Table 4.
Gene therapy limitations
| Limitation | Description | Potential solution(s) |
|---|---|---|
|
| ||
| Insertional mutagenesis | Incorporation of viral vector DNA into a host gene driving malignant transformation or cell death | Identification of vectors less prone to high risk sites of DNA insertion (ex. Lentiviral vectors) Use of gene editing methods (ex. Meganucleases, CRISPR-Cas, Transcription activator-like effector-based nucleases (TALENs), Zinc finger nucleases) |
|
| ||
| Genetic heterogeneity | 21 known gene mutations leading to FA | Target highest frequency complementation group, FANCA (accounts for 60% of cases) [6] |
|
| ||
| Non-hematopoietic disease manifestations | Somatic cells continue to express FA mutations and contribute to risk of solid tumor development | Correction of FA HSCs may improve immune surveillance for transformation of somatic cells Avoid exacerbating exposures (chronic GVHD, mutagens, UV radiation) |
|
| ||
| FA HSPCs: | ||
| - Acquired mutations | FA HSPCs accumulate mutations over time resulting at times in MDS or leukemia | Derive healthy HSPCs from somatic induced pluripotent stem (iPS) cells (not yet demonstrated scientifically) [83–86] |
| - Sensitivity to apoptosis | DNA damage prompts apoptosis | |
| - Low HSPC numbers | FA patients with 2-fold reduction in overall cellularity and 6-fold fewer CD34+ HSPCs compared to healthy controls [82] | Utilize ex vivo HSPC expansion strategies such as aryl hydrocarbon receptor antagonist StemRegenin1 [87], Notch ligand [88, 89], nicotinamide analogs [90], copper chelators [91, 92] |
FA, Fanconi anemia; HSCs, hematopoietic stem cells; GVHD, graft-versus-host disease; HSPCs, hematopoietic stem and progenitor cells; MDS, myelodysplastic syndrome