Abstract
The biomechanical root flexibility in response to hydromechanical soil heterogeneity is the most determining factor of the root architecture which plays a paramount role in mycorrhizal infection and allows the seedlings to adapt to the environmental constraint. We examined the impact of five different hydromechanical medium properties (hydroponics, vermiculite, vermiculite-gravel, sawdust, and sand) on the morphology, physiology, and anatomy of Cedrus atlantica seedlings at a controlled growth chamber. The growth of the seedling is strongly stimulated by the hydroponic medium through the stimulation of the aerial part dry weight and the main root length. However, the sand medium increases the main root dry weight by the radial expanse stimulation at the level of the epidermis, vascular cylinder, and cortex and compensates the less root architecture by the stimulation of the xylem and phloem areas. In contrast to sand and hydroponic media, the sawdust medium stimulates the phloem/xylem ratio, the root architecture, and the short roots. The Pearson bilateral correlation shows that the aerial part dry weight is positively correlated with the permeability, porosity, and water-holding capacity and negatively with the bulk density and density at saturation, whereas the short root production is negatively correlated with the permeability and water-holding capacity. Hence, the hydromechanical characteristics of the soils must be taken into account in the reforestation and mycorrhization attempts.
Highlights
For a maximal success of the afforestation and the mycorrhization of cedar seedlings, we still need to learn more about its root system architecture and the ways to control its growth and development. erefore, we need to understand the hydrological and mechanical medium factors that increase the roots’ receptiveness toward mycorrhizal fungi
We have studied the growth response of Cedrus atlantica seedlings to the variation of the medium hydromechanical characteristics through their morphological and anatomical root traits
Water content was estimated by the difference between the matter fresh weight (FW) and dry weight (DW) of each seedling organ and calculated according to the equation (FW − DW) × 100÷(DW)
Summary
E biomechanical root flexibility in response to hydromechanical soil heterogeneity is the most determining factor of the root architecture which plays a paramount role in mycorrhizal infection and allows the seedlings to adapt to the environmental constraint. Its natural regeneration and transplantation are exposed to many obstacles that are related to biological, chemical, and, especially, physical soil qualities In addition to these natural obstacles, the cedar seedlings are challenged by the early slow growth [11] and the weak mycorrhization [9, 12, 13]. Erefore, we need to understand the hydrological and mechanical medium factors that increase the roots’ receptiveness toward mycorrhizal fungi On this basis, we have studied the growth response of Cedrus atlantica seedlings to the variation of the medium hydromechanical characteristics through their morphological and anatomical root traits
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