5 research outputs found
Design, Synthesis, and Structure–Activity Relationship Studies of Novel GPR88 Agonists (4-Substituted-phenyl)acetamides Based on the Reversed Amide Scaffold
The development of synthetic agonists
for the orphan
receptor GPR88
has recently attracted significant interest, given the promise of
GPR88 as a novel drug target for psychiatric and neurodegenerative
disorders. Examination of structure–activity relationships
of two known agonist scaffolds 2-PCCA and 2-AMPP, as well as the recently
resolved cryo-EM structure of 2-PCCA-bound GPR88, led to the design
of a new scaffold based on the “reversed amide” strategy
of 2-AMPP. A series of novel (4-substituted-phenyl)acetamides were
synthesized and assessed in cAMP accumulation assays as GPR88 agonists,
which led to the discovery of several compounds with better or comparable
potencies to 2-AMPP. Computational docking studies suggest that these
novel GPR88 agonists bind to the same allosteric site of GPR88 that
2-PCCA occupies. Collectively, our findings provide structural insight
and SAR requirement at the allosteric site of GPR88 and a new scaffold
for further development of GPR88 allosteric agonists
Design, Synthesis, and Structure–Activity Relationship Studies of Novel GPR88 Agonists (4-Substituted-phenyl)acetamides Based on the Reversed Amide Scaffold
The development of synthetic agonists
for the orphan
receptor GPR88
has recently attracted significant interest, given the promise of
GPR88 as a novel drug target for psychiatric and neurodegenerative
disorders. Examination of structure–activity relationships
of two known agonist scaffolds 2-PCCA and 2-AMPP, as well as the recently
resolved cryo-EM structure of 2-PCCA-bound GPR88, led to the design
of a new scaffold based on the “reversed amide” strategy
of 2-AMPP. A series of novel (4-substituted-phenyl)acetamides were
synthesized and assessed in cAMP accumulation assays as GPR88 agonists,
which led to the discovery of several compounds with better or comparable
potencies to 2-AMPP. Computational docking studies suggest that these
novel GPR88 agonists bind to the same allosteric site of GPR88 that
2-PCCA occupies. Collectively, our findings provide structural insight
and SAR requirement at the allosteric site of GPR88 and a new scaffold
for further development of GPR88 allosteric agonists
A Vancomycin-Templated DNA-Encoded Library for Combating Drug-Resistant Bacteria
It is an urgent need to tackle the global crisis of multidrug-resistant
bacterial infections. We report here an innovative strategy for large-scale
screening of new antibacterial agents using a whole bacteria-based
DNA-encoded library (DEL) of vancomycin derivatives via peripheral
modifications. A bacterial binding affinity assay was established
to select the modification fragments in high-affinity compounds. The
optimal resynthesized derivatives demonstrated excellently enhanced
activity against various resistant bacterial strains and provided
useful structures for vancomycin derivatization. This work presents
the new concept in a natural product-templated DEL and in antibiotic
discovery through bacterial affinity screening, which promotes the
fight against drug-resistant bacteria
A Vancomycin-Templated DNA-Encoded Library for Combating Drug-Resistant Bacteria
It is an urgent need to tackle the global crisis of multidrug-resistant
bacterial infections. We report here an innovative strategy for large-scale
screening of new antibacterial agents using a whole bacteria-based
DNA-encoded library (DEL) of vancomycin derivatives via peripheral
modifications. A bacterial binding affinity assay was established
to select the modification fragments in high-affinity compounds. The
optimal resynthesized derivatives demonstrated excellently enhanced
activity against various resistant bacterial strains and provided
useful structures for vancomycin derivatization. This work presents
the new concept in a natural product-templated DEL and in antibiotic
discovery through bacterial affinity screening, which promotes the
fight against drug-resistant bacteria
Extra Sugar on Vancomycin: New Analogues for Combating Multidrug-Resistant <i>Staphylococcus aureus</i> and Vancomycin-Resistant <i>Enterococci</i>
Lipophilic
substitution on vancomycin is an effective strategy
for the development of novel vancomycin analogues against drug-resistant
bacteria by enhancing bacterial cell wall interactions. However, hydrophobic
structures usually lead to long elimination half-life and accumulative
toxicity; therefore, hydrophilic fragments were also introduced to
the lipo-vancomycin to regulate their pharmacokinetic/pharmacodynamic
properties. Here, we synthesized a series of new vancomycin analogues
carrying various sugar moieties on the seventh-amino acid phenyl ring
and lipophilic substitutions on vancosamine with extensive structure–activity
relationship analysis. The optimal analogues indicated 128–1024-fold
higher activity against methicillin-susceptible <i>S. aureus</i>, vancomycin-intermediate resistant <i>S. aureus</i> (VISA),
and vancomycin-resistant <i>Enterococci</i> (VRE) compared
with that of vancomycin. In vivo pharmacokinetics studies demonstrated
the effective regulation of extra sugar motifs, which shortened the
half-life and addressed concerns of accumulative toxicity of lipo-vancomycin.
This work presents an effective strategy for lipo-vancomycin derivative
design by introducing extra sugars, which leads to better antibiotic-like
properties of enhanced efficacy, optimal pharmacokinetics, and lower
toxicity