Comparison of Xylem Anatomy and Hydraulic Properties in Black Locust Trees at Two Growth Stages in Semiarid China

• Published in: Forests Vol. 15; no. 1; p. 116
• Main Authors: Ma, Changkun, Zhang, Xi, Yao, Qian, Zhou, Beibei, Wang, Quanjiu, Shao, Mingan
• Format: Journal Article
• Language: English
• Published: Basel MDPI AG 01.01.2024
• Subjects: Architecture; Black locust; Comparative analysis; conduit diameter; Developmental stages; Diameters; Drought; Environmental aspects; Flowers & plants; hydraulic conductivity; Hydraulic equipment; Hydraulic properties; Hydraulics; Loam soils; Measurement; Moisture content; Physiological aspects; Plant species; Precipitation; Skewed distributions; Soil moisture; Soil water; soil water availability; stem height; Stems; Tapering; Trees; Variation; vascular trait; Water conservation; Water content; Water transportation; Xylem; China; Sweden
• ISSN: 1999-4907; 1999-4907
• DOI: 10.3390/f15010116

Tree species transitioning between different developmental phases requires homeostatic adjustments in order to maintain the integrity of the tree hydraulic system. Hence, adjustments related to hydraulic traits (e.g., xylem conduit diameter) are of key functional significance. However, critical information on the differences between different developmental stages is rare. Using sapwood samples from 36 black locust trees with different growth stages (actively growing and declining stages) and a soil water gradient along a hillslope, xylem conduits at stem apexes and breast height (1.3 m above ground) stems were measured. The results showed marked differences in vascular traits between actively growing and declining trees. In contrast to actively growing trees, declining trees exhibited a reduction in conduit diameters accompanied by increased frequency with a positively skewed distribution and a subsequent decline in cumulative theoretical hydraulic conductivity. Across all sampled trees, the hydraulically weighted mean conduit diameter tapered acropetally from breast height to the stem apex. The extent of conduit tapering in actively growing trees (0.244, 95% CI 0.201–0.287) aligned with predictions from the hydraulic optimality model. Conversely, trees in a declining status displayed significantly reduced conduit tapering (0.175, 95% CI 0.146–0.198), indicating an elevation in hydraulic resistance with increasing tree height. Variations in hydraulic properties predominantly resulted from differences in tree height rather than variations in stem diameter or soil water content. The correlation between conduit diameter and soil water content in both actively growing and declining trees stemmed indirectly from variations in tree height rather than presenting a direct response to drought stress.