eli-cel 是一种利用慢病毒载体将 ABCD1 基因添加到干细胞的基因治疗方法，用于治疗伴有伴侣蛋白 ABCD1 缺陷的肾上腺脑白质营养不良症。然而，一项新的研究表明，在 67 名接受 eli-cel 治疗的患者中，有 7 名出现了血液系统癌症。这些癌症包括骨髓增生异常综合征 (MDS) 和急性髓性白血病 (AML)，发生时间从接受治疗后的 14 个月到 92 个月不等。对癌细胞的基因分析表明，大多数患者的肿瘤细胞中存在慢病毒载体的多个插入位点，其中大多数位于 MECOM-EVI1 基因附近。研究表明，慢病毒载体的插入导致癌细胞发生突变，这与先前 γ-逆转录病毒基因治疗中出现的类似问题一致。该研究引发了对基因治疗安全性的担忧，并强调了需要进一步研究以开发更安全有效的基因治疗方法。

🧬 **eli-cel 治疗致癌风险：** 研究表明，在 67 名接受 eli-cel 治疗的患者中，有 7 名出现了血液系统癌症，包括 MDS 和 AML。这些癌症的发生时间从接受治疗后的 14 个月到 92 个月不等。 对癌细胞的基因分析表明，大多数患者的肿瘤细胞中存在慢病毒载体的多个插入位点，其中大多数位于 MECOM-EVI1 基因附近。这意味着慢病毒载体可能插入了重要的基因，从而导致癌细胞发生突变。 此外，研究还发现，6 名患者的癌细胞中存在其他体细胞突变，包括 KRAS、NRAS、WT1、CDKN2A 或 CDKN2B 或 RUNX1 等基因的突变，以及 1 名患者的 7 号染色体单体性。这些突变可能与慢病毒载体的插入有关，也可能与其他因素有关。

⚠️ **慢病毒载体插入的潜在风险：** 这项研究强调了慢病毒载体插入的潜在风险，因为它们可能插入重要的基因，导致癌细胞发生突变。这与先前 γ-逆转录病毒基因治疗中出现的类似问题一致，在 γ-逆转录病毒基因治疗中，也观察到了一些患者出现白血病。 尽管慢病毒载体比 γ-逆转录病毒载体更倾向于插入活跃转录的基因，但它们仍然可能插入重要的基因，并导致癌细胞发生突变。因此，需要进一步研究以开发更安全有效的基因治疗方法，例如使用更精确的基因编辑技术，如 CRISPR-Cas9。

🧬 **CRISPR-Cas9 的应用和局限性：** CRISPR-Cas9 是一种基因编辑技术，它可以利用 Cas9 酶根据添加的引导 RNA 切割双链 DNA。虽然 CRISPR-Cas9 不像慢病毒载体那样插入 DNA，但它可以利用同源重组修复机制将 DNA 片段插入到切割位点。 然而，CRISPR-Cas9 存在一些局限性，包括 Cas9 酶可能切割错误的位点，添加的 DNA 可能无法插入，以及双链 DNA 断裂修复可能出现问题。此外，CRISPR-Cas9 在不同类型的细胞中效果不同，在非干细胞中效果并不理想。 目前，CRISPR-Cas9 的传递主要依赖于物理方法，如显微注射技术、电穿孔和 HTVI，这些方法在活体动物中并不实用，而且对细胞的影响很大。因此，需要进一步研究以开发更有效和安全的 CRISPR-Cas9 传递方法。

Published on October 16, 2024 3:32 PM GMT

Here's a new paper on cancer developing in patients after receiving gene therapy with eli-cel, brand name Skysona.

What is eli-cel?

Stem cells are isolated and modified by using a lentiviral vector to add the ABCD1 gene. The stem cells in bone marrow are killed with chemotherapy, and replaced with the modified stem cells.

How often did cancer develop?

Hematologic cancer developed in 7 of 67 patients after the receipt of eli-cel

Yep, that's about what I expected. How long did it take?

myelodysplastic syndrome (MDS) with unilineage dysplasia in 2 patients at 14 and 26 months; MDS with excess blasts in 3 patients at 28, 42, and 92 months; MDS in 1 patient at 36 months; and acute myeloid leukemia (AML) in 1 patient at 57 months.

Makes sense. What does genetic analysis of the cancer cells indicate?

In the 6 patients with available data, predominant clones contained lentiviral vector insertions at multiple loci, including at either MECOM–EVI1 (MDS and EVI1 complex protein EVI1 [ecotropic virus integration site 1], in 5 patients) or PRDM16 (positive regulatory domain zinc finger protein 16, in 1 patient). Several patients had cytopenias, and most had vector insertions in multiple genes within the same clone; 6 of the 7 patients also had somatic mutations (KRAS, NRAS, WT1, CDKN2A or CDKN2B, or RUNX1), and 1 of the 7 patients had monosomy 7.

Multiple off-target insertions, different ones for different people. Yep.

Has this happened with gene therapy attempts before?

Yes, it's been a big problem with eg γ-retrovirus gene therapy trials. People hoped lentiviruses would be better because they tend to insert around actively transcribed genes, while γ-retroviruses tend to insert near transcription start sites.

Why don't we see high cancer rates after DNA viral infections?

We sort of do: Many cancers are strongly associated with viruses. But eli-cel is:

specifically done to stem cells, which are closer to cancer than usualapplied to cells away from the immune system, which can often detect infections and kill infected cells early

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How about CRISPR instead of a viral vector?

Casgevy is a treatment that uses CRISPR on isolated cells. It has serious side effects, but not as bad as eli-cel. But a lot of people misunderstand what CRISPR actually does.

CRISPR is a technique that uses the Cas9 enzyme to cut double-stranded DNA according to added guide RNA. It doesn't insert DNA itself, but if DNA segments are added that are compatible with the cut section, they sometimes get inserted by homology-directed repair.

So, there are a few obvious issues here:

Cas9 has to be delivered to cells.Sometimes Cas9 cuts the wrong spot; it depends on the sequences.Sometimes the added DNA doesn't get inserted.Double-stranded DNA break repair can have problems.

Also, DNA repair is different in different kinds of human cells, and CRISPR doesn't seem to work as well in non-stem cells.

Currently, physical methods (microinjection technology, electroporation, and HTVI) are commonly used for delivering CRISPR/Cas9. But those aren't very practical in live animals, and also have large effects on cells.

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How about mRNA delivery of CRISPR, then?

Yes, delivering mRNA that codes for Cas9 can work. It might be a better approach for medicine.

That will still probably be limited to isolated cells in general. In live animals, you run into a lot of problems with immune system reactions to Cas9; when that's the desired effect you have mRNA vaccines, which are rather well-known now.

After treatment, any proteins that weren't already being produced can also cause an immune reaction. Eli-cel hasn't had as many immune system rejections as transplants, but it's still been a problem. It doesn't work as well in people with the ABCD1 gene fully deleted instead of nonfunctional, probably because the fixed protein is similar enough to the (already-produced) flawed version to not have an immune response.

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If Cas9 doesn't insert genes, how about bridge RNAs with IS110, that fancy RNA-guided DNA editing technique that was in the news?

That currently only works for bacteria. The guy who discovered it wants to use AI to modify that enzyme so it works in humans, but I think that's probably not usable for eukaryotes. It seems useful for making GM microbes, but plasmid synthesis is already easier than CRISPR.

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OK then, how about editing a virus so whatever inserts viral DNA is more selective?

Ah, a modified retroviral integrase? A selective one won't evolve naturally because the success rate of inserting something somewhere will be lower, but the existence of eg (Cas9 and IS110 and homology-directed repair) shows such an enzyme should be possible. One of my friends has actually worked on this a bit, but they're sort of holding back because of concerns about bioweapons. (They're smarter than me and I'm not qualified to second-guess their concerns.)

Even if the integrase of a virus can't be made sequence-specific, there could still be benefits to modifying its insertion tendencies. If a lentivirus is better than a γ-retrovirus in terms of where it tends to insert DNA, then maybe you can do better than either.

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