The C4 Atriplex halimus vs. the C3 Atriplex hortensis: Similarities and Differences in the Salinity Stress Response

Roberta Calone,Carla Lambertini,Luigi Manfrini,Andrea Simoni,Antonio Cellini,Lorenzo Barbanti,Paola Gioacchini

doi:10.3390/agronomy11101967

Roberta Calone, Carla Lambertini + Show 5 more

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https://doi.org/10.3390/agronomy11101967

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Journal: Agronomy	Publication Date: Sep 29, 2021
Citations: 9	License type: CC BY 4.0

Affiliation: University of Bologna

Abstract

Soil properties and the ability to sustain agricultural production are seriously impaired by salinity. The cultivation of halophytes is seen as a solution to cope with the problem. In this framework, a greenhouse pot experiment was set up to assess salinity response in the perennial C4 species Atriplex halimus, and in the following three cultivars of the annual C3 Atriplex hortensis: green, red, and scarlet. The four genotypes were grown for 35 days with water salinity (WS) ranging from 0 to 360 mM NaCl. Plant height and fresh weight (FW) increased at 360 vs. 0 WS. The stomatal conductance (GS) and transpiration rate (E) were more severely affected by salinity in the C4 A. halimus than in the C3 species A. hortensis. This was reflected in a lower leaf water potential indicating stronger osmotic adjustment, and a higher relative water content associated with more turgid leaves, in A. halimus than A. hortensis. In a PCA including all the studied traits, the GS and E negatively correlated to the FW, which, in turn, positively correlated with Na concentration and intrinsic water use efficiency (iWUE), indicating that reduced gas exchange associated with Na accumulation contributed to sustain iWUE under salinity. Finally, FTIR spectroscopy showed a reduced amount of pectin, lignin, and cellulose under salinity, indicating a weakened cell wall structure. Overall, both species were remarkably adapted to salinity: From an agronomic perspective, the opposite strategies of longer vs. faster soil coverage, involved by the perennial A. halimus vs. the annual A. hortensis cv. scarlet, are viable natural remedies for revegetating marginal saline soils and increasing soil organic carbon.

Highlights

The global population is growing at a rate of 1.1% per year and it is with 95% certainty that by 2050 it will reach between 9.4 and 10.1 billion people [1]
The acronyms used in this study are defined as follows: fresh weight (FW), dry weight (DW), plant height (PH), electrolyte leakage (EL), specific leaf area (SLA), carbon isotope ratio (δ13C), net photosynthesis (A), leaf transpiration (E), stomatal conductance (GS), spad value (SPAD), effective quantum yield efficiency of photosystem II (PSII) (ΦPSII), level of photochemical quenching of PSII, PSII maximum efficiency (Fv /Fm ), electron transport rate (ETR), leaf relative water content (RWC), leaf water potential (LWP), and intrinsic water use efficiency
As stated by Bennert et al [104], inorganic ions (Na, K, Cl) and oxalate, an organic acid, are the main osmotically active solutes in Atriplex spp., while soluble carbohydrates, amino acids, and other organic acids are scarcely involved in the ionic balance maintenance. Both Atriplex halimus and A. hortensis thrived under salinity, as the improved plant growth demonstrates. This is apparently due to mechanisms of physiological adaptation (reduced stomatal conductance (GS) and transpiration (E)) enabling the two species to preserve moisture and improve water use efficiency

Summary

Introduction

The global population is growing at a rate of 1.1% per year and it is with 95% certainty that by 2050 it will reach between 9.4 and 10.1 billion people [1]. Recent projections, which use 2014 as a baseline, estimate that crop production should increase by 25–70% to meet food demand in 2050 [2]. Agricultural topsoil and soil organic carbon (SOC) are key ingredients for intensive food production [3,4,5]. Besides enhancing crop yield, SOC can act either as a source or a sink of atmospheric CO2, and thereby, can influence the global process of climate change [7]. Nearly 1550 GT are in the form of SOC, and the remaining in the form of soil inorganic carbon (SIC), that mainly consists of elemental carbon and carbonate rocks such as calcite, dolomite, and gypsum. The soil carbon reserve is around three times that currently found in the atmosphere (800 GT) and four times that fixed in living plants and animals (560 GT). Oceans have a larger carbon pool (about 38,400 GT), mostly in the inorganic form [8]

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