In the context of gene therapy, the estimated number of active, repopulating HSPCs was correlated with the number of HSPCs per kg infused.
An analysis of human HSPC clonal lineage outputs highlighted the presence of myeloid-dominant, lymphoid-dominant and balanced cell subsets.
In gene therapy with human hematopoietic stem and progenitor cells (HSPCs), each gene-corrected cell and its progeny are marked in a unique way by the integrating vector. This feature enables lineages to be tracked by sampling blood cells and using DNA sequencing to identify the vector integration sites. Here, we studied five cell lineages (granulocytes, monocytes, T cells, B cells, and natural killer cells) in patients having undergone HSPC gene therapy for Wiskott-Aldrich syndrome or beta hemoglobinopathies. We found that the estimated minimum number of active, repopulating HSPCs (which ranged from 2,000 to 50,000) was correlated with the number of HSPCs per kg infused. We sought to quantify the lineage output and dynamics of gene-modified clones; this is usually challenging because of (i) sparse sampling of the various cell types during the analytical procedure, (ii) contamination during cell isolation, and (iii) different levels of vector marking in the various lineages. We therefore measured the residual contamination and corrected our statistical models accordingly, in order to provide a rigorous analysis of the HSPC lineage output. A cluster analysis of the HSPC lineage output highlighted the existence of several stable, distinct differentiation programs, including myeloid-dominant, lymphoid-dominant and balanced cell subsets. Our study evidenced the heterogeneous nature of the cell lineage output from HSPCs, and provided methods for analyzing these complex data.