Cooperative transport mechanism of human monocarboxylate transporter 2

Zhang, Bo; Jin, Qiang; Xu, Lizhen; Li, Ningning; Meng, Ying; Chang, Shenghai; Zheng, Xiang; Wang, Jiangqin; Chen, Yuan; Neculai, Dante; Gao, Ning; Zhang, Xiaokang; Yang, Fan; Guo, Jiangtao; Ye, Sheng

doi:10.1038/s41467-020-16334-1

Cited by 36 publications

(59 citation statements)

References 51 publications

(60 reference statements)

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“…The prototypical, intermediate-affinity MCT1 (K m ≈ 3.5 mM) is ubiquitously expressed and mediates both, import and export of l -lactate in a physiological setting, whereas the high-affinity MCT2 (K m ≈ 0.7 mM) and the low-affinity MCT4 (K m ≈ 28 mM) appear more geared to facilitate l -lactate uptake or release, respectively [ 9 , 10 ]. The recently solved structures of a bacterial MCT homolog, and human MCT1 and MCT2 widely confirmed earlier models on the principal 12 transmembrane spanning topology and alternating access transport mechanism [ 11 – 13 ].…”

Section: Introductionsupporting

confidence: 71%

Basigin drives intracellular accumulation of l-lactate by harvesting protons and substrate anions

et al. 2021

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Transmembrane transport of l-lactate by members of the monocarboxylate transporter family, MCT, is vital in human physiology and a malignancy factor in cancer. Interaction with an accessory protein, typically basigin, is required to deliver the MCT to the plasma membrane. It is unknown whether basigin additionally exerts direct effects on the transmembrane l-lactate transport of MCT1. Here, we show that the presence of basigin leads to an intracellular accumulation of l-lactate 4.5-fold above the substrate/proton concentrations provided by the external buffer. Using basigin truncations we localized the effect to arise from the extracellular Ig-I domain. Identification of surface patches of condensed opposite electrostatic potential, and experimental analysis of charge-affecting Ig-I mutants indicated a bivalent harvesting antenna functionality for both, protons and substrate anions. From these data, and determinations of the cytosolic pH with a fluorescent probe, we conclude that the basigin Ig-I domain drives lactate uptake by locally increasing the proton and substrate concentration at the extracellular MCT entry site. The biophysical properties are physiologically relevant as cell growth on lactate media was strongly promoted in the presence of the Ig-I domain. Lack of the domain due to shedding, or misfolding due to breakage of a stabilizing disulfide bridge reversed the effect. Tumor progression according to classical or reverse Warburg effects depends on the transmembrane l-lactate distribution, and this study shows that the basigin Ig-I domain is a pivotal determinant.

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Section: Introductionsupporting

confidence: 71%

Basigin drives intracellular accumulation of l-lactate by harvesting protons and substrate anions

et al. 2021

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“…However, the actual proton binding site and transfer mechanisms are not known, yet [11]. Subsequently, MCTs undergo a major conformational change (Figure 7, right) that closes the cis-side and opens up the trans-side, where lactate and the proton are released [11,12].…”

Section: Discussionmentioning

confidence: 99%

“…In this study, we compared the dependence on the transmembrane pH gradient of three different types of lactate-conducting proteins. These are a strict neutral solute channel (human aquaporin 9, AQP9) [ 10 ], a prototypical secondary active, proton-driven alternating access monocarboxylate transporter (human MCT1; SLC16 family) [ 11 , 12 ], and the malaria parasite’s lactate transporter (PfFNT; microbial formate–nitrite transporter family) [ 7 , 13 ] ( Figure 1 b). The latter represents an in-between case: although the FNTs form homopentamers, their rigid protomer structure mimics the fold of an aquaporin (AQP) channel [ 14 ], whereas the lactate facilitation mechanism appears proton driven, i.e., secondary active transporter-like [ 8 , 9 ].…”

Section: Introductionmentioning

confidence: 99%

Transmembrane Facilitation of Lactate/H+ Instead of Lactic Acid Is Not a Question of Semantics but of Cell Viability

Bader

Beitz

2020

Membranes

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Transmembrane transport of monocarboxylates is conferred by structurally diverse membrane proteins. Here, we describe the pH dependence of lactic acid/lactate facilitation of an aquaporin (AQP9), a monocarboxylate transporter (MCT1, SLC16A1), and a formate–nitrite transporter (plasmodium falciparum FNT, PfFNT) in the equilibrium transport state. FNTs exhibit a channel-like structure mimicking the aquaporin-fold, yet act as secondary active transporters. We used radiolabeled lactate to monitor uptake via yeast-expressed AQP9, MCT1, and PfFNT for long enough time periods to reach the equilibrium state in which import and export rates are balanced. We confirmed that AQP9 behaved perfectly equilibrative for lactic acid, i.e., the neutral lactic acid molecule enters and passes the channel. MCT1, in turn, actively used the transmembrane proton gradient and acted as a lactate/H+ co-transporter. PfFNT behaved highly similar to the MCT in terms of transport properties, although it does not adhere to the classical alternating access transporter model. Instead, the FNT appears to use the proton gradient to neutralize the lactate anion in the protein’s vestibule to generate lactic acid in a place that traverses the central hydrophobic transport path. In conclusion, we propose to include FNT-type proteins into a more generalized, function-based transporter definition.

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“…Tyr332 and Gly336, which are also involved in substrate specificity, are exposed to the channel. Compared to the recently published structure of hMCT1 in an outward-open conformation, the model exerts all known structural features with an RMSD of 0.936 Å [25]. Overall, key residues that have been identified to participate in the proton-mediated substrate translocation are exposed to the solvent, allowing for efficient pharmacophore modelling and screening for potent inhibitors of the transport channel ( Figure S4).…”

Section: Discussionmentioning

confidence: 97%

A Holistic Evolutionary and 3D Pharmacophore Modelling Study Provides Insights into the Metabolism, Function, and Substrate Selectivity of the Human Monocarboxylate Transporter 4 (hMCT4)

Papakonstantinou

Vlachakis

Thireou

et al. 2021

IJMS

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Monocarboxylate transporters (MCTs) are of great research interest for their role in cancer cell metabolism and their potential ability to transport pharmacologically relevant compounds across the membrane. Each member of the MCT family could potentially provide novel therapeutic approaches to various diseases. The major differences among MCTs are related to each of their specific metabolic roles, their relative substrate and inhibitor affinities, the regulation of their expression, their intracellular localization, and their tissue distribution. MCT4 is the main mediator for the efflux of L-lactate produced in the cell. Thus, MCT4 maintains the glycolytic phenotype of the cancer cell by supplying the molecular resources for tumor cell proliferation and promotes the acidification of the extracellular microenvironment from the co-transport of protons. A promising therapeutic strategy in anti-cancer drug design is the selective inhibition of MCT4 for the glycolytic suppression of solid tumors. A small number of studies indicate molecules for dual inhibition of MCT1 and MCT4; however, no selective inhibitor with high-affinity for MCT4 has been identified. In this study, we attempt to approach the structural characteristics of MCT4 through an in silico pipeline for molecular modelling and pharmacophore elucidation towards the identification of specific inhibitors as a novel anti-cancer strategy.

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Cooperative transport mechanism of human monocarboxylate transporter 2

Cited by 36 publications

References 51 publications

Basigin drives intracellular accumulation of l-lactate by harvesting protons and substrate anions

Basigin drives intracellular accumulation of l-lactate by harvesting protons and substrate anions

Transmembrane Facilitation of Lactate/H+ Instead of Lactic Acid Is Not a Question of Semantics but of Cell Viability

A Holistic Evolutionary and 3D Pharmacophore Modelling Study Provides Insights into the Metabolism, Function, and Substrate Selectivity of the Human Monocarboxylate Transporter 4 (hMCT4)

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