PubMed:27628577 JSONTXT

{"project":"21k_plant_trait_mention","denotations":[{"id":"M_0","span":{"begin":129,"end":134},"obj":"WTO:0000006"},{"id":"M_1","span":{"begin":241,"end":246},"obj":"WTO:0000006"},{"id":"M_2","span":{"begin":76,"end":87},"obj":"funRiceGene:312, xzyao:11323"},{"id":"M_3","span":{"begin":623,"end":634},"obj":"funRiceGene:312, xzyao:11323"},{"id":"M_4","span":{"begin":82,"end":87},"obj":"funRiceGene:377"},{"id":"M_5","span":{"begin":403,"end":408},"obj":"funRiceGene:377"},{"id":"M_6","span":{"begin":629,"end":634},"obj":"funRiceGene:377"},{"id":"M_7","span":{"begin":76,"end":81},"obj":"funRiceGene:91"},{"id":"M_8","span":{"begin":623,"end":628},"obj":"funRiceGene:91"},{"id":"M_9","span":{"begin":60,"end":64},"obj":"hunflair:NA:Species"},{"id":"M_10","span":{"begin":533,"end":537},"obj":"hunflair:NA:Species"},{"id":"M_11","span":{"begin":60,"end":64},"obj":"pubtator:4530:Species"},{"id":"M_12","span":{"begin":533,"end":537},"obj":"pubtator:4530:Species"}],"text":"QTL editing confers opposing yield performance in different rice varieties.\nGrain yield is one of the most important and complex trait for genetic improvement in crops; it is known to be controlled by a number of genes known as quantitative trait loci (QTLs). In the past decade, many yield-contributing QTLs have been identified in crops. However, it remains unclear whether those QTLs confer the same yield performance in different genetic backgrounds. Here, we performed CRISPR/Cas9-mediated QTL editing in five widely-cultivated rice varieties and revealed that the same QTL can have diverse, even opposing, effects on grain yield in different genetic backgrounds."}

{"project":"OryzaGP_2021","denotations":[{"id":"T1","span":{"begin":623,"end":634},"obj":"http://identifiers.org/oryzabase.gene/2034"},{"id":"T20874","span":{"begin":76,"end":87},"obj":"http://identifiers.org/ricegap/LOC_Os08g07740"},{"id":"T2","span":{"begin":623,"end":634},"obj":"http://identifiers.org/ricegap/LOC_Os08g07740"},{"id":"T74268","span":{"begin":76,"end":87},"obj":"http://identifiers.org/rapdb.locus/Os08g0174500"},{"id":"T8307","span":{"begin":623,"end":634},"obj":"http://identifiers.org/rapdb.locus/Os08g0174500"},{"id":"M_0","span":{"begin":60,"end":64},"obj":"hunflair:NA:Species"},{"id":"M_1","span":{"begin":533,"end":537},"obj":"hunflair:NA:Species"}],"text":"QTL editing confers opposing yield performance in different rice varieties.\nGrain yield is one of the most important and complex trait for genetic improvement in crops; it is known to be controlled by a number of genes known as quantitative trait loci (QTLs). In the past decade, many yield-contributing QTLs have been identified in crops. However, it remains unclear whether those QTLs confer the same yield performance in different genetic backgrounds. Here, we performed CRISPR/Cas9-mediated QTL editing in five widely-cultivated rice varieties and revealed that the same QTL can have diverse, even opposing, effects on grain yield in different genetic backgrounds."}

{"project":"pqqtest_sentence","denotations":[{"id":"M_0","span":{"begin":228,"end":251},"obj":"xzyao:20915"},{"id":"M_1","span":{"begin":76,"end":87},"obj":"funRiceGene:312, xzyao:28456"},{"id":"M_2","span":{"begin":623,"end":634},"obj":"funRiceGene:312, xzyao:28456"},{"id":"M_3","span":{"begin":29,"end":34},"obj":"funRiceGene:377"},{"id":"M_4","span":{"begin":82,"end":87},"obj":"funRiceGene:377"},{"id":"M_5","span":{"begin":285,"end":290},"obj":"funRiceGene:377"},{"id":"M_6","span":{"begin":403,"end":408},"obj":"funRiceGene:377"},{"id":"M_7","span":{"begin":629,"end":634},"obj":"funRiceGene:377"},{"id":"M_8","span":{"begin":76,"end":81},"obj":"funRiceGene:91"},{"id":"M_9","span":{"begin":623,"end":628},"obj":"funRiceGene:91"},{"id":"M_10","span":{"begin":424,"end":453},"obj":"xzyao:35950"},{"id":"M_11","span":{"begin":638,"end":667},"obj":"xzyao:35950"},{"id":"M_12","span":{"begin":228,"end":246},"obj":"xzyao:12182"},{"id":"M_13","span":{"begin":129,"end":134},"obj":"WTO:0000006"},{"id":"M_14","span":{"begin":241,"end":246},"obj":"WTO:0000006"},{"id":"M_15","span":{"begin":139,"end":158},"obj":"xzyao:38537"},{"id":"M_16","span":{"begin":522,"end":537},"obj":"xzyao:44209"},{"id":"M_17","span":{"begin":60,"end":64},"obj":"hunflair:NA:Species"},{"id":"M_18","span":{"begin":533,"end":537},"obj":"hunflair:NA:Species"},{"id":"M_19","span":{"begin":60,"end":64},"obj":"pubtator:4530:Species"},{"id":"M_20","span":{"begin":533,"end":537},"obj":"pubtator:4530:Species"}],"text":"QTL editing confers opposing yield performance in different rice varieties.\nGrain yield is one of the most important and complex trait for genetic improvement in crops; it is known to be controlled by a number of genes known as quantitative trait loci (QTLs). In the past decade, many yield-contributing QTLs have been identified in crops. However, it remains unclear whether those QTLs confer the same yield performance in different genetic backgrounds. Here, we performed CRISPR/Cas9-mediated QTL editing in five widely-cultivated rice varieties and revealed that the same QTL can have diverse, even opposing, effects on grain yield in different genetic backgrounds."}

{"project":"OryzaGP_2021_FLAIR","denotations":[{"id":"M_0","span":{"begin":60,"end":64},"obj":"hunflair:NA:Species"},{"id":"M_1","span":{"begin":533,"end":537},"obj":"hunflair:NA:Species"}],"text":"QTL editing confers opposing yield performance in different rice varieties.\nGrain yield is one of the most important and complex trait for genetic improvement in crops; it is known to be controlled by a number of genes known as quantitative trait loci (QTLs). In the past decade, many yield-contributing QTLs have been identified in crops. However, it remains unclear whether those QTLs confer the same yield performance in different genetic backgrounds. Here, we performed CRISPR/Cas9-mediated QTL editing in five widely-cultivated rice varieties and revealed that the same QTL can have diverse, even opposing, effects on grain yield in different genetic backgrounds."}

{"project":"Oryza_sentences","blocks":[{"id":"T1","span":{"begin":0,"end":75},"obj":"Sentence"},{"id":"T2","span":{"begin":76,"end":259},"obj":"Sentence"},{"id":"T3","span":{"begin":260,"end":339},"obj":"Sentence"},{"id":"T4","span":{"begin":340,"end":454},"obj":"Sentence"},{"id":"T5","span":{"begin":455,"end":668},"obj":"Sentence"}],"text":"QTL editing confers opposing yield performance in different rice varieties.\nGrain yield is one of the most important and complex trait for genetic improvement in crops; it is known to be controlled by a number of genes known as quantitative trait loci (QTLs). In the past decade, many yield-contributing QTLs have been identified in crops. However, it remains unclear whether those QTLs confer the same yield performance in different genetic backgrounds. Here, we performed CRISPR/Cas9-mediated QTL editing in five widely-cultivated rice varieties and revealed that the same QTL can have diverse, even opposing, effects on grain yield in different genetic backgrounds."}