A Genome-wide Map of CTCF Multivalency Redefines the CTCF Code

The “CTCF code” hypothesis posits that CTCF pleiotropic functions are driven by recognition of diverse sequences through combinatorial use of its 11 zinc fingers (ZFs). This model, however, is supported by in vitro binding studies of a limited number of sequences. To study CTCF multivalency in vivo, we define ZF binding requirements at ∼50,000 genomic sites in primary lymphocytes. We find that CTCF reads sequence diversity through ZF clustering. ZFs 4–7 anchor CTCF to ∼80% of targets containing the core motif. Nonconserved flanking sequences are recognized by ZFs 1–2 and ZFs 8–11 clusters, which also stabilize CTCF broadly. Alternatively, ZFs 9–11 associate with a second phylogenetically conserved upstream motif at ∼15% of its sites. Individually, ZFs increase overall binding and chromatin residence time. Unexpectedly, we also uncovered a conserved downstream DNA motif that destabilizes CTCF occupancy. Thus, CTCF associates with a wide array of DNA modules via combinatorial clustering of its 11 ZFs. [Display omitted] •Genome-wide maps of 11 CTCF zinc finger mutants in B lymphocytes•Zinc finger mutations differentially affect CTCF binding and nuclear mobility•CTCF uses zinc finger clusters to recognize DNA sequence diversity•DNA sequences flanking the core motif modulate CTCF binding CTCF is a nuclear architectural protein that binds to thousands of highly diverse sequences in eukaryotes. The current hypothesis, known as the “CTCF code,” proposes that CTCF binds DNA targets through combinatorial use of its 11 zinc fingers (ZFs). This model, however, is mostly supported by in vitro binding studies. By expressing ZF mutants in B lymphocytes, Resch, Casellas, and colleagues now present genome-wide maps of CTCF multivalency. They show that CTCF reads sequence diversity by relying on well-defined ZF clusters.