Effects of Salt Stress on the Leaf Shape and Scaling of Pyrus betulifolia Bunge

Yu Yu,Liu Liu,Zhang Zhang,Hui Hui,Feng Feng,Miao Miao,Shi Shi

doi:10.3390/sym11080991

Abstract

Leaf shape can reflect the survival and development of plants in different environments. In particular, leaf area, showing a scaling relationship with other leaf-shape indices, has been used to evaluate the extent of salt stress on plants. Based on the scaling relationships between leaf area and other leaf-shape indices in experiments at different levels of salt stress, we could examine which leaf-shape indices are also related to salt stress. In the present study, we explored the effects of different salt concentration treatments on leaf dry mass per unit area (LMA), the quotient of leaf perimeter and leaf area (QPA), the quotient of leaf width and length (QWL), the areal quotient (AQ) of left and right sides of a leaf and the standardized index (SI) for bilateral symmetry. We treated Pyrus betulifolia Bunge under NaCl salt solution of 2‰, 4‰ and 6‰, respectively, with fresh water with no salt as the control. The reduced major axis (RMA) was used to fit a linear relationship of the log-transformed data between any leaf trait measures and leaf area. We found that leaf fresh weight and dry weight decrease with salt concentration increasing, whereas the exponents of leaf dry weight versus leaf area exhibit an increasing trend, which implies that the leaves expanding in higher salt environments are prone to have a higher cost of dry mass investment to increase per unit leaf area than those in lower salt environments. Salt concentration has a significant influence on leaf shape especially QWL, and QWL under 6‰ concentration treatment is significantly greater than the other treatments. However, there is no a single increasing or decreasing trend for the extent of leaf bilateral symmetry with salt concentration increasing. In addition, we found that the scaling exponents of QPA versus leaf area for four treatments have no significant difference. It indicates that the scaling relationship of leaf perimeter versus leaf area did not change with salt concentration increasing. The present study suggests that salt stress can change leaf functional traits especially the scaling relationship of leaf dry weight versus leaf area and QWL, however, it does not significantly affect the scaling relationships between leaf morphological measures (including QPA and the extent of leaf bilateral symmetry) and leaf area.

Highlights

Land salinization has been a global environmental issue, especially in more than 100 countries located in the arid, semi-arid and coastal areas [1,2]
The estimated scaling exponent of leaf dry weight versus leaf area for the lower salt concentration treatment (i.e., 2% salt concentration) has no significant difference with that of the control group. This means that to increase per unit leaf area for two higher salt concentration treatments will require more leaf dry mass input than the control group and the 2% salt concentration treatment
Despite a weak positive correlation between leaf area and the quotient of leaf width and length (QWL) under 6% salt concentration treatment, QWL did not show a significant correction with leaf area for the remaining treatments including the control group

Summary

Introduction

Land salinization has been a global environmental issue, especially in more than 100 countries located in the arid, semi-arid and coastal areas [1,2]. Intensifying human activities in the country will further accelerate soil salinization at an annual rate of increase by millions of hectares. This trend will inevitably suppress land productivity and agriculture sustainability, posing adverse effects on the environment and the socioeconomic system. It is of great ecological and social values to develop approaches to alleviate soil salinity at a massive scale

Results

Discussion

Conclusion