%0 Journal Article %1 Martreetal_00 %A Martre, P. %A Cochard, H. %A Durand, J. L. %D 2000 %J New Phytologist %K anatomy, bibtex-import, citeulikeExport grass, unread %P 235--247 %T Changes in axial hydraulic conductivity along elongating leaf blades in relation to xylem maturation in tall fescue %V 146 %X Xylem maturation in elongating leaf blades of tall fescue (Festuca arundinacea) was studied using staining and microcasting. Three distinctive regions were identifed in the blade: (1) a basal region, in which elongation was occurring and protoxylem (PX) vessels were functioning throughout; (2) a maturation region, in which elongation had stopped and narrow (NMX) and large (LMX) metaxylem vessels were beginning to function; (3) a distal, mature region in which most of the longitudinal water movements occurred in the LMX. The axial hydraulic conductivity (Kh) was measured in leaf sections from all these regions and compared with the theoretical axial hydraulic conductivity (Kt) computed from the diameter of individual inner vessels. Kt was proportional to Kh throughout the leaf, but Kt was about three times Kh. The changes in Kh and Kt along the leaf reected the different stages of xylem maturation. In the basal 60 mm region, Kh was about 0.300.07 mmol s?" mm MPa?". Beyond that region, Kh rapidly increased with metaxylem element maturation to a maximum value of 5.00.3 mmol s?" mm MPa?", 105 mm from the leaf base. It then decreased to 3.50.2 mmol s?" mm MPa?" near the leaf tip. The basal expanding region was observed to restrict longitudinal water movement. There was a close relationship between the water deposition rate in the elongation zone and the sum of the perimeters of PX vessels. The implications of this longitudinal vasculature on the partitioning of water between growth and transpiration is discussed.

@article{Martreetal_00, abstract = {{Xylem maturation in elongating leaf blades of tall fescue (Festuca arundinacea) was studied using staining and microcasting. Three distinctive regions were identifed in the blade: (1) a basal region, in which elongation was occurring and protoxylem (PX) vessels were functioning throughout; (2) a maturation region, in which elongation had stopped and narrow (NMX) and large (LMX) metaxylem vessels were beginning to function; (3) a distal, mature region in which most of the longitudinal water movements occurred in the LMX. The axial hydraulic conductivity (Kh) was measured in leaf sections from all these regions and compared with the theoretical axial hydraulic conductivity (Kt) computed from the diameter of individual inner vessels. Kt was proportional to Kh throughout the leaf, but Kt was about three times Kh. The changes in Kh and Kt along the leaf reected the different stages of xylem maturation. In the basal 60 mm region, Kh was about 0.300.07 mmol s?" mm MPa?". Beyond that region, Kh rapidly increased with metaxylem element maturation to a maximum value of 5.00.3 mmol s?" mm MPa?", 105 mm from the leaf base. It then decreased to 3.50.2 mmol s?" mm MPa?" near the leaf tip. The basal expanding region was observed to restrict longitudinal water movement. There was a close relationship between the water deposition rate in the elongation zone and the sum of the perimeters of PX vessels. The implications of this longitudinal vasculature on the partitioning of water between growth and transpiration is discussed.}}, added-at = {2019-03-31T01:14:40.000+0100}, author = {Martre, P. and Cochard, H. and Durand, J. L.}, biburl = {https://www.bibsonomy.org/bibtex/24fdeeab374595572f63509da6e57ce7a/dianella}, citeulike-article-id = {1523828}, comment = {(private-note)theoretical computed vs actual hydraulic conductivity vessels. Kt was proportional to Kh throughout the leaf, but Kt was about three times Kh. Sumr4 Kt is proportional to Kh but theoretical conductivity from the hp rule doesn't fully explain Kh. Not just diameter, but also pit membranes, perforation plates, non-functional vessels... Protoxylem assumed to be functional throughout. The function of the narrow metaxylem is to increase the transfer surface area between the protoxylem and the large metaxylem. That's why it's only found in the transitional region of the leaf between where the protoxylem dominates flow and where the metaxylem does. Even Px lacunae are conductive.}, interhash = {fa550557506b104dd20cce9929352dcd}, intrahash = {4fdeeab374595572f63509da6e57ce7a}, journal = {New Phytologist}, keywords = {anatomy, bibtex-import, citeulikeExport grass, unread}, pages = {235--247}, posted-at = {2007-07-31 06:38:40}, priority = {0}, timestamp = {2019-03-31T01:16:26.000+0100}, title = {{Changes in axial hydraulic conductivity along elongating leaf blades in relation to xylem maturation in tall fescue}}, volume = 146, year = 2000 }