Role of Vacuolar Membrane Transport Systems in Plant Salinity Tolerance

About 20% of all irrigated land is adversely affected by salinity hazards and therefore understanding plant defense mechanisms against salinity will have great impact on plant productivity. In the last decades, comprehension of salinity resistance at molecular level has been achieved through the identification of key genes encoding biomarker proteins underpinning salinity tolerance. Implication of the vacuolar transport systems in plant salinity tolerance is one example of these central mechanisms rendering tolerance to saline stress. One important organelle in plant cells is the central vacuole that plays pivotal multiple roles in cell functioning under normal and stress conditions. This review thus attempts to address different lines of evidence supporting the role of the vacuolar membrane transport systems in plant salinity tolerance. Vacuolar transport systems include Na+(K+)/H+ antiporters, V-ATPase, V-PPase, Ca2+/H+ exchangers, Ca2+-ATPase, ion channels, aquaporins, and ABC transporters. They contribute essentially in retaining a high cytosolic K+/Na+ ratio, K+ level, sequestrating Na+ and Cl- into vacuoles, as well as regulation of other salinity responsive pathways. However, little is known about the regulation and functions of some of the vacuolar transporters under salinity stress and therefore need more exploration and focus. Numerous studies demonstrated that the activities of the vacuolar transporters are upregulated in response to salinity stress, confirming their central roles in salinity tolerance mechanism. The second line of evidence is that manipulation of one of the genes encoding the vacuolar transport proteins results in some successful improvement of plant salinity tolerance. Therefore, transgene pyramiding of more than one gene for developing genotypes with better and strong salinity tolerance and productivity should gain more attention in future research. In addition, we should move step further and verify the experimental data obtained from either a greenhouse or controlled environment into field trials in order to support our claims.

Automated summary

Salinity stress adversely affects plant productivity, and understanding plant defense mechanisms against it is crucial. The vacuolar transport system plays a key role in plant salinity tolerance by maintaining a high cytosolic K+/Na+ ratio, sequestering Na+ and Cl- into vacuoles, and regulating other salinity responsive pathways. However, more research is needed to explore the regulation and functions of certain vacuolar transporters under salinity stress. The activities of vacuolar transporters are upregulated in response to salinity stress, and manipulating the genes encoding these proteins can improve plant salinity tolerance. Further studies should focus on transgene pyramiding to develop genotypes with stronger salinity tolerance and productivity.