PubMed:24475234
Annnotations
21k_plant_trait_mention
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a gibberellin metabolism enzyme, is involved in plant growth, the root gravity response and salt stress.\nGibberellin (GA) 2-oxidases play an important role in the GA catabolic pathway through 2β-hydroxylation. There are two classes of GA2oxs, i.e., a larger class of C₁₉-GA2oxs and a smaller class of C₂₀-GA2oxs. In this study, the gene encoding a GA 2-oxidase of rice, Oryza sativa GA 2-oxidase 5 (OsGA2ox5), was cloned and characterized. BLASTP analysis showed that OsGA2ox5 belongs to the C₂₀-GA2oxs subfamily, a subfamily of GA2oxs acting on C₂₀-GAs (GA₁₂, GA₅₃). Subcellular localization of OsGA2ox5-YFP in transiently transformed onion epidermal cells revealed the presence of this protein in both of the nucleus and cytoplasm. Real-time PCR analysis, along with GUS staining, revealed that OsGA2ox5 is expressed in the roots, culms, leaves, sheaths and panicles of rice. Rice plants overexpressing OsGA2ox5 exhibited dominant dwarf and GA-deficient phenotypes, with shorter stems and later development of reproductive organs than the wild type. The dwarfism phenotype was partially rescued by the application of exogenous GA3 at a concentration of 10 µM. Ectopic expression of OsGA2ox5 cDNA in Arabidopsis resulted in a similar phenotype. Real-time PCR assays revealed that both GA synthesis-related genes and GA signaling genes were expressed at higher levels in transgenic rice plants than in wild-type rice; OsGA3ox1, which encodes a key enzyme in the last step of the bioactive GAs synthesis pathway, was highly expressed in transgenic rice. The roots of OsGA2ox5-ox plants exhibited increased starch granule accumulation and gravity responses, revealing a role for GA in root starch granule development and gravity responses. Furthermore, rice and Arabidopsis plants overexpressing OsGA2ox5 were more resistant to high-salinity stress than wild-type plants. These results suggest that OsGA2ox5 plays important roles in GAs homeostasis, development, gravity responses and stress tolerance in rice."}
OryzaGP_2021_v2
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OryzaGP_2022
{"project":"OryzaGP_2022","denotations":[{"id":"T1","span":{"begin":934,"end":948},"obj":"http://identifiers.org/oryzabase.gene/2019"}],"text":"OsGA2ox5, a gibberellin metabolism enzyme, is involved in plant growth, the root gravity response and salt stress.\nGibberellin (GA) 2-oxidases play an important role in the GA catabolic pathway through 2β-hydroxylation. There are two classes of GA2oxs, i.e., a larger class of C₁₉-GA2oxs and a smaller class of C₂₀-GA2oxs. In this study, the gene encoding a GA 2-oxidase of rice, Oryza sativa GA 2-oxidase 5 (OsGA2ox5), was cloned and characterized. BLASTP analysis showed that OsGA2ox5 belongs to the C₂₀-GA2oxs subfamily, a subfamily of GA2oxs acting on C₂₀-GAs (GA₁₂, GA₅₃). Subcellular localization of OsGA2ox5-YFP in transiently transformed onion epidermal cells revealed the presence of this protein in both of the nucleus and cytoplasm. Real-time PCR analysis, along with GUS staining, revealed that OsGA2ox5 is expressed in the roots, culms, leaves, sheaths and panicles of rice. Rice plants overexpressing OsGA2ox5 exhibited dominant dwarf and GA-deficient phenotypes, with shorter stems and later development of reproductive organs than the wild type. The dwarfism phenotype was partially rescued by the application of exogenous GA3 at a concentration of 10 µM. Ectopic expression of OsGA2ox5 cDNA in Arabidopsis resulted in a similar phenotype. Real-time PCR assays revealed that both GA synthesis-related genes and GA signaling genes were expressed at higher levels in transgenic rice plants than in wild-type rice; OsGA3ox1, which encodes a key enzyme in the last step of the bioactive GAs synthesis pathway, was highly expressed in transgenic rice. The roots of OsGA2ox5-ox plants exhibited increased starch granule accumulation and gravity responses, revealing a role for GA in root starch granule development and gravity responses. Furthermore, rice and Arabidopsis plants overexpressing OsGA2ox5 were more resistant to high-salinity stress than wild-type plants. These results suggest that OsGA2ox5 plays important roles in GAs homeostasis, development, gravity responses and stress tolerance in rice."}
pqqtest_sentence
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a gibberellin metabolism enzyme, is involved in plant growth, the root gravity response and salt stress.\nGibberellin (GA) 2-oxidases play an important role in the GA catabolic pathway through 2β-hydroxylation. There are two classes of GA2oxs, i.e., a larger class of C₁₉-GA2oxs and a smaller class of C₂₀-GA2oxs. In this study, the gene encoding a GA 2-oxidase of rice, Oryza sativa GA 2-oxidase 5 (OsGA2ox5), was cloned and characterized. BLASTP analysis showed that OsGA2ox5 belongs to the C₂₀-GA2oxs subfamily, a subfamily of GA2oxs acting on C₂₀-GAs (GA₁₂, GA₅₃). Subcellular localization of OsGA2ox5-YFP in transiently transformed onion epidermal cells revealed the presence of this protein in both of the nucleus and cytoplasm. Real-time PCR analysis, along with GUS staining, revealed that OsGA2ox5 is expressed in the roots, culms, leaves, sheaths and panicles of rice. Rice plants overexpressing OsGA2ox5 exhibited dominant dwarf and GA-deficient phenotypes, with shorter stems and later development of reproductive organs than the wild type. The dwarfism phenotype was partially rescued by the application of exogenous GA3 at a concentration of 10 µM. 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OryzaGP_2021_FLAIR
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Ectopic expression of OsGA2ox5 cDNA in Arabidopsis resulted in a similar phenotype. Real-time PCR assays revealed that both GA synthesis-related genes and GA signaling genes were expressed at higher levels in transgenic rice plants than in wild-type rice; OsGA3ox1, which encodes a key enzyme in the last step of the bioactive GAs synthesis pathway, was highly expressed in transgenic rice. The roots of OsGA2ox5-ox plants exhibited increased starch granule accumulation and gravity responses, revealing a role for GA in root starch granule development and gravity responses. Furthermore, rice and Arabidopsis plants overexpressing OsGA2ox5 were more resistant to high-salinity stress than wild-type plants. These results suggest that OsGA2ox5 plays important roles in GAs homeostasis, development, gravity responses and stress tolerance in rice."}
OryzaGP_2021
{"project":"OryzaGP_2021","denotations":[{"id":"T1","span":{"begin":0,"end":8},"obj":"http://identifiers.org/oryzabase.gene/9081"},{"id":"T2","span":{"begin":102,"end":106},"obj":"http://identifiers.org/oryzabase.gene/451"},{"id":"T3","span":{"begin":102,"end":106},"obj":"http://identifiers.org/oryzabase.gene/21170"},{"id":"T4","span":{"begin":393,"end":407},"obj":"http://identifiers.org/oryzabase.gene/9081"},{"id":"T5","span":{"begin":409,"end":417},"obj":"http://identifiers.org/oryzabase.gene/9081"},{"id":"T6","span":{"begin":478,"end":486},"obj":"http://identifiers.org/oryzabase.gene/9081"},{"id":"T7","span":{"begin":606,"end":614},"obj":"http://identifiers.org/oryzabase.gene/9081"},{"id":"T8","span":{"begin":807,"end":815},"obj":"http://identifiers.org/oryzabase.gene/9081"},{"id":"T9","span":{"begin":915,"end":923},"obj":"http://identifiers.org/oryzabase.gene/9081"},{"id":"T10","span":{"begin":934,"end":948},"obj":"http://identifiers.org/oryzabase.gene/2019"},{"id":"T11","span":{"begin":1139,"end":1142},"obj":"http://identifiers.org/oryzabase.gene/527"},{"id":"T12","span":{"begin":1194,"end":1202},"obj":"http://identifiers.org/oryzabase.gene/9081"},{"id":"T13","span":{"begin":1428,"end":1436},"obj":"http://identifiers.org/oryzabase.gene/2278"},{"id":"T14","span":{"begin":1576,"end":1584},"obj":"http://identifiers.org/oryzabase.gene/9081"},{"id":"T15","span":{"begin":1804,"end":1812},"obj":"http://identifiers.org/oryzabase.gene/9081"},{"id":"T16","span":{"begin":1907,"end":1915},"obj":"http://identifiers.org/oryzabase.gene/9081"},{"id":"T25835","span":{"begin":0,"end":8},"obj":"http://identifiers.org/ricegap/LOC_Os07g01340"},{"id":"T86088","span":{"begin":102,"end":106},"obj":"http://identifiers.org/ricegap/LOC_Os11g07450"},{"id":"T59479","span":{"begin":102,"end":106},"obj":"http://identifiers.org/ricegap/LOC_Os01g24710"},{"id":"T71825","span":{"begin":393,"end":407},"obj":"http://identifiers.org/ricegap/LOC_Os07g01340"},{"id":"T24705","span":{"begin":409,"end":417},"obj":"http://identifiers.org/ricegap/LOC_Os07g01340"},{"id":"T5610","span":{"begin":478,"end":486},"obj":"http://identifiers.org/ricegap/LOC_Os07g01340"},{"id":"T53342","span":{"begin":606,"end":614},"obj":"http://identifiers.org/ricegap/LOC_Os07g01340"},{"id":"T99250","span":{"begin":807,"end":815},"obj":"http://identifiers.org/ricegap/LOC_Os07g01340"},{"id":"T62851","span":{"begin":915,"end":923},"obj":"http://identifiers.org/ricegap/LOC_Os07g01340"},{"id":"T57663","span":{"begin":934,"end":948},"obj":"http://identifiers.org/ricegap/LOC_Os01g10460"},{"id":"T11477","span":{"begin":1194,"end":1202},"obj":"http://identifiers.org/ricegap/LOC_Os07g01340"},{"id":"T23983","span":{"begin":1428,"end":1436},"obj":"http://identifiers.org/ricegap/LOC_Os05g08540"},{"id":"T49828","span":{"begin":1576,"end":1584},"obj":"http://identifiers.org/ricegap/LOC_Os07g01340"},{"id":"T54216","span":{"begin":1804,"end":1812},"obj":"http://identifiers.org/ricegap/LOC_Os07g01340"},{"id":"T97599","span":{"begin":1907,"end":1915},"obj":"http://identifiers.org/ricegap/LOC_Os07g01340"},{"id":"T53186","span":{"begin":0,"end":8},"obj":"http://identifiers.org/rapdb.locus/Os07g0103500"},{"id":"T99008","span":{"begin":102,"end":106},"obj":"http://identifiers.org/rapdb.locus/Os11g0175500"},{"id":"T22942","span":{"begin":102,"end":106},"obj":"http://identifiers.org/rapdb.locus/Os01g0348900"},{"id":"T54730","span":{"begin":393,"end":407},"obj":"http://identifiers.org/rapdb.locus/Os07g0103500"},{"id":"T2017","span":{"begin":409,"end":417},"obj":"http://identifiers.org/rapdb.locus/Os07g0103500"},{"id":"T80383","span":{"begin":478,"end":486},"obj":"http://identifiers.org/rapdb.locus/Os07g0103500"},{"id":"T63926","span":{"begin":606,"end":614},"obj":"http://identifiers.org/rapdb.locus/Os07g0103500"},{"id":"T95465","span":{"begin":807,"end":815},"obj":"http://identifiers.org/rapdb.locus/Os07g0103500"},{"id":"T97036","span":{"begin":915,"end":923},"obj":"http://identifiers.org/rapdb.locus/Os07g0103500"},{"id":"T77371","span":{"begin":934,"end":948},"obj":"http://identifiers.org/rapdb.locus/Os01g0201275"},{"id":"T1544","span":{"begin":1194,"end":1202},"obj":"http://identifiers.org/rapdb.locus/Os07g0103500"},{"id":"T87104","span":{"begin":1428,"end":1436},"obj":"http://identifiers.org/rapdb.locus/Os05g0178100"},{"id":"T97456","span":{"begin":1576,"end":1584},"obj":"http://identifiers.org/rapdb.locus/Os07g0103500"},{"id":"T40400","span":{"begin":1804,"end":1812},"obj":"http://identifiers.org/rapdb.locus/Os07g0103500"},{"id":"T480","span":{"begin":1907,"end":1915},"obj":"http://identifiers.org/rapdb.locus/Os07g0103500"},{"id":"T80832","span":{"begin":0,"end":8},"obj":"http://identifiers.org/uniprot/A2YHB5"},{"id":"T91598","span":{"begin":102,"end":106},"obj":"http://identifiers.org/uniprot/Q53PH3"},{"id":"T89942","span":{"begin":102,"end":106},"obj":"http://identifiers.org/uniprot/B9G9N6"},{"id":"T9935","span":{"begin":393,"end":407},"obj":"http://identifiers.org/uniprot/A2YHB5"},{"id":"T78324","span":{"begin":409,"end":417},"obj":"http://identifiers.org/uniprot/A2YHB5"},{"id":"T49668","span":{"begin":478,"end":486},"obj":"http://identifiers.org/uniprot/A2YHB5"},{"id":"T39765","span":{"begin":606,"end":614},"obj":"http://identifiers.org/uniprot/A2YHB5"},{"id":"T9463","span":{"begin":807,"end":815},"obj":"http://identifiers.org/uniprot/A2YHB5"},{"id":"T52057","span":{"begin":915,"end":923},"obj":"http://identifiers.org/uniprot/A2YHB5"},{"id":"T48438","span":{"begin":934,"end":948},"obj":"http://identifiers.org/uniprot/Q5QN07"},{"id":"T88327","span":{"begin":1194,"end":1202},"obj":"http://identifiers.org/uniprot/A2YHB5"},{"id":"T27617","span":{"begin":1428,"end":1436},"obj":"http://identifiers.org/uniprot/Q94IE3"},{"id":"T74373","span":{"begin":1428,"end":1436},"obj":"http://identifiers.org/uniprot/Q6AT12"},{"id":"T22898","span":{"begin":1576,"end":1584},"obj":"http://identifiers.org/uniprot/A2YHB5"},{"id":"T71423","span":{"begin":1804,"end":1812},"obj":"http://identifiers.org/uniprot/A2YHB5"},{"id":"T95170","span":{"begin":1907,"end":1915},"obj":"http://identifiers.org/uniprot/A2YHB5"},{"id":"M_0","span":{"begin":380,"end":392},"obj":"hunflair:NA:Species"},{"id":"M_1","span":{"begin":245,"end":251},"obj":"hunflair:NA:Gene"},{"id":"M_2","span":{"begin":281,"end":287},"obj":"hunflair:NA:Gene"},{"id":"M_3","span":{"begin":315,"end":321},"obj":"hunflair:NA:Gene"},{"id":"M_4","span":{"begin":506,"end":512},"obj":"hunflair:NA:Gene"},{"id":"M_5","span":{"begin":539,"end":545},"obj":"hunflair:NA:Gene"},{"id":"M_6","span":{"begin":888,"end":899},"obj":"hunflair:NA:Species"},{"id":"M_7","span":{"begin":128,"end":130},"obj":"hunflair:NA:Gene"},{"id":"M_8","span":{"begin":173,"end":175},"obj":"hunflair:NA:Gene"},{"id":"M_9","span":{"begin":358,"end":360},"obj":"hunflair:NA:Gene"},{"id":"M_10","span":{"begin":393,"end":395},"obj":"hunflair:NA:Gene"},{"id":"M_11","span":{"begin":953,"end":955},"obj":"hunflair:NA:Gene"},{"id":"M_12","span":{"begin":1296,"end":1298},"obj":"hunflair:NA:Gene"},{"id":"M_13","span":{"begin":1327,"end":1329},"obj":"hunflair:NA:Gene"},{"id":"M_14","span":{"begin":1687,"end":1689},"obj":"hunflair:NA:Gene"},{"id":"M_15","span":{"begin":393,"end":407},"obj":"hunflair:NA:Gene"},{"id":"M_16","span":{"begin":374,"end":378},"obj":"hunflair:NA:Species"},{"id":"M_17","span":{"begin":882,"end":886},"obj":"hunflair:NA:Species"},{"id":"M_18","span":{"begin":1392,"end":1396},"obj":"hunflair:NA:Species"},{"id":"M_19","span":{"begin":1422,"end":1426},"obj":"hunflair:NA:Species"},{"id":"M_20","span":{"begin":1557,"end":1561},"obj":"hunflair:NA:Species"},{"id":"M_21","span":{"begin":1761,"end":1765},"obj":"hunflair:NA:Species"},{"id":"M_22","span":{"begin":2013,"end":2017},"obj":"hunflair:NA:Species"},{"id":"M_23","span":{"begin":560,"end":563},"obj":"hunflair:NA:Chemical"},{"id":"M_24","span":{"begin":1499,"end":1502},"obj":"hunflair:NA:Chemical"},{"id":"M_25","span":{"begin":1941,"end":1944},"obj":"hunflair:NA:Chemical"},{"id":"M_26","span":{"begin":502,"end":522},"obj":"hunflair:NA:Gene"},{"id":"M_27","span":{"begin":115,"end":126},"obj":"hunflair:NA:Chemical"},{"id":"M_28","span":{"begin":571,"end":575},"obj":"hunflair:NA:Gene"},{"id":"M_29","span":{"begin":1211,"end":1222},"obj":"hunflair:NA:Species"},{"id":"M_30","span":{"begin":1770,"end":1781},"obj":"hunflair:NA:Species"},{"id":"M_31","span":{"begin":1066,"end":1074},"obj":"hunflair:NA:Disease"},{"id":"M_32","span":{"begin":646,"end":651},"obj":"hunflair:NA:Species"},{"id":"M_33","span":{"begin":606,"end":618},"obj":"hunflair:NA:Gene"},{"id":"M_34","span":{"begin":1139,"end":1142},"obj":"hunflair:NA:Chemical"},{"id":"M_35","span":{"begin":358,"end":370},"obj":"hunflair:NA:Gene"},{"id":"M_36","span":{"begin":393,"end":405},"obj":"hunflair:NA:Gene"},{"id":"M_37","span":{"begin":1428,"end":1436},"obj":"hunflair:NA:Gene"},{"id":"M_38","span":{"begin":779,"end":782},"obj":"hunflair:NA:Gene"},{"id":"M_39","span":{"begin":943,"end":948},"obj":"hunflair:NA:Gene"},{"id":"M_40","span":{"begin":1576,"end":1587},"obj":"hunflair:NA:Gene"},{"id":"M_41","span":{"begin":0,"end":8},"obj":"hunflair:NA:Gene"},{"id":"M_42","span":{"begin":409,"end":417},"obj":"hunflair:NA:Gene"},{"id":"M_43","span":{"begin":478,"end":486},"obj":"hunflair:NA:Gene"},{"id":"M_44","span":{"begin":606,"end":614},"obj":"hunflair:NA:Gene"},{"id":"M_45","span":{"begin":807,"end":815},"obj":"hunflair:NA:Gene"},{"id":"M_46","span":{"begin":915,"end":923},"obj":"hunflair:NA:Gene"},{"id":"M_47","span":{"begin":1194,"end":1202},"obj":"hunflair:NA:Gene"},{"id":"M_48","span":{"begin":1576,"end":1584},"obj":"hunflair:NA:Gene"},{"id":"M_49","span":{"begin":1804,"end":1812},"obj":"hunflair:NA:Gene"},{"id":"M_50","span":{"begin":1907,"end":1915},"obj":"hunflair:NA:Gene"}],"text":"OsGA2ox5, a gibberellin metabolism enzyme, is involved in plant growth, the root gravity response and salt stress.\nGibberellin (GA) 2-oxidases play an important role in the GA catabolic pathway through 2β-hydroxylation. There are two classes of GA2oxs, i.e., a larger class of C₁₉-GA2oxs and a smaller class of C₂₀-GA2oxs. In this study, the gene encoding a GA 2-oxidase of rice, Oryza sativa GA 2-oxidase 5 (OsGA2ox5), was cloned and characterized. BLASTP analysis showed that OsGA2ox5 belongs to the C₂₀-GA2oxs subfamily, a subfamily of GA2oxs acting on C₂₀-GAs (GA₁₂, GA₅₃). Subcellular localization of OsGA2ox5-YFP in transiently transformed onion epidermal cells revealed the presence of this protein in both of the nucleus and cytoplasm. Real-time PCR analysis, along with GUS staining, revealed that OsGA2ox5 is expressed in the roots, culms, leaves, sheaths and panicles of rice. Rice plants overexpressing OsGA2ox5 exhibited dominant dwarf and GA-deficient phenotypes, with shorter stems and later development of reproductive organs than the wild type. The dwarfism phenotype was partially rescued by the application of exogenous GA3 at a concentration of 10 µM. Ectopic expression of OsGA2ox5 cDNA in Arabidopsis resulted in a similar phenotype. Real-time PCR assays revealed that both GA synthesis-related genes and GA signaling genes were expressed at higher levels in transgenic rice plants than in wild-type rice; OsGA3ox1, which encodes a key enzyme in the last step of the bioactive GAs synthesis pathway, was highly expressed in transgenic rice. The roots of OsGA2ox5-ox plants exhibited increased starch granule accumulation and gravity responses, revealing a role for GA in root starch granule development and gravity responses. Furthermore, rice and Arabidopsis plants overexpressing OsGA2ox5 were more resistant to high-salinity stress than wild-type plants. These results suggest that OsGA2ox5 plays important roles in GAs homeostasis, development, gravity responses and stress tolerance in rice."}
PubmedHPO
{"project":"PubmedHPO","denotations":[{"id":"T1","span":{"begin":1066,"end":1074},"obj":"HP_0003510"}],"text":"OsGA2ox5, a gibberellin metabolism enzyme, is involved in plant growth, the root gravity response and salt stress.\nGibberellin (GA) 2-oxidases play an important role in the GA catabolic pathway through 2β-hydroxylation. There are two classes of GA2oxs, i.e., a larger class of C₁₉-GA2oxs and a smaller class of C₂₀-GA2oxs. In this study, the gene encoding a GA 2-oxidase of rice, Oryza sativa GA 2-oxidase 5 (OsGA2ox5), was cloned and characterized. BLASTP analysis showed that OsGA2ox5 belongs to the C₂₀-GA2oxs subfamily, a subfamily of GA2oxs acting on C₂₀-GAs (GA₁₂, GA₅₃). Subcellular localization of OsGA2ox5-YFP in transiently transformed onion epidermal cells revealed the presence of this protein in both of the nucleus and cytoplasm. Real-time PCR analysis, along with GUS staining, revealed that OsGA2ox5 is expressed in the roots, culms, leaves, sheaths and panicles of rice. Rice plants overexpressing OsGA2ox5 exhibited dominant dwarf and GA-deficient phenotypes, with shorter stems and later development of reproductive organs than the wild type. The dwarfism phenotype was partially rescued by the application of exogenous GA3 at a concentration of 10 µM. Ectopic expression of OsGA2ox5 cDNA in Arabidopsis resulted in a similar phenotype. Real-time PCR assays revealed that both GA synthesis-related genes and GA signaling genes were expressed at higher levels in transgenic rice plants than in wild-type rice; OsGA3ox1, which encodes a key enzyme in the last step of the bioactive GAs synthesis pathway, was highly expressed in transgenic rice. The roots of OsGA2ox5-ox plants exhibited increased starch granule accumulation and gravity responses, revealing a role for GA in root starch granule development and gravity responses. Furthermore, rice and Arabidopsis plants overexpressing OsGA2ox5 were more resistant to high-salinity stress than wild-type plants. These results suggest that OsGA2ox5 plays important roles in GAs homeostasis, development, gravity responses and stress tolerance in rice."}
Allie
{"project":"Allie","denotations":[{"id":"SS1_24475234_3_0","span":{"begin":380,"end":407},"obj":"expanded"},{"id":"SS2_24475234_3_0","span":{"begin":409,"end":417},"obj":"abbr"}],"relations":[{"id":"AE1_24475234_3_0","pred":"abbreviatedTo","subj":"SS1_24475234_3_0","obj":"SS2_24475234_3_0"}],"text":"OsGA2ox5, a gibberellin metabolism enzyme, is involved in plant growth, the root gravity response and salt stress.\nGibberellin (GA) 2-oxidases play an important role in the GA catabolic pathway through 2β-hydroxylation. There are two classes of GA2oxs, i.e., a larger class of C₁₉-GA2oxs and a smaller class of C₂₀-GA2oxs. In this study, the gene encoding a GA 2-oxidase of rice, Oryza sativa GA 2-oxidase 5 (OsGA2ox5), was cloned and characterized. BLASTP analysis showed that OsGA2ox5 belongs to the C₂₀-GA2oxs subfamily, a subfamily of GA2oxs acting on C₂₀-GAs (GA₁₂, GA₅₃). Subcellular localization of OsGA2ox5-YFP in transiently transformed onion epidermal cells revealed the presence of this protein in both of the nucleus and cytoplasm. Real-time PCR analysis, along with GUS staining, revealed that OsGA2ox5 is expressed in the roots, culms, leaves, sheaths and panicles of rice. Rice plants overexpressing OsGA2ox5 exhibited dominant dwarf and GA-deficient phenotypes, with shorter stems and later development of reproductive organs than the wild type. The dwarfism phenotype was partially rescued by the application of exogenous GA3 at a concentration of 10 µM. Ectopic expression of OsGA2ox5 cDNA in Arabidopsis resulted in a similar phenotype. Real-time PCR assays revealed that both GA synthesis-related genes and GA signaling genes were expressed at higher levels in transgenic rice plants than in wild-type rice; OsGA3ox1, which encodes a key enzyme in the last step of the bioactive GAs synthesis pathway, was highly expressed in transgenic rice. The roots of OsGA2ox5-ox plants exhibited increased starch granule accumulation and gravity responses, revealing a role for GA in root starch granule development and gravity responses. Furthermore, rice and Arabidopsis plants overexpressing OsGA2ox5 were more resistant to high-salinity stress than wild-type plants. These results suggest that OsGA2ox5 plays important roles in GAs homeostasis, development, gravity responses and stress tolerance in rice."}
OryzaGP
{"project":"OryzaGP","denotations":[{"id":"T1","span":{"begin":0,"end":8},"obj":"gene"},{"id":"T2","span":{"begin":606,"end":614},"obj":"gene"},{"id":"T3","span":{"begin":807,"end":815},"obj":"gene"},{"id":"T4","span":{"begin":1428,"end":1436},"obj":"gene"},{"id":"T5","span":{"begin":1804,"end":1812},"obj":"gene"},{"id":"T6","span":{"begin":1907,"end":1915},"obj":"gene"}],"text":"OsGA2ox5, a gibberellin metabolism enzyme, is involved in plant growth, the root gravity response and salt stress.\nGibberellin (GA) 2-oxidases play an important role in the GA catabolic pathway through 2β-hydroxylation. There are two classes of GA2oxs, i.e., a larger class of C₁₉-GA2oxs and a smaller class of C₂₀-GA2oxs. In this study, the gene encoding a GA 2-oxidase of rice, Oryza sativa GA 2-oxidase 5 (OsGA2ox5), was cloned and characterized. BLASTP analysis showed that OsGA2ox5 belongs to the C₂₀-GA2oxs subfamily, a subfamily of GA2oxs acting on C₂₀-GAs (GA₁₂, GA₅₃). Subcellular localization of OsGA2ox5-YFP in transiently transformed onion epidermal cells revealed the presence of this protein in both of the nucleus and cytoplasm. Real-time PCR analysis, along with GUS staining, revealed that OsGA2ox5 is expressed in the roots, culms, leaves, sheaths and panicles of rice. Rice plants overexpressing OsGA2ox5 exhibited dominant dwarf and GA-deficient phenotypes, with shorter stems and later development of reproductive organs than the wild type. The dwarfism phenotype was partially rescued by the application of exogenous GA3 at a concentration of 10 µM. Ectopic expression of OsGA2ox5 cDNA in Arabidopsis resulted in a similar phenotype. Real-time PCR assays revealed that both GA synthesis-related genes and GA signaling genes were expressed at higher levels in transgenic rice plants than in wild-type rice; OsGA3ox1, which encodes a key enzyme in the last step of the bioactive GAs synthesis pathway, was highly expressed in transgenic rice. The roots of OsGA2ox5-ox plants exhibited increased starch granule accumulation and gravity responses, revealing a role for GA in root starch granule development and gravity responses. Furthermore, rice and Arabidopsis plants overexpressing OsGA2ox5 were more resistant to high-salinity stress than wild-type plants. These results suggest that OsGA2ox5 plays important roles in GAs homeostasis, development, gravity responses and stress tolerance in rice."}