6 research outputs found
Not Available
Not AvailableA rapid and reproducible method to develop transgenic plants with enhanced transformation
efficiency using Agrobacterium has been developed for the elite indica rice variety BPT 5204. Different
rice calli aged from 3 to 30 d were co-cultivated with pre-incubated Agrobacterium suspension culture
(LBA4404: pSB1, pCAMBIA1301) and incubated in dark for 3 d. Based on the transient GUS gene
expression analysis, 6-day-old young calli showed high transformation frequency followed by 21-day-old
ones. Thus, both 6- and 21-day-old calli were used for assessing the stable transformation efficiency. It
was observed that the 6-day-old young transformed calli showed about 2-fold higher regeneration
frequency when compared with 21-day-old calli. The transformation efficiency was enhanced for young
calli to 5.9% compared with 0.8% of the 21-day-old calli. Molecular and genetic analysis of transgenic
plants (T0) revealed the presence of 1–2 copies of T-DNA integration in transformants and it follows
Mendalian ratio in T1 transgenic plants. From the present study, it was concluded that the development
of transgenic rice plants in less duration with high regeneration and transformation efficiency was
achieved in BPT 5204 by using 6-day-old young calli as explants.Not Availabl
Not Available
Not AvailableA rapid and reproducible method to develop transgenic plants with enhanced transformation efficiency using Agrobacterium has been developed for the elite indica rice variety BPT 5204. Different rice calli aged from 3 to 30 d were co-cultivated with pre-incubated Agrobacterium suspension culture (LBA4404: pSB1, pCAMBIA1301) and incubated in dark for 3 d. Based on the transient GUS gene expression analysis, 6-day-old young calli showed high transformation frequency followed by 21-day-old ones. Thus, both 6- and 21-day-old calli were used for assessing the stable transformation efficiency. It was observed that the 6-day-old young transformed calli showed about 2-fold higher regeneration frequency when compared with 21-day-old calli. The transformation efficiency was enhanced for young calli to 5.9% compared with 0.8% of the 21-day-old calli. Molecular and genetic analysis of transgenic plants (T0) revealed the presence of 1-2 copies of T-DNA integration in transformants and it follows Mendalian ratio in T1transgenic plants. From the present study, it was concluded that the development of transgenic rice plants in less duration with high regeneration and transformation efficiency was achieved in BPT 5204 by using 6-day-old young calli as explants. © 2013 China National Rice Research Institute.Not Availabl
Not Available
Not AvailableNot RNAi mediated silencing of pectin degrading enzyme of R. solani gives a high level of resistance against sheath blight disease of rice. Rice sheath blight disease caused by Rhizoctonia solani Kuhn (telemorph; Thanatephorus cucumeris) is one of the most devastating fungal diseases which cause severe loss to rice grain production. In the absence of resistant cultivars, the disease is currently managed through fungicides which add to environmental pollution. To explore the potential of utilizing RNA interference (RNAi)-mediated resistance against sheath blight disease, we identified genes encoding proteins and enzymes involved in the RNAi pathway in this fungal pathogen. The RNAi target genes were deciphered by RNAseq analysis of a highly virulent strain of the R. solani grown in pectin medium. Additionally, pectin metabolism associated genes of R. solani were analyzed through transcriptome sequencing of infected rice tissues obtained from six diverse rice cultivars. One of the key candidate gene AG1IA_04727 encoding polygalacturonase (PG), which was observed to be significantly upregulated during infection, was targeted through RNAi to develop disease resistance. Stable expression of PG-RNAi construct in rice showed efficient silencing of AG1IA_04727 and suppression of sheath blight disease. This study highlights important information about the existence of RNAi machinery and key genes of R. solani which can be targeted through RNAi to develop pathogen-derived resistance, thus opening an alternative strategy for developing sheath blight-resistant rice cultivars.Not Availabl