Abstract
Carpinus betulus L. is a deciduous tree widely distributed in Europe with strong adaptation, and it plays a key role in landscaping and timbering because of its variety of colors and shapes. Recently introduced to China for similar purposes, this species needs further study as to its physiological adaptability under various soil salinity conditions. In this study, the growth and physicochemical changes of C. betulus seedlings cultivated in soil under six different levels of salinity stress (NaCl: 0, 17, 34, 51, 68, and 85 mM) were studied for 14, 28 and 42 days. The plant growth and gas exchange parameters were not changed much by 17 and 34 mM NaCl, but they were significantly affected after treatments with 51 ~ 85 mM NaCl. The chlorophyll content was not significantly affected at 17 and 34 mM salinity, and the relative water content, malondialdehyde content and cell membrane stability of C. betulus did not change obviously under the 17 and 34 mM treatments, indicating that C. betulus is able to adapt to low-salinity conditions. The amount of osmotic adjustment substances and the antioxidant enzyme activity of C. betulus increased after 14 and 28 days and then decreased with increasing salinity gradients, but the proline content was increased during the entire time for different salinities. The Na content of different organs increased in response to salinity, and the K/Na, Ca/Na, and Mg/Na ratios were significantly affected by salinity. These results suggest that the ability of C. betulus to synthesize osmotic substances and enzymatic antioxidants may be impaired under severe saline conditions (68 ~ 85 mM NaCl) but that it can tolerate and accumulate salt at low salinity concentrations (17 ~ 34 mM NaCl). Such information is useful for land managers considering introducing this species to sites with various soil salinity conditions.
Highlights
Salinity stress is one of the main abiotic stresses affecting the growth of plants
The results showed that (Table 1) the reductions in growth became more pronounced with the increasing levels of salt in the soil; the root length, leaf area, dry weight of leaves were slightly higher under low salinity conditions (S1) than those in the control plants, which indicated that moderate (S3) and high (S4, S5) salt concentrations had obvious inhibitory effects on C. betulus but that the low concentration of salt treatment (S1) may promote the growth of the roots and leaves
This study showed that the growth and physicochemical parameters of C. betulus seedlings were inhibited under high salinity stress, including reduced gas exchange and increased Malondialdehyde Concentration (MDA)
Summary
Salinity stress is one of the main abiotic stresses affecting the growth of plants. Due to the influence of human population growth, increased industrial pollution, and improper irrigation, the existing salinized land in the world covers approximately 9.5 × 108 hm , approximately 22% of agricultural land worldwide [1,2]. The area of saline-alkaline land in China is approximately 9.9 × 107 hm , which accounts for 25% of the arable land in China [3]. Soil salinization has caused problems over vast areas in the world. In addition to soil salinity, de-icing salts have become a serious constraint for plant growth, in cities [4]. De-icing salts help to keep pavements dry and safe during ice and snow, their extensive use can cause damage to plants along sidewalks, walkways, and driveways
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