Disruption, replacement, and cosuppression of nitrate assimilation genes in Stagonospora nodorum

We used Stagonospora (Septoria) nodorum to explore gene disruption as a general method of fungicide target validation. Nitrate reductase was chosen as a model target because the gene (NIA1) has been cloned from S. nodorum and disruptants should have a readily detectable phenotype (chlorate resistant...

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Veröffentlicht in:	Fungal genetics and biology 1999-03, Vol.26 (2), p.152-162
Hauptverfasser:	Howard, K, Foster, S.G, Cooley, R.N, Caten, C.E
Format:	Artikel
Sprache:	eng
Schlagworte:	Blotting, Southern enzyme activity excretion Gene Deletion Gene Targeting Genes, Fungal genetic transformation homologous recombination leaves Leptosphaeria nodorum Mitosporic Fungi - enzymology Mitosporic Fungi - genetics Mitosporic Fungi - growth & development Mitosporic Fungi - pathogenicity mutagenesis nia1 gene Nitrate Reductase Nitrate Reductases - genetics Nitrate Reductases - metabolism nitrates Nitrates - metabolism nitrites Nitrites - metabolism pathogenicity phenotype plasmid vectors Recombination, Genetic reduction Restriction Mapping Stagonospora nodorum structural genes Transformation, Genetic Triticum - microbiology Triticum aestivum
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creator	Howard, K Foster, S.G Cooley, R.N Caten, C.E
description	We used Stagonospora (Septoria) nodorum to explore gene disruption as a general method of fungicide target validation. Nitrate reductase was chosen as a model target because the gene (NIA1) has been cloned from S. nodorum and disruptants should have a readily detectable phenotype (chlorate resistant and nitrate nonutilizing). We have succeeded in disrupting the NIA1 gene by both integration of an unselected vector during cotransformation and one-step gene replacement. Around 2% of transformants from the cotransformation approach became nitrate nonutilizing and Southern analysis confirmed disruption of the resident NIA1 gene. Half of the transformants with the gene replacement vector showed the nitrate nonutilizing phenotype expected from disruption. However, Southern analyses of 14 of these transformants showed that only 6 contained the expected NIA1 gene replacement. Of the remaining transformants, 6 had integrated multiple copies of the vector elsewhere in their genome and still had a functional nitrate reductase gene. Their inability to utilize nitrate was due to a lack of nitrite reductase activity. How this phenotype arose is not clear, but it might involve cosuppression of the nitrite reductase gene as the vector carried 1. 1 kb of the coding region and the complete 5' region of this gene which is adjacent to NIA1. Mutants of both types retained full pathogenicity in detached leaf assays, thereby invalidating both nitrate and nitrite reductase as fungicide targets.
doi_str_mv	10.1006/fgbi.1998.1113
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Nitrate reductase was chosen as a model target because the gene (NIA1) has been cloned from S. nodorum and disruptants should have a readily detectable phenotype (chlorate resistant and nitrate nonutilizing). We have succeeded in disrupting the NIA1 gene by both integration of an unselected vector during cotransformation and one-step gene replacement. Around 2% of transformants from the cotransformation approach became nitrate nonutilizing and Southern analysis confirmed disruption of the resident NIA1 gene. Half of the transformants with the gene replacement vector showed the nitrate nonutilizing phenotype expected from disruption. However, Southern analyses of 14 of these transformants showed that only 6 contained the expected NIA1 gene replacement. Of the remaining transformants, 6 had integrated multiple copies of the vector elsewhere in their genome and still had a functional nitrate reductase gene. Their inability to utilize nitrate was due to a lack of nitrite reductase activity. How this phenotype arose is not clear, but it might involve cosuppression of the nitrite reductase gene as the vector carried 1. 1 kb of the coding region and the complete 5' region of this gene which is adjacent to NIA1. 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Nitrate reductase was chosen as a model target because the gene (NIA1) has been cloned from S. nodorum and disruptants should have a readily detectable phenotype (chlorate resistant and nitrate nonutilizing). We have succeeded in disrupting the NIA1 gene by both integration of an unselected vector during cotransformation and one-step gene replacement. Around 2% of transformants from the cotransformation approach became nitrate nonutilizing and Southern analysis confirmed disruption of the resident NIA1 gene. Half of the transformants with the gene replacement vector showed the nitrate nonutilizing phenotype expected from disruption. However, Southern analyses of 14 of these transformants showed that only 6 contained the expected NIA1 gene replacement. Of the remaining transformants, 6 had integrated multiple copies of the vector elsewhere in their genome and still had a functional nitrate reductase gene. 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Mutants of both types retained full pathogenicity in detached leaf assays, thereby invalidating both nitrate and nitrite reductase as fungicide targets.</description><subject>Blotting, Southern</subject><subject>enzyme activity</subject><subject>excretion</subject><subject>Gene Deletion</subject><subject>Gene Targeting</subject><subject>Genes, Fungal</subject><subject>genetic transformation</subject><subject>homologous recombination</subject><subject>leaves</subject><subject>Leptosphaeria nodorum</subject><subject>Mitosporic Fungi - enzymology</subject><subject>Mitosporic Fungi - genetics</subject><subject>Mitosporic Fungi - growth & development</subject><subject>Mitosporic Fungi - pathogenicity</subject><subject>mutagenesis</subject><subject>nia1 gene</subject><subject>Nitrate Reductase</subject><subject>Nitrate Reductases - genetics</subject><subject>Nitrate Reductases - metabolism</subject><subject>nitrates</subject><subject>Nitrates - metabolism</subject><subject>nitrites</subject><subject>Nitrites - metabolism</subject><subject>pathogenicity</subject><subject>phenotype</subject><subject>plasmid vectors</subject><subject>Recombination, Genetic</subject><subject>reduction</subject><subject>Restriction Mapping</subject><subject>Stagonospora nodorum</subject><subject>structural genes</subject><subject>Transformation, Genetic</subject><subject>Triticum - microbiology</subject><subject>Triticum aestivum</subject><issn>1087-1845</issn><issn>1096-0937</issn><fulltext>true</fulltext><rsrctype>article</rsrctype><creationdate>1999</creationdate><recordtype>article</recordtype><sourceid>EIF</sourceid><recordid>eNqF0D1PwzAQBmALgWj5WBnBE1NTfHYS2yPiW6rEAJ3DNbEro8QOdjLw70lVmJnu1d1zNxwhF8CWwFh5Y7cbtwSt1RIAxAGZA9NlxrSQh7usZAYqL2bkJKVPxgCKHI7JDJjgSqtiTj7uXYpjP7jgFzSavsXadMYPC4q-oXVIY99Hk9I0p8FS74aIg6E4dTrX4m6Pbo03iTpP3wbcBh9SHyJSH5oQx-6MHFlskzn_radk_fjwfvecrV6fXu5uV5nlJR8yKXJEvpGqQFGjUqpgHHRdG2vRqrzhWnIuDRaN4oj1FEuGghWIRtRNacUpud7f7WP4Gk0aqs6l2rQtehPGVJValoKD_BeC5MAl8Ale_sJx05mm6qPrMH5Xf8-bwNUeWAwVbqNL1fqNMxCMa8ZyDeIHVeJ8lA</recordid><startdate>19990301</startdate><enddate>19990301</enddate><creator>Howard, K</creator><creator>Foster, S.G</creator><creator>Cooley, R.N</creator><creator>Caten, C.E</creator><scope>FBQ</scope><scope>CGR</scope><scope>CUY</scope><scope>CVF</scope><scope>ECM</scope><scope>EIF</scope><scope>NPM</scope><scope>8FD</scope><scope>FR3</scope><scope>M7N</scope><scope>P64</scope><scope>RC3</scope><scope>7X8</scope></search><sort><creationdate>19990301</creationdate><title>Disruption, replacement, and cosuppression of nitrate assimilation genes in Stagonospora nodorum</title><author>Howard, K ; 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Nitrate reductase was chosen as a model target because the gene (NIA1) has been cloned from S. nodorum and disruptants should have a readily detectable phenotype (chlorate resistant and nitrate nonutilizing). We have succeeded in disrupting the NIA1 gene by both integration of an unselected vector during cotransformation and one-step gene replacement. Around 2% of transformants from the cotransformation approach became nitrate nonutilizing and Southern analysis confirmed disruption of the resident NIA1 gene. Half of the transformants with the gene replacement vector showed the nitrate nonutilizing phenotype expected from disruption. However, Southern analyses of 14 of these transformants showed that only 6 contained the expected NIA1 gene replacement. Of the remaining transformants, 6 had integrated multiple copies of the vector elsewhere in their genome and still had a functional nitrate reductase gene. Their inability to utilize nitrate was due to a lack of nitrite reductase activity. How this phenotype arose is not clear, but it might involve cosuppression of the nitrite reductase gene as the vector carried 1. 1 kb of the coding region and the complete 5' region of this gene which is adjacent to NIA1. Mutants of both types retained full pathogenicity in detached leaf assays, thereby invalidating both nitrate and nitrite reductase as fungicide targets.</abstract><cop>United States</cop><pmid>10328985</pmid><doi>10.1006/fgbi.1998.1113</doi><tpages>11</tpages></addata></record>
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subjects	Blotting, Southern enzyme activity excretion Gene Deletion Gene Targeting Genes, Fungal genetic transformation homologous recombination leaves Leptosphaeria nodorum Mitosporic Fungi - enzymology Mitosporic Fungi - genetics Mitosporic Fungi - growth & development Mitosporic Fungi - pathogenicity mutagenesis nia1 gene Nitrate Reductase Nitrate Reductases - genetics Nitrate Reductases - metabolism nitrates Nitrates - metabolism nitrites Nitrites - metabolism pathogenicity phenotype plasmid vectors Recombination, Genetic reduction Restriction Mapping Stagonospora nodorum structural genes Transformation, Genetic Triticum - microbiology Triticum aestivum
title	Disruption, replacement, and cosuppression of nitrate assimilation genes in Stagonospora nodorum
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