Abstract
Since the earlier investigations of workers such as Silver (1957) and Pichinoty and Metenier (1967), progress in the study of the structure and regulation of the enzymes of nitrate assimilation in yeasts has been disappointing, compared with filamentous fungi and unicellular algae. However, more recent investigations with the imperfect, asporogenous yeast, Candida nitratophila, have yielded much useful information and this has helped to fill the gaps in our knowledge (Hipkin 1989). It is clear from all studies that the nitrate assimilation pathway in yeasts is similar to that found in other organisms that use nitrate as a nitrogen source and our current understanding of the pathway that incorporates nitrate-nitrogen into a-amino nitrogen in C. nitratophila is outlined in Figure 1. There are several noteworthy features here. Firstly, in yeasts, the heterotrophic reduction of nitrate to ammonium (via nitrite) can be driven entirely by reducing power in the form of NADPH. In species like C. nitratophila, the enzyme nitrate reductase (NR) is able to use NADH or NADPH as an electron donor whereas nitrite reductase is NADPH-specific (Hipkin 1989). Secondly, although it has been accepted widely that the NADPH-glutamate dehydrogenase pathway is the major pathway for the incorporation of ammonium nitrogen into a-amino nitrogen in nitrateutilizing yeasts (Sims and Folkes 1964; Brown et al. 1973; Miflin and Lea 1980), it is clear now that a significant amount of ammonium may be assimilated via the glutamate syn-thase cycle in these organisms under non-nitrogen-replete conditions; e.g. when nitrate is the sole source of nitrogen being assimilated (Hipkin et al. 1990). Thirdly, although many forms of reduced nitrogen could be regarded as end products of nitrate assimilation, ammonium, glutamate and glutamine are the ones that occupy a central position in terms of the regulation of nitrate metabolism.
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References
Ali AH, Hipkin CR (1986) Nitrate assimilation in Candida nitratophila and other yeasts. Arch Microbiol 144: 263–267
Arst HN Jr, Cove DJ (1973) Nitrogen metabolite repression in Aspergillus nidulans. Mol Gen Genet 126: 111–141
Brown CM, Burn VJ, Johnson B (1973) Presence of glutamate synthase in fission yeast and its possible role in ammonia asssimilation. Nature 246: 115–116
Bruinenberg PM, Van Dijken JP, Scheffers AW (1983 a) A theoretical analysis of NADPH production and consumption in Candida utilis. J Gen Microbiol 129: 953–964
Bruinenberg PM, Van Dijken JP, Scheffers AW (1983 b) An enzymatic analysis of NADPH production and consumption in Candida utilis. J Gen Microbiol 129: 965–971
Calza R, Huttner E, Vincentz M, Rouze P, Galangau F, Vaucheret H, Cherel I, Meyer C, Kronenberger J, Caboche M (1987) Cloning of DNA fragments complementary to tobacco nitrate reductase mRNA and encoding epitopes common to the nitrate reductases from higher plants. Mol Gen Genet 209: 552–562
Cannons AC, Ali AH, Hipkin CR (1986) Regulation of nitrate reductase in the yeast Candida nitratophila. J Gen Microbiol 132: 2005–2011
Cannons AC, Hipkin CR (1987) Evidence for the transcriptional control of nitrate reductase in Candida nitratophila from in vitro translation studies. Eur J Biochem 164: 383–387
Cheng CL, Dewdney J, Kleinhofs A, Goodman HM (1986) Cloning and nitrate induction of nitrate reductase mRNA. Proc Nad Acad Sci USA 83: 6825–6828
Crawford NM, Campbell WH, Davis RW (1986) Nitrate reductase from squash: cDNA cloning and regulation. Proc Natl Acad Sci USA 83: 8073–8076
Flynn K, Hipkin CR (1990) Changes in intracellular amino acids and glutamine:glutamate during N-deprivation and feeding in Candida nitratophila. New Phytol 114: 435–440
Hamoudl ZS (1988) Ammonium assimilation in yeasts. M Sc Thesis, University of Wales, Swansea Hankinson O, Cove DJ (1974) Regulation of the pentose phosphate pathway in the fungus Aspergillus nidulans. J Biol Chem 249: 2344–2353
Hipkin CR (1989) Nitrate assimilation in yeasts. In: Wray JL, Kinghorn Jr (eds) Molecular and Genetic Aspects of Nitrate Assimilation. Oxford Sci Publications, Oxford New York Tokyo, pp 51–68
Hipkin CR, Ali AH, Cannons AC (1986) Structure and properties of assimilatory nitrate reductase from the yeast Candida nitratophila. J Gen Microbiol 132: 1997–2003
Hipkin CR, Cannons AC (1985) Inorganic nitrogen assimilation and the regulation of glucosesphosphate dehydrogenase in unicellular algae. Plant Sci 41: 155–160
Hipkin CR, Cannons AC (1987) The regulation of nitrate reductase in yeasts. In: Ullrich WR, Aparicio PJ, Syrett PJ, Castillo F (eds) Inorganic Nitrogen Metabolism. Springer, Berlin Heidelberg New York, pp 89–93
Hipkin CR, Flynn KJ, Marjot E, Hamoudi ZS, Cannons AC (1990) Ammonium assimilation in nitrate utilising yeast, Candida nitratophila. New Phytol 114: 429–434
Hipkin CR, Kau DA, Cannons AC, Jones DH, Gallon Jr, Kay CJ, Barber MJ, Solomonson LP (1989) Physical and chemical properties of assimilatory nitrate reductase from Candida nitratophila. Trans Biochem Soc Lond 17: 928–929
Kinghorn Jr (1989) Genetic, biochemical and structural organisation of the Aspergillus nidulans cnrA-niiA-niaD gene cluster. In: Wray JL, Kinghorn Jr (eds) Molecular and Genetic Aspects of Nitrate Assimilation. Oxford Sci Publications, Oxford New York Tokyo, pp 69
Marzluf GA (1981) Regulation of nitrogen metabolism and gene expression in fungi. Microb Rev 45: 437–461
Marzluf GA, Fu Y-H (1989) Genetic regulation and molecular studies of nitrate assimilation in Neurospora crassa. In: Wray JL, Kinghorn Jr (eds) Molecular and Genetic Aspects of Nitrate Assimilation. Oxford Sci Publications, Oxford New York Tokyo, pp 314
Osmond CB, ap Rees T (1969) Control of the pentose phosphate pathway in yeast. Biochim Biophys Acta 184: 35–42
Pichinoty F, Metenier G (1966) Contribution a l’etude de la nitrate-reductase assimilatrice d’une levure. Ann Inst Pasteur 111: 282–313
Scazzocchio C, Arst HN Jr (1989) Regulation of nitrate assimilation in Aspergillus nidulans. In: Wray JL, Kinghorn Jr (eds) Molecular and Genetic Aspects of Nitrate Assimilation. Oxford Sci Publications, Oxford New York Tokyo, pp 299
Silver WS (1957) Pyridine nucleotide-nitrate reductase from Hansenula anomala, a nitrate reducing yeast. J Bacteriol 73: 241–246
Sims AP, Folkes BF (1964) A kinetic study of the assimilation of [15N] ammonia and the synthesis of amino acids in an exponentially growing culture of Candida utilis. Proc Roy Soc (London) 159: 479–502
Smarrelli J Jr, Malone MJ, Walters MT, Curtis LT (1987) Transcriptional control of the inducible nitrate reductase isoform from soybean. Biochem Biophys Res Commun 146: 1160–1165
Wiame JM, Grenson M, Arst HN Jr (1985) Nitrogen catabolite repression in yeasts and filamentous fungi. Adv Microb Physiol 26: 1–88
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Hipkin, C.R. (1990). The Regulation of Nitrate Assimilation in Yeast. In: Ullrich, W.R., Rigano, C., Fuggi, A., Aparicio, P.J. (eds) Inorganic Nitrogen in Plants and Microorganisms. Springer, Berlin, Heidelberg. https://doi.org/10.1007/978-3-642-75812-6_28
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DOI: https://doi.org/10.1007/978-3-642-75812-6_28
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