NUT1, a major nitrogen regulatory gene inMagnaporthe grisea, is dispensable for pathogenicity

Froeliger, Eunice H.; Carpenter, Bob

doi:10.1007/bf02174113

Cited by 78 publications

(102 citation statements)

References 35 publications

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“…3). The bias does not correspond (21); N ϭ NUT1 (38). Published TI frequencies are 16%, 11%, 21%, 3%, and 22%, respectively.…”

Section: Resultsmentioning

confidence: 99%

“…Targeted integration (TI) for creating gene-specific mutations is very efficient and requires only 50-bp fragments of target gene homology on either side of a selectable marker (11,12). In contrast, many filamentous fungi have genome sizes in the range of [30][31][32][33][34][35][36][37][38][39][40] Mb and are estimated to contain at least 10,000 genes (13). Genome studies using expressed sequence tag analysis suggest that more than half of these genes lack homologues in S. cerevisiae (14).…”

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confidence: 99%

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Gene discovery and gene function assignment in filamentous fungi

Hamer

Adachi

Montenegro-Chamorro

et al. 2001

Proc. Natl. Acad. Sci. U.S.A.

104

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Filamentous fungi are a large group of diverse and economically important microorganisms. Large-scale gene disruption strategies developed in budding yeast are not applicable to these organisms because of their larger genomes and lower rate of targeted integration (TI) during transformation. We developed transposonarrayed gene knockouts (TAGKO) to discover genes and simultaneously create gene disruption cassettes for subsequent transformation and mutant analysis. Transposons carrying a bacterial and fungal drug resistance marker are used to mutagenize individual cosmids or entire libraries in vitro. Cosmids are annotated by DNA sequence analysis at the transposon insertion sites, and cosmid inserts are liberated to direct insertional mutagenesis events in the genome. Based on saturation analysis of a cosmid insert and insertions in a fungal cosmid library, we show that TAGKO can be used to rapidly identify and mutate genes. We further show that insertions can create alterations in gene expression, and we have used this approach to investigate an amino acid oxidation pathway in two important fungal phytopathogens.A powerful asset for functional genomic analysis is the ability to create large annotated single gene mutant collections. For model research organisms such as baker's yeast, Drosophila, Caenorhabditis, Arabidopsis, and mice, whole genome knockout collections (1), transposon lines (2), or insertional mutant collections (3, 4) are well developed. However, in addition to these model organisms there is a vast array of economically important organisms where genome sequences and functional genomic technologies are lacking. For example, filamentous fungi are causal agents of severe human (5, 6) and crop (7, 8) diseases, and many others are being exploited in the fermentation and food industries (9). Few of these fungal genomes have been analyzed, and large-scale approaches to functional analysis are needed.The model fungus, Saccharomyces cerevisiae, has Ϸ6000 genes in 12 Mb of DNA sequence (10). Targeted integration (TI) for creating gene-specific mutations is very efficient and requires only 50-bp fragments of target gene homology on either side of a selectable marker (11,12). In contrast, many filamentous fungi have genome sizes in the range of 30-40 Mb and are estimated to contain at least 10,000 genes (13). Genome studies using expressed sequence tag analysis suggest that more than half of these genes lack homologues in S. cerevisiae (14). TI occurs at very low frequencies (1-20%) for many filamentous fungi, and larger fragments of target gene homology must be used to obtain targeted insertion events (15).To initiate genome-wide mutagenesis studies in filamentous fungi we developed an approach we call transposon-arrayed gene knockouts (TAGKO) (Fig. 1). In vitro transposition (IVT) (16-19) into cosmid libraries is used to create gene sequencing templates. Subsequent sequencing and analysis from these templates creates an annotated collection of insertional gene disruption vectors. We demonstrate that IVT can...

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“…3). The bias does not correspond (21); N ϭ NUT1 (38). Published TI frequencies are 16%, 11%, 21%, 3%, and 22%, respectively.…”

Section: Resultsmentioning

confidence: 99%

mentioning

confidence: 99%

Gene discovery and gene function assignment in filamentous fungi

Hamer

Adachi

Montenegro-Chamorro

et al. 2001

Proc. Natl. Acad. Sci. U.S.A.

104

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“…The expression of selected genes involved in nitrogen metabolism is reduced in cells exposed to readily metabolizable nitrogen sources such as ammonia (Facklam & Marzluf, 1978;Sikora & Marzluf, 1982a, b). One transcriptional regulator, named NIT2 in N. crassa and AREA in A. nidulans, has been identified in several fungi (Fu & Marzluf, 1990b, c;Haas et al, 1995;Froeliger & Carpenter, 1996, Screen et al, 1998, and its binding to DNA is necessary for the expression of the genes involved in utilization of nitrogen sources (Scazzocchio, 2000). In the absence of ammonia, AREA binds to two closely spaced 59-GATA sequences in various gene promoters and activates their transcription .…”

Section: Introductionmentioning

confidence: 99%

Sulphur and nitrogen regulation of the protease-encoding ACP1 gene in the fungus Botrytis cinerea: correlation with a phospholipase D activity

Bruel

2008

Microbiology

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Sulphur and nitrogen catabolic repressions are regulations that have long been recognized in fungi, but whose molecular bases remain largely elusive. This paper shows that catabolic repression of a protease-encoding gene correlates with the modulation of a phosphatidylethanolamine (PE)-specific phospholipase D (PLD) activity in the pathogenic fungus Botrytis cinerea. Our results first demonstrate that the ACP1 gene is subject to sulphur catabolic repression, with sulphate and cysteine inhibiting its expression. Sulphate and cysteine also cause a decrease of the total cellular PLD activity and, reciprocally, the two PLD inhibitors AEBSF [4-(2-aminoethyl)benzenesulphonyl fluoride] and curcumin negatively affect ACP1 expression in vivo. Cysteine moreover inhibits the PE-specific PLD activity in cell extracts. ACP1 is regulated by nitrogen, but here we show that this regulation does not rely on the proximal AREA binding site in its promoter, and that glutamine does not play a particular role in the process. A decrease in the total cellular PLD activity is also observed when the cells are fed ammonia, but this effect is smaller than that produced by sulphur. RNA-interference experiments finally suggest that the enzyme responsible for the PE-specific PLD activity is encoded by a gene that does not belong to the known HKD gene family of PLDs.

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“…Ammonia is the preferred nitrogen source for M. oryzae. The NMR in M. oryzae occurs through the transcriptional activator Nut1, the M. oryzae AreA/Nit2 orthologue (Froeliger & Carpenter, 1996). The expression of a large number of genes encoding enzymes that are involved in the utilisation of various secondary nitrogen sources -nitrate, purines or amino acids-is subject to nitrogen metabolic repression and is positively regulated by Nut1.…”

Section: Fungal Metabolism and Plant Infectionmentioning

confidence: 99%

“…The assimilation of nitrogen by M. oryzae from underground plant tissues is regulated by the global nitrogen regulator Nut1 (Froeliger & Carpenter, 1996). The Δnut1 mutant is non-pathogenic on roots but infects leaves as well as the wildtype strain .…”

Section: The Dark Phase Of Blast: M Oryzae Root Infection Biologymentioning

confidence: 99%

Molecular mechanisms regulating plant infection in the rice blast fungus Magnaporthe oryzae

Otero¹

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NUT1, a major nitrogen regulatory gene inMagnaporthe grisea, is dispensable for pathogenicity

Cited by 78 publications

References 35 publications

Gene discovery and gene function assignment in filamentous fungi

Gene discovery and gene function assignment in filamentous fungi

Sulphur and nitrogen regulation of the protease-encoding ACP1 gene in the fungus Botrytis cinerea: correlation with a phospholipase D activity

Molecular mechanisms regulating plant infection in the rice blast fungus Magnaporthe oryzae

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