The physiological and molecular mechanisms of tolerance to osmotic and ionic components of salinity stress are reviewed at the cellular, organ, and whole-plant level. Plant growth responds to salinity in two phases: a rapid, osmotic phase that inhibits growth of young leaves, and a slower, ionic phase that accelerates senescence of mature leaves. Plant adaptations to salinity are of three distinct types: osmotic stress tolerance, Na + or Cl − exclusion, and the tolerance of tissue to accumulated Na + or Cl − . Our understanding of the role of the HKT gene family in Na + exclusion from leaves is increasing, as is the understanding of the molecular bases for many other transport processes at the cellular level. However, we have a limited molecular understanding of the overall control of Na + accumulation and of osmotic stress tolerance at the whole-plant level. Molecular genetics and functional genomics provide a new opportunity to synthesize molecular and physiological knowledge to improve the salinity tolerance of plants relevant to food production and environmental sustainability.

https://rodas5.us.es/file/c2a700e9-8b4a-1970-d343-4a269c302970/1/estres_salino_bibliografia_scorm.zip/files/estres_salino_bibliografia.pdf

Mechanisms of salinity tolerance

Scarcity of water is a severe environmental constraint to plant productivity. Drought-induced loss in crop yield probably exceeds losses from all other causes, since both the severity and duration of the stress are critical. Here, we have reviewed the effects of drought stress on the growth, phenology, water and nutrient relations, photosynthesis, assimilate partitioning, and respiration in plants. This article also describes the mechanism of drought resistance in plants on a morphological, physiological and molecular basis. Various management strategies have been proposed to cope with drought stress. Drought stress reduces leaf size, stem extension and root proliferation, disturbs plant water relations and reduces water-use efficiency. Plants display a variety of physiological and biochemical responses at cellular and whole-organism levels towards prevailing drought stress, thus making it a complex phenomenon. CO2 assimilation by leaves is reduced mainly by stomatal closure, membrane damage and disturbed activity of various enzymes, especially those of CO2 fixation and adenosine triphosphate synthesis. Enhanced metabolite flux through the photorespiratory pathway increases the oxidative load on the tissues as both processes generate reactive oxygen species. Injury caused by reactive oxygen species to biological macromolecules under drought stress is among the major deterrents to growth. Plants display a range of mechanisms to withstand drought stress. The major mechanisms include curtailed water loss by increased diffusive resistance, enhanced water uptake with prolific and deep root systems and its efficient use, and smaller and succulent leaves to reduce the transpirational loss. Among the nutrients, potassium ions help in osmotic adjustment; silicon increases root endodermal silicification and improves the cell water balance. Low-molecular-weight osmolytes, including glycinebetaine, proline and other amino acids, organic acids, and polyols, are crucial to sustain cellular functions under drought. Plant growth substances such as salicylic acid, auxins, gibberrellins, cytokinin and abscisic acid modulate the plant responses towards drought. Polyamines, citrulline and several enzymes act as antioxidants and reduce the adverse effects of water deficit. At molecular levels several drought-responsive genes and transcription factors have been identified, such as the dehydration-responsive element-binding gene, aquaporin, late embryogenesis abundant proteins and dehydrins. Plant drought tolerance can be managed by adopting strategies such as mass screening and breeding, marker-assisted selection and exogenous application of hormones and osmoprotectants to seed or growing plants, as well as engineering for drought resistance.

https://hal.archives-ouvertes.fr/hal-00886451/document

Plant drought stress: effects, mechanisms and management

Salinity tolerance comes from genes that limit the rate of salt uptake from the soil and the transport of salt throughout the plant, adjust the ionic and osmotic balance of cells in roots and shoots, and regulate leaf development and the onset of senescence. This review lists some candidate genes for salinity tolerance, and draws together hypotheses about the functions of these genes and the specific tissues in which they might operate. Little has been revealed by gene expression studies so far, perhaps because the studies are not tissue-specific, and because the treatments are often traumatic and unnatural. Suggestions are made to increase the value of molecular studies in identifying genes that are important for salinity tolerance.

https://nph.onlinelibrary.wiley.com/doi/pdf/10.1111/j.1469-8137.2005.01487.x

Genes and salt tolerance: bringing them together.

Salinity is a major abiotic stress limiting growth and productivity of plants in many areas of the world due to increasing use of poor quality of water for irrigation and soil salinization. Plant adaptation or tolerance to salinity stress involves complex physiological traits, metabolic pathways, and molecular or gene networks. A comprehensive understanding on how plants respond to salinity stress at different levels and an integrated approach of combining molecular tools with physiological and biochemical techniques are imperative for the development of salt-tolerant varieties of plants in salt-affected areas. Recent research has identified various adaptive responses to salinity stress at molecular, cellular, metabolic, and physiological levels, although mechanisms underlying salinity tolerance are far from being completely understood. This paper provides a comprehensive review of major research advances on biochemical, physiological, and molecular mechanisms regulating plant adaptation and tolerance to salinity stress.

/pdf/mechanism-of-salinity-tolerance-in-plants-physiological-3ixvqhezre.pdf

Mechanism of Salinity Tolerance in Plants: Physiological, Biochemical, and Molecular Characterization

An ordered draft sequence of the 17-gigabase hexaploid bread wheat (Triticum aestivum) genome has been produced by sequencing isolated chromosome arms. We have annotated 124,201 gene loci distributed nearly evenly across the homeologous chromosomes and subgenomes. Comparative gene analysis of wheat subgenomes and extant diploid and tetraploid wheat relatives showed that high sequence similarity and structural conservation are retained, with limited gene loss, after polyploidization. However, across the genomes there was evidence of dynamic gene gain, loss, and duplication since the divergence of the wheat lineages. A high degree of transcriptional autonomy and no global dominance was found for the subgenomes. These insights into the genome biology of a polyploid crop provide a springboard for faster gene isolation, rapid genetic marker development, and precise breeding to meet the needs of increasing food demand worldwide.

A chromosome-based draft sequence of the hexaploid bread wheat (Triticum aestivum) genome

Wheat (Triticum aestivum L.) is a cultivated crop with a narrow genetic base. Due to long-term cultivation it is now difficult to enhance its yield and quality to a great extent by conventional breeding for the increasing need of food in the world. It is necessary to introduce exogenous beneficial traits from related plants to overcome this difficulty.

Asymmetrie Somatic Hybridization Between Triticum aestivum L. (Wheat) and Leymus chinensis (Trin.) Tzvel

Background: The wild herb Swertia mussotii is a source of the anti-hepatitis compounds swertiamarin, mangiferin and gentiopicroside. Its over-exploitation has raised the priority of producing these compounds heterologously. Somatic hybridization represents a novel approach for introgressing Swertia mussotii genes into a less endangered species. Results: Protoplasts derived from calli of Bupleurum scorzonerifolium and S. mussotii were fused to produce 194 putative hybrid cell lines, of which three (all derived from fusions where the S. mussotii protoplasts were pretreated for 30 s with UV light) later differentiated into green plants. The hybridity of the calli was confirmed by a combination of isozyme, RAPD and chromosomal analysis. The hybrid calli genomes were predominantly B. scorzonerifolium. GISH analysis of mitotic chromosomes confirmed that the irradiation of donor protoplasts increased the frequency of chromosome elimination and fragmentation. RFLP analysis of organellar DNA revealed that mitochondrial and chloroplast DNA of both parents coexisted and recombined in some hybrid cell lines. Some of the hybrid calli contained SmG10H from donor, and produced swertiamarin, mangiferin and certain volatile compounds characteristic of S. mussotii. The expression of SmG10H (geraniol 10-hydroxylase) was associated with the heterologous accumulation of swertiamarin. Conclusions: Somatic hybrids between B. scorzonerifolium and S. mussotii were obtained, hybrids selected all contained introgressed nuclear and cytoplasmic DNA from S. mussotii; and some produced more mangiferin than the donor itself. The introgression of SmG10H was necessary for the accumulation of swertiamarin.

Introgression of Swertia mussotii gene into Bupleurum scorzonerifolium via somatic

ADP-ribosylation mediated by ADP-ribosyltransferases (ARTs) is an intricate modification that regulates diverse cellular processes including DNA repair, chromatin remodeling and gene transcription responding to stresses. In addition to the canonical poly(ADP-ribose) polymerases (PARPs), plant specific SRO (Similar to RCD One) family also contain the catalytic core of the PARP domain. However, whether the PARP domains in SROs execute the ART function is still under debate. In 2014, we reported a wheat SRO, Ta-sro1, had the ADP-ribosyltransferase activity and enhanced wheat seedling growth and abiotic stress resistance, however, a recent work by Vogt et al. showed that Ta-sro1 without ADP-ribosyltransferase activity. Based on the recent progress on PARPs and SROs in relation to ADP-ribosyltransferase activity, along with our former and recent evolving results, we argued that Ta-sro1 is a non-canonical ADP-ribosyltransferase with the enzymatic activity. Although we have revealed the novel mechanism of Ta-sro1 regulate redox homeostasis and enhance salinity stress tolerance through interacting with TaSIP1, it is of interest to further clarify whether and how the enzymatic activity of Ta-sro1 responsible for the salinity tolerance of wheat. Our study raises some interesting points and caveats that helpful for understanding the research progresses and debates about the enzymatic activity of SROs.

Whether the ADP-ribosyltransferase activity of Ta-sro1, a noncanonical PARP protein, contributes to its function in salinity-stress tolerance?

To characterize the low molecular mass glutenin subunit gene 177-21 (AY994364) in wheat (Triticum aestivum L. cv. Jinan 177), we developed a specific PCR primer set to decide its locus with nullisomic-tetrasomic lines of Chinese spring wheat. The result showed that it was assigned to Glu-D3. The DNA fragment of 177-21 was then subcloned into the pGEX-4T-1 expression vector and expressed in E. coli with isopropyl-1-thio-β-D-galactoside induction. The result indicated that this gene encodes about 30 kD polypeptide and deduced amino acid sequence consists of eight cysteine residues. Of the eight, six may be related with the formation of intra-molecular disulfide bonds, the last two with the formation of inter-molecular disulfide bonds, which could be a potential extender in “glutenin polymer” to have positive influence on quality of wheat flour.

Location and prokaryotic expression of low molecular mass glutanin subunit gene 177-21 from Triticum aestivum

Ca2+-dependent TaCCD1 cooperates with TaSAUR215 to enhance plasma membrane H+-ATPase activity and alkali stress tolerance by inhibiting PP2C-mediated dephosphorylation of TaHA2 in wheat.

Guangmin Xia

Papers

Asymmetrie Somatic Hybridization Between Triticum aestivum L. (Wheat) and Leymus chinensis (Trin.) Tzvel

Introgression of Swertia mussotii gene into Bupleurum scorzonerifolium via somatic

Whether the ADP-ribosyltransferase activity of Ta-sro1, a noncanonical PARP protein, contributes to its function in salinity-stress tolerance?

Location and prokaryotic expression of low molecular mass glutanin subunit gene 177-21 from Triticum aestivum

Ca2+-dependent TaCCD1 cooperates with TaSAUR215 to enhance plasma membrane H+-ATPase activity and alkali stress tolerance by inhibiting PP2C-mediated dephosphorylation of TaHA2 in wheat.