Regulation of Chlorella nitrate reductase: control of enzyme activity and immunoreactive protein levels by ammonia

Functional complementation of a nitrate reductase defective mutant of a green alga Dunaliella viridis by introducing the nitrate reductase gene

Nitrate reductase (NR) catalyzes NAD (P) H dependent reduction of nitrate to nitrite. Transformation systems have been established in several species of green algae by nitrate reductase gene functional complementation. In this report, an endogenous NR cDNA (3.4 kb) and a genomic fragment (14.6 kb) containing the NR gene (DvNIA1) were isolated from the D. viridis cDNA and genomic libraries respectively. Southern blot and Northern blot analyses showed that this gene exists as a single copy in D. viridis and is induced by nitrate. To obtain a NR defective mutant as a recipient strain, D. viridis cells were treated with a chemical mutagen and then cultured on a chlorate-containing plate to enrich chlorate tolerant mutants. Southern analysis showed that one isolate, B14, had a deletion in the DvNIA1 gene region. Using electroporation conditions determined in this laboratory, plasmid pDVNR containing the intact DvNIA1 gene has been electroporated into the defective mutant B14. Strains retaining a nitrate assimilation phenotype were obtained from nitrate plates after spreading the electroporated cells. In some individual strains, transcription of the introduced gene was detected. NR activity in these strains was slightly higher than that in the defective B14 cell, but excretion of nitrite into culture media was almost as high as that of the wild-type cell. Possible episomal presence of the introduced DNA in D. viridis is discussed.

Blue-light-control of the uptake of amino acids and of ammonia in Chlorella mutants

In non-photosynthetic, yellow or colourless mutant cells of Chlorella kessleri, grown with nitrate as sole nitrogen source, blue light inhibited the uptake of the amino acids glycine, proline and arginine and of ammonia in growing cells, while it enhanced the uptake of these amino acids in resting cells. On the other hand, in cells grown with ammonia as the only nitrogen source without nitrate reductase activity, blue light did not influence the uptake of amino acids and of ammonia in growing cells, while it enhanced the uptake of amino acids in resting cells. Addition of methionine sulphoximine, a potent inhibitor of glutamine synthetase, to growing cells, resulted in intracellular ammonia-accumulation and inhibition of uptake of glycine and of ammonia. For the colourless mutant, blue light was shown to activate purified nitrate reductase. These results indicate that in the mutant cells of Chlorella examined, uptake of ammonia seems to be influenced by nitrate reductase and the uptake of amino acids was influenced by both nitrate reductase and an unknown blue-light-receptor(s). The uptake of urea in mutant cells is not influenced by the irradiation with blue light. Uptake of glycine was also increased after addition of glucose (hexose) in the dark. Because blue light is known to enhance the breakdown of starch, a reaction producing glucose for oxidative degradation in the algae used, the role of glucose (hexose) in the blue light-affected uptake of amino acids is discussed.

Cloning and characterization of the nitrate reductase-encoding gene from Chlorella vulgaris: structure and identification of transcription start points and initiator sequences

The reduction of nitrate to nitrite catalyzed by nitrate reductase (NR) is considered to be the rate-limiting and regulated step of nitrate assimilation, a major metabolic pathway occurring in a wide range of organisms which in turn supply the nutritional nitrogen requirements for other forms of life. Chlorella vulgaris NR mRNA levels are very responsive to changes in nitrogen source. In the presence of ammonia as the sole nitrogen source, under repressed conditions, NR mRNA is undetectable. Under inducing conditions, the removal of ammonia and addition of nitrate, rapid NR mRNA synthesis occurs. We are studying the elements involved in regulating the expression of this important gene. Two overlapping genomic clones (NRS1 and NR5') were isolated from a cosmid library. The two clones were sequenced and their sequences were aligned with that of a full-length NR cDNA. The gene is approximately 8 kb long and consists of 19 exons and 18 introns. Unlike NR isolated from other species, the exons which code for the functional domains of C. vulgaris are separated by introns. Two transcription start points (tsp) were identified and each is surrounded by potential initiator sequences. No TATA, CAAT or GC-rich promoter elements were located. A time course of NR induction revealed that while transcription initiation from one tsp remains at a constant level from the point of induction through steady state, the level of initiation from another tsp is high upon induction, but decreases as steady state is attained.

Possible role for mRNA stability in the ammonium-controlled regulation of nitrate reductase expression

Ammonium, or a metabolite of ammonium, represses the expression of nitrate reductase (NR) in Chlorella vulgaris. The removal of ammonium and addition of nitrate (induction) resulted in a rapid (20 min) peaked synthesis of NR mRNA. Nitrate reductase protein and activity increased at a much lower rate, reaching their maxima by 8 h. Ammonium added to nitrate-grown cells resulted in a dramatic decrease in NR mRNA from a steady-state level to undetectable levels within 15 min of ammonium addition. Nitrate reductase activity and protein levels decreased to 20% and 40% of initial levels respectively over 8 h. The half-life for NR mRNA under these conditions was estimated to be less than 5 min, compared with 120 min for NR protein. Such rapid decreases in NR mRNA suggested a degradation and/or cessation in NR mRNA transcription. No apparent difference in NR mRNA-specific RNAase activity of crude cell extracts (NR-induced or repressed) was observed. However, a significant difference in the susceptibility to degradation of NR mRNA from long-term nitrate-grown cells compared with the NR mRNA isolated from short-term induced cells (20 min in nitrate) was observed. NR mRNA isolated from long-term-nitrate-grown cells was completely degraded by RNAases in cell extracts under conditions in which the NR mRNA isolated from short-term induced cells was resistant to degradation. These results suggest that mRNA stability may be an important factor in the metabolic regulation of assimilatory nitrate reductase in Chlorella.

The nitrate reductase-encoding gene of Volvox carteri: map location, sequence and induction kinetics

The nitrate reductase (NR) structural gene (nitA) of Volvox carteri has been cloned and characterized. There is a single copy of this gene in the genome, and RFLP (restriction-fragment length polymorphism) analysis assigns it to the previously defined nitA/chlR locus on linkage group IX, 20-30 cM from the two beta-tubulin-encoding loci. Determination of the 5871-nt sequence of the coding region of genomic clones, and comparisons to a cDNA sequence, revealed ten introns and eleven exons that encode a 864-aa polypeptide. Detailed comparisons with higher-plant and fungal NRs indicate that, whereas the aa sequence is strongly conserved within functional domains for the flavin adenine dinucleotide-, heme- and molybdenum-pterin cofactor-binding sites, substantial differences in the aa sequence occur in the N-terminal end and the two inter-domain regions. Two potential transcription start points 439 and 452 nt upstream from the start codon and a polyadenylation signal 355 nt downstream from the stop codon have been identified by primer-extension analysis and cDNA sequencing, respectively. Accumulation of the nitA transcript is both induced by nitrate and repressed by ammonium and urea: after the organism is transferred from ammonium to nitrate as the nitrogen source, a 3.6-kb NR transcript is readily detectable on Northern blots by 10 min, reaches maximum abundance by 30 min, and then rapidly declines to an intermediate level that is subsequently maintained. Substantial induction by nitrate is observed at the end of the dark portion of the daily light/dark cycle, but the inductive response peaks in the first hour of the light period.(ABSTRACT TRUNCATED AT 250 WORDS)

Expression of a cDNA clone encoding the haem-binding domain of Chlorella nitrate reductase

A partial cDNA clone coding for the haem-binding domain of NADH:nitrate reductase (EC 1.6.6.1) (NR) from the unicellular green alga Chlorella vulgaris has been isolated, sequenced and expressed. A 1.2 kb cDNA (pCVNR1) was isolated from a lambda gt11 expression library produced from polyadenylated RNA extracted from nitrate-grown Chlorella cells. pCVNR1 hybridized to a 3.5 kb mRNA transcript that was nitrate-inducible and absent from ammonium-grown cells. The entire sequence of pCVNR1 was obtained and found to have a single uninterrupted reading frame. The derived amino acid sequence of 318 amino acids has a 45-50% similarity to higher-plant NRs, including Arabidopsis thaliana, spinach (Spinacia oleracea) and tobacco (Nicotiana tabacum). A comparison with the putative domain structure of higher-plant nitrate reductases suggested that this sequence contains the complete haem-binding domain, approximately one-third of the Mo-pterin domain and no FAD-binding domain. A 32% sequence similarity is evident when comparing the Chlorella NR haem domain with that of calf cytochrome b5. Expression of pCVNR1 in a pET vector synthesized a 35 kDa protein that was antigenic to anti-(Chlorella NR) antibody. The spectral properties of this protein (reduced and oxidized) in the 400-600 nm region are identical with those of native Chlorella NR and indicate that haem is associated with the protein.