Abstract
Calcium (Ca) is often supplied to crop species to prevent the occurrence of Ca–related disorders. Mechanisms of Ca absorption and transport are not fully understood and the effectiveness of root and/or foliar Ca fertilization may be variable. To characterize the rate of Ca absorption and transport, trials were developed with chili pepper and sweet cherry plants, using 45CaCl2 as a tracer. The Ca treatments supplied were: (1) No 45Ca (control); (2) 45Ca soil application; (3) 45Ca supply to basal leaves, and (4) 45Ca application to apical leaves. After two months, plants were harvested for biomass and Ca content determination. The recovery of 45Ca in different plant parts was measured with a liquid scintillation counter and leaf traits were observed by scanning electronic microscopy. In general, the highest 45Ca concentrations were recovered in treated organs, while root applications led to highest 45Ca translocation rates, which varied between chili pepper and cherry plants. For chili pepper, 45Ca applied to the soil was detected mainly in roots (44 %) followed by leaves (36.6 %) stems (17.4 %) and fruits (2 %). In sweet cherry trees, soil–applied 45Ca was principally recovered in roots (45.3 %), shoots (28.5 %), leaves (14.3 %) and trunks (11.9 %). The results provide evidence of increased absorption of root–applied Ca, as well as different degrees of Ca mobility between species. Foliar application led to major Ca increases in treated leaves, with Ca transported to other plant organs after apical leaf Ca supply chiefly in cherry trees.
Highlights
Calcium is an essential plant nutrient mainly for cell wall formation, cellular signalling responses, and cell membrane stability (Marschner, 2012)
The highest 45Ca concentrations were recovered in treated organs, while root applications led to highest 45Ca translocation rates, which varied between chili pepper and cherry plants
This study investigated the Ca partitioning and rate of absorption and mobility of 45Ca supplied to chili pepper and sweet cherry plants, after root and foliar application
Summary
Calcium is an essential plant nutrient mainly for cell wall formation, cellular signalling responses, and cell membrane stability (Marschner, 2012). Calcium absorbed from the soil solution is transported from the roots via xylem to different tissues and organs (Khalaj et al, 2016; Saure, 2005). Root Ca 2+ uptake decreases with increasing distance from the root apex (Marschner, 2012) and it is much higher in apical than in basal root zones (Saure, 2005). Transport of Ca to aerial plant organs depends on several factors, such as xylem sap Ca2+ concentration, balanced mineral nutrition, water uptake and plant water potential, transpiration and growth rate (Hocking et al, 2016; Souri and Hatamian, 2019). Excessive Ca accumulation may occur in organs with high transpiration rates (i.e., leaves; de Freitas and Mitcham, 2012; de Freitas et al, 2015), while low transpiring organs may suffer localized Ca deficiencies, as reported for several fruit and vegetable crops (e.g., Sampaio et al, 1999; Val et al, 2008; Marschner, 2012)
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