Recognition of histone covalent modifications by “reader” modules constitutes a major mechanism for epigenetic regulation. A recent upsurge of newly discovered histone lysine acylations, such as crotonylation (Kcr), butyrylation (Kbu), and propionylation (Kpr), greatly expands the coding potential of histone lysine modifications. Here we demonstrate that the histone acetylation-binding double PHD finger (DPF) domains of human MOZ (a.k.a. KAT6A) and DPF2 (a.k.a. BAF45d) accommodate a wide range of histone lysine acylations with the strongest preference for Kcr. Crystal structures of the DPF domain of MOZ in complex with H3K14cr, H3K14bu, and H3K14pr peptides reveal that these non-acetyl acylations are anchored in a hydrophobic “dead-end” pocket with selectivity for crotonylation arising from intimate encapsulation and amide-sensing hydrogen bonding network. Immunofluorescence and ChIP-qPCR show that MOZ and H3K14cr colocalize in a DPF-dependent manner. Our studies call attention to a new regulatory mechanism centered on histone crotonylation readout by DPF family members.
Viral DNA sensing within the cytosol of infected cells activates type I interferon (IFN) expression. MITA/STING plays an essential role in this pathway by acting as both a sensor for the second messenger cGAMP and as an adaptor for downstream signaling components. In an expression screen for proteins that can activate the IFNB1 promoter, we identified the ER-associated protein ZDHHC1 as a positive regulator of virus-triggered, MITA/STING-dependent immune signaling. Zdhhc1(-/-) cells failed to effectively produce IFNs and other cytokines in response to infection with DNA but not RNA viruses. Zdhhc1(-/-) mice infected with the neurotropic DNA virus HSV-1 exhibited lower cytokine levels and higher virus titers in the brain, resulting in higher lethality. ZDHHC1 constitutively associated with MITA/STING and mediates dimerization/aggregation of MITA/STING and recruitment of the downstream signaling components TBK1 and IRF3. These findings support a role for ZDHHC1 in mediating MITA/STING-dependent innate immune response against DNA viruses.
Although bespoke, sequence-specific proteases have the potential to advance
biotechnology and medicine, generation of proteases with tailor-made cleavage
specificities remains a major challenge. We developed a phage-assisted protease
evolution system with simultaneous positive and negative selection and applied it
to three botulinum neurotoxin (BoNT) light-chain proteases. We evolved BoNT/X
protease into separate variants that preferentially cleave vesicle-associated
membrane protein 4 (VAMP4) and Ykt6, evolved BoNT/F protease to selectively cleave
the non-native substrate VAMP7, and evolved BoNT/E protease to cleave phosphatase
and tensin homolog (PTEN) but not any natural BoNT protease substrate in neurons.
The evolved proteases display large changes in specificity (218- to
>11,000,000-fold) and can retain their ability to form holotoxins that
self-deliver into primary neurons. These findings establish a versatile platform
for reprogramming proteases to selectively cleave new targets of therapeutic
interest.
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