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Genetic studies have identified thousands of individual disease-associated non-coding alleles, but the identification of the causal alleles and their functions remains a critical bottleneck. CRISPR-Cas editing has enabled targeted modification of DNA to introduce and test disease alleles. However, the combination of inefficient editing, heterogeneous editing outcomes in individual cells and nonspecific transcriptional changes caused by editing and culturing conditions limits the ability to detect the functional consequences of disease alleles. To overcome these challenges, we present a multi-omic single-cell sequencing approach that directly identifies genomic DNA edits, assays the transcriptome and measures cell-surface protein expression. We apply this approach to investigate the effects of gene disruption, deletions in regulatory regions, non-coding single-nucleotide polymorphism alleles and multiplexed editing. We identify the effects of individual single-nucleotide polymorphisms, including the state-specific effects of an IL2RA autoimmune variant in primary human T cells. Multimodal functional genomic single-cell assays, including DNA sequencing, enable the identification of causal variation in primary human cells and bridge a crucial gap in our understanding of complex human diseases.