Using a training set of diketo-like acid HIV-1 integrase (IN) strand-transfer inhibitors, a 3D pharmacophore model was derived having quantitative predictive ability in terms of activity. The best statistical hypothesis consisted of four features (one hydrophobic aromatic region, two hydrogen-bond acceptors, and one hydrogen-bond donor) with r of 0.96. The resulting pharmacophore model guided the rational design of benzylindoles as new potent IN inhibitors, whose microwave-assisted synthesis and biological evaluation are reported.
Graphene quantum dots (GQD) are the next generation of nanomaterials with great potential in drug delivery and target-specific HIV inhibition. In this study we investigated the antiviral activity of graphene based nanomaterials by using water-soluble GQD synthesized from multiwalled carbon nanotubes (MWCNT) through prolonged acidic oxidation and exfoliation and compared their anti-HIV activity with that exerted by reverse transcriptase inhibitors (RTI) conjugated with the same nanomaterial. The antiretroviral agents chosen in this study, CHI499 and CDF119, belong to the class of non-nucleoside reverse transcriptase inhibitors (NNRTI). From this study emerged the RTI-conjugated compound GQD-CHI499 as a good potential candidate for HIV treatment, showing an IC of 0.09 μg/mL and an EC value in cell of 0.066 μg/mL. The target of action in the replicative cycle of HIV of the drug conjugated samples GQD-CHI499 and GQD-CDF119 was also investigated by a time of addition (TOA) method, showing for both conjugated samples a mechanism of action similar to that exerted by NNRTI drugs.
The cellular protein lens epithelium‐derived growth factor, or transcriptional coactivator p75 (LEDGF/p75), plays a crucial role in HIV integration. The protein–protein interactions (PPIs) between HIV‐1 integrase (IN) and its cellular cofactor LEDGF/p75 may therefore serve as targets for the development of new anti‐HIV drugs. In this work, a structure‐based pharmacophore model for potential small‐molecule inhibitors of HIV‐1 IN–LEDGF/p75 interaction was developed using the LigandScout software. The 3D model obtained was used for virtual screening of our in‐house chemical database, CHIME, leading to the identification of compound CHIBA‐3002 as an interesting hit for further optimization. The rational design, synthesis and biological evaluation of four derivatives were then carried out. Our studies resulted in the discovery of a new and more potent small molecule (7, CHIBA‐3003) that is able to interfere with the HIV‐1 IN–LEDGF/p75 interaction at micromolar concentration, representing one of the first compounds to show activity against these specific PPIs. Docking simulations were subsequently performed in order to investigate the possible binding mode of our new lead compound to HIV‐1 IN. This study is a valid starting point for the identification of anti‐HIV agents with a different mechanism of action from currently available antiviral drugs.
TBZE-029 {1-(2,6-difluorophenyl)-6-trifluoromethyl-1H,3H-thiazolo[3,4-a]benzimidazole} is a novel selec-Entero-and rhinoviruses are involved in a wide range of infections in humans and animals. Among the species in the enterovirus genus are the coxsackieviruses, which have been reported to be associated with various clinical manifestations, including myocarditis, pancreatitis, meningitis, and encephalitis. Other clinically relevant enteroviruses are poliovirus, which can cause paralytic poliomyelitis, and echovirus, causing aseptic meningitis or encephalomyelitis (33,36,43). Rhinoviruses are the main pathogens associated with the common cold, and, although usually mild and self-limiting, rhinovirus infections have an enormous socioeconomical impact (47,59).Enteroviruses belong to the family Picornaviridae, which consists of small, nonenveloped viruses containing a singlestranded positive-strand RNA [(ϩ)RNA] genome of 7.5 kb, which is covalently linked to a small viral protein (VPg) at its 5Ј end and polyadenylated at its 3Ј end (49). The genomic RNA has a long, highly structured 5Ј noncoding region, which contains the internal ribosome entry site, necessary for translation initiation, and a shorter 3Ј noncoding region preceding the poly(A) tract, which are both thought to be involved in RNA replication and translation (9). The coding region encodes a single polyprotein that will eventually be cleaved to generate 4 structural and 10 nonstructural proteins (either mature or in their precursor form). The icosahedral capsid of the virus is formed by 60 protomers, each one assembled by the four structural proteins, designated VP1 to -4. The nonstructural region comprises two proteases, the viral RNA-dependent RNA polymerase and seven other proteins that are involved in viral replication (8).One of the most conserved nonstructural viral proteins among picornaviruses is 2C. Although this protein is an indispensable component of the replication complex, its exact role in viral replication has remained elusive. Protein 2C appears to be multifunctional, and this entails multiple interactions (23). The amino acid sequence of 2C contains three conserved motifs which are typically found in NTP-binding proteins (motifs A and B) or in members of helicase superfamily III (motif C) (28)(29)(30)(31)69). In fact, ATPase activity has been demonstrated for several picornavirus 2C proteins (37, 57, 60) whereas so far, every attempt to demonstrate in vitro RNA helicase activity has failed. Protein 2C contains two regions involved in RNA binding (58). It has been suggested that, in poliovirus, this binding occurs at the 3Ј cloverleaf of (Ϫ)RNA (3-5); for echovirus, RNA binding was reported to occur in a nonspecific way
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