A gatekeeper helix determines the substrate specificity of Sjögren–Larsson Syndrome enzyme fatty aldehyde dehydrogenase

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作者
Markus A. Keller
Ulrich Zander
Julian E. Fuchs
Christoph Kreutz
Katrin Watschinger
Thomas Mueller
Georg Golderer
Klaus R. Liedl
Markus Ralser
Bernhard Kräutler
Ernst R. Werner
Jose A. Marquez
机构
[1] Biocenter,Division of Biological Chemistry
[2] Innsbruck Medical University,Department of Biochemistry and Cambridge Systems Biology Centre
[3] University of Cambridge,undefined
[4] European Molecular Biology Laboratory,undefined
[5] Grenoble Outstation,undefined
[6] Institute of General,undefined
[7] Inorganic and Theoretical Chemistry and Center for Molecular Biosciences Innsbruck (CMBI),undefined
[8] University of Innsbruck,undefined
[9] Institute of Organic Chemistry and Center for Molecular Biosciences Innsbruck (CMBI),undefined
[10] University of Innsbruck,undefined
[11] MRC National Institute for Medical Research,undefined
[12] Unit of Virus Host-Cell Interactions,undefined
[13] University of Grenoble Alpes-EMBL-CNRS,undefined
来源
Nature Communications | / 5卷
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摘要
Mutations in the gene coding for membrane-bound fatty aldehyde dehydrogenase (FALDH) lead to toxic accumulation of lipid species and development of the Sjögren–Larsson Syndrome (SLS), a rare disorder characterized by skin defects and mental retardation. Here, we present the crystallographic structure of human FALDH, the first model of a membrane-associated aldehyde dehydrogenase. The dimeric FALDH displays a previously unrecognized element in its C-terminal region, a ‘gatekeeper’ helix, which extends over the adjacent subunit, controlling the access to the substrate cavity and helping orientate both substrate cavities towards the membrane surface for efficient substrate transit between membranes and catalytic site. Activity assays demonstrate that the gatekeeper helix is important for directing the substrate specificity of FALDH towards long-chain fatty aldehydes. The gatekeeper feature is conserved across membrane-associated aldehyde dehydrogenases. Finally, we provide insight into the previously elusive molecular basis of SLS-causing mutations.
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