Abstrakt:
Widespread increases in soil salinization significantly reduce agricultural lands. Nevertheless, salt-tolerant
plants, such as Salicornia europaea L., can play a crucial role in the reclamation of these lands. We selected
S. europaea for this study due to its potential to mitigate soil salinization and its numerous applications, such as
intercropping in agriculture, biocompounds production and bioenergy. This work was designed to determine
whether different salinities induce significant biophysical, anatomical, lignin and gene transcript changes in
S. europaea. Through atomic force microscopy (AFM), we revealed that salinity stimulated an increase in cell wall
elasticity (CWE) as an important physiological mechanism of adaptation known as cell’s turgor conservation
effect. Direct values of the cell wall stiffness subjected to salinity were obtained, with Young’s modulus (E)
ranging from low and high salinity 0.52 to 0.03 MPa. The softening of the cell wall properly correlated with an
increase in cell size, plant cells under strong salinity 1000 mM NaCl, swelled 5.4 times. The best salinity range
found for its optimum growth was 200–400 mM NaCl. At higher salinities, we identified increases in the lignified
xylem, large calcium oxalate crystals, and in transcript amounts of SeSOS1 and SeNHX1, which has a significant
negative correlation with cell wall stiffness ( 0.57 and 0.95, respectively). The high syringyl and guaiacyl ratio
(S/G) in lignin for 0–400 mM NaCl may have influenced the rigidity and hydrophobicity of the cell walls. A
positive S/G ratio and sugar yields are associated with higher bioethanol production, these values may also be
useful for agriculture, biorefinery, biocompounds and plant-breeding applications. We conclude that salinity
indeed influenced the cell wall traits of S. europaea. This halophyte is capable of markedly softening its cell wall
as a way of adapting to the high level of salinity. Our presented insights and correlations not only provide a better
understanding of cell wall remodelling but are also considered vital traits of adaptation strategies that this
halophyte holds under salinity environment. These inputs can also be applied in future research aiming to
produce biomass and biofuel or to improve the salinity tolerance during the cultivation of non-tolerant plants,
crops and glycophytes, which is a significant challenge in agriculture, particularly in arid and coastal regions.
The unique properties of the S. europaea cell walls could also inspire the development of materials with enhanced
nanomechanical elasticity for resistance to osmotic stress.