The NS2B/NS3 serine proteases of the Zika and Dengue
flaviviruses
are attractive targets for the development of antiviral drugs. We
report the synthesis and evaluation of a new, proline-based compound
class that displays allosteric inhibition of both proteases. The structural
features relevant for protease binding and inhibition were determined
to establish them as new lead compounds for flaviviral inhibitors.
Based on our structure–activity relationship studies, the molecules
were further optimized, leading to inhibitors with submicromolar IC50 values and improved lipophilic ligand efficiency. The allosteric
binding site in the proteases was probed using mutagenesis and covalent
modification of the obtained cysteine mutants with maleimides, followed
by computational elucidation of the possible binding modes. In infected
cells, antiviral activity against Dengue virus serotype 2 using prodrugs
of the inhibitors was observed. In summary, a novel inhibitor scaffold
targeting an allosteric site shared between flaviviral NS2B/NS3 proteases
is presented whose efficacy is demonstrated in vitro and in cellulo.
Rhodesain is a major cysteine protease of Trypanosoma brucei rhodesiense, a pathogen causing Human African Trypanosomiasis, and a validated drug target. Recently, we reported the development of α-halovinylsulfones as a new class of covalent reversible cysteine protease inhibitors. Here, αfluorovinylsulfones/-sulfonates were optimized for rhodesain based on molecular modeling approaches. 2d, the most potent and selective inhibitor in the series, shows a single-digit nanomolar affinity and high selectivity toward mammalian cathepsins B and L. Enzymatic dilution assays and MS experiments indicate that 2d is a slow-tight binder (K i = 3 nM). Furthermore, the nonfluorinated 2d-(H) shows favorable metabolism and biodistribution by accumulation in mice brain tissue after intraperitoneal and oral administration. The highest antitrypanosomal activity was observed for inhibitors with an N-terminal 2,3-dihydrobenzo [b][1,4]dioxine group and a 4-Me-Phe residue in P2 (2e/4e) with nanomolar EC 50 values (0.14/0.80 μM). The different mechanisms of reversible and irreversible inhibitors were explained using QM/MM calculations and MD simulations.
Selective manipulation of the epitranscriptome could
be beneficial
for the treatment of cancer and also broaden the understanding of
epigenetic inheritance. Inhibitors of the tRNA methyltransferase DNMT2,
the enzyme catalyzing the S-adenosylmethionine-dependent
methylation of cytidine 38 to 5-methylcytidine, were designed, synthesized,
and analyzed for their enzyme-binding and -inhibiting properties.
For rapid screening of potential DNMT2 binders, a microscale thermophoresis
assay was established. Besides the natural inhibitors S-adenosyl-l-homocysteine (SAH) and sinefungin (SFG), we
identified new synthetic inhibitors based on the structure of N-adenosyl-2,4-diaminobutyric acid (Dab). Structure–activity
relationship studies revealed the amino acid side chain and a Y-shaped
substitution pattern at the 4-position of Dab as crucial for DNMT2
inhibition. The most potent inhibitors are alkyne-substituted derivatives,
exhibiting similar binding and inhibitory potencies as the natural
compounds SAH and SFG. CaCo-2 assays revealed that poor membrane permeabilities
of the acids and rapid hydrolysis of an ethylester prodrug might be
the reasons for the insufficient activity in cellulo.
Inhibition of coronavirus (CoV)‐encoded papain‐like cysteine proteases (PLpro) represents an attractive strategy to treat infections by these important human pathogens. Herein we report on structure‐activity relationships (SAR) of the noncovalent active‐site directed inhibitor (R)‐5‐amino‐2‐methyl‐N‐(1‐(naphthalen‐1‐yl)ethyl) benzamide (2 b), which is known to bind into the S3 and S4 pockets of the SARS‐CoV PLpro. Moreover, we report the discovery of isoindolines as a new class of potent PLpro inhibitors. The studies also provide a deeper understanding of the binding modes of this inhibitor class. Importantly, the inhibitors were also confirmed to inhibit SARS‐CoV‐2 replication in cell culture suggesting that, due to the high structural similarities of the target proteases, inhibitors identified against SARS‐CoV PLpro are valuable starting points for the development of new pan‐coronaviral inhibitors.
Targeting RNA with small molecules is an emerging field.
While
several ligands for different RNA targets are reported, structure-based
virtual screenings (VSs) against RNAs are still rare. Here, we elucidated
the general capabilities of protein-based docking programs to reproduce
native binding modes of small-molecule RNA ligands and to discriminate
known binders from decoys by the scoring function. The programs were
found to perform similar compared to the RNA-based docking tool rDOCK,
and the challenges faced during docking, namely, protomer and tautomer
selection, target dynamics, and explicit solvent, do not largely differ
from challenges in conventional protein-ligand docking. A prospective
VS with the Bacillus subtilis preQ1-riboswitch aptamer domain performed with FRED, HYBRID, and
FlexX followed by microscale thermophoresis assays identified six
active compounds out of 23 tested VS hits with potencies between 29.5
nM and 11.0 μM. The hits were selected not solely based on their
docking score but for resembling key interactions of the native ligand.
Therefore, this study demonstrates the general feasibility to perform
structure-based VSs against RNA targets, while at the same time it
highlights pitfalls and their potential solutions when executing RNA–ligand
docking.
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