Project description:Petunia is an excellent model system, especially for genetic, physiological and molecular studies. Thus far, however, genome-wide expression analysis has been rarely applied because of the lack of sequence information. We applied next-generation sequencing to generate, through de novo read assembly, a large catalogue of transcripts for Petunia axillaris and Petunia inflata. On the basis of the transcriptome of each species, comprehensive microarray chips for gene expression analysis were established and used for the analysis of global- and organ-specific gene expression in both species. In addition, microarray analysis was applied to explore the molecular basis of the seed coat defects in Petunia hybrida mutants, homozygous for a null allele of the AN11 gene, encoding a WDR transcription regulator. Among the transcripts differentially expressed in an11 seeds compared to wild type, many expected targets of AN11 were found but also several interesting new candidates that might play a role in morphogenesis of the seed coat. Our results validate the combination of next-generation sequencing with microarray analyses strategies to identify the transcriptome of two petunia species without previous knowledge of their genome, and to develop comprehensive chips as useful tools for the analysis of gene expression in P. axillaris, P. inflata and P. hybrida. The manuscript describes the creation by next generation sequencing of a large catalogue of the transcriptome of the two Petunia species, that are considered to represent the natural material from which the breeders selected their varieties. This submission represents the transcriptome component of study. The high throughput sequencing data were submitted to SRA (accession numbers: SRA027293, SRP004866.1, SRX036999.2, SRX036998.2).
Project description:Petunia is an excellent model system, especially for genetic, physiological and molecular studies. Thus far, however, genome-wide expression analysis has been rarely applied because of the lack of sequence information. We applied next-generation sequencing to generate, through de novo read assembly, a large catalogue of transcripts for Petunia axillaris and Petunia inflata. On the basis of the transcriptome of each species, comprehensive microarray chips for gene expression analysis were established and used for the analysis of global- and organ-specific gene expression in both species. In addition, microarray analysis was applied to explore the molecular basis of the seed coat defects in Petunia hybrida mutants, homozygous for a null allele of the AN11 gene, encoding a WDR transcription regulator. Among the transcripts differentially expressed in an11 seeds compared to wild type, many expected targets of AN11 were found but also several interesting new candidates that might play a role in morphogenesis of the seed coat. Our results validate the combination of next-generation sequencing with microarray analyses strategies to identify the transcriptome of two petunia species without previous knowledge of their genome, and to develop comprehensive chips as useful tools for the analysis of gene expression in P. axillaris, P. inflata and P. hybrida.
Project description:Raw Genotyping-by-sequencing reads of Petunia axillaris subsp. subandina, Petunia exserta, and Petunia sp3 (natural hybrid between P. exserta and P. secreta). Raw sequence reads
Project description:Raw Genotyping-by-Sequencing reads of a population of Petunia that displays variation in the color of the corolla, as well as other species used in the project: Petunia secreta, Petunia exserta, and Petunia integrifolia subspecies integrifolia.
Project description:We report the application of sequencing-by-synthesis technology for high-throughput profiling of small RNAs involved in Chalcone synthase A (CHS-A) sense cosuppression in petunia. Sense cosuppression is a classical form of eukaryotic post-transcriptional gene silencing. It was first reported in transgenic petunia, where a transgene overexpressing the host Chalcone Synthase-A (CHS-A) gene caused the degradation of the homologous transcripts and the loss of flower pigmentation. Though sense cosuppression is recognized as an RNA silencing mechanism, little evidence has been yet provided demonstrating its association with the generation of individual small interfering RNAs (siRNAs) that are the assumed determinants. In this work, the deep sequencing of small RNAs in cosuppressed transgenic petunia and WT petunia respectively allowed for the identication of siRNAs that vastly predominate in the silenced flower and guide prominent cleavage events in CHS-A mRNA.
Project description:We report the application of sequencing-by-synthesis technology for high-throughput profiling of small RNAs involved in Chalcone synthase A (CHS-A) sense cosuppression in petunia. Sense cosuppression is a classical form of eukaryotic post-transcriptional gene silencing. It was first reported in transgenic petunia, where a transgene overexpressing the host Chalcone Synthase-A (CHS-A) gene caused the degradation of the homologous transcripts and the loss of flower pigmentation. Though sense cosuppression is recognized as an RNA silencing mechanism, little evidence has been yet provided demonstrating its association with the generation of individual small interfering RNAs (siRNAs) that are the assumed determinants. In this work, the deep sequencing of small RNAs in cosuppressed transgenic petunia and WT petunia respectively allowed for the identication of siRNAs that vastly predominate in the silenced flower and guide prominent cleavage events in CHS-A mRNA. Examination of 2 small RNA populations from WT and cosuppressed petunia petals respectively