimates if we assumed that all water‐filled conduits were functional rather than only those containing tracer. Embolism estimates from microCT differed from both the benchtop and centrifuge methods. The benchtop and centrifuge methods did not differ from one another. Conclusions: The new microCT method presented here is valuable in sampling species that may contain nonconductive conduits. Disagreement between microCT and two other methods was likely due to differences in the ways they quantify embolism. MicroCT assess the theoretical effect of embolism, whereas benchtop and centrifuge methods directly measure hydraulic conductivity. The theoretical approach does not fully account for the resistances of flow through a complex 3D vascular network.
- Subjects
EMBOLISMS; VITIS vinifera; CARDIOVASCULAR system; HYDRAULIC conductivity; GRAPES; DROUGHTS
- Publication
American Journal of Botany, 2020, Vol 107, Issue 4, p618
- ISSN
0002-9122
- Publication type
Article
- DOI
10.1002/ajb2.1450