2 research outputs found
Functional Characterization of Human Peptide/Histidine Transporter 1 in Stably Transfected MDCK Cells
The
proton-coupled oligopeptide transporter PHT1 (SLC15A4), which
facilitates cross-membrane transport of histidine and small peptides
from inside the endosomes or lysosomes to cytosol, plays an important
role in intracellular peptides homeostasis and innate immune responses.
However, it remains a challenge to elucidate functional properties
of the PHT1 transporter because of its subcellular localization. The
purpose of this study was to resort hPHT1 protein from the subcellular
to outer cell membrane of MDCK cells stably transfected with human
PHT1 mutants, and to characterize its functional activity in these
cells. Using this model, the functional activity of hPHT1 was evaluated
by cellular uptake studies with d<sub>3</sub>-l-histidine,
GlySar, and the bacterial peptidoglycan products MDP and Tri-DAP.
We found that the disruption of two dileucine motifs was indispensable
for hPHT1 transporter being preferentially targeting to plasma membranes.
hPHT1 showed high affinity for d<sub>3</sub>-l-histidine
and low affinity for GlySar, with <i>K</i><sub>m</sub> values
of 16.3 ± 1.9 μM and 1.60 ± 0.30 mM, respectively.
Moreover, the bacterial peptidoglycan components MDP and Tri-DAP were
shown conclusively to be hPHT1 substrates. The uptake of MDP by hPHT1
was inhibited by di/tripeptides and peptide-like drugs, but not by
glycine and acyclovir. The functional activity of hPHT1 was also pH-dependent,
with an optimal cellular uptake in buffer pH 6.5. Taken together,
we established a novel cell model to evaluate the function of hPHT1 <i>in vitro</i>, and confirmed that MDP and Tri-DAP were substrates
of hPHT1. Our findings suggest that PHT1 may serve as a potential
target for reducing the immune responses and for drug treatment of
inflammatory diseases
Platinum(II)-Oligonucleotide Coordination Based Aptasensor for Simple and Selective Detection of Platinum Compounds
Wide
use of platinum-based chemotherapeutic regimens for the treatment
for carcinoma calls for a simple and selective detection of platinum
compound in biological samples. On the basis of the platinumÂ(II)-base
pair coordination, a novel type of aptameric platform for platinum
detection has been introduced. This chemiluminescence (CL) aptasensor
consists of a designed streptavidin (SA) aptamer sequence in which
several base pairs were replaced by G-G mismatches. Only in the presence
of platinum, coordination occurs between the platinum and G-G base
pairs as opposed to the hydrogen-bonded G-C base pairs, which leads
to SA aptamer sequence activation, resulting in their binding to SA
coated magnetic beads. These Pt-DNA coordination events were monitored
by a simple and direct luminol-peroxide CL reaction through horseradish
peroxidase (HRP) catalysis with a strong chemiluminescence emission.
The validated ranges of quantification were 0.12–240 μM
with a limit of detection of 60 nM and selectivity over other metal
ions. This assay was also successfully used in urine sample determination.
It will be a promising candidate for the detection of platinum in
biomedical and environmental samples