Project description:Graft compatibility is the ability of two plants to form cohesive vascular connections. Tomato and pepper grafts are incompatible but the underlying causes of this phenomenon remain unknown. We utilzied a broad array of techniques to profile graft compatibility including viability, biophysical stability, and growth. Cell death in the junction was quantified using trypan blue and TUNNEL assays. Transcriptomic analysis of cell death in the junction was preformed using RNA-sequncing. Finally a meta-transcriptomic analysis was conducted with published datasets to further explore the genetic signature of graft incompatibility.We found that all varieties of pepper tested across two species were incompatible with tomato. Tomato and pepper graft incompatibility is characterized by stem instability, reduced growth, and persistent cell death in the graft junction. We showed that tomato and pepper heterografts have prolonger transcriptional activity, with defense processes highly enrched. We identfied a large subset of NLRs and genes involved in programmed cell death which were upregulated in incompatible tissue. We also identified a set of genes with orthologs in both tomato and pepper which are upregulated in incompatible grafts including biosythesis of steroidal glycoalkaloids. Finally we utilized various biological stressors to explore the genetic signature of grafting. We found a significant overlap in the genetic profile of grafting and plant parsitism. We also identified over 1000 genes uniquely upregulated in incompatible grafting including genes in involved in DNA-damage repair. Based on the broad upregulation of NLRs and genes involved with programmed cell death, prolonged cell death in the junction, and DNA damage, we have determined that tomato and pepper graft incompatibility is likely caused by a form of genetic incompatibility which triggers an autoimmune-like response.
Project description:The tomato SlWRKY3 transcription factor was overexpressed in cultivated tomato (Solanum lycopersicum)and transgenic plants transcriptome was compared to that of wild-type plants.
Project description:RNA sequencing in tomato for detect mRNA expression of Solanum lycopersicum flower.The two cultivars (monomaker, raceme) had three different flowering stages (budlet, Flower bud, Full bloom) for transcriptome sequencing
Project description:RNA sequencing in tomato for detect mRNA expression of Solanum lycopersicum Axillary bud.The two cultivars (monomaker, raceme) at Axillary bud for transcriptome sequencing
Project description:In this study, we explored the metabolome and transcriptome of the ripe fruit in nine landrace accessions representing the seven genetic groups and compared them to the mature fruit of the wild progenitor S. pimpinellifolium. The goal is to shed light in understanding the factors responsible for acquiring tomato fruit quality (taste and flavour) at molecular level during the domestication process.
Project description:To characterize the PTI response of tomato and the effect of the delivery of a subset of effectors, we performed an RNA-seq analysis of tomato Rio Grande prf3 leaves challenged with either the flgII-28 peptide or the following bacterial strains: Agrobacterium tumefaciens GV2260, Pseudomonas fluorescens 55, Pseudomonas putida KT2440, Pseudomonas syringae pv. tomato (Pst) DC3000, Pst DC3000 deltahrcQ-U deltafliC and Pst DC3000 deltaavrPto deltaavrPtoB. NOTE: Samples in SRA were assigned the same sample accession. This is incorrect as there are different samples, hence âSource Nameâ was replaced with new values. Comment[ENA_SAMPLE] contains the original SRA sample accessions.
Project description:RNA interference (RNAi) is a widely-used approach to generate virus-resistant transgenic crops. However, durability of RNAi-mediated resistance under extreme field conditions and side-effects of stable RNAi expression have not been thoroughly investigated. Here we performed field trials and molecular characterization of two RNAi-transgenic Solanum lycopersicum lines resistant to Tomato yellow leaf curl virus (TYLCV) disease, the major constraint for tomato cultivation in Cuba and worldwide. In order to determine potential impact of the hairpin RNA transgene expression on tomato genome expression and development, differences in the phenotypes and the transcriptome profiles between the transgenic and non-transgenic plants were examined. Transcriptome profiling revealed a common set of up- and down-regulated tomato genes, which correlated with slight developmental abnormalities in both transgenic lines.
