3 research outputs found
Chemical Modulation of the Human Oligopeptide Transporter 1, hPepT1
In
humans, peptides derived from dietary proteins and peptide-like
drugs are transported via the proton-dependent oligopeptide transporter
hPepT1 (SLC15A1). hPepT1 is located across the apical membranes of
the small intestine and kidney, where it serves as a high-capacity
low-affinity transporter of a broad range of di- and tripeptides.
hPepT1 is also overexpressed in the colon of inflammatory bowel disease
(IBD) patients, where it mediates the transport of harmful peptides
of bacterial origin. Therefore, hPepT1 is a drug target for prodrug
substrates interacting with intracellular proteins or inhibitors blocking
the transport of toxic bacterial products. In this study, we construct
multiple structural models of hPepT1 representing different conformational
states that occur during transport and inhibition. We then identify
and characterize five ligands of hPepT1 using computational methods,
such as virtual screening and QM-polarized ligand docking (QPLD),
and experimental testing with uptake kinetic measurements and electrophysiological
assays. Our results improve our understanding of the substrate and
inhibitor specificity of hPepT1. Furthermore, the newly discovered
ligands exhibit unique chemotypes, providing a framework for developing
tool compounds with optimal intestinal absorption as well as future
IBD therapeutics against this emerging drug target
Converting a Light-Driven Proton Pump into a Light-Gated Proton Channel
There
are two types of membrane-embedded ion transport machineries
in nature. The ion pumps generate electrochemical potential by energy-coupled
active ion transportation, while the ion channels produce action potential
by stimulus-dependent passive ion transportation. About 80% of the
amino acid residues of the light-driven proton pump archaerhodopsin-3
(AR3) and the light-gated cation channel channelrhodopsin (ChR) differ
although they share the close similarity in architecture. Therefore,
the question arises: How can these proteins function differently?
The absorption maxima of ion pumps are red-shifted about 30–100
nm compared with ChRs, implying a structural difference in the retinal
binding cavity. To modify the cavity, a blue-shifted AR3 named AR3-T
was produced by replacing three residues located around the retinal
(i.e., M128A, G132V, and A225T). AR3-T showed an inward H<sup>+</sup> flux across the membrane, raising the possibility that it works
as an inward H<sup>+</sup> pump or an H<sup>+</sup> channel. Electrophysiological
experiments showed that the reverse membrane potential was nearly
zero, indicating light-gated ion channeling activity of AR3-T. Spectroscopic
characterization of AR3-T revealed similar photochemical properties
to some of ChRs, including an all-<i>trans</i> retinal configuration,
a strong hydrogen bond between the protonated retinal Schiff base
and its counterion, and a slow photocycle. From these results, we
concluded that the functional determinant in the H<sup>+</sup> transporters
is localized at the center of the membrane-spanning domain, but not
in the cytoplasmic and extracellular domains
Formation of M‑Like Intermediates in Proteorhodopsin in Alkali Solutions (pH ≥ ∼8.5) Where the Proton Release Occurs First in Contrast to the Sequence at Lower pH
Proteorhodopsin (PR) is an outward
light-driven proton pump observed
in marine eubacteria. Despite many structural and functional similarities
to bacteriorhodopsin (BR) in archaea, which also acts as an outward
proton pump, the mechanism of the photoinduced proton release and
uptake is different between two H<sup>+</sup>-pumps. In this study,
we investigated the pH dependence of the photocycle and proton transfer
in PR reconstituted with the phospholipid membrane under alkaline
conditions. Under these conditions, as the medium pH increased, a
blue-shifted photoproduct (defined as M<sub>a</sub>), which is different
from M, with a p<i>K</i><sub>a</sub> of ca. 9.2 was produced.
The sequence of the photoinduced proton uptake and release during
the photocycle was inverted with the increase in pH. A p<i>K</i><sub>a</sub> value of ca. 9.5 was estimated for this inversion and
was in good agreement with the p<i>K</i><sub>a</sub> value
of the formation of M<sub>a</sub> (∼9.2). In addition, we measured
the photoelectric current generated by PRs attached to a thin polymer
film at varying pH. Interestingly, increases in the medium pH evoked
bidirectional photocurrents, which may imply a possible reversal of
the direction of the proton movement at alkaline pH. On the basis
of these findings, a putative photocycle and proton transfer scheme
in PR under alkaline pH conditions was proposed