Recently, six genes of the gibberellin (GA) biosynthesis gene cluster in Gibberella fujikuroi were cloned and the functions of five of these genes were determined. Here we describe the function of the sixth gene, P450 -3, and the cloning and functional analysis of a seventh gene, orf3, located at the left border of the gene cluster. We have thereby defined the complete GA biosynthesis gene cluster in this fungus. The predicted amino acid sequence of orf3 revealed no close homology to known proteins. High performance liquid chromatography and gas chromatography-mass spectrometry analyses of the culture fluid of knock-out mutants identified GA 1 and GA 4 , rather than GA 3 and GA 7 , as the major C 19 -GA products, suggesting that orf3 encodes the GA 4 1,2-desaturase. This was confirmed by transformation of the SG139 mutant, which lacks the GA biosynthesis gene cluster, with the desaturase gene renamed des. The transformants converted GA 4 to GA 7 , and also metabolized GA 9 (3-deoxyGA 4 ) to GA 120 (1,2-didehydroGA 9 ), but the 2␣-hydroxylated compound GA 40 was the major product in this case. We demonstrate also by gene disruption that P450-3, one of the four cytochrome P450 monooxygenase genes in the GA gene cluster, encodes the 13-hydroxylase, which catalyzes the conversion of GA 7 to GA 3 , in the last step of the pathway. This enzyme also catalyzes the 13-hydroxylation of GA 4 to GA 1 . Disruption of the des gene in an UV-induced P450 -3 mutant produced a double mutant lacking both desaturase and 13-hydroxylase activities that accumulated high amounts of the commercially important GA 4 . The des and P450 -3 genes differ in their regulation by nitrogen metabolite repression. In common with the other five GA biosynthesis genes, expression of the desaturase gene is repressed by high amounts of nitrogen in the culture medium, whereas P450-3 is the only gene in the cluster not repressed by nitrogen.
Phytoene synthase, phytoene dehydrogenase and carotene cyclase are three of the four enzyme activities needed to produce the acidic carotenoid neurosporaxanthin from the precursor geranylgeranyl pyrophosphate. In the filamentous fungus Fusarium fujikuroi, these three enzyme activities are encoded by two closely linked genes, carRA and carB, oriented in the same direction in the genome. The two genes are separated by 548 bp and code for two polypeptides of 612 and 541 amino acids, respectively, which are highly similar to the homologous proteins from other filamentous fungi. The ORF of carRA contains a 96-bp insertion that is absent in the other fungal homologues. The 32 additional residues are located in one of the two repeated domains responsible for the cyclase activity in the homologous fungal proteins. We have determined the function of carRA by gene disruption. The resulting mutants were albino and had lost the ability to produce phytoene, as expected from the simultaneous loss of phytoene synthase and carotene cyclase. In the same experiments, we also found transformants in which carB had been deleted. These mutants accumulate phytoene, confirming the function of the gene previously shown by gene-targeted mutagenesis. Expression of carRA and carB is strongly induced by light. Loss of carB or disruption of the carRA ORF led to enhanced expression of the carRA gene, suggesting the existence of a feedback regulatory mechanism.
The rice pathogen Fusarium fujikuroi is known to produce a wide range of secondary metabolites, such as the pigments bikaverin and fusarubins, the mycotoxins fusarins and fusaric acid, and the phytohormones gibberellic acids (GAs), which are applied as plant growth regulators in agri- and horticulture. The development of high-producing strains is a prerequisite for the efficient biotechnological production of GAs. In this work, we used different molecular approaches for strain improvement to directly affect expression of early isoprenoid genes as well as GA biosynthetic genes. Overexpression of the first GA pathway gene ggs2, encoding geranylgeranyl diphosphate synthase 2, or additional integration of ggs2 and cps/ks, the latter encoding the bifunctional ent-copalyldiphosphate synthase/ent-kaurene synthase, revealed an enhanced production level of 150%. However, overexpression of hmgR and fppS, encoding the key enzymes of the mevalonate pathway, hydroxymethylglutaryl coenzyme A reductase, and farnesyldiphosphate synthase, resulted in a reduced production level probably due to a negative feedback regulation of HmgR. Subsequent deletion of the transmembrane domains of HmgR and overexpression of the remaining catalytic domain led to an increased GA content (250%). Using green fluorescent protein and mCherry fusion constructs, we localized Cps/Ks in the cytosol, Ggs2 in small point-like structures, which are not the peroxisomes, and HmgR at the endoplasmatic reticulum. In summary, it was shown for the first time that amplification or truncation of key enzymes of the isoprenoid and GA pathway results in elevated production levels (2.5-fold). Fluorescence microscopy revealed localization of the key enzymes in different compartments.
We induced mutants of Gibberella fujikuroi deficient in gibberellin (GA) biosynthesis by transformation-mediated mutagenesis with the vector pAN7-1. We recovered 24 GA-defective mutants in one of nine transformation experiments performed without the addition of a restriction enzyme. Each mutant had a similar Southern blot pattern, suggesting the integration of the vector into the same site. The addition of a restriction enzyme by restriction enzyme-mediated integration (REMI) significantly increased the transformation rate and the rate of single-copy integration events. Of 1,600 REMI transformants, two produced no GAs. Both mutants had multiple copies of the vector pAN7-1 and one had a Southern blot pattern similar to those of the 24 conventionally transformed GA-deficient mutants. Biochemical analysis of the two REMI mutants confirmed that they cannot produceent-kaurene, the first specific intermediate of the GA pathway. Feeding the radioactively labelled precursorsent-kaurene and GA12-aldehyde followed by high-performance liquid chromatography and gas chromatography-mass spectrometry analysis showed that neither of these intermediates was converted to GAs in the mutants. Southern blot analysis and pulsed-field gel electrophoresis of the transformants using the bifunctional ent-copalyl diphosphate/ent-kaurene synthase gene (cps/ks) and the flanking regions as probes revealed a large deletion in the GA-deficient REMI transformants and in the GA-deficient transformants obtained by conventional insertional transformation. We conclude that transformation procedures with and without the addition of restriction enzymes can lead to insertion-mediated mutations and to deletions and chromosome translocations.
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