Physiology of Salt Stress in Plants. Группа авторов
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Название: Physiology of Salt Stress in Plants

Автор: Группа авторов

Издательство: John Wiley & Sons Limited

Жанр: Биология

Серия:

isbn: 9781119700494

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СКАЧАТЬ level of other essential plant nutrients such as potassium, thereby causing reduced yield and, ultimately, senescence (Ashraf 2004; Zhu 2007).

      The inherent countermeasures also destructively impact plant biology. The generation of reactive oxygen species (ROS) can cause potential oxidation injury to the interstitial components like DNA structure, cell protein, and cell walls. The other sets of nondestructive defense mechanisms include elevation of photosynthetic rate, re‐exercising ion and water relation in the vesicular system, etc.

      The saline balance of the terrestrial water sources is globally affected due to continual anthropogenic activities, for example, new England Marshes (Williams 2002). Perennial inland sweet water sources are worst affected due to the waste charging throughout the trajectory. Whereas, the salinity of global waters is also sacrificed due to the melting of glaciers. Territorial brackish streams such as arid estuaries and salt‐marshes are as well reasonably affected by the artificial agricultural discharge. But, this sudden change caters to a tremendous threat to the aquatic ecosystem. It incorporates abridged survivability, inhibited fertility, metabolic disorder, and retarded physiology (Velasco et al. 2019). Any varied salinity can mainly disrupt the osmotic balance between the surrounding hydrosphere and organismic, cellular fluid. The severity of impact varies between a minor metabolic malfunction and decease. To counteract the above, marine organisms develop an osmoregulation defense mechanism and eliminate hypo and hyperstress conditions. But, severe salinity or attenuation majorly conquers over the internal defense. Moreover, the consequences of successful defense are also majorly anonymous.

      Additionally, investigations were also pursued to recognize the impact of ancillary factors such as temperature, but it seemed to be relatively insignificant. For instance, a study performed on zooplanktons reported metabolic issues upon exposure to altered salinity, but no apparent influence of temperature (Garreta‐Lara et al. 2018). Basic metabolic disfunctionalities elicited due to OS are addressed by spontaneous excretion. But, stress ascertained due to bioaccumulation of metals is far more complex, so the defense is required. Moreover, each metal is highly specific in terms of threat enforced.

      Dry farming also raises intricate contact interaction amid washed off pesticides and water salinity. These halogenated chemicals probably act as a neurotoxin and inhibit the counteract mechanisms of the nervous system. Remarkably, hypersalinity pivotally helps anadromous varieties such as Brown trout to subside the impacts of exposure efficaciously. The effective counter mechanism correlated with an interpretation of malfunctioning of the neural system upon instantaneous exposure to elevated salinity. Furthermore, collateral stress induced due to the combined effect of salinity and dehydration results in protraction of the osmoregulatory responses in some plants and marine bugs, thereby diminishing the moisture loss. It portrays the discordant individual stressors that abolish each other, while severe impacts were observed upon elementary exposure (Williams 1998; Kultz 2015; Cañedo‐Argüelles et al. 2018).

      The existence and survivability of the global population are mostly dependent on agriculture. It is estimated that about 99% or more consumable fodder sources are scattered across the lithosphere, whereas a hydrosphere contributes a negligible fraction of 0.5% or less. Thus, it is evident that a healthy and sufficient existence of earth crust is mandatory for the sustainable coexistence of the human being. Furthermore, soil erosion drastically impacts the agricultural yield. It is estimated that annually approximately 75 million tonnes of soil loss occurs only from the cultivable topographic regions worldwide. Other prominent effects of salinization include the erosion of the hilly terrains, which is probably less investigated (Aslam et al. 2017).

      Saline soil mostly produces superficial seals due to two causes: (i) sodium pressure fragmentizes the soil structure and eliminates clay particles, resulting in clogging of interstitial voids and (ii) lean vegetative cover exposes the saline soil to precipitation compaction (Agassi et al. 1994, Singer and Lindquist 1998). Both the processes mainly decrease percolation and enhance surface runoff. Though the layer beneath gets safeguarded against vigorous erosion, the top layer gets severely imposed due to the disintegration caused by salinization (Agassi et al. 1994). Therefore, it is evident that soil salinity also can indirectly influence soil erosion up to a greater extent.

      1 The satellite‐based remote‐sensing approach with geographic information system (GIS) mapping and real‐time ground truthing can provide an array of escalating salinity footprint (Singh et al. 2010).

      2 Gypsum‐dosed alkali reparation techniques for soils affected with sodium toxicity.

      3 Reclamation of flooded wetlands through downward drainage– the method is quite useful in addressing multidimensional issues such as water stagnation and salinization.

      4 Chemical regeneration of saline soil with ameliorants is also practiced in some parts of the globe. The method is expensive and hence challenging to impose for more giant footprints.

      5 Phytoremediation with salt‐tolerant species is contrarily an inexpensive and eco‐friendly mechanism.

      6 Multilayer agroforestry is a recent trend in the agricultural industry to mitigate rising demand. Anyhow, the method also assists in reclaiming saline soil by reducing the soil density and thereby causing an elevated percolation rate. Furthermore, the littered biomass improves soil fertility and yield (Kaur et al. 2000; Nosetto et al. 2007).

      7 Nonconventional techniques such as inland fishery have also gained limited popularity, majorly in the southern peninsula of the country. Flood‐planes and wetlands near to the coastal regions are effectively serving as the source of alternate revenue generation.

      8 Microbialremediation: Desalination through microbial action is indeed rigorous. The inoculants are expensive and seek a suitable environment.