Footprinting of the spinach nitrite reductase gene promoter reveals the preservation of nitrate regulatory elements between fungi and higher plants

Nitrite reductase (NiR) is the second enzyme in the nitrate assimilatory pathway reducing nitrite to ammonium. The expression of the NiR gene is induced upon the addition of nitrate. In an earlier study, a 130 bp upstream region of the spinach NiR gene promoter, located between –330 to –200, was shown to be necessary for nitrate induction of -glucuronidase (GUS) expression in tissue-specific manner in transgenic tobacco plant [28]. To further delineate the cis-acting elements involved in nitrate regulation of NiR gene expression, transgenic tobacco plants were generated with 5 deletions in the–330 to –200 region of the spinach NiR gene promoter fused to the GUS gene. Plants with the NiR promoter deleted to –230 showed a considerable increase in GUS activity in the presence of nitrate, indicating that the 30 bp region between –230 to –200 is crucial for nitrate-regulated expression of NiR. In vivo DMS footprinting of the –300 to –130 region of the NiR promoter in leaf tissues from two independent transgenic lines revealed several nitrate-inducible footprints. Footprinting within the –230 to –181 region revealed factor binding to two adjacent GATA elements separated by 24 bp. This arrangement of GATA elements is analogous to cis-regulatory sequences found in the promoters of nitrate-inducible genes of Neurospora crassa, regulated by the NIT2 Zn-finger protein. The –240 to –110 fragment of the NiR promoter, which contains two NIT2 consensus core elements, bound in vitro to a fusion protein comprising the zinc finger domain of the N. crassa NIT2 protein. The data presented here show that nitrate-inducible expression of the NiR gene is mediated by nitrate-specific binding of trans-acting factors to sequences preserved between fungi and higher plants.     

Screening for Arabidopsis mutants affected in the Nii gene expression using the Gus reporter gene

A mutant screen was developed to isolate Arabidopsis thaliana mutants affected in the regulation of the nitrate assimilation pathway. A fusion between the tobacco Nii1 gene (that encodes a foliar nitrite reductase involved in nitrate assimilation) and the Gus reporter gene was introduced into A. thaliana , and shown to be properly regulated by nitrate. Moreover, β -glucuronidase (GUS) activity in the transgenic plants was essentially detected in the cotyledons and leaves, showing that the organ-specific expression of the tobacco Nii1 gene was retained in Arabidopsis . M2 plantlets derived from mutagenized seeds homozygous for the Nii-Gus fusion were screened by histochemical staining of whole plates for GUS activity after growth on nitrate or glutamine. About 250 progenies were screened, leading to the isolation of plants showing an enhanced or reduced staining compared to the control non-mutagenized plants. Several mutants were analyzed for the transmission of the phenotype to the M3 generation, as well as for levels of GUS or nitrite reductase activities or mRNA levels. A major problem encountered during the screening was the high background of false positives that reproducibly showed altered GUS histochemical staining compared to control plants and did not, however, display any changes in GUS activity levels. One interesting family of mutants was isolated that overexpressed GUS activity and Nii mRNA in the absence of nitrate. These mutants turned out to be cnx mutants impaired in the molybdenum cofactor biosynthesis that is necessary for nitrate reductase activity. These results may indicate that active nitrate reductase is necessary for a correct regulation of nitrate assimilation genes by nitrate.     

The nitrate reductase promoter of birch directs differential reporter gene expression in tissues of transgenic tobacco

A 1535 bp promoter of the nitrate reductase gene (nia) from birch (Betula pendula) and a series of 5′ deletions were fused to the β-glucuronidase (GUS) gene and introduced into Nicotiana plumbaginifolia. In transgenic plants the NR promoter sequences directed strong GUS expression in the root epidermal hair cells, and in phloem cells of leaf and stem vascular tissue. The NR promoter confers also a significant stimulation of the GUS gene expression by nitrate. These findings might indicate that nitrate flow is one of the signals involved into tissue and cell specific expression of the NR promoter GUS fusions. This revised version was published online in June 2006 with corrections to the Cover Date.     

Cell Specific,Cross-Species Expression of Myrosinases in Brassica Napus,Arabidopsis Thaliana and Nicotiana Tabacum

A prototypical characteristic of the Brassicaceae is the presence of the myrosinase-glucosinolate system. Myrosinase, the only known S-glycosidase in plants, degrades glucosinolates, thereby initiating the formation of isothiocyanates, nitriles and other reactive products with biological activities. We have used myrosinase gene promoters from Brassica napus and Arabidopsis thaliana fused to the beta -glucuronidase (GUS) reporter gene and introduced into Arabidopsis thaliana, Brassica napus and/or Nicotiana tabacum plants to compare and determine the cell types expressing the myrosinase genes and the GUS expression regulated by these promoters. The A. thaliana TGG1 promoter directs expression to guard cells and phloem myrosin cell idioblasts of transgenic A. thaliana plants. Expression from the same promoter construct in transgenic tobacco plants lacking the myrosinase enzyme system also directs expression to guard cells. The B. napus Myr1.Bn1 promoter directs a cell specific expression to idioblast myrosin cells of immature and mature seeds and myrosin cells of phloem of B. napus. In A. thaliana the B. napus promoter directs expression to guard cells similar to the expression pattern of TGG1. The Myr1.Bn1 signal peptide targets the gene product to the reticular myrosin grains of myrosin cells. Our results indicate that myrosinase gene promoters from Brassicaceae direct cell, organ and developmental specific expression in B. napus, A. thaliana and N. tabacum.