The protease of dengue virus is a promising target for antiviral drug discovery. We here report a new generation of peptide-hybrid inhibitors of dengue protease that incorporate N-substituted 5-arylidenethiazolidinone heterocycles (rhodanines and thiazolidinediones) as N-terminal capping groups of the peptide moiety. The compounds were extensively characterized with respect to inhibition of various proteases, inhibition mechanisms, membrane permeability, antiviral activity, and cytotoxicity in cell culture. A sulfur/oxygen exchange in position 2 of the capping heterocycle (thiazolidinedione-capped vs rhodanine-capped peptide hybrids) has a significant effect on these properties and activities. The most promising in vitro affinities were observed for thiazolidinedione-based peptide hybrids containing hydrophobic groups with Ki values between 1.5 and 1.8 μM and competitive inhibition mechanisms. Rhodanine-capped peptide hybrids with hydrophobic substituents have, in correlation with their membrane permeability, a more pronounced antiviral activity in cell culture than the thiazolidinediones.
Pathogen-selective labeling was achieved by using the novel gemcitabine metabolite analogue 2'-deoxy-2',2'-difluoro-5-ethynyluridine (dF-EdU) and click chemistry. Cells infected with Herpes Simplex Virus-1 (HSV-1), but not uninfected cells, exhibit nuclear staining upon the addition of dF-EdU and a fluorescent azide. The incorporation of the dF-EdU into DNA depends on its phosphorylation by a herpes virus thymidine kinase (TK). Crystallographic analyses revealed how dF-EdU is well accommodated in the active site of HSV-1 TK, but steric clashes prevent dF-EdU from binding human TK. These results provide the first example of pathogen-enzyme-dependent incorporation and labeling of bioorthogonal functional groups in human cells.
Fluorescent
nucleoside triphosphates are powerful probes of DNA
synthesis, but their potential use in living animals has been previously
underexplored. Here, we report the synthesis and characterization
of 7-deaza-(1,2,3-triazole)-2′-deoxyadenosine-5′-triphosphate
(dATP) derivatives of tetramethyl rhodamine (“TAMRA-dATP”),
cyanine (“Cy3-dATP”), and boron-dipyrromethene (“BODIPY-dATP”).
Upon microinjection into live zebrafish embryos, all three compounds
were incorporated into the DNA of dividing cells; however, their impact
on embryonic toxicity was highly variable, depending on the exact
structure of the dye. TAMRA-EdATP exhibited superior characteristics
in terms of its high brightness, low toxicity, and rapid incorporation
and depletion kinetics in both a vertebrate (zebrafish) and a nematode
(Caenorhabditis elegans). TAMRA-EdATP
allows for unprecedented, real-time visualization of DNA replication
and chromosome segregation in vivo.
Modified
nucleoside triphosphates (NTPs) are powerful probes and
medicines, but their anionic character impedes membrane permeability.
As such, invasive delivery techniques, transport carriers, or prodrug
strategies are required for their in vivo use. Here,
we present a fluorescent 2′-deoxyribonucleoside triphosphate
“TAMRA-dATP” that exhibits surprisingly high bioavailability in vivo. TAMRA-dATP spontaneously forms nanoparticles in
Mg+2-containing buffers that are taken into the vesicles
of living cells and animals by energy-dependent processes. In cell
cultures, photochemical activation with yellow laser light (561 nm)
facilitated endosomal escape of TAMRA-dATP, resulting in its metabolic
incorporation into DNA in vitro. In contrast, in vivo studies revealed that TAMRA-dATP is extensively
trafficked by active pathways into cellular DNA of zebrafish (Danio rerio) and Caenorhabditis elegans where DNA labeling was observed in live animals, even without photochemical
release. Metabolic labeling of DNA in whole, living animals can therefore
be achieved by simply soaking animals in a buffer containing TAMRA-dATP
or a structurally related compound, Cy3-dATP.
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