The identification of a family of NAR2-type genes in higher plants showed that there was a homolog in Arabidopsis (Arabidopsis thaliana), AtNAR2.1. These genes encode part of a two-component nitrate high-affinity transport system (HATS). As the Arabidopsis NRT2 gene family of nitrate transporters has been characterized, we tested the idea that AtNAR2.1 and AtNRT2.1 are partners in a two-component HATS. Results using the yeast split-ubiquitin system and Xenopus oocyte expression showed that the two proteins interacted to give a functional HATS. The growth and nitrogen (N) physiology of two Arabidopsis gene knockout mutants, atnrt2.1-1 and atnar2.1-1, one for each partner protein, were compared. Both types of plants had lost HATS activity at 0.2 mM nitrate, but the effect was more severe in atnar2.1-1 plants. The relationship between plant N status and nitrate transporter expression revealed a pattern that was characteristic of N deficiency that was again stronger in atnar2.1-1. Plants resulting from a cross between both mutants (atnrt2.1-1 3 atnar2.1-1) showed a phenotype like that of the atnar2.1-1 mutant when grown in 0.5 mM nitrate. Lateral root assays also revealed growth differences between the two mutants, confirming that atnar2.1-1 had a stronger phenotype. To show that the impaired HATS did not result from the decreased expression of AtNRT2.1, we tested if constitutive root expression of a tobacco (Nicotiana plumbaginifolia) gene, NpNRT2.1, previously been shown to complement atnrt2.1-1, can restore HATS to the atnar2.1-1 mutant. These plants did not recover wild-type nitrate HATS. Taken together, these results show that AtNAR2.1 is essential for HATS of nitrate in Arabidopsis.
In higher plants, nitrate is taken up by root cells where Arabidopsis thaliana NITRATE TRANSPORTER2.1 (ATNRT2.1) chiefly acts as the high-affinity nitrate uptake system. Nitrate taken up by the roots can then be translocated from the root to the leaves and the seeds. In this work, the function of the ATNRT2.7 gene, one of the seven members of the NRT2 family in Arabidopsis, was investigated. High expression of the gene was detected in reproductive organs and peaked in dry seeds. b-Glucuronidase or green fluorescent protein reporter gene expression driven by the ATNRT2.7 promoter confirmed this organ specificity. We assessed the capacity of ATNRT2.7 to transport nitrate in Xenopus laevis oocytes or when it is expressed ectopically in mutant plants deficient in nitrate transport. We measured the impact of an ATNRT2.7 mutation and found no difference from the wild type during vegetative development. By contrast, seed nitrate content was affected by overexpression of ATNRT2.7 or a mutation in the gene. Finally, we showed that this nitrate transporter protein was localized to the vacuolar membrane. Our results demonstrate that ATNRT2.7 plays a specific role in nitrate accumulation in the seed.
In Arabidopsis the NRT2.1 gene encodes a main component of the root high-affinity nitrate uptake system (HATS). Its regulation has been thoroughly studied showing a strong correlation between NRT2.1 expression and HATS activity. Despite its central role in plant nutrition, nothing is known concerning localization and regulation of NRT2.1 at the protein level. By combining a green fluorescent protein fusion strategy and an immunological approach, we show that NRT2.1 is mainly localized in the plasma membrane of root cortical and epidermal cells, and that several forms of the protein seems to co-exist in cell membranes (the monomer and at least one higher molecular weight complex). The monomer is the most abundant form of NRT2.1, and seems to be the one involved in NO 3 ؊ transport. It strictly requires the NAR2.1 protein to be expressed and addressed at the plasma membrane. No rapid changes in NRT2.1 abundance were observed in response to light, sucrose, or nitrogen treatments that strongly affect both NRT2.1 mRNA level and HATS activity. This suggests the occurrence of posttranslational regulatory mechanisms. One such mechanism could correspond to the cleavage of NRT2.1 C terminus, which results in the presence of both intact and truncated proteins in the plasma membrane.The NRT2.1 gene of Arabidopsis thaliana is part of a small multigene family comprising 7 members, which with the exception of NRT2.7, are predominantly expressed in the roots (1, 2). NRT2 genes are found in a large variety of organisms (fungi, certain yeasts, green algae, and plants) and belong to the nitrate nitrite porter family of transporter genes (3).It is generally assumed that NRT2 genes encode high-affinity nitrate (NO 3 Ϫ ) or nitrite transporters (4 -11), and that in higher plants, they play a key role in the root high-affinity transport system (HATS), 3 which ensures uptake of NO 3 Ϫ from the soil solution (3,(12)(13)(14). In all plant species investigated to date, the NO 3 Ϫ HATS displays a saturable activity, with a V max generally reached for NO 3 Ϫ concentrations comprised between 0.2 and 0.5 mM (3,12,14). Although the functional characterization of almost all higher plant NRT2 transporters remains to be done, it is now well documented that NRT2.1 is a major component of the HATS in A. thaliana as shown by the fact that (i) of the seven NRT2 members, only NRT2.1 transcript abundance showed significant correlation (r 2 ϭ 0.74) with HATS activity (2, 11) and (ii) several mutants disrupted for the NRT2.1 gene (15, 16) or for both NRT2.1-NRT2.2 genes (17, 18) have lost up to 75% of the high-affinity NO 3 Ϫ uptake activity. As a consequence, growth of these mutants is severely impaired at low NO 3 Ϫ concentration (15,19,20), but not at high NO 3 Ϫ concentration when low-affinity transporters, most probably those of the NRT1 family (3,12,14), are active.Despite its firmly established role in root NO 3 Ϫ uptake, several aspects of NRT2.1 function remain enigmatic. First, unlike the Aspergillus nidulans or Chlorella sorokiniana NRT2 trans...
Nitrate transporters are important for nitrogen acquisition by plants and in algae some require two gene products, NRT2 and NAR2, for function. The NRT2 family was already described and the recent identification of a family of the NAR2-type genes in higher plants showed that there was a homologue in Arabidopsis, AtNAR2.1. Using heterologous expression in yeast and oocytes we showed that the two Arabidopsis AtNRT2.1 and AtNAR2.1 proteins interacted to give a functional high affinity nitrate transport system (HATS). The gene knock out mutant atnar2.1-1 is deficient specifically for HATS activity and the resulting growth phenotype on low nitrate concentration is more severe than for the atnrt2.1-1 knock out mutant. Physiological characterisation of the plant N status and gene expression revealed a pattern that was characteristic of severe nitrogen deficiency. Consistent with the down regulation of AtNRT2.1 expression, the atnar2.1-1 plants also displayed the same phenotype as atnrt2.1 mutants in lateral root (LR) response to low nitrate supply. Using atnar2.1-1 plants constitutively expressing the NpNRT2.1 gene, we now show a specific role for AtNAR2.1 in LR response to low nitrate supply. AtNAR2.1 is also involved in the repression of LR initiation in response to high ratios of sucrose to nitrogen in the medium. Therefore the two component system itself is likely to be involved in the signaling pathway integrating nutritional cues for LR architecture regulation. Using a green fluorescent protein-NRT2.1 protein fusion we show the essential role of AtNAR2.1 for the presence of AtNRT2.1 to the plasma membrane.
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