Root Proteomic Analysis of Two Grapevine Rootstock Genotypes Showing Different Susceptibility to Salt Stress

Prinsi, Bhakti; Failla, O.; Scienza, A.; Espen, Luca

doi:10.3390/ijms21031076

Cited by 11 publications

(9 citation statements)

References 76 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…Membrane‐localised pyrophosphatase, such as the cation stimulated tonoplast V‐PPase (Walker and Leigh 1981a, Rea and Poole 1993) and the predominantly anion stimulated tonoplast V‐ATPase (Walker and Leigh 1981b), may also have roles in maintaining intracellular ion gradients between the cytoplasm and vacuole. In grapevine, the possible roles of H + ‐ATPases and VPPase in salt tolerance have not yet been clarified, although proteomic analysis on the rootstock M4 may support a possible function of grapevine ATPases in Na + vacuolar internalisation (Prinsi et al 2020).…”

Section: Mechanisms Of Salt Tolerance In Grapevinementioning

confidence: 99%

“…An analysis of M4 under saline irrigation showed an increase of proteins related to carbohydrate catabolism and an increased activity of ATP and coenzyme biosynthesis pathways (Prinsi et al 2020), potentially indicating a metabolic shift to supply the energy needed for the salt stress responses, while being restricted by photoinhibition (Munns et al 2020). The M4 rootstock has also been shown to display a higher amount of enzymes related to ROS scavenging and secondary metabolism, which may relate to increases in antioxidative activity (Prinsi et al 2020). No apparent increase in ion transport proteins was observed, however, which may relate to the higher leaf ion accumulation that has been observed for the M4 variety previously (Meggio et al 2014).…”

Section: Studies On Salt Tolerance In Grapevine Rootstocksmentioning

confidence: 99%

See 1 more Smart Citation

Grapevine salt tolerance

Zhou‐Tsang

Henderson

et al. 2021

Australian Journal of Grape and Wine Research

View full text Add to dashboard Cite

Salinity, which is predominantly an issue for agricultural systems in arid and semi-arid regions, has the potential to impair grape production and wine quality, and its impact on the grape and wine industries is predicted to increase with climate change. Research on the physiological and molecular changes that occur in salt-affected vines has unveiled complex osmotic and ionic responses that include oxidative stress, water loss, photoinhibition, growth inhibition and necrosis. Proposed salt tolerance mechanisms include elevated antioxidant production, hydric regulation and salt exclusion from shoots and berries. These later of these mechanisms is found in certain Vitis genotypes that, when grafted as rootstocks, can protect fruit-bearing scions from accumulating significant amounts of saline ions from soils, most notably through the presence of specific transport proteins that are involved in regulating the transfer of ions from root to shoot via the xylem. Significant gaps in knowledge remain, however, regarding salt tolerance mechanisms for Vitis species, with many mechanisms inferred from other species or documented only at the level of gene expression. A better understanding of the mechanisms that confer salt tolerance in Vitis species is needed to improve the production of new germplasm that is locally adapted and better suited to the challenges of a changing climate. Hence, this review covers the current knowledge on the characteristics that are associated with salt damage and tolerance in grapevine cultivars and rootstocks and highlights possible future avenues that will enable development of new options for the industry to combat salinity.

show abstract

Section: Mechanisms Of Salt Tolerance In Grapevinementioning

confidence: 99%

Section: Studies On Salt Tolerance In Grapevine Rootstocksmentioning

confidence: 99%

Grapevine salt tolerance

Zhou‐Tsang

Henderson

et al. 2021

Australian Journal of Grape and Wine Research

View full text Add to dashboard Cite

show abstract

“…In a subsequent study, Henderson et al (2018), successfully mapped a QTL that controls Na + exclusion in rootstocks and identified the causal gene ( VisHTK1;1 ) underlying that trait; these findings may assist with breeding Na + tolerant grapevine rootstocks. Recently, Prinsi et al (2020) characterised the root‐level response to salt stress of two grapevine rootstocks (M4 and 101‐14), indicating that M4 had a greater capability to maintain and adapt energy metabolism and to sustain the activation of salt‐protective mechanisms, while, in 101‐14, the energy metabolism was deeply affected and an evident induction of the enzymatic antioxidant system occurred. Overall, the information provided by this group of studies constitutes the basis for further research on the performance of different graft combinations against salt stress.…”

Section: Challenges Related To Abiotic Stressesmentioning

confidence: 99%

“…Therefore, the selection of new rootstocks could be an interesting solution to overcome some of the risks associated with salinity, such as preventing excess of Cl − and Na + in leaves and bunches, and the subsequent negative effect on yield and fruit composition, and should rely on the research efforts mentioned in this section (Gong et al 2014, Henderson et al 2018, Prinsi et al 2020), despite these being restricted to only three genotypes. In this context, a recent survey (Heinitz et al 2020) identified promising Cl − ‐excluding accessions within a collection of Vitis species native to south‐western USA and northern Mexico.…”

Section: Challenges Related To Abiotic Stressesmentioning

confidence: 99%

Challenges of viticulture adaptation to global change: tackling the issue from the roots

Ederra

Armengol

Carbonell‐Bejerano

et al. 2020

Australian Journal of Grape and Wine Research

View full text Add to dashboard Cite

Viticulture is facing emerging challenges not only because of the effect of climate change on yield and composition of grapes, but also of a social demand for environmental‐friendly agricultural management. Adaptation to these challenges is essential to guarantee the sustainability of viticulture. The aim of this review is to present adaptation possibilities from the soil‐hidden, and often disregarded, part of the grapevine, the roots. The complexity of soil–root interactions makes necessary a comprehensive approach taking into account physiology, pathology and genetics, in order to outline strategies to improve viticulture adaptation to current and future threats. Rootstocks are the link between soil and scion in grafted crops, and they have played an essential role in viticulture since the introduction of phylloxera into Europe at the end of the 19th century. This review outlines current and future challenges that are threatening the sustainability of the wine sector and the relevant role that rootstocks can play to face these threats. We describe how rootstocks along with soil management can be exploited as an essential tool to deal with the effects of climate change and of emerging soil‐borne pests and pathogens. Moreover, we discuss the possibilities and limitations of diverse genetic strategies for rootstock breeding.

show abstract

“…In the present work, we adopted biochemical and proteomic approaches to analyze, in the root of M4 grapevine rootstock, the responses occurring after the addition of NO 3 − to the nutrient solution in hydroponics. This rootstock genotype was selected on the basis of its good response to abiotic stress [ 31 , 32 , 33 , 34 , 35 ], which is contributing to the expansion of its use in viticulture. The biochemical evaluations were devoted to verifying the role played by roots in the response to NO 3 − resupply, monitoring key parameters.…”

Section: Introductionmentioning

confidence: 99%

Biochemical and Proteomic Changes in the Roots of M4 Grapevine Rootstock in Response to Nitrate Availability

Prinsi

Muratore

Espen

2021

Plants

Self Cite

View full text Add to dashboard Cite

In agricultural soils, nitrate (NO3−) is the major nitrogen (N) nutrient for plants, but few studies have analyzed molecular and biochemical responses involved in its acquisition by grapevine roots. In viticulture, considering grafting, NO3− acquisition is strictly dependent on rootstock. To improve the knowledge about N nutrition in grapevine, this study analyzed biochemical and proteomic changes induced by, NO3− availability, in a hydroponic system, in the roots of M4, a recently selected grapevine rootstock. The evaluation of biochemical parameters, such as NO3−, sugar and amino acid contents in roots, and the abundance of nitrate reductase, allowed us to define the time course of the metabolic adaptations to NO3− supply. On the basis of these results, the proteomic analysis was conducted by comparing the root profiles in N-starved plants and after 30 h of NO3− resupply. The analysis quantified 461 proteins, 26% of which differed in abundance between conditions. Overall, this approach highlighted, together with an increased N assimilatory metabolism, a concomitant rise in the oxidative pentose phosphate pathway and glycolysis, needed to fulfill the redox power and carbon skeleton demands, respectively. Moreover, a wide modulation of protein and amino acid metabolisms and changes of proteins involved in root development were observed. Finally, some results open new questions about the importance of redox-related post-translational modifications and of NO3− availability in modulating the dialog between root and rhizosphere.

show abstract

Root Proteomic Analysis of Two Grapevine Rootstock Genotypes Showing Different Susceptibility to Salt Stress

Cited by 11 publications

References 76 publications

Grapevine salt tolerance

Grapevine salt tolerance

Challenges of viticulture adaptation to global change: tackling the issue from the roots

Biochemical and Proteomic Changes in the Roots of M4 Grapevine Rootstock in Response to Nitrate Availability

Contact Info

Product

Resources

About