The HIV-1 capsid (CA) protein plays essential roles in both early and late stages of HIV-1 replication and is considered an important, clinically unexploited therapeutic target. As such, small drug-like molecules that inhibit this critical HIV-1 protein have become a priority for several groups. Therefore, in this study we explore small molecule targeting of the CA protein, and in particular a very attractive inter-protomer pocket. We report the design, parallel synthesis, and anti-HIV-1 activity evaluation of a series of novel phenylalanine derivatives as HIV-1 CA protein inhibitors synthesized via Cu(I)-catalyzed alkyne-azide 1,3-dipolar cycloaddition (CuAAC) reaction. We demonstrate robust inhibitory activity over a range of potencies against the HIV-1 NL reference strain. In particular, compound 13m exhibited the greatest potency and lowest toxicity within this new series with an EC value of 4.33 μM and CC value of >57.74 μM (SI > 13.33). These values are very similar to the lead compound PF-74 (EC = 5.95 μM, CC > 70.50 μM, SI > 11.85) in our assay, despite significant structural difference. Furthermore, we demonstrate via surface plasmon resonance (SPR) binding assays that 13m interacts robustly with recombinant HIV-1 CA and exhibits antiviral activity in both the early and late stages of HIV-1 replication. Overall, the novel parallel synthesis and structure-activity relationships (SARs) identified within this study set the foundation for further rational optimization and discovery of CA-targeting compounds with improved potency.
The continuous spread of SARS-CoV-2 calls for more direct-acting antiviral agents to
combat the highly infectious variants. The main protease (M
pro
) is an
promising target for anti-SARS-CoV-2 drug design. Here, we report the discovery of
potent non-covalent non-peptide M
pro
inhibitors featuring a
1,2,4-trisubstituted piperazine scaffold. We systematically modified the non-covalent
hit MCULE-5948770040 by structure-based rational design combined with multi-site binding
and privileged structure assembly strategies. The optimized compound
GC-14
inhibits M
pro
with high potency (IC
50
= 0.40 μM) and
displays excellent antiviral activity (EC
50
= 1.1 μM), being more
potent than Remdesivir. Notably,
GC-14
exhibits low cytotoxicity
(CC
50
> 100 μM) and excellent target selectivity for SARS-CoV-2
M
pro
(IC
50
> 50 μM for cathepsins B, F, K, L, and
caspase 3). X-ray co-crystal structures prove that the inhibitors occupy multiple
subpockets by critical non-covalent interactions. These studies may provide a basis for
developing a more efficient and safer therapy for COVID-19.
There is an urgent unmet medical need for novel human immunodeficiency virus type 1 (HIV-1) inhibitors that are effective against a variety of NNRTI-resistance mutations. We report our research efforts aimed at discovering a novel chemotype of anti-HIV-1 agents with improved potency against a variety of NNRTI-resistance mutations in this paper. Structural modifications of the lead K-5a2 led to the identification of a potent inhibitor 16c. 16c yielded highly potent anti-HIV-1 activities and improved resistance profiles compared with the approved drug etravirine. The co-crystal structure revealed the key role of the water networks surrounding the NNIBP for binding and for resilience against resistance mutations, while suggesting further extension of 16c toward the NNRTI-adjacent site as a lead development strategy. Furthermore, 16c demonstrated favorable pharmacokinetic and safety properties, suggesting the potential of 16c as a promising anti-HIV-1 drug candidate.
A novel series of diarylpyrimidine derivatives, which could simultaneously occupy the classical NNRTIs binding pocket (NNIBP) and the newly reported "NNRTI Adjacent" binding site, were designed, synthesized, and evaluated for their antiviral activities in MT-4 cell cultures. The results demonstrated that six compounds (, and-) showed excellent activities against wild-type (WT) HIV-1 strain (EC = 2.4-3.8 nM), which were more potent than that of ETV (EC = 4.0 nM). Furthermore, ,, , and showed more potent or equipotent activity against single mutant HIV-1 strains compared to that of ETV. Especially, showed marked antiviral activity, which was 1.5-fold greater against WT and 1.5- to 3-fold greater against L100I, K103N, Y181C, Y188L, and E138K when compared with ETV. In addition, all compounds showed lower toxicity (CC = 5.1-149.2 μM) than ETV (CC = 2.2 μM). The HIV-1 RT inhibitory assay was further conducted to confirm their binding target. Preliminary structure-activity relationships (SARs), molecular modeling, and calculated physicochemical properties of selected compounds were also discussed comprehensively.
Novel phenylalanine derivatives were discovered as HIV-1 capsid protein inhibitors via “click reaction”. Most of them exhibited remarkable anti-HIV-1 activity.
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