Parse Biosciences' single-cell RNA-seq workflow uses a split-pool barcoding technique to analyze gene expression in thousands to millions of cells without needing physical separation. Cells are repeatedly split and pooled across several rounds of barcoding, creating unique combinatorial barcodes for each cell's RNA. After barcoding, the RNA is reverse transcribed, amplified, and converted into sequencing libraries. The data generated is used to reconstruct gene expression profiles for individual cells, allowing for in-depth analysis of cellular diversity and function. This method is highly scalable and cost-effective for large-scale studies. The GCTU is an official service provider for Parse Bioscience workflows.

The GCTU offer the below Parse Bioscience workflows:

• Parse Evercode Mini Kit V3 (1-12 samples/10,000 cells)
• Parse Evercode WT Kit V3 (1-48 samples/100,000 cells)
• Parse Evercode Mega Kit V3 (1-96 samples/1M cells)

 

Spatial Transcriptomic Services

At the GCTU, we offer 10X Genomics spatial transcriptomic workflows - namely Visium, VisiumHD and Xenium. These complementary workflows differ in terms of number of genes detected, capture area size, sequencing requirements and available species. Please reach out to us at genomics@qub.ac.uk to discuss your spatial transcriptomic project and optimal workflow.

For Visium & VisiumHD we accept freshly cut tissue section on glass slides, whereas for Xenium we will provider users with specific Xenium slides on to which tissues are to be placed onto directly. We can also support tumour microarray (TMA) creation and use on both workflow - please reach out to discuss.

Visium & VisiumHD

The 10x Genomics Visium CytAssist workflow is tailored for spatial transcriptomics, enabling gene expression mapping within tissue sections while preserving spatial information. The Visium workflow affords researcher whole transcriptome information at multi-Cell (standard) or near single cell (HD) resolution. The workflow begins with the preparation of fresh-frozen or FFPE tissue sections, which are placed onto standard glass slides. The CytAssist instrument then transfers mRNA from the tissue sections to Visium slides with barcoded capture spots. These spots capture the mRNA while maintaining the tissue's spatial context. The captured RNA is reverse-transcribed into cDNA, which is then used to create sequencing libraries. After sequencing, the data is processed to generate spatial gene expression maps, providing insights into gene activity across different regions of the tissue, all while maintaining the original spatial architecture.

The GCTU offer the below Visium workflows:

• Standard Visium: resolution around 55µM, 2 capture areas per slide at 6.5x6.5mm or 11x11mm
• VisiumHD: resolution 2µM (binned to 8µM), 2 capture areas per slide at 6.5x6.5mm

Xenium

The 10x Genomics Xenium workflow is designed for high-resolution spatial transcriptomics, allowing detailed mapping of gene expression within tissue sections. The Xenium workflow affords researcher access to information for between 100-5,000 genes at sub-cellular resolution. The workflow involves preparing fresh-frozen tissue sections, which are placed onto Xenium slides with high-density barcoded capture areas. These areas capture and preserve mRNA from specific locations in the tissue. The captured RNA is then reverse-transcribed into cDNA and used to create sequencing libraries. After sequencing, the data is analyzed to produce high-resolution spatial gene expression maps, providing in-depth insights into tissue architecture and cellular function at a finer spatial scale.

The GCTU offer the below Xenium workflow:

• Xenium run: sub-cellular resolution, 1 capture area per slide at 10.45mm x 22.45mm. Note - 2 slides must be run per Xenium instrument run.
• 10X Genomics offers a range of off the shelf panels for Human and Mouse, as well as fully customisable panels. See here for more information.