Project description:We present a new approach, Light-Seq, for multiplexed spatial indexing of intact biological samples using light-directed DNA barcoding in fixed cells and tissues followed by ex situ sequencing. Light-Seq combines spatially-targeted, rapid photocrosslinking of DNA barcodes onto cDNAs in situ with a novel one-step DNA stitching reaction to create pooled, spatially-indexed sequencing libraries. This light-directed barcoding enables in situ selection of multiple cell populations in intact fixed tissue samples for full transcriptome sequencing based on location, morphology, or protein stains, without cellular dissociation. Applying Light-Seq to mouse retinal sections, we recovered thousands of differentially enriched transcripts from three adjacent cellular layers and discovered new biomarkers for a very rare neuronal subtype, dopaminergic amacrine cells, from only 4-8 individual cells per section. Light-Seq provides an accessible workflow to combine in situ imaging and protein staining with next-generation sequencing of the same cells, leaving the sample intact sample for further analysis post-sequencing.

Project description:Purpose The heterogeneity of squamous cell carcinoma tissue complicates diagnosis and an individualized therapy to a great extent. Therefore it is of utmost importance to spatially characterize this tissue heterogeneity and to identify appropriate biomarkers. Matrix assisted laser desorption/ionization (MALDI) mass spectrometry imaging (MSI) can analyze spatially resolved tissue biopsies on a molecular level. Experimental design MALDI MSI of snap frozen tissues as well as of formalin-fixed and paraffin-embedded (FFPE) tissue samples from patients with head and neck cancer (HNC) were used to analyze m/z values localized in tumor and non-tumor regions. Peptide identification was performed by using liquid chromatography (LC)-MS/MS and immunohistochemistry (IHC). Results In both FFPE and frozen tissue specimen seven characteristic masses of the tumor epithelial region were found identified. Using LC-MS/MS, the peaks were identified as Vimentin, Keratin type II, Nucleolin, Heat shock protein 90, Prelamin-A/C, Junction plakoglobin and PGAM1. Finally, Vimentin, Nucleolin and PGAM1 were verified with IHC. Conclusions and Clinical Relevance The combination of MALDI MSI, LC-MS/MS and subsequent IHC is an appropriate tool to characterize the molecular heterogeneity of tissue as well as to identify new representative biomarkers for a more individualized therapy.

Project description:For the effectiveness of targeted immunotherapy, which is currently one of the most promising treatments for brain tumors, it is necessary to know specific tumor-associated antigens (TAA). This project aimed to validate the suitability of formalin-fixed and paraffin-embedded (FFPE) material instead of fresh-frozen material for RNA sequencing and downstream TAA identification. Purpose: Detect potential oligodendroglioma-associated antigens using both fresh-frozen and FFPE brain tissues; assess the suitability of the FFPE material for TAA identification. Results: A comparative analysis based on the RNA-seq of canine oligodendroglioma showed that formalin fixation of the samples had a significant effect on the RNA-seq library in terms of quality. Read distribution analysis showed that the FFPE samples contained fewer reads mapping to exonic regions and were enriched with reads mapped to introns and intergenic regions, while the fresh-frozen samples were mostly enriched in reads mapping to exons. Mismatch profile and SNVs calling analyses revealed some substitution artefacts present in the FFPE samples and absent in the corresponding fresh-frozen samples. However, according to the Principal Component Analysis, 36% of the variance between the samples could be explained by the types of conservation, while 43% of the variance could still be attributed to different expression profiles between oligodendroglioma and control conditions. A differential expression analysis of fresh-frozen oligodendroglioma versus fresh-frozen control samples identified 62 potential TAA strongly up-regulated in tumor tissue. The same analysis using the FFPE samples showed 80% of these genes (49/62) also to be differentially expressed. Comparative analysis showed good agreement between FFPE and fresh-frozen RNA-seq libraries in terms of the accuracy of gene expression measurements indicating that archived FFPE tissue can be used for identification of TAA candidates by RNA-seq providing a wealthy source of clinical samples for research. The following 10 genes encoding cell surface proteins have been identified by both approaches as potential TAA candidates based on their strong overexpression in oligodendrogliomas: PDGFRA, NOTCH1, DLL1, GPER1, TNR, IQGAP3, CD44, ERBB3, BCAS1 and ROR2. Future projects still need to investigate their suitability as TAA for targeted immunotherapy. Conclusion: Formalin fixation of the samples had a significant impact on the RNA-seq quality in terms of the accuracy of gene expression measurements, as well as the quality of the nucleotide sequences. Nevertheless, the comparative analysis showed good agreement between FFPE and fresh-frozen RNA-seq libraries.

Project description:Integration of ChIP, MeDIP, MeRIP, and RT Seq for multiomics analysis of frozen and FFPE tissue

Project description:Integration of ChIP, MeDIP, MeRIP, and RT Seq for multiomics analysis of frozen and FFPE tissue

Project description:Integration of ChIP, MeDIP, MeRIP, and RT Seq for multiomics analysis of frozen and FFPE tissue

Project description:Integration of ChIP, MeDIP, MeRIP, and RT Seq for multiomics analysis of frozen and FFPE tissue

Project description:Integration of ChIP, MeDIP, MeRIP, and RT Seq for multiomics analysis of frozen and FFPE tissue

Project description:Integration of ChIP, MeDIP, MeRIP, and RT Seq for multiomics analysis of frozen and FFPE tissue

Project description:We present spatially resolved chromatin accessibility profiling of tissue sections via next-generation sequencing by combining in situ ATAC-seq chemistry and microfluidic deterministic barcoding. Mouse and human tissues were profiled by spatial-ATAC-seq.