ABSTRACT
JBP1 (J-DNA Binding Protein 1) contributes to biosynthesis and maintenance of base J (β-D-glucosyl-hydroxymethyluracil), a modification of thymidine (T) confined to pathogenic protozoa. JBP1 has two known functional domains: an N-terminal thymidine hydroxylase (TH) homologous to the 5-methylcytosine hydroxylase domain in TET proteins; and a J-DNA binding domain (JDBD) that resides in the middle of JBP1. Here we show that removing JDBD from JBP1 results in a soluble protein (Δ-JDBD) with the N- and C-terminal regions tightly associated together in a well-ordered domain. This Δ-JDBD domain retains thymidine hydroxylation activity in vitro, but displays a fifteen-fold lower apparent rate of hydroxylation compared to JBP1. Small Angle X-ray Scattering (SAXS) experiments on JBP1 and JDBD in the presence and absence of J-DNA, and on Δ-JDBD, allowed us to generate low-resolution three-dimensional models. We conclude that Δ-JDBD, and not the N-terminal region of JBP1 alone, is a distinct folding unit. Our SAXS-based model supports the notion that binding of JDBD specifically to J-DNA can facilitate hydroxylation a T 12–14 bp downstream on the complementary strand of the J-recognition site. We postulate that insertion of the JDBD module in the Δ-JDBD scaffold during evolution provided a mechanism to synergize between J recognition and T hydroxylation, ensuring inheritance of J in specific sequence patterns following DNA replication.
Footnotes
The authors wish it to be known that, in their opinion, the first two authors should be regarded as joint First Authors. Lead contact: Anastassis Perrakis, a.perrakis{at}nki.nl