SummaryAtHKT1 is a sodium (Na þ ) transporter that functions in mediating tolerance to salt stress. To investigate the membrane targeting of AtHKT1 and its expression at the translational level, antibodies were generated against peptides corresponding to the first pore of AtHKT1. Immunoelectron microscopy studies using anti-AtHKT1 antibodies demonstrate that AtHKT1 is targeted to the plasma membrane in xylem parenchyma cells in leaves. AtHKT1 expression in xylem parenchyma cells was also confirmed by AtHKT1 promoter-GUS reporter gene analyses. Interestingly, AtHKT1 disruption alleles caused large increases in the Na þ content of the xylem sap and conversely reduced the Na þ content of the phloem sap. The athkt1 mutant alleles had a smaller and inverse influence on the potassium (K þ ) content compared with the Na þ content of the xylem, suggesting that K þ transport may be indirectly affected. The expression of AtHKT1 was modulated not only by the concentrations of Na þ and K þ but also by the osmolality of non-ionic compounds. These findings show that AtHKT1 selectively unloads sodium directly from xylem vessels to xylem parenchyma cells. AtHKT1 mediates osmolality balance between xylem vessels and xylem parenchyma cells under saline conditions. Thus AtHKT1 reduces the sodium content in xylem vessels and leaves, thereby playing a central role in protecting plant leaves from salinity stress.
Excessive accumulation of sodium in plants causes toxicity. No mutation that greatly diminishes sodium (Na þ ) influx into plant roots has been isolated. The OsHKT2;1 (previously named OsHKT1) transporter from rice functions as a relatively Na þ -selective transporter in heterologous expression systems, but the in vivo function of OsHKT2;1 remains unknown. Here, we analyzed transposon-insertion rice lines disrupted in OsHKT2;1. Interestingly, three independent oshkt2;1-null alleles exhibited significantly reduced growth compared with wildtype plants under low Na þ and K þ starvation conditions. The mutant alleles accumulated less Na þ , but not less K þ , in roots and shoots. OsHKT2;1 was mainly expressed in the cortex and endodermis of roots. 22 Na þ tracer influx experiments revealed that Na þ influx into oshkt2;1-null roots was dramatically reduced compared with wild-type plants. A rapid repression of OsHKT2;1-mediated Na þ influx and mRNA reduction were found when wild-type plants were exposed to 30 mM NaCl. These analyses demonstrate that Na þ can enhance growth of rice under K þ starvation conditions, and that OsHKT2;1 is the central transporter for nutritional Na þ uptake into K þ -starved rice roots.
T-DNA disruption mutations in the AtHKT1 gene have previously been shown to suppress the salt sensitivity of the sos3 mutant. However, both sos3 and athkt1 single mutants show sodium (Na+) hypersensitivity. In the present study we further analyzed the underlying mechanisms for these non-additive and counteracting Na+ sensitivities by characterizing athkt1-1 sos3 and athkt1-2 sos3 double mutant plants. Unexpectedly, mature double mutant plants grown in soil clearly showed an increased Na+ hypersensitivity compared with wild-type plants when plants were subjected to salinity stress. The salt sensitive phenotype of athkt1 sos3 double mutant plants was similar to that of athkt1 plants, which showed chlorosis in leaves and stems. The Na+ content in xylem sap samples of soil-grown athkt1 sos3 double and athkt1 single mutant plants showed dramatic Na+ overaccumulation in response to salinity stress. Salinity stress analyses using basic minimal nutrient medium and Murashige-Skoog (MS) medium revealed that athkt1 sos3 double mutant plants show a more athkt1 single mutant-like phenotype in the presence of 3 mM external Ca2+, but show a more sos3 single mutant-like phenotype in the presence of 1 mM external Ca2+. Taken together multiple analyses demonstrate that the external Ca2+ concentration strongly impacts the Na+ stress response of athkt1 sos3 double mutants. Furthermore, the presented findings show that SOS3 and AtHKT1 are physiologically distinct major determinants of salinity resistance such that sos3 more strongly causes Na+ overaccumulation in roots, whereas athkt1 causes an increase in Na+ levels in the xylem sap and shoots and a concomitant Na+ reduction in roots.
Here we describe the development of a microarray-based mapping strategy to rapidly isolate deletion mutant genes. The presented approach is particularly useful for mapping mutant genes that are difficult to phenotype. This strategy uses masking bulk segregant analysis to mask unrelated deletions, thus allowing identification of target deletions by microarray hybridization of pooled genomic DNA from both WT and mutant F 2 populations. Elemental profiling has proven to be a powerful tool for isolation of nutrient and toxic metal accumulation mutants in Arabidopsis. Using microarray mapping, a sodium overaccumulation mutant FN1148 was identified as having a 523-bp genomic deletion within the second exon and intron of the AtHKT1 gene. Further cosegregation, complementation, and comparative analyses among different salt-sensitive mutants confirmed that the deletion within the AtHKT1 gene is responsible for the sodium overaccumulation in shoots and leaf sodium sensitivity of the FN1148 mutant. These results demonstrate that microarray-based cloning is an efficient and powerful tool to rapidly clone ion accumulation or other genetic deletion mutants that are otherwise difficult to phenotype for mapping, such as metabolic or cell signaling mutants.
Cell transplantation therapy has long been investigated as a therapeutic intervention for neurodegenerative disorders, including spinal cord injury, Parkinson’s disease, and amyotrophic lateral sclerosis. Indeed, patients have high hopes for a cell-based therapy. However, there are numerous practical challenges for clinical translation. One major problem is that only very low numbers of donor cells survive and achieve functional integration into the host. Glial scar tissue in chronic neurodegenerative disorders strongly inhibits regeneration, and this inhibition must be overcome to accomplish successful cell transplantation. Intraneural cell transplantation is considered to be the best way to deliver cells to the host. We questioned this view with experiments in vivo on a rat glial scar model of the auditory system. Our results show that intraneural transplantation to the auditory nerve, preceded by chondroitinase ABC (ChABC)-treatment, is ineffective. There is no functional recovery, and almost all transplanted cells die within a few weeks. However, when donor cells are placed on the surface of a ChABC-treated gliotic auditory nerve, they autonomously migrate into it and recapitulate glia- and neuron-guided cell migration modes to repair the auditory pathway and recover auditory function. Surface transplantation may thus pave the way for improved functional integration of donor cells into host tissue, providing a less invasive approach to rescue clinically important neural tracts.
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