COPII Coat Composition Is Actively Regulated by Luminal Cargo Maturation

Export from the ER is an essential process driven by the COPII coat, which forms vesicles at ER exit sites (ERESs) to transport mature secretory proteins to the Golgi. Although the basic mechanism of COPII assembly is known, how COPII machinery is regulated to meet varying cellular secretory demands...

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Published inCurrent biology Vol. 25; no. 2; pp. 152 - 162
Main Authors Manzano-Lopez, Javier, Perez-Linero, Ana M., Aguilera-Romero, Auxiliadora, Martin, Maria E., Okano, Tatsuki, Silva, Daniel Varon, Seeberger, Peter H., Riezman, Howard, Funato, Kouichi, Goder, Veit, Wellinger, Ralf E., Muñiz, Manuel
Format Journal Article
LanguageEnglish
Published England Elsevier Ltd 19.01.2015
Subjects
COP-Coated Vesicles - metabolism
Endoplasmic Reticulum - metabolism
Glycosylphosphatidylinositols - metabolism
Protein Binding
Saccharomyces cerevisiae - metabolism
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Abstract Export from the ER is an essential process driven by the COPII coat, which forms vesicles at ER exit sites (ERESs) to transport mature secretory proteins to the Golgi. Although the basic mechanism of COPII assembly is known, how COPII machinery is regulated to meet varying cellular secretory demands is unclear. Here, we report a specialized COPII system that is actively recruited by luminal cargo maturation. Glycosylphosphatidylinositol-anchored proteins (GPI-APs) are luminal secretory proteins anchored to the membrane by the glycolipid GPI. After protein attachment in the ER lumen, lipid and glycan parts of the GPI anchor are remodeled. In yeast, GPI-lipid remodeling concentrates GPI-APs into specific ERESs. We found that GPI-glycan remodeling induces subsequent recruitment of the specialized ER export machinery that enables vesicle formation from these specific ERESs. First, the transmembrane cargo receptor p24 complex binds GPI-APs as a lectin by recognizing the remodeled GPI-glycan. Binding of remodeled cargo induces the p24 complex to recruit the COPII subtype Lst1p, specifically required for GPI-AP ER export. Our results show that COPII coat recruitment by cargo receptors is not constitutive but instead is actively regulated by binding of mature ligands. Therefore, we reveal a novel functional link between luminal cargo maturation and COPII vesicle budding, providing a mechanism to adjust specialized COPII vesicle production to the amount and quality of their luminal cargos that are ready for ER exit. This helps to understand how the ER export machinery adapts to different needs for luminal cargo secretion. •Ted1p remodels the anchor of newly synthesized GPI-anchored proteins•The p24 complex recognizes the remodeled GPI anchor through its lectin function•GPI-cargo/p24 complex then recruits the COPII subtype containing Lst1p•Specialized GPI-cargo vesicles are formed Manzano-Lopez et al. show that the p24 complex recognizes, through its lectin domain, remodeled GPI-cargo and then recruits a specialized COPII coat for vesicle formation in the ER, providing a link between mature, luminal cargo and coat selection.
AbstractList Export from the ER is an essential process driven by the COPII coat, which forms vesicles at ER exit sites (ERESs) to transport mature secretory proteins to the Golgi. Although the basic mechanism of COPII assembly is known, how COPII machinery is regulated to meet varying cellular secretory demands is unclear. Here, we report a specialized COPII system that is actively recruited by luminal cargo maturation. Glycosylphosphatidylinositol-anchored proteins (GPI-APs) are luminal secretory proteins anchored to the membrane by the glycolipid GPI. After protein attachment in the ER lumen, lipid and glycan parts of the GPI anchor are remodeled. In yeast, GPI-lipid remodeling concentrates GPI-APs into specific ERESs. We found that GPI-glycan remodeling induces subsequent recruitment of the specialized ER export machinery that enables vesicle formation from these specific ERESs. First, the transmembrane cargo receptor p24 complex binds GPI-APs as a lectin by recognizing the remodeled GPI-glycan. Binding of remodeled cargo induces the p24 complex to recruit the COPII subtype Lst1p, specifically required for GPI-AP ER export. Our results show that COPII coat recruitment by cargo receptors is not constitutive but instead is actively regulated by binding of mature ligands. Therefore, we reveal a novel functional link between luminal cargo maturation and COPII vesicle budding, providing a mechanism to adjust specialized COPII vesicle production to the amount and quality of their luminal cargos that are ready for ER exit. This helps to understand how the ER export machinery adapts to different needs for luminal cargo secretion.
Export from the ER is an essential process driven by the COPII coat, which forms vesicles at ER exit sites (ERESs) to transport mature secretory proteins to the Golgi. Although the basic mechanism of COPII assembly is known, how COPII machinery is regulated to meet varying cellular secretory demands is unclear.BACKGROUNDExport from the ER is an essential process driven by the COPII coat, which forms vesicles at ER exit sites (ERESs) to transport mature secretory proteins to the Golgi. Although the basic mechanism of COPII assembly is known, how COPII machinery is regulated to meet varying cellular secretory demands is unclear.Here, we report a specialized COPII system that is actively recruited by luminal cargo maturation. Glycosylphosphatidylinositol-anchored proteins (GPI-APs) are luminal secretory proteins anchored to the membrane by the glycolipid GPI. After protein attachment in the ER lumen, lipid and glycan parts of the GPI anchor are remodeled. In yeast, GPI-lipid remodeling concentrates GPI-APs into specific ERESs. We found that GPI-glycan remodeling induces subsequent recruitment of the specialized ER export machinery that enables vesicle formation from these specific ERESs. First, the transmembrane cargo receptor p24 complex binds GPI-APs as a lectin by recognizing the remodeled GPI-glycan. Binding of remodeled cargo induces the p24 complex to recruit the COPII subtype Lst1p, specifically required for GPI-AP ER export.RESULTSHere, we report a specialized COPII system that is actively recruited by luminal cargo maturation. Glycosylphosphatidylinositol-anchored proteins (GPI-APs) are luminal secretory proteins anchored to the membrane by the glycolipid GPI. After protein attachment in the ER lumen, lipid and glycan parts of the GPI anchor are remodeled. In yeast, GPI-lipid remodeling concentrates GPI-APs into specific ERESs. We found that GPI-glycan remodeling induces subsequent recruitment of the specialized ER export machinery that enables vesicle formation from these specific ERESs. First, the transmembrane cargo receptor p24 complex binds GPI-APs as a lectin by recognizing the remodeled GPI-glycan. Binding of remodeled cargo induces the p24 complex to recruit the COPII subtype Lst1p, specifically required for GPI-AP ER export.Our results show that COPII coat recruitment by cargo receptors is not constitutive but instead is actively regulated by binding of mature ligands. Therefore, we reveal a novel functional link between luminal cargo maturation and COPII vesicle budding, providing a mechanism to adjust specialized COPII vesicle production to the amount and quality of their luminal cargos that are ready for ER exit. This helps to understand how the ER export machinery adapts to different needs for luminal cargo secretion.CONCLUSIONSOur results show that COPII coat recruitment by cargo receptors is not constitutive but instead is actively regulated by binding of mature ligands. Therefore, we reveal a novel functional link between luminal cargo maturation and COPII vesicle budding, providing a mechanism to adjust specialized COPII vesicle production to the amount and quality of their luminal cargos that are ready for ER exit. This helps to understand how the ER export machinery adapts to different needs for luminal cargo secretion.
Export from the ER is an essential process driven by the COPII coat, which forms vesicles at ER exit sites (ERESs) to transport mature secretory proteins to the Golgi. Although the basic mechanism of COPII assembly is known, how COPII machinery is regulated to meet varying cellular secretory demands is unclear. Here, we report a specialized COPII system that is actively recruited by luminal cargo maturation. Glycosylphosphatidylinositol-anchored proteins (GPI-APs) are luminal secretory proteins anchored to the membrane by the glycolipid GPI. After protein attachment in the ER lumen, lipid and glycan parts of the GPI anchor are remodeled. In yeast, GPI-lipid remodeling concentrates GPI-APs into specific ERESs. We found that GPI-glycan remodeling induces subsequent recruitment of the specialized ER export machinery that enables vesicle formation from these specific ERESs. First, the transmembrane cargo receptor p24 complex binds GPI-APs as a lectin by recognizing the remodeled GPI-glycan. Binding of remodeled cargo induces the p24 complex to recruit the COPII subtype Lst1p, specifically required for GPI-AP ER export. Our results show that COPII coat recruitment by cargo receptors is not constitutive but instead is actively regulated by binding of mature ligands. Therefore, we reveal a novel functional link between luminal cargo maturation and COPII vesicle budding, providing a mechanism to adjust specialized COPII vesicle production to the amount and quality of their luminal cargos that are ready for ER exit. This helps to understand how the ER export machinery adapts to different needs for luminal cargo secretion. •Ted1p remodels the anchor of newly synthesized GPI-anchored proteins•The p24 complex recognizes the remodeled GPI anchor through its lectin function•GPI-cargo/p24 complex then recruits the COPII subtype containing Lst1p•Specialized GPI-cargo vesicles are formed Manzano-Lopez et al. show that the p24 complex recognizes, through its lectin domain, remodeled GPI-cargo and then recruits a specialized COPII coat for vesicle formation in the ER, providing a link between mature, luminal cargo and coat selection.
Author Funato, Kouichi
Riezman, Howard
Silva, Daniel Varon
Martin, Maria E.
Manzano-Lopez, Javier
Perez-Linero, Ana M.
Okano, Tatsuki
Goder, Veit
Wellinger, Ralf E.
Aguilera-Romero, Auxiliadora
Muñiz, Manuel
Seeberger, Peter H.
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  surname: Manzano-Lopez
  fullname: Manzano-Lopez, Javier
  organization: Department of Cell Biology, University of Seville, 41012 Seville, Spain
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  givenname: Ana M.
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  fullname: Perez-Linero, Ana M.
  organization: Department of Cell Biology, University of Seville, 41012 Seville, Spain
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  givenname: Auxiliadora
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  organization: Department of Bioresource Science and Technology, Hiroshima University, Hiroshima 739-8528, Japan
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  givenname: Daniel Varon
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  fullname: Silva, Daniel Varon
  organization: Department of Biomolecular Systems, Max Planck Institute of Colloids and Interfaces, 14476 Potsdam, Germany
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  givenname: Peter H.
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  fullname: Seeberger, Peter H.
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  organization: NCCR Chemical Biology and Department of Biochemistry, Sciences II, University of Geneva, 1211 Geneva 4, Switzerland
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  givenname: Kouichi
  surname: Funato
  fullname: Funato, Kouichi
  organization: Department of Bioresource Science and Technology, Hiroshima University, Hiroshima 739-8528, Japan
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  surname: Goder
  fullname: Goder, Veit
  organization: Department of Genetics, University of Seville, 41012 Seville, Spain
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  givenname: Ralf E.
  surname: Wellinger
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  organization: Centro Andaluz de Biología Molecular y Medicina Regenerativa (CABIMER), 41092 Seville, Spain
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  givenname: Manuel
  surname: Muñiz
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  email: mmuniz@us.es
  organization: Department of Cell Biology, University of Seville, 41012 Seville, Spain
BackLink https://www.ncbi.nlm.nih.gov/pubmed/25557665$$D View this record in MEDLINE/PubMed
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Snippet Export from the ER is an essential process driven by the COPII coat, which forms vesicles at ER exit sites (ERESs) to transport mature secretory proteins to...
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SubjectTerms COP-Coated Vesicles - metabolism
Endoplasmic Reticulum - metabolism
Glycosylphosphatidylinositols - metabolism
Protein Binding
Saccharomyces cerevisiae - metabolism
Title COPII Coat Composition Is Actively Regulated by Luminal Cargo Maturation
URI https://dx.doi.org/10.1016/j.cub.2014.11.039
https://www.ncbi.nlm.nih.gov/pubmed/25557665
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