- Muench, David;
- Olsson, Andre;
- Ferchen, Kyle;
- Pham, Giang;
- Serafin, Rachel;
- Chutipongtanate, Somchai;
- Dwivedi, Pankaj;
- Song, Baobao;
- Hay, Stuart;
- Chetal, Kashish;
- Trump-Durbin, Lisa;
- Mookerjee-Basu, Jayati;
- Zhang, Kejian;
- Yu, Jennifer;
- Lutzko, Carolyn;
- Myers, Kasiani;
- Nazor, Kristopher;
- Greis, Kenneth;
- Kappes, Dietmar;
- Way, Sing;
- Salomonis, Nathan;
- Grimes, H
Advances in genetics and sequencing have identified a plethora of disease-associated and disease-causing genetic alterations. To determine causality between genetics and disease, accurate models for molecular dissection are required; however, the rapid expansion of transcriptional populations identified through single-cell analyses presents a major challenge for accurate comparisons between mutant and wild-type cells. Here we generate mouse models of human severe congenital neutropenia (SCN) using patient-derived mutations in the GFI1 transcription factor. To determine the effects of SCN mutations, we generated single-cell references for granulopoietic genomic states with linked epitopes1, aligned mutant cells to their wild-type equivalents and identified differentially expressed genes and epigenetic loci. We find that GFI1-target genes are altered sequentially, as cells go through successive states of differentiation. These insights facilitated the genetic rescue of granulocytic specification but not post-commitment defects in innate immune effector function, and underscore the importance of evaluating the effects of mutations and therapy within each relevant cell state.