Background:
Despite the availability of various classes of antihypertensive medications, a large proportion of hypertensive individuals remain resistant to treatments. The reason for what contributes to low efficacy of antihypertensive medications in these individuals is elusive. The knowledge that gut microbiota is involved in pathophysiology of hypertension and drug metabolism led us to hypothesize that gut microbiota catabolize antihypertensive medications and compromised their blood pressure (BP)-lowering effects.
Methods and Results:
To test this hypothesis, we examined the BP responses to a representative ACE (angiotensin-converting enzyme) inhibitor quinapril in spontaneously hypertensive rats (SHR) with or without antibiotics. BP-lowering effect of quinapril was more pronounced in the SHR+antibiotics, indicating that gut microbiota of SHR lowered the antihypertensive effect of quinapril. Depletion of gut microbiota in the SHR+antibiotics was associated with decreased gut microbial catabolism of quinapril as well as significant reduction in the bacterial genus
Coprococcus
.
C. comes
, an anaerobic species of
Coprococcus
, harbored esterase activity and catabolized the ester quinapril in vitro. Co-administration of quinapril with
C. comes
reduced the antihypertensive effect of quinapril in the SHR. Importantly,
C. comes
selectively reduced the antihypertensive effects of ester ramipril but not nonester lisinopril.
Conclusions:
Our study revealed a previously unrecognized mechanism by which human commensal
C. comes
catabolizes ester ACE inhibitors in the gut and lowers its antihypertensive effect.
Photoaffinity
labeling (PAL) remains one of the most widely utilized
methods of determining protein targets of drugs. Although useful,
the scope of this technique has been limited to in vitro applications because of the inability of UV light to penetrate whole
organisms. Herein, pigment-free Casper zebrafish were employed to
allow in vivo PAL. A methamphetamine-related phenethylamine
PAL probe, designated here as 2, demonstrated dose-dependent
effects on behavior similar to methamphetamine and permitted concentration-dependent
labeling of protein binding partners. Click chemistry was used to
analyze binding partners via fluoroimaging. Conjugation to a biotin
permitted streptavidin pull-down and proteomic analysis to define
direct binding partners of the methamphetamine probe. Bioinformatic
analysis revealed the probe was chiefly bound to proteins involved
in phagocytosis and mitochondrial function. Future applications of
this experimental paradigm combining examination of drug–protein
binding interactions alongside neurobehavioral readouts via in vivo PAL will significantly enhance our understanding
of drug targets, mechanism(s) of action, and toxicity/lethality.
Nitric oxide (NO) mimetics and other agents capable of enhancing NO/cGMP signaling have demonstrated efficacy as potential therapies for Alzheimer's disease. A group of thiol-dependent NO mimetics known as furoxans may be designed to exhibit attenuated reactivity to provide slow onset NO effects. The present study describes the design, synthesis, and evaluation of a furoxan library resulting in the identification of a prototype furoxan, 5a, which was profiled for use in the central nervous system. Furoxan 5a demonstrated negligible reactivity toward generic cellular thiols under physiological conditions. Nonetheless, cGMP-dependent neuroprotection was observed, and 5a (20 mg/kg) reversed cholinergic memory deficits in a mouse model of passive avoidance fear memory. Importantly, 5a can be prepared as a pharmaceutically acceptable salt and is observed in the brain 12 h after oral administration, suggesting potential for daily dosing and excellent metabolic stability. Continued investigation into furoxans as attenuated NO mimetics for the CNS is warranted.
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