Library Construction Strategies¶
Padlock probe-based spatial transcriptomics can use different ligation strategies depending on the substrate (RNA or cDNA) and probe design. The choice affects detection efficiency, specificity (SNP discrimination), and self-ligation risk.
Strategy Comparison¶
| Strategy | Substrate | Ligase | Detection Efficiency | SNP Specificity | Self-Ligation Risk | Extra Steps |
|---|---|---|---|---|---|---|
| Direct RNA (dRNA) | mRNA | SplintR (PBCV-1) | Highest | None | High | None |
| Chimeric Padlock dRNA | mRNA | T4 RNA Ligase 2 | Higher than dRNA | None | High | None |
| cDNA | cDNA (after RT) | T4 DNA Ligase / Tth | ~⅕ of dRNA | Yes | Low--moderate | Reverse transcription + RNase H |
| iLock dRNA | mRNA | SplintR (after Taq activation) | ~1/10 of dRNA | Yes | Minimal | Taq activation step |
Direct RNA (dRNA)¶
The simplest approach. Standard DNA padlock probes hybridize directly to mRNA, and SplintR ligase (PBCV-1 DNA Ligase) ligates the DNA nick on the RNA template (DNA:RNA hybrid).
Pros:
- Highest detection efficiency (no conversion loss)
- Fewest steps (no reverse transcription)
Cons:
- Almost no single-nucleotide specificity -- SplintR ligase tolerates mismatches at the ligation junction
- Self-ligation risk: SplintR ligase can ligate probes that circularize without a template (template-independent self-ligation), producing false positives
Protocol: RCA: Direct RNA | Used in: Standard PRISM and SPRINTseq protocols (current default).
Chimeric Padlock Direct RNA¶
A variant of direct RNA where the 3' and/or 5' terminal nucleotides of the padlock probe are replaced with ribonucleotides (chimeric DNA-RNA probe). This creates an RNA-RNA hybrid at the ligation junction instead of a DNA-RNA hybrid.
Ligase: T4 RNA Ligase 2 (T4Rnl2), which ligates RNA-RNA hybrids more efficiently than SplintR ligates DNA-RNA hybrids. SplintR can also be used but is less efficient on chimeric substrates.
Pros:
- Higher detection efficiency than standard dRNA (more stable RNA-RNA junction)
- No extra steps compared to standard dRNA
Cons:
- Same lack of SNP specificity as standard dRNA
- Same self-ligation risk
- Chimeric oligo synthesis is more expensive
Reference: Chimeric padlock and iLock probes for increased efficiency of targeted RNA detection. RNA 25(1), 82--89 (2019). 10.1261/rna.066753.118
cDNA¶
Reverse transcription converts mRNA to cDNA first. Padlock probes then hybridize to the cDNA strand, and a DNA-templated ligase (T4 DNA Ligase, Tth Ligase, etc.) ligates the nick.
Pros:
- SNP specificity: DNA-templated ligases discriminate single-nucleotide mismatches at the ligation junction
- Lower self-ligation risk than SplintR (though template-dependent self-ligation between probes is still possible -- use blocking oligos to mitigate)
Cons:
- Detection efficiency ~⅕ of direct RNA (conversion loss during reverse transcription)
- Extra step: reverse transcription
- Extra step: RNase H digestion to remove the RNA strand after RT, exposing the cDNA for padlock hybridization
Protocol: RCA: cDNA — includes reverse transcription, RNase H digestion, and T4 DNA Ligase ligation steps.
iLock Direct RNA¶
iLock (invader padLock) probes add a 5' non-complementary flap to the standard padlock design. Before ligation, Taq DNA Polymerase cleaves this flap via its 5'→3' flap endonuclease activity. This structure-specific cleavage requires correct base-pairing at the cleavage site, providing a dual specificity checkpoint (cleavage + ligation).
Pros:
- Highest specificity: SNP discrimination at the flap cleavage site + ligation junction
- Minimal self-ligation: The flap must be cleaved before ligation can occur, fundamentally preventing template-independent circularization
Cons:
- Lowest detection efficiency (~1/10 of dRNA): Taq activation requires elevated temperature (~45--51°C) where the short flap duplex is unstable, leading to low activation efficiency
- Extra step: Taq activation (45°C, 60 min)
Potential optimization
Increasing Taq polymerase concentration + 37°C overnight activation may improve activation efficiency. This is an active area of optimization.
Unpublished
iLock probe protocols are currently internal to the Huang Lab.
Reference: Chimeric padlock and iLock probes for increased efficiency of targeted RNA detection. RNA 25(1), 82--89 (2019). 10.1261/rna.066753.118
Choosing a Strategy¶
graph TD
Q1{"Need SNP<br/>specificity?"} -->|No| Q2{"Maximize<br/>detection?"}
Q1 -->|Yes| Q3{"Minimize<br/>false positives?"}
Q2 -->|"Yes, max efficiency"| A["Chimeric Padlock dRNA"]
Q2 -->|"Standard is fine"| B["Direct RNA (dRNA)"]
Q3 -->|"Specificity > sensitivity"| C["iLock dRNA"]
Q3 -->|"Balance both"| D["cDNA"]
style A fill:#E9EEE6,stroke:#5F7A57
style B fill:#E9EEE6,stroke:#5F7A57
style C fill:#F5ECDA,stroke:#B5832F
style D fill:#E7EDF1,stroke:#5B7488For most spatial transcriptomics applications where detection efficiency is the priority and single-nucleotide specificity is not required, direct RNA is the recommended default strategy.