Lili Huang, Satoko Ishibe-Murakami, Dinshaw J. Patel, and
Alexander Serganov
Tetrahydrofolate
(THF), a biologically active form of the vitamin folate (B9), is an essential cofactor in one-carbon transfer
reactions. In bacteria, expression of folate-related genes is controlled by
feedback modulation in response to specific binding of THF and related
compounds to a riboswitch. Here, we present the X-ray structures of the
THF-sensing domain from the Eubacterium siraeumriboswitch
in the ligand-bound and unbound states. The structure reveals an “inverted”
three-way junctional architecture, most unusual for riboswitches, with the
junction located far from the regulatory helix P1 and not directly
participating in helix P1 formation. Instead, the three-way junction,
stabilized by binding to the ligand, aligns the riboswitch stems for long-range
tertiary pseudoknot interactions that contribute to the organization of helix
P1 and therefore stipulate the regulatory response of the riboswitch. The
pterin moiety of the ligand docks in a semiopen pocket adjacent to the
junction, where it forms specific hydrogen bonds with two moderately conserved
pyrimidines. The aminobenzoate moiety stacks on a guanine base, whereas the
glutamate moiety does not appear to make strong interactions with the RNA. In
contrast to other riboswitches, these findings demonstrate that the THF
riboswitch uses a limited number of available determinants for ligand
recognition. Given that modern antibiotics target folate metabolism, the THF
riboswitch structure provides insights on mechanistic aspects of riboswitch
function and may help in manipulating THF levels in pathogenic bacteria.
Journal: Proceedings of the National Academy of Sciences
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