Project description:Near-isogenic lines TW16-1263 and TW16-1029 were developed from the cross between TN1 (recurrent parent susceptible to rice tungro spherical virus (RTSV)) and Utri Merah (donor parent resistant to RTSV). TW16-1263 is susceptible to RTSV, whereas TW16-1029 is resistant to RTSV. In order to identify genes which are constitutively differentially expressed between TW16-1263 and TW16-1029, the gene expression in the two lines were compared at three different conditions (healthy, green leafhopper (GLH)-inoculated, and RTSV-inoculated). Experiment Overall Design: Total RNA was isolated from 14-day old plants of TW16-1263 and TW16-1029 at three different conditions (healthy, GLH-inoculated, and RTSV-inoculated). The levels of gene expression in the two lines of the same condition were compared by microarray. Each experiment was repeated twice.

Project description:Near-isogenic lines TW16-4 and TW16-69 were developed from the cross between TN1 (recurrent parent susceptible to RTSV) and Utri Merah (donor parent resistant to RTSV). TW16-4 is susceptible to RTSV, whereas TW16-69 is resistant to RTSV based on a serolog. Experiment Overall Design: Comparison between RTSV and mock-infected rice. Biological replicates: 2 control (mock), 2 RTSV-infected, independently grown and harvested at 7 days after inoculation (DAI). Each sample was prepared using leaf tissues pooled from 5 plants grown under the same conditions.

Project description:Near-isogenic lines TW16-4 and TW16-69 were developed from the cross between TN1 (recurrent parent susceptible to rice tungro spherical virus (RTSV)) and Utri Merah (donor parent resistant to RTSV). TW16-4 is susceptible to RTSV, whereas TW16-69 is resistant to RTSV. In order to identify genes which are constitutively differentially expressed between TW16-4 and TW16-69, the gene expression in the two lines were compared at three different conditions (healthy, green leafhopper (GLH)-inoculated, and RTSV-inoculated). Keywords: Constitutive differential expression

Project description:Near-isogenic lines TW16-4 and TW16-69 were developed from the cross between TN1 (recurrent parent susceptible to RTSV) and Utri Merah (donor parent resistant to RTSV). TW16-4 is susceptible to RTSV, whereas TW16-69 is resistant to RTSV based on a serolog. Keywords: time course, virus infection, disease response

Project description:Near-isogenic lines TW16-1263 and TW16-1029 were developed from the cross between TN1 (recurrent parent susceptible to rice tungro spherical virus (RTSV)) and Utri Merah (donor parent resistant to RTSV). TW16-1263 is susceptible to RTSV, whereas TW16-1029 is resistant to RTSV. In order to identify genes which are constitutively differentially expressed between TW16-1263 and TW16-1029, the gene expression in the two lines were compared at three different conditions (healthy, green leafhopper (GLH)-inoculated, and RTSV-inoculated). Keywords: Constitutive differential expression

Project description:Rice tungro disease is caused by the interaction between Rice tungro spherical virus (RTSV) and Rice tungro bacilliform virus. Infection with RTSV alone does not result in any distinctive symptoms in TW16 that is one of RTSV resistant indica rice. To elucidate the basis of asymptomatic response of rice to RTSV at the gene expression level, global gene response in RTSV-infected TN1 was detected by custom microarray. Keywords: time course, virus infection, disease response Comparison between RTSV and mock infected rice. Biological replicates: 3 control (mock), 3 RTSV-infected at each time point, independently grown and harvested at 6 to 15 days after inoculation (DAI). 1 samples prepared with whole plant 5 cm above ground and pooled from 5 plants grown under same conditons.

Project description:Near-isogenic lines NIL37 and NIL22 were developed from the cross between Ilpum (recurrent parent susceptible to rice stripe virus (RSV)) and Shinkwang (donor parent resistant to RSV). NIL37 is susceptible to RSV, whereas NIL22 is resistant to RSV. In order to identify genes which are constitutively differentially expressed between NIL37 and NIL22, the gene expression in the two lines were compared at two different conditions (healthy, and RSV-inoculated). Experiment Overall Design: Total RNA was isolated from 14-day old plants of NIL37 and NIL22 at two different conditions (healthy and RSV-inoculated). The levels of gene expression in the two lines of the same condition were compared by microarray. Each experiment was repeated twice.

Project description:Rice tungro disease is caused by the interaction between Rice tungro spherical virus (RTSV) and Rice tungro bacilliform virus. Infection with RTSV alone does not result in any distinctive symptoms in Taichung Native 1 (TN1) that is one of RTSV susceptive indica rice cultivar. To elucidate the basis of asymptomatic response of rice to RTSV at the gene expression level, global gene response in RTSV-infected TN1 was detected by custom microarray. Keywords: time course, virus infection, disease response Comparison between RTSV and mock infected rice. Biological replicates: 3 control (mock), 3 RTSV-infected at each time point, independently grown and harvested at 6 to 15 days after inoculation (DAI). 1 samples prepared with whole plant 5 cm above ground and pooled from 5 plants grown under same conditons.

Project description:This SuperSeries is composed of the following subset Series: GSE16140: Transcriptome analysis of rice (Oryza sativa cv.TW16) in relation to infection with rice tungro spherical virus (RTSV) GSE16141: Transcriptome analysis of rice (Oryza sativa cv. Taichung Native 1) in relation to infection with RTSV Refer to individual Series

Project description:Rice tungro disease is caused by the interaction between Rice tungro spherical virus (RTSV) and Rice tungro bacilliform virus. Infection with RTSV alone does not result in any distinctive symptoms in TW16 that is one of RTSV resistant indica rice. To elucidate the basis of asymptomatic response of rice to RTSV at the gene expression level, global gene response in RTSV-infected TN1 was detected by custom microarray. Keywords: time course, virus infection, disease response