Identification of mechanisms that decrease cadmium accumulation in plants is a prerequisite for minimizing dietary uptake of cadmium from contaminated crops. Here, we show that cadmium inhibits nitrate transporter 1.1 (NRT1.1)-mediated nitrate (NO 3 2 ) uptake in Arabidopsis (Arabidopsis thaliana) and impairs NO 3 2 homeostasis in roots. In NO 3
2-containing medium, loss of NRT1.1 function in nrt1.1 mutants leads to decreased levels of cadmium and several other metals in both roots and shoots and results in better biomass production in the presence of cadmium, whereas in NO 3 2 -free medium, no difference is seen between nrt1.1 mutants and wild-type plants. These results suggest that inhibition of NRT1.1 activity reduces cadmium uptake, thus enhancing cadmium tolerance in an NO 3 2 uptake-dependent manner. Furthermore, using a treatment rotation system allowing synchronous uptake of NO 3 2 and nutrient cations and asynchronous uptake of cadmium, the nrt1.1 mutants had similar cadmium levels to wild-type plants but lower levels of nutrient metals, whereas the opposite effect was seen using treatment rotation allowing synchronous uptake of NO 3 2 and cadmium and asynchronous uptake of nutrient cations. We conclude that, although inhibition of NRT1.1-mediated NO 3 2 uptake by cadmium might have negative effects on nitrogen nutrition in plants, it has a positive effect on cadmium detoxification by reducing cadmium entry into roots. NRT1.1 may regulate the uptake of cadmium and other cations by a common mechanism.
Cadmium (Cd) contamination of agricultural soils is an increasingly serious problem. Measures need to be developed to minimize Cd entering the human food chain from contaminated soils. We report here that, under Cd exposure condition, application with low doses of (0.1–0.5 μM) abscisic acid (ABA) clearly inhibited Cd uptake by roots and decreased Cd level in Arabidopsis wild-type plants (Col-0). Expression of IRT1 in roots was also strongly inhibited by ABA treatment. Decrease in Cd uptake and the inhibition of IRT1 expression were clearly lesser pronounced in an ABA-insensitive double mutant snrk2.2/2.3 than in the Col-0 in response to ABA application. The ABA-decreased Cd uptake was found to correlate with the ABA-inhibited IRT1 expression in the roots of Col-0 plants fed two different levels of iron. Furthermore, the Cd uptake of irt1 mutants was barely affected by ABA application. These results indicated that inhibition of IRT1 expression is involved in the decrease of Cd uptake in response to exogenous ABA application. Interestingly, ABA application increased the iron level in both Col-0 plants and irt1 mutants, suggesting that ABA-increased Fe acquisition does not depend on the IRT1 function, but on the contrary, the ABA-mediated inhibition of IRT1 expression may be due to the elevation of iron level in plants. From our results, we concluded that ABA application might increase iron acquisition, followed by the decrease in Cd uptake by inhibition of IRT1 activity. Thus, for crop production in Cd contaminated soils, developing techniques based on ABA application potentially is a promising approach for reducing Cd accumulation in edible organs in plants.
Background
Cadmium (Cd) is a widespread toxic heavy metal pollutant in agricultural soil, and Cd accumulation in rice grains is a major intake source of Cd for Asian populations that adversely affect human health. However, the molecular mechanism underlying Cd uptake, translocation and accumulation has not been fully understood in rice plants.
Results
In this study, a mutant displaying extremely low Cd accumulation (
lcd1
) in rice plant and grain was generated by EMS mutagenesis from
indica
rice cultivar 9311 seeds. The candidate SNPs associated with low Cd accumulation phenotype in the
lcd1
mutant were identified by MutMap and the transcriptome changes between
lcd1
and WT under Cd exposure were analyzed by RNA-seq. The
lcd1
mutant had lower Cd uptake and accumulation in rice root and shoot, as well as less growth inhibition compared with WT in the presence of 5 μM Cd. Genetic analysis showed that
lcd1
was a single locus recessive mutation. The SNP responsible for low Cd accumulation in the
lcd1
mutant located at position 8,887,787 on chromosome 7, corresponding to the seventh exon of
OsNRAMP5
. This SNP led to a Pro236Leu amino acid substitution in the highly conserved region of OsNRAMP5 in the
lcd1
mutant. A total of 1208 genes were differentially expressed between
lcd1
and WT roots under Cd exposure, and DEGs were enriched in transmembrane transport process GO term. Increased
OsHMA3
expression probably adds to the effect of
OsNRAMP5
mutation to account for the significant decreases in Cd accumulation in rice plant and grain of the
lcd1
mutant.
Conclusions
An extremely low Cd mutant
lcd1
was isolated and identified using MutMap and RNA-seq. A Pro236Leu amino acid substitution in the highly conserved region of OsNRAMP5 is likely responsible for low Cd accumulation in the
lcd1
mutant. This work provides more insight into the mechanism of Cd uptake and accumulation in rice, and will be helpful for developing low Cd accumulation rice by marker-assisted breeding.
Electronic supplementary material
The online version of this article (10.1186/s12870-019-1867-y) contains supplementary material, which is available to authorized users.
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