Drug and peptide transport in humans

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(Difference between revisions)

Revision as of 18:56, 4 December 2024

This page is under construction. This notice will be removed when it is ready. Eric Martz 01:56, 3 December 2024 (UTC)

1 Peptide Transporter Function & Structure
2 Rocker-Switch Transport Mechanism
3 Channel Shapes and Sizes
4 Green Links

Peptide Transporter Function & Structure

Human promiscuous peptide transporter 1 (PepT1) plays a crucual role in nutrition, transporting di- and tri-peptides from digested protein into intestinal cells.^[1] It is also crucial in uptake of orally delivered drugs.^[1] It is a member of the proton-coupled oligopeptide transporter (POT) family. These secondary active transporters are powered by the inward-directed electrochemical proton gradient, enabling intracellular accumulation of peptides/drugs above extracellular concentrations.^[1].

Click the green links below to change the molecular scene. Rotate to view the molecule from all sides (drag to rotate). Zoom with your mouse wheel, or Shift-Drag up/down.

with an extracellular domain (beta sheets), and a transmembrane transporter domain (alpha helices) with a cytoplasmic amphipathic linker (green protrusion). The latter looks like the toe of a boot formed by the linker (toe) with the transmembrane domain. The function of the extracellular and cytoplasmic linker domains are not well understood, although the extracellular domain appears to be important in transport^[2].

The transmembrane domain has a (enabling it to sit within the lipid bilayer membrane) which is . The cytoplamic linker "toe" has a net positive charge, enabling it to bind to the inner leaflet of the lipid bilayer, which typically has a negative charge.

Rocker-Switch Transport Mechanism

PepT1 is believed to transport using a rocker-switch mechanism, in which the outer (extracellular) face opens a pocket to bind peptides to a conserved binding site, then the outer face closes and the inner (cytoplasmic) face opens to release the peptide. However, prior to 2021, no structure was captured with an outward-facing opening, despite 47 structures in the PDB for bacterial homologs, representing 10 different bacterial POTs^[1].

In 2021, Killer et al. reported human PepT1 structures in outward-open conformations (with and without bound dipeptide)^[1]. This greatly furthered understanding of the transport mechanism.

(7pmx and 7pmy) of the transmembrane domain (extracellular domain hidden) illustrates the rocker-switch-like mechanism of transport. (7pmy is actually human PepT2, a different transporter with a very similar structure, and about 65% sequence identify with PepT1 in the transporter core domain.) This morph is oversimplified. Killer et al. actually captured 4 different conformations, revealing additional details of the rocker-switch mechanism. Their supplementary materials include a revealing morph movie (see also the movie explanation) that includes all 4 conformations.

. Rotate to position the opposite side in front to see into the inward-facing open but partially occluded channel.

Channel Shapes and Sizes

The shapes and sizes of open spaces in proteins can be visualized by filling them with pseudoatoms. in 7pmx. The channel has been filled by PACUPP with small pseudoatoms (2.0 Å in diameter^[3], vs. 3.0 Å van der Waals diameter of an oxygen atom).

Green Links

References and Notes

↑ ^1.0 ^1.1 ^1.2 ^1.3 ^1.4 Killer M, Wald J, Pieprzyk J, Marlovits TC, Low C. Structural snapshots of human PepT1 and PepT2 reveal mechanistic insights into substrate and drug transport across epithelial membranes. Sci Adv. 2021 Nov 5;7(45):eabk3259. doi: 10.1126/sciadv.abk3259. Epub 2021 Nov 3. PMID:34730990 doi:http://dx.doi.org/10.1126/sciadv.abk3259
↑ Shen J, Hu M, Fan X, Ren Z, Portioli C, Yan X, Rong M, Zhou M. Extracellular domain of PepT1 interacts with TM1 to facilitate substrate transport. Structure. 2022 Jul 7;30(7):1035-1041.e3. PMID:35580608 doi:10.1016/j.str.2022.04.011
↑ 2.0 Å pseudoatoms are called "extra fine detail" in PACUPP. It defaults to "fine" (3.0 Å), and also offers "very fine" (2.4 Å) or user-specified diameters.

Proteopedia Page Contributors and Editors (what is this?)

Eric Martz

Retrieved from "http://52.214.119.220/wiki/index.php/Drug_and_peptide_transport_in_humans"

@@ Line 24: / Line 24: @@
 <scene name='10/1066775/Chimerax-morph-pdb/3'>This view looks down into the outward-facing channel, while it closes and opens</scene>. Rotate to position the opposite side in front to see into the inward-facing open but partially occluded channel.
-==Channel Shapes and Volumes==
+==Channel Shapes and Sizes==
-The shapes and volumes of open spaces in proteins can be visualized by filling them with pseudoatoms. <scene name='10/1066775/Pacupp_7pmx_xf_s_noload/1'>Here is the shape of the outward facing channel</scene> in [[7pmx]]. The channel has been filled by [[PACUPP]] with small pseudoatoms (2.0 &Aring; in diameter<ref name="xf">2.0 &Aring; pseudoatoms are called "extra fine detail" in [[PACUPP]]. It defaults to "fine" (3.0 &Aring;), and also offers "very fine" (2.4 &Aring;) or user-specified diameters.</ref>, vs. 3.0 &Aring; van der Waals diameter of an oxygen atom).
+The shapes and sizes of open spaces in proteins can be visualized by filling them with pseudoatoms. <scene name='10/1066775/Pacupp_7pmx_xf_s_noload/1'>Here is the shape of the outward facing channel</scene> in [[7pmx]]. The channel has been filled by [[PACUPP]] with small pseudoatoms (2.0 &Aring; in diameter<ref name="xf">2.0 &Aring; pseudoatoms are called "extra fine detail" in [[PACUPP]]. It defaults to "fine" (3.0 &Aring;), and also offers "very fine" (2.4 &Aring;) or user-specified diameters.</ref>, vs. 3.0 &Aring; van der Waals diameter of an oxygen atom).
 ==Green Links==

Drug and peptide transport in humans

From Proteopedia

Revision as of 18:56, 4 December 2024

Contents

Peptide Transporter Function & Structure

Rocker-Switch Transport Mechanism

Channel Shapes and Sizes

Green Links

References and Notes

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