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Structure and mechanism of the SGLT family of glucose transporters

Author

Listed:
  • Lei Han

    (Stanford University School of Medicine)

  • Qianhui Qu

    (Stanford University School of Medicine
    Stanford University School of Medicine
    Fudan University)

  • Deniz Aydin

    (Stanford University School of Medicine
    Stanford University School of Medicine
    Stanford University
    Stanford University)

  • Ouliana Panova

    (Stanford University School of Medicine
    Stanford University School of Medicine)

  • Michael J. Robertson

    (Stanford University School of Medicine
    Stanford University School of Medicine)

  • Yan Xu

    (Stanford University School of Medicine)

  • Ron O. Dror

    (Stanford University School of Medicine
    Stanford University School of Medicine
    Stanford University
    Stanford University)

  • Georgios Skiniotis

    (Stanford University School of Medicine
    Stanford University School of Medicine)

  • Liang Feng

    (Stanford University School of Medicine
    Stanford University School of Medicine)

Abstract

Glucose is a primary energy source in living cells. The discovery in 1960s that a sodium gradient powers the active uptake of glucose in the intestine1 heralded the concept of a secondary active transporter that can catalyse the movement of a substrate against an electrochemical gradient by harnessing energy from another coupled substrate. Subsequently, coupled Na+/glucose transport was found to be mediated by sodium–glucose cotransporters2,3 (SGLTs). SGLTs are responsible for active glucose and galactose absorption in the intestine and for glucose reabsorption in the kidney4, and are targeted by multiple drugs to treat diabetes5. Several members within the SGLT family transport key metabolites other than glucose2. Here we report cryo-electron microscopy structures of the prototypic human SGLT1 and a related monocarboxylate transporter SMCT1 from the same family. The structures, together with molecular dynamics simulations and functional studies, define the architecture of SGLTs, uncover the mechanism of substrate binding and selectivity, and shed light on water permeability of SGLT1. These results provide insights into the multifaceted functions of SGLTs.

Suggested Citation

  • Lei Han & Qianhui Qu & Deniz Aydin & Ouliana Panova & Michael J. Robertson & Yan Xu & Ron O. Dror & Georgios Skiniotis & Liang Feng, 2022. "Structure and mechanism of the SGLT family of glucose transporters," Nature, Nature, vol. 601(7892), pages 274-279, January.
  • Handle: RePEc:nat:nature:v:601:y:2022:i:7892:d:10.1038_s41586-021-04211-w
    DOI: 10.1038/s41586-021-04211-w
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    Cited by:

    1. Farha Khan & Matthias Elgeti & Samuel Grandfield & Aviv Paz & Fiona B. Naughton & Frank V. Marcoline & Thorsten Althoff & Natalia Ermolova & Ernest M. Wright & Wayne L. Hubbell & Michael Grabe & Jeff , 2023. "Membrane potential accelerates sugar uptake by stabilizing the outward facing conformation of the Na/glucose symporter vSGLT," Nature Communications, Nature, vol. 14(1), pages 1-12, December.
    2. Yafei Yuan & Fang Kong & Hanwen Xu & Angqi Zhu & Nieng Yan & Chuangye Yan, 2022. "Cryo-EM structure of human glucose transporter GLUT4," Nature Communications, Nature, vol. 13(1), pages 1-8, December.
    3. Shuhui Wang & Kun Wang & Kangkang Song & Zon Weng Lai & Pengfei Li & Dongying Li & Yajie Sun & Ye Mei & Chen Xu & Maofu Liao, 2024. "Structures of the Mycobacterium tuberculosis efflux pump EfpA reveal the mechanisms of transport and inhibition," Nature Communications, Nature, vol. 15(1), pages 1-11, December.

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