You acknowledge this but I feel you downplay the risk of cancer—an accidental point mutation in a tumour suppressor gene or regulatory region in a single founder cell could cause a tumour.
For each target the likely off-targets can be predicted, allowing one to avoid particularly risky edits. There may still be issues with sequence-independent off-targets, though I believe these are a much larger problem with base editors than with prime editors (which have lower off-target rates in general). Agree that this might still end up being an issue.
Unless you are using the term “off-target” to refer to any incorrect edit of the target site, and wider unwanted edits—in my community this term referred specifically to ectopic edits elsewhere in the genome away from the target site.
This is exactly it—the term “off-target” was used imprecisely in the post to keep things simple. The thing we’re most worried about here is misedits (mostly indels) at noncoding target sites. We know a target site does something (if the variant there is in fact causal), so we might worry that an indel will cause a big issue (e.g. disabling a promoter binding site). Then again, the causal variant we’re targeting has a very small effect, so maybe the sequence isn’t very sensitive and an indel won’t be a big deal? But it also seems perfectly possible that the sequence could be sensitive to most mutations while permitting a specific variant with a small effect. The effect of an indel will at least probably be less bad than in a coding sequence, where it has a high chance of causing a frameshift mutation and knocking out the coded-for protein.
The important figure of merit for editors with regards to this issue is the ratio of correct edits to misedits at the target site. In the case of prime editors, IIUC, all misedits at the target site are reported as “indels” in the literature (base editors have other possible outcomes such as bystander edits or conversion to the wrong base). Some optimized prime editors have edit:indel ratios of >100:1 (best I’ve seen so far is 500:1, though IIUC this was just at two target sites, and the rates seem to vary a lot by target site). Is this good enough? I don’t know, though I suspect not for the purposes of making a thousand edits. It depends on how large the negative effects of indels are at noncoding target sites: is there a significant risk the neuron gets borked as a result? It might be possible to predict this on a site-by-site basis with a better understanding of the functional genomics of the sequences housing the causal variants which affect polygenic traits (which would also be useful for finding the causal variants in the first place without needing as much data).
For each target the likely off-targets can be predicted, allowing one to avoid particularly risky edits. There may still be issues with sequence-independent off-targets, though I believe these are a much larger problem with base editors than with prime editors (which have lower off-target rates in general). Agree that this might still end up being an issue.
This is exactly it—the term “off-target” was used imprecisely in the post to keep things simple. The thing we’re most worried about here is misedits (mostly indels) at noncoding target sites. We know a target site does something (if the variant there is in fact causal), so we might worry that an indel will cause a big issue (e.g. disabling a promoter binding site). Then again, the causal variant we’re targeting has a very small effect, so maybe the sequence isn’t very sensitive and an indel won’t be a big deal? But it also seems perfectly possible that the sequence could be sensitive to most mutations while permitting a specific variant with a small effect. The effect of an indel will at least probably be less bad than in a coding sequence, where it has a high chance of causing a frameshift mutation and knocking out the coded-for protein.
The important figure of merit for editors with regards to this issue is the ratio of correct edits to misedits at the target site. In the case of prime editors, IIUC, all misedits at the target site are reported as “indels” in the literature (base editors have other possible outcomes such as bystander edits or conversion to the wrong base). Some optimized prime editors have edit:indel ratios of >100:1 (best I’ve seen so far is 500:1, though IIUC this was just at two target sites, and the rates seem to vary a lot by target site). Is this good enough? I don’t know, though I suspect not for the purposes of making a thousand edits. It depends on how large the negative effects of indels are at noncoding target sites: is there a significant risk the neuron gets borked as a result? It might be possible to predict this on a site-by-site basis with a better understanding of the functional genomics of the sequences housing the causal variants which affect polygenic traits (which would also be useful for finding the causal variants in the first place without needing as much data).