posted on 2019-04-23, 00:00authored byXinxin Yang, Tianao Yuan, Rui Ma, Kieran I. Chacko, Melissa Smith, Gintaras Deikus, Robert Sebra, Andrew Kasarskis, Harm van Bakel, Scott G. Franzblau, Nicole S. Sampson
One-third of the world’s population
carries Mycobacterium tuberculosis (Mtb), the infectious agent that causes tuberculosis (TB), and every
17 s someone dies of TB. After infection, Mtb can
live dormant for decades in a granuloma structure arising from the
host immune response, and cholesterol is important for this persistence
of Mtb. Current treatments require long-duration
drug regimens with many associated toxicities, which are compounded
by the high doses required. We phenotypically screened 35 6-azasteroid
analogues against Mtb and found that, at low micromolar
concentrations, a subset of the analogues sensitized Mtb to multiple TB drugs. Two analogues were selected for further study
to characterize the bactericidal activity of bedaquiline and isoniazid
under normoxic and low-oxygen conditions. These two 6-azasteroids
showed strong synergy with bedaquiline (fractional inhibitory concentration
index = 0.21, bedaquiline minimal inhibitory concentration = 16 nM
at 1 μM 6-azasteroid). The rate at which spontaneous resistance
to one of the 6-azasteroids arose in the presence of bedaquiline was
approximately 10–9, and the 6-azasteroid-resistant
mutants retained their isoniazid and bedaquiline sensitivity. Genes
in the cholesterol-regulated Mce3R regulon were required for 6-azasteroid
activity, whereas genes in the cholesterol catabolism pathway were
not. Expression of a subset of Mce3R genes was down-regulated upon
6-azasteroid treatment. The Mce3R regulon is implicated in stress
resistance and is absent in saprophytic mycobacteria. This regulon
encodes a cholesterol-regulated stress-resistance pathway that we
conclude is important for pathogenesis and contributes to drug tolerance,
and this pathway is vulnerable to small-molecule targeting in live
mycobacteria.