3D mapping and accelerated super-resolution imaging of the human genome using in situ sequencing.

That genome function may respond to its three-dimensional (3D) organization highlights the need for methods that can image genomes with superior coverage as well as greater genomic and optical resolution. Here, we push toward this goal by introducing OligoFISSEQ, a suite of three methods that leverage fluorescent in situ sequencing of barcoded Oligopaint probes to enable the rapid visualization of many targeted genomic regions. Applying OligoFISSEQ to human diploid fibroblast cells, we show how only four rounds of sequencing are sufficient to produce 3D maps of 66 genomic targets across 6 chromosomes in hundreds to thousands of cells. We then use OligoFISSEQ to trace chromosomes at finer resolution, following the path of the X chromosome through 46 regions, with separate studies showing compatibility of OligoFISSEQ with immunochemistry. Finally, we combined OligoFISSEQ with OligoSTORM, laying the foundation for accelerated single-molecule super-resolution imaging of large swaths of, if not entire, human genomes.