Project description:Laser capture microdissection (LCM) provides a useful method for isolating specific cells or tissues from biological samples. Here, we adapted microdissection protocols to allow high-resolution transcript analysis of different tissues from developing Arabidopsis seed. However, to obtain enough RNA for microarray analyses it was necessary to amplify the RNA. Microarray analyses, using endosperm derived RNA amplified by two-round IVT, reproducibly identified endosperm enriched marker genes. Keywords: LCM Endosperm Arabidopsis

Project description:Thirty-five adult (8-16 week old) C57BL/6 mice (which had undergone previous behavioral protocols) were anesthetized with isoflurane, and the brains were removed quickly, embedded in OCT, and frozen in a dry ice-ethanol mixture. The interval between decapitation and complete freezing was always less than 3 minutes. The brain was warmed up to -20oC, and cut into 10-14 m sections with a cryostat (Leica). Serial coronal sections were kept on slides in 100% ethanol until sectioning was complete. Tissue was then processed with hematoxylin and eosin (H&E) staining for cell layer visualization, followed by dehydration with increasing concentrations of ethanol and then xylene. We focused on two cell types, the Purkinje (Pk) and granule cells (gc) of the flocculus. We used an Arcturus PixCell II laser capture microdissection (LCM) scope to locate and capture cells from the appropriate areas, obtaining ten samples per cell type per mouse. We estimate that each Pk sample contained about 50-100 Purkinje cells, and each gc sample contained a few thousand granule cells. Granule cell samples (dorsal flocculus) were captured before Purkinje cell samples, to reduce contamination of the Purkinje cell samples by granule cell material. Samples were removed from the LCM caps with RNEasy lysis buffer (Qiagen) containing 1% -mercaptoethanol, then frozen at -80oC. For each mouse, all the samples of a given cell type were pooled together; samples from different mice were not pooled. Total RNA samples were isolated using RNEasy kits (Qiagen), then amplified in two rounds of in vitro transcription (IVT) using the Ambion MessageAmp aRNA kit. IVT-amplified samples were hybridized to microarrays if the end product after the second round of amplification was of concentration greater than or equal to 0.2 g/l, and at least 10 times the negative control signal (measured after two rounds of amplification of a blank sample). Due to the small starting sample sizes, samples often were rejected due to insufficient quantity for hybridization: thus, 18/35 granule cell samples and 23/35 Purkinje cell samples survived this quality control process, and were run on arrays (41 arrays total). Mus musculus spotted cDNA microarrays (MM arrays) containing ~42,000 spots were obtained from the Stanford Functional Genomics facility (complete information at http://www.microarray.org/), in order to analyze gene expression in each cell type. We used a type II experimental design, where all experimental samples were hybridized against a common reference sample for multi-way comparison. The reference sample comprised mRNA extracted from neonatal and adult brain and liver, and amplified twice by IVT. We used standard protocols for cDNA labeling, as well as array hybridization, washing, scanning, and data analysis (http://cmgm.stanford.edu/pbrown/protocols/index.html). A cell type comparison design experiment design type compares cells of different type for example different cell lines. Keywords: cell_type_comparison_design

Project description:Thirty-five adult (8-16 week old) C57BL/6 mice (which had undergone previous behavioral protocols) were anesthetized with isoflurane, and the brains were removed quickly, embedded in OCT, and frozen in a dry ice-ethanol mixture. The interval between decapitation and complete freezing was always less than 3 minutes. The brain was warmed up to -20oC, and cut into 10-14 m sections with a cryostat (Leica). Serial coronal sections were kept on slides in 100% ethanol until sectioning was complete. Tissue was then processed with hematoxylin and eosin (H&E) staining for cell layer visualization, followed by dehydration with increasing concentrations of ethanol and then xylene. We focused on two cell types, the Purkinje (Pk) and granule cells (gc) of the flocculus. We used an Arcturus PixCell II laser capture microdissection (LCM) scope to locate and capture cells from the appropriate areas, obtaining ten samples per cell type per mouse. We estimate that each Pk sample contained about 50-100 Purkinje cells, and each gc sample contained a few thousand granule cells. Granule cell samples (dorsal flocculus) were captured before Purkinje cell samples, to reduce contamination of the Purkinje cell samples by granule cell material. Samples were removed from the LCM caps with RNEasy lysis buffer (Qiagen) containing 1% -mercaptoethanol, then frozen at -80oC. For each mouse, all the samples of a given cell type were pooled together; samples from different mice were not pooled. Total RNA samples were isolated using RNEasy kits (Qiagen), then amplified in two rounds of in vitro transcription (IVT) using the Ambion MessageAmp aRNA kit. IVT-amplified samples were hybridized to microarrays if the end product after the second round of amplification was of concentration greater than or equal to 0.2 g/l, and at least 10 times the negative control signal (measured after two rounds of amplification of a blank sample). Due to the small starting sample sizes, samples often were rejected due to insufficient quantity for hybridization: thus, 18/35 granule cell samples and 23/35 Purkinje cell samples survived this quality control process, and were run on arrays (41 arrays total). Mus musculus spotted cDNA microarrays (MM arrays) containing ~42,000 spots were obtained from the Stanford Functional Genomics facility (complete information at http://www.microarray.org/), in order to analyze gene expression in each cell type. We used a type II experimental design, where all experimental samples were hybridized against a common reference sample for multi-way comparison. The reference sample comprised mRNA extracted from neonatal and adult brain and liver, and amplified twice by IVT. We used standard protocols for cDNA labeling, as well as array hybridization, washing, scanning, and data analysis (http://cmgm.stanford.edu/pbrown/protocols/index.html).

Project description:We collected globular stage seed compartments from 5 or 7-micron paraffin sections using the Leica LMD6000 system in order to identify the mRNAs present in different compartments of an Arabidopsis seed containing a globular stage embryo. For the purposes of this study we broke down the seed into 7 capturable compartments: embyro proper, suspensor, micropylar endosperm, peripheral endosperm, chalazal endosperm, chalazal seed coat and general seed coat. Experiment Overall Design: Globular stage seed compartments were isolated using the LMD6000 system. Total RNA was amplified and hybridized with Affymetrix ATH1 Arabidopsis array for 15 samples (Embryo Proper, Micropylar Endosperm, Peripheral Endosperm, General Seed Coat and Chalazal Seed Coat, 2 biological replicates each and Chalazal Endosperm with 3 biological replicates).

Project description:The evaluation of mycotoxicity of type B trichothecenes using a yeast gene expression comparison analysis. The yeast BY4743 derivative PDR5 mutant was used for this study. The yeast cells were treated with trichothecene mycotoxins, and incubated at 25 degree for two hours, respectively. Total RNA was isolated with commercial kit (FastRNA Pro Red kit, Q-Biogene), and amplified RNA (aRNA) was synthesized with 3'IVT Express kit (Affymetrix). All samples were hybridized with Gene Chip (Yeast Genome 2.0 Array, Affymetrix), then each array chip was scanned by GeneChip Sanner 3000 (Affymetrix).

Project description:We collected mature green seed compartments from 7 micron paraffin sections using the Leica LMD6000 system in order to identify the mRNAs present in different compartments from seeds containing mature green-stage embryos. For the purposes of this study we captured 6 compartments: embryo proper, micropylar endosperm, cellularized peripherial endosperm, chalazal endosperm, chalazal seed coat and seed coat, as well sets of serial sections encompassing the entire mature green stage seed. Experiment Overall Design: Mature green stage seed compartments were isolated using the LMD6000 system. Total RNA was amplified and hybridized with Affymetrix ATH1 Arabidopsis array for 14 samples (embryo proper, micropylar endosperm, peripherial endosperm, chalazal endosperm, chalazal seed coat, seed coat and whole seeds, 2 biological replicates each).

Project description:We collected heart stage seed compartments from 7 micron paraffin sections using the Leica LMD6000 system in order to identify the mRNAs present in different compartments from seeds containing heart stage embryos. For the purposes of this study we captured 6 compartments: embryo proper, micropylar endosperm, peripheral endosperm, chalazal endosperm, chalazal seed coat and seed coat, as well sets of serial sections encompassing the entire heart stage seed. Experiment Overall Design: Heart stage seed compartments were isolated using the LMD6000 system. Total RNA was amplified and hybridized with Affymetrix ATH1 Arabidopsis array for 16 samples (embryo proper, micropylar endosperm, peripheral endosperm, seed coat and whole seeds, 2 biological replicates each; chalazal endosperm, chalazal seed coat, 3 biological replicates each).

Project description:We collected bending cotyledon seed compartments from 7 micron paraffin sections using the Leica LMD6000 system in order to identify the mRNAs present in different compartments from seeds containing linear cotyledon stage embryos. For the purposes of this study we captured 5 compartments: embyro proper, cellularized peripherial endosperm, chalazal endosperm, chalazal seed coat and seed coat, in addition to serial sections encompasing the entire linear cotyledon stage seed. Bending cotyledon stage seed compartments were isolated using the LMD6000 system. Total RNA was amplified and hybridized with Affymetrix ATH1 Arabidopsis array for 14 samples (embryo proper, micropylar endosperm, peripherial endosperm, chalazal endosperm, chalazal seed coat, seed coat and whole seeds, 2 biological replicates each).

Project description:We collected linear-cotyledon stage seed compartments from 5 to 7 micron paraffin sections using the Leica LMD6000 system in order to identify the mRNAs present in different compartments from seeds containing linear-coyledon-stage embryos. For the purposes of this study we captured 5 compartments: embyro proper, cellularized endosperm, chalazal endosperm, chalazal seed coat and general seed coat. Experiment Overall Design: linear-cotyledon stage seed compartments were isolated using the LMD6000 system. Total RNA was amplified and hybridized with Affymetrix ATH1 Arabidopsis array for 10 samples (embryo proper, micropylar endosperm, cellularized endosperm, general seed coat and chalazal seed coat, 2 biological replicates each ).

Project description:Here we compare transcriptomic data generated using Affymetrix one-cycle (standard labelling protocol), two-cycle (small-sample protocol) and IVT-Express protocols with the Affymetrix ATH1 array using Arabidopsis root samples. Results obtained with each protocol are broadly similar. However, we show that there are 35 probe sets (of a total of 22810) that are misrepresented in the two-cycle data sets. Of these, 33 probe sets were classed as mis-amplified when comparisons of two independent publicly available data sets were undertaken.