Project description: Not available

Project description: Not available

Project description:DNA microarrays are two-dimensional arrangements of specific probes deposited on a substrate that have been widely used in gene expression analysis by measuring mRNA accumulation. The use of this type of microarrays involves the synthesis of cDNA, which has to be double stranded (ds) if the microarray probes are of the positive strand. We have used a custom-synthesized non-commercial NimbleGen microarray from melon to evaluate an alternative method of ds cDNA synthesis, which differs substantially in its economical cost relative to a widely recommended method. The results suggested that both methods produce cDNA representative of the melon transcriptome to a similar extent, indicating that the alternative technique provides a cheaper method of ds cDNA synthesis for microarray gene expression assays. Recently, we have analyzed the transcriptome of melon in response to WMV infection. Cotyledons of two genotypes of melon were virus inoculated and transcriptomic responses to the infection were analyzed by comparing infected and mock inoculated samples at 1, 3, and 7 days post-inoculation (dpi). Three biological replicates were performed for each sample. Double stranded cDNA was obtained with the Double stranded cDNA synthesis kit (Invitrogen, Carlsbad, CA, USA), based on the nick translation approach (Mol. Cell. Biol (1982) 2:161-170; Gene (1983) 25:263-269). Raw and processed microarray data are freely available from GEO database under the accession number GSE30111. By using this set of microarray hybridizations as a reference, RNA corresponding to infected cotyledons replicate 3 at 1 dpi (A1) and replicate 1 at 3 dpi (A2) (GEO accession numbers GSM745566 and GSM745567) were used to perform cDNA synthesis by the alternative method (samples B1 and B2, respectively), based on the SMART approach (BioTechniques (2001) 30:892-897), and microarray data were compared.

Project description:DNA microarrays are two-dimensional arrangements of specific probes deposited on a substrate that have been widely used in gene expression analysis by measuring mRNA accumulation. The use of this type of microarrays involves the synthesis of cDNA, which has to be double stranded (ds) if the microarray probes are of the positive strand. We have used a custom-synthesized non-commercial NimbleGen microarray from melon to evaluate an alternative method of ds cDNA synthesis, which differs substantially in its economical cost relative to a widely recommended method. The results suggested that both methods produce cDNA representative of the melon transcriptome to a similar extent, indicating that the alternative technique provides a cheaper method of ds cDNA synthesis for microarray gene expression assays.

Project description: Not available

Project description:These experiments were designed to quantify depletion of rRNA sequencing reads from bacterial RNA-seq libraries and verify that mRNA sequencing reads were not altered. Specifically, we tested an rRNA depletion method using custom-designed biotinylated oligonucleotides and compared these results to undepleted (total RNA) libraries and libraries made with the previously-available Ribo-Zero kit (Illumina).

Project description:we developed a simple Digestion-Ligation-Only Hi-C (DLO Hi-C) technology to explore the 3D landscape of the genome

Project description: Not available

Project description: Not available

Project description:Advances in single-cell genomics enable commensurate improvements in methods for uncovering lineage relations among individual cells. Current sequencing based methods for cell lineage analysis depend on low resolution bulk analysis or rely on extensive single cell sequencing which is not scalable and could be biased by functional dependencies. Here we show an integrated biochemical-computational platform for generic single-cell lineage analysis that is retrospective, cost-effective and scalable. It consists of a biochemical-computational pipeline that inputs individual cells, produces targeted single-cell sequencing data and uses it to generate a lineage tree of the input cells. We validated the platform by applying it to cells sampled from an ex vivo grown tree and analyzed its feasibility landscape by computer simulations. We conclude that the platform may serve as a generic tool for lineage analysis and thus pave the way towards large-scale human cell lineage discovery.