Recently, a new class of HIV-1 integrase (IN) inhibitors with a dual mode of action, called IN-LEDGF/p75 allosteric inhibitors (INLAIs), was described. Designed to interfere with the IN-LEDGF/p75 interaction during viral integration, unexpectedly, their major impact was on virus maturation. This activity has been linked to induction of aberrant IN multimerization, while inhibition of the IN-LEDGF/p75 interaction accounts for weaker antiretroviral effect at integration. Since these dual activities result from INLAI binding to IN at a single binding site, we expected that these activities co-evolved together, driven by the affinity for IN. Using an original INLAI, MUT-A, and its activity on an Ala-125 (A125) IN variant, we found that these two activities on A125 IN can be fully dissociated: MUT-A-induced IN multimerization and the formation of eccentric condensates in viral particles, that are responsible for inhibition of virus maturation, were lost, while inhibition of the IN-LEDGF/p75 interaction and consequently integration, was fully retained. Hence the mere binding of INLAI to A125 IN is insufficient to promote the conformational changes of IN required for aberrant multimerization. By analyzing the Xray structures of MUT-A bound to the IN catalytic core domain (CCD) with or without the A125 polymorphism, we discovered that the loss of IN multimerization is due to stabilization of the A125 IN variant CCD dimer, highlighting the importance of the CCD dimerization energy for IN multimerization. Our study reveals that affinity for the LEDGF/p75-binding pocket is not sufficient to induce INLAI-dependent IN multimerization and the associated inhibition of viral maturation.The integrase (IN) protein of Human Immunodeficiency Virus type 1 (HIV-1) catalyzes the stable insertion of the viral cDNA genome into the host cell chromatin, a step of the viral life cycle that is required for efficient viral gene expression. Integration occurs via a two-step reaction where IN initially cleaves after a conserved CA dinucleotide at the 3' end of the viral cDNA genome to free a 3'-OH group (3' processing), which is next used to carry out a nucleophilic attack on cellular chromosomal DNA (strand transfer).IN is one of the preferred targets for the development of antiretroviral (ARV) drugs. However, given the high genetic variability of HIV-1, IN mutations conferring cross-resistance to the first generation INSTIs, RAL and EVG, were described in patients receiving INSTI-containing regimens (2). The second generation INSTI DTG has a higher genetic barrier and conserves good ARV activity against a number of RAL-and EVGresistant strains. Recent reports showed that Bictegravir, a second generation INSTI still in development from Gilead Sciences, has a resistance profile similar to DTG (3). Nevertheless, DTG and Bictegravir are sensitive to the most detrimental INSTI resistant mutations albeit at lower levels than first generation INSTIs (4). Therefore, the development of small molecule inhibitors impairing IN functions with dis...
Penicillin-binding proteins (PBPs) are the targets of the β-lactams, the most successful class of antibiotics ever developed against bacterial infections. Unfortunately, the worldwide and rapid spread of large spectrum β-lactam resistance genes such as carbapenemases is detrimental to the use of antibiotics in this class. New potent PBP inhibitors are needed, especially compounds that resist β-lactamase hydrolysis. Here we describe the structure of the E. coli PBP2 in its Apo form and upon its reaction with 2 diazabicyclo derivatives, avibactam and CPD4, a new potent PBP2 inhibitor. Examination of these structures shows that unlike avibactam, CPD4 can perform a hydrophobic stacking on Trp370 in the active site of E. coli PBP2. This result, together with sequence analysis, homology modeling, and SAR, allows us to propose CPD4 as potential starting scaffold to develop molecules active against a broad range of bacterial species at the top of the WHO priority list.
An efficient and modulable total synthesis of discodermolide (DDM), a unique marine anticancer polyketide is described including related alternative synthetic approaches. Particularly notable is the repeated application of a crotyltitanation reaction to yield homoallylic (Z)-O-ene-carbamate alcohols with excellent selectivity. Advantage was taken of this reaction not only for the stereocontrolled building of the syn-anti methyl-hydroxy-methyl triads of DDM, but also for the direct construction of the terminal (Z)-diene. Of particular interest is also the installation of the C13=C14 (Z)-double bond through a highly selective dyotropic rearrangement. The preparation of the middle C8-C14 fragment in two sequential stages and its coupling to the C1-C7 moiety was a real challenge and required careful optimization. Several synthetic routes were explored to allow high and reliable yields. Due to the flexibility and robust character of this approach, it might enable a systematic structural variation of DDM and, therefore, the elaboration and exploration of novel discodermolide structural analogues.
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