Proton-dependent oligopeptide transporters (POTs) are major facilitator superfamily (MFS) proteins that mediate the uptake of peptides and peptide-like molecules, using the inwardly directed H + gradient across the membrane. The human POT family transporter peptide transporter 1 is present in the brush border membrane of the small intestine and is involved in the uptake of nutrient peptides and drug molecules such as β-lactam antibiotics. Although previous studies have provided insight into the overall structure of the POT family transporters, the question of how transport is coupled to both peptide and H + binding remains unanswered. Here we report the high-resolution crystal structures of a bacterial POT family transporter, including its complex with a dipeptide analog, alafosfalin. These structures revealed the key mechanistic and functional roles for a conserved glutamate residue (Glu310) in the peptide binding site. Integrated structural, biochemical, and computational analyses suggested a mechanism for H + -coupled peptide symport in which protonated Glu310 first binds the carboxyl group of the peptide substrate. The deprotonation of Glu310 in the inward open state triggers the release of the bound peptide toward the intracellular space and salt bridge formation between Glu310 and Arg43 to induce the state transition to the occluded conformation.membrane transporter | molecular dynamics simulation | X-ray crystallography
A far-red type of oxygenic photosynthesis was discovered in Acaryochloris marina, a recently found marine prokaryote that produces an atypical pigment chlorophyll d
The photoconversion mechanism of a green/red sensory cyanobacteriochrome AnPixJ was studied. The phycocyanobilin-binding second GAF domain of AnPixJ of Anabaena sp. PCC 7120 was expressed in Escherichia coli cells. The His-tagged AnPixJ-GAF2 domain exhibited photoconversion between the green- and red-absorbing forms, APg(543) and APr(648), respectively. We detected four intermediate states in the photocycle between them, as follows: APr(648) → red light → APr(648)* → (with a rise time constant τ(r) of <100 ns) R1(650-80) (with a decay time constant τ(d) of <1 μs) → R2(610) (τ(d) = 920 μs) → APg(543) → green light → APg(543)* → (τ(r) < 50 ns) G1(570) (τ(d) = 190 μs) → G2(630) (τ(d) = 1.01 ms) → APr(648). These intermediates were named for their absorption peak wavelengths, which were estimated on the basis of the time-resolved difference spectra and global analysis of the time courses. The absorption spectrum of APr(648) resembles that of the Pr form of the phytochrome, while all the other states showed peaks at 530-650 nm and had wider bandwidths with smaller peak amplitudes. The fastest decay phases of fluorescence from APr(648)* and APg(543)* gave lifetimes of 200 and 42 ps, respectively, suggesting fast primary reactions. The APg(543)-minus-APr(648) difference FTIR spectrum in an H(2)O medium was significantly different from those reported for the Pfr/Pr difference spectra in phytochromes. Most of the peaks in the difference spectrum were shifted in the D(2)O medium, suggesting the high accessibility to the aqueous phase. The interactions of the phycocyanobilin chromophore with the surrounding amino acid residues, which are fairly different from those in the GAF domain of phytochromes, realize the unique green/red photocycle of AnPixJ.
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