Results shown for selected experiment:


Experiment ID28
PubMed ID 35333565   
Identification method Protein
Extracellular vesicle typeSmall extracellular vesicles
MISEVSmall EVs
SpeciesHomo sapiens
Experiment descriptionLAMP2A regulates the loading of proteins into exosomes
SampleRetinal pigment epithelial cells
Sample nameARPE-19-KO-LAMP2A
Isolation/purification methodsDifferential centrifugation
Filtration
Ultracentrifugation
Methods used in the studyWestern blotting
Mass spectrometry
Flotation density-
AuthorsFerreira JV, da Rosa Soares A, Ramalho J, Máximo Carvalho C, Cardoso MH, Pintado P, Carvalho AS, Beck HC, Matthiesen R, Zuzarte M, Girão H, van Niel G, Pereira P
Journal name Sci Adv
Publication year2022
EV-TRACK -



   Contents identified in selected experiment:





   Top 200 abundant gene(s) for selected experiment:




   Other experiments from same study (PubMed ID):



 PubMed IDSpeciesExperiment descriptionSampleSample nameIdentificationsIsolation methodsVesicle typeMISEVQuantification
1 35333565 Homo sapiens LAMP2A regulates the loading of proteins into exosomes Retinal pigment epithelial cells ARPE-19-Cas9-WT Protein Differential centrifugation
Filtration
Ultracentrifugation
Small extracellular vesicles Small EVs EVQuant
2 35333565 Homo sapiens LAMP2A regulates the loading of proteins into exosomes Retinal pigment epithelial cells ARPE-19-KO-LAMP2A Protein Differential centrifugation
Filtration
Ultracentrifugation
Small extracellular vesicles Small EVs EVQuant



   Experiments in which GLB1 is identified:



 PubMed IDSpeciesExperiment descriptionSampleSample nameIdentificationsIsolation methodsVesicle typeMISEVQuantification
1 32938681 Homo sapiens Annexin A1-dependent tethering promotes extracellular vesicle aggregation revealed with single-extracellular vesicle analysis Smooth muscle cells Carotid artery-derived primary smooth muscle cells Protein Differential centrifugation
Ultracentrifugation
Extracellular vesicles EVs EVQuant
2 33661579 Homo sapiens Pannexin-1 channel regulates nuclear content packaging into apoptotic bodies and their size T lymphoblast Jurkat T cells Protein Differential centrifugation Apoptotic bodies Large EVs EVQuant
3 32938681 Homo sapiens Annexin A1-dependent tethering promotes extracellular vesicle aggregation revealed with single-extracellular vesicle analysis Smooth muscle cells Carotid artery-derived primary smooth muscle cells Protein Differential centrifugation
Ultracentrifugation
Extracellular vesicles EVs EVQuant
4 35333565 Homo sapiens LAMP2A regulates the loading of proteins into exosomes Retinal pigment epithelial cells ARPE-19-Cas9-WT Protein Differential centrifugation
Filtration
Ultracentrifugation
Small extracellular vesicles Small EVs EVQuant
5 32938681 Homo sapiens Annexin A1-dependent tethering promotes extracellular vesicle aggregation revealed with single-extracellular vesicle analysis Valvular interstitial cells Aortic valve-derived primary valvular interstial cells Protein Differential centrifugation
Ultracentrifugation
Extracellular vesicles EVs EVQuant
6 33661579 Homo sapiens Pannexin-1 channel regulates nuclear content packaging into apoptotic bodies and their size T lymphoblast Jurkat T cells Protein Differential centrifugation Apoptotic bodies Large EVs EVQuant
7 35333565 Homo sapiens LAMP2A regulates the loading of proteins into exosomes Retinal pigment epithelial cells ARPE-19-KO-LAMP2A Protein Differential centrifugation
Filtration
Ultracentrifugation
Small extracellular vesicles Small EVs EVQuant
8 33661579 Homo sapiens Pannexin-1 channel regulates nuclear content packaging into apoptotic bodies and their size T lymphoblast Jurkat T cells Protein Differential centrifugation Apoptotic bodies Large EVs EVQuant
9 32938681 Homo sapiens Annexin A1-dependent tethering promotes extracellular vesicle aggregation revealed with single-extracellular vesicle analysis Valvular interstitial cells Aortic valve-derived primary valvular interstial cells Protein Differential centrifugation
Ultracentrifugation
Extracellular vesicles EVs EVQuant