posted on 2021-06-22, 17:36authored byJake C. Lachowicz, Anthony S. Gizzi, Steven C. Almo, Tyler L. Grove
Viperin
is a member of the radical S-adenosylmethionine
superfamily and has been shown to restrict the replication of a wide
range of RNA and DNA viruses. We recently demonstrated that human
viperin (HsVip) catalyzes the conversion of CTP to 3′-deoxy-3′,4′-didehydro-CTP
(ddhCTP or ddh-synthase), which acts as a chain terminator for virally
encoded RNA-dependent RNA polymerases from several flaviviruses. Viperin
homologues also exist in non-chordate eukaryotes (e.g., Cnidaria and
Mollusca), numerous fungi, and members of the archaeal and eubacterial
domains. Recently, it was reported that non-chordate and non-eukaryotic
viperin-like homologues are also ddh-synthases and generate a diverse
range of ddhNTPs, including the newly discovered ddhUTP and ddhGTP.
Herein, we expand on the catalytic mechanism of mammalian, fungal,
bacterial, and archaeal viperin-like enzymes with a combination of
X-ray crystallography and enzymology. We demonstrate that, like mammalian
viperins, these recently discovered viperin-like enzymes operate through
the same mechanism and can be classified as ddh-synthases. Furthermore,
we define the unique chemical and physical determinants supporting
ddh-synthase activity and nucleotide selectivity, including the crystallographic
characterization of a fungal viperin-like enzyme that utilizes UTP
as a substrate and a cnidaria viperin-like enzyme that utilizes CTP
as a substrate. Together, these results support the evolutionary conservation
of the ddh-synthase activity and its broad phylogenetic role in innate
antiviral immunity.