PRISM Technology

Overview

PRISM (Profiling of RNA In-situ through Single-round iMaging) is a high-resolution spatial transcriptomics technology developed by the Huang Lab. It employs color-intensity barcodes and a radius vector encoding strategy to achieve high-plex RNA imaging in a single staining and imaging round with conventional fluorescence microscopes.

Key Features

• Single-Round Imaging: No sequential hybridization rounds needed -- all targets are decoded from one imaging session.
• Color-Intensity Barcodes: Expands coding capacity through graded fluorescence intensities across multiple channels, achieving up to 64-plex detection.
• Sub-Micron Resolution: Precise spatial localization of individual RNA molecules.
• 3D Capability: Compatible with both thin sections and thick tissue blocks.
• RCA Amplification: Uses Rolling Circle Amplification to generate bright DNA nanoballs (rolonies) for robust signal detection.

Applications

PRISM has been validated across diverse biological contexts, including:

• 3D atlas of mouse embryonic development (E12.5--E14.5)
• Tumor--normal transition landscape in human hepatocellular carcinoma
• 3D cell atlas and subcellular RNA localization in mouse brain

Workflow Summary

1. Sample Preparation: Tissue sectioning and fixation.
2. Probe Hybridization: Target-specific padlock probes hybridize to RNA.
3. Ligation: Probes are circularized upon perfect matching.
4. RCA Amplification: Generation of DNA nanoballs (rolonies).
5. Fluorescent Probe Staining: Detection probes carrying color-intensity barcodes hybridize to rolonies.
6. Single-Round Imaging: Multi-channel fluorescence microscopy captures all barcode signals simultaneously.
7. Decoding: Radius vector encoding algorithm decodes gene identity from the barcode pattern.

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