4 research outputs found
Left-Hand Side Exploration of Novel Bacterial Topoisomerase Inhibitors to Improve Selectivity against hERG Binding
Structure–activity
relationship (SAR) exploration on the
left-hand side (LHS) of a novel class of bacterial topoisomerase inhibitors led to a significant improvement
in the selectivity against hERG cardiac channel binding with concomitant
potent antimycobacterial activity. Bulky polar substituents at the
C-7 position of the naphthyridone ring did not disturb its positioning
between two base pairs of DNA. Further optimization of the polar substituents
on the LHS of the naphthyridone ring led to potent antimycobacterial
activity (Mtb MIC = 0.06 μM) against <i>Mycobacterium tuberculosis</i> (Mtb). Additionally, this knowledge provided a robust SAR understanding
to mitigate the hERG risk. This compound class inhibits Mtb DNA gyrase
and retains its antimycobacterial activity against moxifloxacin-resistant
strains of Mtb. Finally, we demonstrate <i>in vivo</i> proof
of concept in an acute mouse model of TB following oral administration
of compound <b>19</b>
Thiazolopyridine Ureas as Novel Antitubercular Agents Acting through Inhibition of DNA Gyrase B
A pharmacophore-based search led
to the identification of thiazolopyridine
ureas as a novel scaffold with antitubercular activity acting through
inhibition of DNA Gyrase B (GyrB) ATPase. Evaluation of the binding
mode of thiazolopyridines in a Mycobacterium tuberculosis (Mtb) GyrB homology model prompted exploration of the side chains
at the thiazolopyridine ring C-5 position to access the ribose/solvent
pocket. Potent compounds with GyrB IC<sub>50</sub> ≤ 1 nM and
Mtb MIC ≤ 0.1 μM were obtained with certain combinations
of side chains at the C-5 position and heterocycles at the C-6 position
of the thiazolopyridine core. Substitutions at C-5 also enabled optimization
of the physicochemical properties. Representative compounds were cocrystallized
with Streptococcus pneumoniae (Spn)
ParE; these confirmed the binding modes predicted by the homology
model. The target link to GyrB was confirmed by genetic mapping of
the mutations conferring resistance to thiazolopyridine ureas. The
compounds are bactericidal in vitro and efficacious in vivo in an
acute murine model of tuberculosis
Discovery of Imidazo[1,2‑<i>a</i>]pyridine Ethers and Squaramides as Selective and Potent Inhibitors of Mycobacterial Adenosine Triphosphate (ATP) Synthesis
The approval of bedaquiline
to treat tuberculosis has validated
adenosine triphosphate (ATP) synthase as an attractive target to kill Mycobacterium tuberculosis (Mtb). Herein, we report
the discovery of two diverse lead series imidazoÂ[1,2-<i>a</i>]Âpyridine ethers (IPE) and squaramides (SQA) as inhibitors of mycobacterial
ATP synthesis. Through medicinal chemistry exploration, we established
a robust structure–activity relationship of these two scaffolds,
resulting in nanomolar potencies in an ATP synthesis inhibition assay.
A biochemical deconvolution cascade suggested cytochrome c oxidase
as the potential target of IPE class of molecules, whereas characterization
of spontaneous resistant mutants of SQAs unambiguously identified
ATP synthase as its molecular target. Absence of cross resistance
against bedaquiline resistant mutants suggested a different binding
site for SQAs on ATP synthase. Furthermore, SQAs were found to be
noncytotoxic and demonstrated efficacy in a mouse model of tuberculosis
infection
Discovery of Imidazo[1,2‑<i>a</i>]pyridine Ethers and Squaramides as Selective and Potent Inhibitors of Mycobacterial Adenosine Triphosphate (ATP) Synthesis
The approval of bedaquiline
to treat tuberculosis has validated
adenosine triphosphate (ATP) synthase as an attractive target to kill Mycobacterium tuberculosis (Mtb). Herein, we report
the discovery of two diverse lead series imidazoÂ[1,2-<i>a</i>]Âpyridine ethers (IPE) and squaramides (SQA) as inhibitors of mycobacterial
ATP synthesis. Through medicinal chemistry exploration, we established
a robust structure–activity relationship of these two scaffolds,
resulting in nanomolar potencies in an ATP synthesis inhibition assay.
A biochemical deconvolution cascade suggested cytochrome c oxidase
as the potential target of IPE class of molecules, whereas characterization
of spontaneous resistant mutants of SQAs unambiguously identified
ATP synthase as its molecular target. Absence of cross resistance
against bedaquiline resistant mutants suggested a different binding
site for SQAs on ATP synthase. Furthermore, SQAs were found to be
noncytotoxic and demonstrated efficacy in a mouse model of tuberculosis
infection