BACKGROUND: Antigen-specific CD4 T cells are activated by small numbers of antigenic peptide-MHC class II (pMHC-II) complexes on dendritic cells (DCs). RESULTS: Newly generated pMHC-II complexes are present in small clusters on the DC surface. CONCLUSION: pMHC-II clusters permit efficient T cell activation. SIGNIFICANCE: The appearance of clustered pMHC-II reveals the organization of the T cell antigen receptor ligand on the DC surface. Dendritic cells (DCs) function by stimulating naive antigen-specific CD4 T cells to proliferate and secrete a variety of immunomodulatory factors. The ability to activate naive T cells comes from the capacity of DCs to internalize, degrade, and express peptide fragments of antigenic proteins on their surface bound to MHC class II molecules (MHC-II). Although DCs express tens of thousands of distinct MHC-II, very small amounts of specific peptide-MHC-II complexes are required to interact with and activate T cells. We now show that stimulatory MHC-II I-A(k)-HEL(46-61) complexes that move from intracellular antigen-processing compartments to the plasma membrane are not randomly distributed on the DC surface. Confocal immunofluorescence microscopy and quantitative immunoelectron microscopy reveal that the majority of newly generated MHC-II I-A(k)-HEL(46-61) complexes are expressed in sub-100-nm microclusters on the DC membrane. These microclusters are stabilized in cholesterol-containing microdomains, and cholesterol depletion inhibits the stability of these clusters as well as the ability of the DCs to function as antigen-presenting cells. These results demonstrate that specific cohorts of peptide-MHC-II complexes expressed on the DC surface are present in cholesterol-dependent microclusters and that cluster integrity is important for antigen-specific naive CD4 T cell activation by DCs.
BACKGROUND: Antigen-specific CD4 T cells are activated by small numbers of antigenic peptide-MHC class II (pMHC-II) complexes on dendritic cells (DCs). RESULTS: Newly generated pMHC-II complexes are present in small clusters on the DC surface. CONCLUSION: pMHC-II clusters permit efficient T cell activation. SIGNIFICANCE: The appearance of clustered pMHC-II reveals the organization of the T cell antigen receptor ligand on the DC surface. Dendritic cells (DCs) function by stimulating naive antigen-specific CD4 T cells to proliferate and secrete a variety of immunomodulatory factors. The ability to activate naive T cells comes from the capacity of DCs to internalize, degrade, and express peptide fragments of antigenic proteins on their surface bound to MHC class II molecules (MHC-II). Although DCs express tens of thousands of distinct MHC-II, very small amounts of specific peptide-MHC-II complexes are required to interact with and activate T cells. We now show that stimulatory MHC-II I-A(k)-HEL(46-61) complexes that move from intracellular antigen-processing compartments to the plasma membrane are not randomly distributed on the DC surface. Confocal immunofluorescence microscopy and quantitative immunoelectron microscopy reveal that the majority of newly generated MHC-II I-A(k)-HEL(46-61) complexes are expressed in sub-100-nm microclusters on the DC membrane. These microclusters are stabilized in cholesterol-containing microdomains, and cholesterol depletion inhibits the stability of these clusters as well as the ability of the DCs to function as antigen-presenting cells. These results demonstrate that specific cohorts of peptide-MHC-II complexes expressed on the DC surface are present in cholesterol-dependent microclusters and that cluster integrity is important for antigen-specific naive CD4 T cell activation by DCs.
Entities:
Keywords:
Dendritic Cells; Lipid Raft; Major Histocompatibility Complex (MHC); Membrane Trafficking; T Cell
Authors: H Kropshofer; S Spindeldreher; T A Röhn; N Platania; C Grygar; N Daniel; A Wölpl; H Langen; V Horejsi; A B Vogt Journal: Nat Immunol Date: 2001-12-17 Impact factor: 25.606
Authors: Marianne Boes; Jan Cerny; Ramiro Massol; Marjolein Op den Brouw; Tom Kirchhausen; Jianzhu Chen; Hidde L Ploegh Journal: Nature Date: 2002-08-29 Impact factor: 49.962
Authors: K Inaba; S Turley; T Iyoda; F Yamaide; S Shimoyama; C Reis e Sousa; R N Germain; I Mellman; R M Steinman Journal: J Exp Med Date: 2000-03-20 Impact factor: 14.307
Authors: Jenny J Y Lin; Shalini T Low-Nam; Katherine N Alfieri; Darren B McAffee; Nicole C Fay; Jay T Groves Journal: Sci Signal Date: 2019-01-15 Impact factor: 8.192
Authors: Aranzazu Perianes-Cachero; María V T Lobo; Alberto M Hernández-Pinto; Rebeca Busto; Miguel Angel Lasunción-Ripa; Eduardo Arilla-Ferreiro; Lilian Puebla-Jiménez Journal: Mol Neurobiol Date: 2019-09-10 Impact factor: 5.590