Gene ontology annotations for DPP3 |
|
Experiment description of studies that identified DPP3 in exosomes |
1 |
Experiment ID |
79 |
MISEV standards |
✘
|
EV Biophysical techniques |
✔
CD81|MHCII
|
EV Enriched markers |
✘
|
EV Negative markers |
✘
|
EV Particle analysis
|
|
Identified molecule |
protein
|
Identification method |
Mass spectrometry
|
PubMed ID |
20458337
|
Organism |
Homo sapiens |
Experiment description |
MHC class II-associated proteins in B-cell exosomes and potential functional implications for exosome biogenesis - Sample 1 |
Authors |
Buschow SI, van Balkom BW, Aalberts M, Heck AJ, Wauben M, Stoorvogel W. |
Journal name |
ICB
|
Publication year |
2010 |
Sample |
B cells |
Sample name |
RN (HLA-DR15) |
Isolation/purification methods |
Differential centrifugation Sucrose density gradient Immunobeads (MHC Class II) |
Flotation density |
-
|
Molecules identified in the study |
Protein |
Methods used in the study |
Mass spectrometry [FT-ICR] Western blotting |
|
|
2 |
Experiment ID |
80 |
MISEV standards |
✘
|
EV Biophysical techniques |
✔
CD81|MHCII
|
EV Enriched markers |
✘
|
EV Negative markers |
✘
|
EV Particle analysis
|
|
Identified molecule |
protein
|
Identification method |
Mass spectrometry
|
PubMed ID |
20458337
|
Organism |
Homo sapiens |
Experiment description |
MHC class II-associated proteins in B-cell exosomes and potential functional implications for exosome biogenesis -Sample 2 |
Authors |
Buschow SI, van Balkom BW, Aalberts M, Heck AJ, Wauben M, Stoorvogel W. |
Journal name |
ICB
|
Publication year |
2010 |
Sample |
B cells |
Sample name |
RN (HLA-DR15) |
Isolation/purification methods |
Differential centrifugation Sucrose density gradient Immunobeads (MHC Class II) |
Flotation density |
-
|
Molecules identified in the study |
Protein |
Methods used in the study |
Mass spectrometry [FT-ICR] Western blotting |
|
|
3 |
Experiment ID |
81 |
MISEV standards |
✘
|
EV Biophysical techniques |
✔
CD81|MHCII
|
EV Enriched markers |
✘
|
EV Negative markers |
✘
|
EV Particle analysis
|
|
Identified molecule |
protein
|
Identification method |
Mass spectrometry
|
PubMed ID |
20458337
|
Organism |
Homo sapiens |
Experiment description |
MHC class II-associated proteins in B-cell exosomes and potential functional implications for exosome biogenesis - Sample 3 |
Authors |
Buschow SI, van Balkom BW, Aalberts M, Heck AJ, Wauben M, Stoorvogel W. |
Journal name |
ICB
|
Publication year |
2010 |
Sample |
B cells |
Sample name |
RN (HLA-DR15) |
Isolation/purification methods |
Differential centrifugation Sucrose density gradient Immunobeads (MHC Class II) |
Flotation density |
-
|
Molecules identified in the study |
Protein |
Methods used in the study |
Mass spectrometry [FT-ICR] Western blotting |
|
|
4 |
Experiment ID |
489 |
MISEV standards |
✔
EM
|
EV Biophysical techniques |
✔
Cd9|Cd81|Cd63|Gapdh|Sdcbp|Lamp1|Aqp1|Rab5a|Icam1|Cd82|Itga2b|Tsg101|Lamp2|Rab35|Flot1|Flot2|Cd151|Rab5b|Tfrc|Uchl1
|
EV Enriched markers |
✔
Canx
|
EV Negative markers |
✔
NTA
|
EV Particle analysis
|
|
Identified molecule |
Protein
|
Identification method |
Mass spectrometry
|
PubMed ID |
36408942
|
Organism |
Rattus norvegicus |
Experiment description |
Quantitative proteomic analysis of exosomes from umbilical cord mesenchymal stem cells and rat bone marrow stem cells |
Authors |
Xu X, Yin F, Guo M, Gan G, Lin G, Wen C, Wang J, Song P, Wang J, Qi ZQ, Zhong CQ. |
Journal name |
Proteomics
|
Publication year |
2023 |
Sample |
Bone marrow mesenchymal stem cells |
Sample name |
BMSC - Passage 6 |
Isolation/purification methods |
Differential centrifugation Filtration Ultracentrifugation |
Flotation density |
-
|
Molecules identified in the study |
Protein |
Methods used in the study |
Western blotting Mass spectometry |
|
|
5 |
Experiment ID |
490 |
MISEV standards |
✔
EM
|
EV Biophysical techniques |
✔
Cd9|Cd81|Cd63|Gapdh|Sdcbp|Lamp1|Aqp1|Rab5a|Icam1|Cd82|Itga2b|Tsg101|Lamp2|Rab35|Flot1|Flot2|Cd151|Rab5b|Tfrc|Uchl1
|
EV Enriched markers |
✔
Canx
|
EV Negative markers |
✔
NTA
|
EV Particle analysis
|
|
Identified molecule |
Protein
|
Identification method |
Mass spectrometry
|
PubMed ID |
36408942
|
Organism |
Rattus norvegicus |
Experiment description |
Quantitative proteomic analysis of exosomes from umbilical cord mesenchymal stem cells and rat bone marrow stem cells |
Authors |
Xu X, Yin F, Guo M, Gan G, Lin G, Wen C, Wang J, Song P, Wang J, Qi ZQ, Zhong CQ. |
Journal name |
Proteomics
|
Publication year |
2023 |
Sample |
Bone marrow mesenchymal stem cells |
Sample name |
BMSC - Passage 7 |
Isolation/purification methods |
Differential centrifugation Filtration Ultracentrifugation |
Flotation density |
-
|
Molecules identified in the study |
Protein |
Methods used in the study |
Western blotting Mass spectometry |
|
|
6 |
Experiment ID |
491 |
MISEV standards |
✔
EM
|
EV Biophysical techniques |
✔
Cd9|Cd81|Cd63|Gapdh|Sdcbp|Lamp1|Aqp1|Rab5a|Icam1|Cd82|Itga2b|Tsg101|Lamp2|Rab35|Flot1|Flot2|Cd151|Rab5b|Tfrc|Uchl1
|
EV Enriched markers |
✔
Canx
|
EV Negative markers |
✔
NTA
|
EV Particle analysis
|
|
Identified molecule |
Protein
|
Identification method |
Mass spectrometry
|
PubMed ID |
36408942
|
Organism |
Rattus norvegicus |
Experiment description |
Quantitative proteomic analysis of exosomes from umbilical cord mesenchymal stem cells and rat bone marrow stem cells |
Authors |
Xu X, Yin F, Guo M, Gan G, Lin G, Wen C, Wang J, Song P, Wang J, Qi ZQ, Zhong CQ. |
Journal name |
Proteomics
|
Publication year |
2023 |
Sample |
Bone marrow mesenchymal stem cells |
Sample name |
BMSC - Passage 8 |
Isolation/purification methods |
Differential centrifugation Filtration Ultracentrifugation |
Flotation density |
-
|
Molecules identified in the study |
Protein |
Methods used in the study |
Western blotting Mass spectometry |
|
|
7 |
Experiment ID |
492 |
MISEV standards |
✔
EM
|
EV Biophysical techniques |
✔
Cd9|Cd81|Cd63|Gapdh|Sdcbp|Lamp1|Aqp1|Rab5a|Icam1|Cd82|Itga2b|Tsg101|Lamp2|Rab35|Flot1|Flot2|Cd151|Rab5b|Tfrc|Uchl1
|
EV Enriched markers |
✔
Canx
|
EV Negative markers |
✔
NTA
|
EV Particle analysis
|
|
Identified molecule |
Protein
|
Identification method |
Mass spectrometry
|
PubMed ID |
36408942
|
Organism |
Rattus norvegicus |
Experiment description |
Quantitative proteomic analysis of exosomes from umbilical cord mesenchymal stem cells and rat bone marrow stem cells |
Authors |
Xu X, Yin F, Guo M, Gan G, Lin G, Wen C, Wang J, Song P, Wang J, Qi ZQ, Zhong CQ. |
Journal name |
Proteomics
|
Publication year |
2023 |
Sample |
Bone marrow mesenchymal stem cells |
Sample name |
BMSC - Passage 9 |
Isolation/purification methods |
Differential centrifugation Filtration Ultracentrifugation |
Flotation density |
-
|
Molecules identified in the study |
Protein |
Methods used in the study |
Western blotting Mass spectometry |
|
|
8 |
Experiment ID |
412 |
MISEV standards |
✔
EM
|
EV Biophysical techniques |
✔
CD81|CD9|CD63|SDCBP|LAMP1|GAPDH|FLOT1|TFRC|FLOT2|TSG101|RAB35
|
EV Enriched markers |
✔
CANX|ACTB
|
EV Negative markers |
✔
NTA
|
EV Particle analysis
|
|
Identified molecule |
Protein
|
Identification method |
Mass spectrometry
|
PubMed ID |
34108659
|
Organism |
Homo sapiens |
Experiment description |
Quantitative Proteomics Identifies the Core Proteome of Exosomes with Syntenin-1 as the highest abundant protein and a Putative Universal Biomarker |
Authors |
Kugeratski FG, Hodge K, Lilla S, McAndrews KM, Zhou X, Hwang RF, Zanivan S, Kalluri R. |
Journal name |
Nat Cell Biol
|
Publication year |
2021 |
Sample |
Breast cancer cells |
Sample name |
MCF7 |
Isolation/purification methods |
Differential centrifugation Filtration Ultracentrifugation |
Flotation density |
-
|
Molecules identified in the study |
Protein mRNA |
Methods used in the study |
RT-qPCR Western blotting Mass spectrometry Flow cytometry |
|
|
9 |
Experiment ID |
414 |
MISEV standards |
✔
EM
|
EV Biophysical techniques |
✔
CD81|CD9|CD63|SDCBP|LAMP1|GAPDH|FLOT1|TFRC|FLOT2|TSG101|RAB35
|
EV Enriched markers |
✔
CANX
|
EV Negative markers |
✔
NTA
|
EV Particle analysis
|
|
Identified molecule |
Protein
|
Identification method |
Mass spectrometry
|
PubMed ID |
34108659
|
Organism |
Homo sapiens |
Experiment description |
Quantitative Proteomics Identifies the Core Proteome of Exosomes with Syntenin-1 as the highest abundant protein and a Putative Universal Biomarker |
Authors |
Kugeratski FG, Hodge K, Lilla S, McAndrews KM, Zhou X, Hwang RF, Zanivan S, Kalluri R. |
Journal name |
Nat Cell Biol
|
Publication year |
2021 |
Sample |
Breast cancer cells |
Sample name |
MDA-MB-231 |
Isolation/purification methods |
Differential centrifugation Filtration Ultracentrifugation |
Flotation density |
-
|
Molecules identified in the study |
Protein mRNA |
Methods used in the study |
RT-qPCR Western blotting Mass spectrometry Flow cytometry |
|
|
10 |
Experiment ID |
426 |
MISEV standards |
✘
|
EV Biophysical techniques |
✔
SDCBP|FLOT1|CD81|CD9|CD151|FLOT2|TSG101|LAMP1|TFRC|RAB5A|RAB35|GAPDH|UCHL1|ICAM1
|
EV Enriched markers |
✔
CANX
|
EV Negative markers |
✘
|
EV Particle analysis
|
|
Identified molecule |
Protein
|
Identification method |
Mass spectrometry
|
PubMed ID |
34108659
|
Organism |
Homo sapiens |
Experiment description |
Quantitative Proteomics Identifies the Core Proteome of Exosomes with Syntenin-1 as the highest abundant protein and a Putative Universal Biomarker |
Authors |
Kugeratski FG, Hodge K, Lilla S, McAndrews KM, Zhou X, Hwang RF, Zanivan S, Kalluri R. |
Journal name |
Nat Cell Biol
|
Publication year |
2021 |
Sample |
Breast cancer cells |
Sample name |
MDA-MB-231 - Exo-rich fractions 7-10 pooled |
Isolation/purification methods |
Differential centrifugation Filtration Ultracentrifugation Size exclusion chromatography |
Flotation density |
-
|
Molecules identified in the study |
Protein |
Methods used in the study |
Western blotting Mass spectrometry |
|
|
11 |
Experiment ID |
427 |
MISEV standards |
✘
|
EV Biophysical techniques |
✔
CD81|SDCBP|FLOT1|CD9|CD151|FLOT2|TSG101|LAMP1|TFRC|RAB5A|RAB35|GAPDH|UCHL1|ICAM1
|
EV Enriched markers |
✔
CANX
|
EV Negative markers |
✘
|
EV Particle analysis
|
|
Identified molecule |
Protein
|
Identification method |
Mass spectrometry
|
PubMed ID |
34108659
|
Organism |
Homo sapiens |
Experiment description |
Quantitative Proteomics Identifies the Core Proteome of Exosomes with Syntenin-1 as the highest abundant protein and a Putative Universal Biomarker |
Authors |
Kugeratski FG, Hodge K, Lilla S, McAndrews KM, Zhou X, Hwang RF, Zanivan S, Kalluri R. |
Journal name |
Nat Cell Biol
|
Publication year |
2021 |
Sample |
Breast cancer cells |
Sample name |
MDA-MB-231 - Exo-rich fractions 1-6 pooled |
Isolation/purification methods |
Differential centrifugation Filtration Ultracentrifugation OptiPrep density gradient centrifugation |
Flotation density |
-
|
Molecules identified in the study |
Protein |
Methods used in the study |
Mass spectrometry |
|
|
12 |
Experiment ID |
207 |
MISEV standards |
✔
EM
|
EV Biophysical techniques |
✔
TSG101|HSP70|FLOT1
|
EV Enriched markers |
✔
VDAC
|
EV Negative markers |
✔
NTA
|
EV Particle analysis
|
|
Identified molecule |
protein
|
Identification method |
Mass spectrometry
|
PubMed ID |
23161513
|
Organism |
Homo sapiens |
Experiment description |
Proteomic analysis of exosomes from mutant KRAS colon cancer cells identifies intercellular transfer of mutant KRAS. |
Authors |
Demory Beckler M, Higginbotham JN, Franklin JL, Ham AJ, Halvey PJ, Imasuen IE, Whitwell C, Li M, Liebler DC, Coffey RJ. |
Journal name |
Mol Cell Proteomics
|
Publication year |
2012 |
Sample |
Colorectal cancer cells |
Sample name |
DKO-1 |
Isolation/purification methods |
Differential centrifugation Filtration |
Flotation density |
-
|
Molecules identified in the study |
Protein |
Methods used in the study |
Mass spectrometry |
|
|
13 |
Experiment ID |
208 |
MISEV standards |
✔
EM
|
EV Biophysical techniques |
✔
TSG101|HSP70|FLOT1
|
EV Enriched markers |
✔
VDAC
|
EV Negative markers |
✔
NTA
|
EV Particle analysis
|
|
Identified molecule |
protein
|
Identification method |
Mass spectrometry
|
PubMed ID |
23161513
|
Organism |
Homo sapiens |
Experiment description |
Proteomic analysis of exosomes from mutant KRAS colon cancer cells identifies intercellular transfer of mutant KRAS. |
Authors |
Demory Beckler M, Higginbotham JN, Franklin JL, Ham AJ, Halvey PJ, Imasuen IE, Whitwell C, Li M, Liebler DC, Coffey RJ. |
Journal name |
Mol Cell Proteomics
|
Publication year |
2012 |
Sample |
Colorectal cancer cells |
Sample name |
Dks-8 |
Isolation/purification methods |
Differential centrifugation Filtration |
Flotation density |
-
|
Molecules identified in the study |
Protein |
Methods used in the study |
Mass spectrometry |
|
|
14 |
Experiment ID |
209 |
MISEV standards |
✘
|
EV Biophysical techniques |
✔
TSG101|HSP70|FLOT1
|
EV Enriched markers |
✔
VDAC
|
EV Negative markers |
✔
NTA
|
EV Particle analysis
|
|
Identified molecule |
protein
|
Identification method |
Mass spectrometry
|
PubMed ID |
23161513
|
Organism |
Homo sapiens |
Experiment description |
Proteomic analysis of exosomes from mutant KRAS colon cancer cells identifies intercellular transfer of mutant KRAS. |
Authors |
Demory Beckler M, Higginbotham JN, Franklin JL, Ham AJ, Halvey PJ, Imasuen IE, Whitwell C, Li M, Liebler DC, Coffey RJ. |
Journal name |
Mol Cell Proteomics
|
Publication year |
2012 |
Sample |
Colorectal cancer cells |
Sample name |
DLD-1 |
Isolation/purification methods |
Differential centrifugation Filtration |
Flotation density |
-
|
Molecules identified in the study |
Protein |
Methods used in the study |
Mass spectrometry |
|
|
15 |
Experiment ID |
1203 |
MISEV standards |
✔
EM
|
EV Biophysical techniques |
✔
SDCBP|FLOT1|CD9|CD81|CD63|EPCAM|GAPDH|LAMP1|TFRC|CD151|CD82|LAMP2|RAB35|TSG101|FLOT2|RAB5B|ICAM1|RAB5A
|
EV Enriched markers |
✘
|
EV Negative markers |
✘
|
EV Particle analysis
|
|
Identified molecule |
protein
|
Identification method |
Mass spectrometry
|
PubMed ID |
34887515
|
Organism |
Homo sapiens |
Experiment description |
Supermeres are functional extracellular nanoparticles replete with disease biomarkers and therapeutic targets |
Authors |
Zhang Q, Jeppesen DK, Higginbotham JN, Graves-Deal R, Trinh VQ, Ramirez MA, Sohn Y, Neininger AC, Taneja N, McKinley ET, Niitsu H, Cao Z, Evans R, Glass SE, Ray KC, Fissell WH, Hill S, Rose KL, Huh WJ, Washington MK, Ayers GD, Burnette DT, Sharma S, Rome LH, Franklin JL, Lee YA, Liu Q, Coffey RJ. |
Journal name |
Nat Cell Biol
|
Publication year |
2021 |
Sample |
Colorectal cancer cells |
Sample name |
DiFi |
Isolation/purification methods |
Differential centrifugation Filtration Centrifugal ultrafiltration Ultracentrifugation OptiPrep density gradient centrifugation |
Flotation density |
-
|
Molecules identified in the study |
Protein miRNA |
Methods used in the study |
Western blotting Mass spectrometry RNA sequencing |
|
|
16 |
Experiment ID |
407 |
MISEV standards |
✔
EM
|
EV Biophysical techniques |
✔
CD9|CD63|CD81|SDCBP|TSG101|LAMP1|GAPDH|FLOT1|TFRC|FLOT2|RAB35
|
EV Enriched markers |
✔
CANX
|
EV Negative markers |
✔
NTA
|
EV Particle analysis
|
|
Identified molecule |
Protein
|
Identification method |
Mass spectrometry
|
PubMed ID |
34108659
|
Organism |
Homo sapiens |
Experiment description |
Quantitative Proteomics Identifies the Core Proteome of Exosomes with Syntenin-1 as the highest abundant protein and a Putative Universal Biomarker |
Authors |
Kugeratski FG, Hodge K, Lilla S, McAndrews KM, Zhou X, Hwang RF, Zanivan S, Kalluri R. |
Journal name |
Nat Cell Biol
|
Publication year |
2021 |
Sample |
Embryonic kidney cells |
Sample name |
HEK293T |
Isolation/purification methods |
Differential centrifugation Filtration Ultracentrifugation |
Flotation density |
-
|
Molecules identified in the study |
Protein mRNA |
Methods used in the study |
RT-qPCR Western blotting Mass spectrometry Flow cytometry |
|
|
17 |
Experiment ID |
419 |
MISEV standards |
✘
|
EV Biophysical techniques |
✔
SDCBP|FLOT1|CD81|CD9|CD151|FLOT2|TSG101|LAMP1|TFRC|RAB5A|RAB35|GAPDH|UCHL1|ICAM1
|
EV Enriched markers |
✔
CANX
|
EV Negative markers |
✘
|
EV Particle analysis
|
|
Identified molecule |
Protein
|
Identification method |
Mass spectrometry
|
PubMed ID |
34108659
|
Organism |
Homo sapiens |
Experiment description |
Quantitative Proteomics Identifies the Core Proteome of Exosomes with Syntenin-1 as the highest abundant protein and a Putative Universal Biomarker |
Authors |
Kugeratski FG, Hodge K, Lilla S, McAndrews KM, Zhou X, Hwang RF, Zanivan S, Kalluri R. |
Journal name |
Nat Cell Biol
|
Publication year |
2021 |
Sample |
Embryonic kidney cells |
Sample name |
HEK293T - Exo-rich fractions 7-10 pooled |
Isolation/purification methods |
Differential centrifugation Filtration Ultracentrifugation Size exclusion chromatography |
Flotation density |
-
|
Molecules identified in the study |
Protein |
Methods used in the study |
Western blotting Mass spectrometry |
|
|
18 |
Experiment ID |
419 |
MISEV standards |
✘
|
EV Biophysical techniques |
✔
SDCBP|FLOT1|CD81|CD9|CD151|FLOT2|TSG101|LAMP1|TFRC|RAB5A|RAB35|GAPDH|UCHL1|ICAM1
|
EV Enriched markers |
✔
CANX
|
EV Negative markers |
✘
|
EV Particle analysis
|
|
Identified molecule |
Protein
|
Identification method |
Mass spectrometry
|
PubMed ID |
34108659
|
Organism |
Homo sapiens |
Experiment description |
Quantitative Proteomics Identifies the Core Proteome of Exosomes with Syntenin-1 as the highest abundant protein and a Putative Universal Biomarker |
Authors |
Kugeratski FG, Hodge K, Lilla S, McAndrews KM, Zhou X, Hwang RF, Zanivan S, Kalluri R. |
Journal name |
Nat Cell Biol
|
Publication year |
2021 |
Sample |
Embryonic kidney cells |
Sample name |
HEK293T - Exo-rich fractions 7-10 pooled |
Isolation/purification methods |
Differential centrifugation Filtration Ultracentrifugation Size exclusion chromatography |
Flotation density |
-
|
Molecules identified in the study |
Protein |
Methods used in the study |
Western blotting Mass spectrometry |
|
|
19 |
Experiment ID |
420 |
MISEV standards |
✘
|
EV Biophysical techniques |
✔
CD81|SDCBP|FLOT1|CD9|CD151|FLOT2|TSG101|LAMP1|TFRC|RAB5A|RAB35|GAPDH|UCHL1|ICAM1
|
EV Enriched markers |
✔
CANX
|
EV Negative markers |
✘
|
EV Particle analysis
|
|
Identified molecule |
Protein
|
Identification method |
Mass spectrometry
|
PubMed ID |
34108659
|
Organism |
Homo sapiens |
Experiment description |
Quantitative Proteomics Identifies the Core Proteome of Exosomes with Syntenin-1 as the highest abundant protein and a Putative Universal Biomarker |
Authors |
Kugeratski FG, Hodge K, Lilla S, McAndrews KM, Zhou X, Hwang RF, Zanivan S, Kalluri R. |
Journal name |
Nat Cell Biol
|
Publication year |
2021 |
Sample |
Embryonic kidney cells |
Sample name |
HEK293T - Exo-rich fractions 1-6 pooled |
Isolation/purification methods |
Differential centrifugation Filtration Ultracentrifugation OptiPrep density gradient centrifugation |
Flotation density |
-
|
Molecules identified in the study |
Protein |
Methods used in the study |
Mass spectrometry |
|
|
20 |
Experiment ID |
420 |
MISEV standards |
✘
|
EV Biophysical techniques |
✔
CD81|SDCBP|FLOT1|CD9|CD151|FLOT2|TSG101|LAMP1|TFRC|RAB5A|RAB35|GAPDH|UCHL1|ICAM1
|
EV Enriched markers |
✔
CANX
|
EV Negative markers |
✘
|
EV Particle analysis
|
|
Identified molecule |
Protein
|
Identification method |
Mass spectrometry
|
PubMed ID |
34108659
|
Organism |
Homo sapiens |
Experiment description |
Quantitative Proteomics Identifies the Core Proteome of Exosomes with Syntenin-1 as the highest abundant protein and a Putative Universal Biomarker |
Authors |
Kugeratski FG, Hodge K, Lilla S, McAndrews KM, Zhou X, Hwang RF, Zanivan S, Kalluri R. |
Journal name |
Nat Cell Biol
|
Publication year |
2021 |
Sample |
Embryonic kidney cells |
Sample name |
HEK293T - Exo-rich fractions 1-6 pooled |
Isolation/purification methods |
Differential centrifugation Filtration Ultracentrifugation OptiPrep density gradient centrifugation |
Flotation density |
-
|
Molecules identified in the study |
Protein |
Methods used in the study |
Mass spectrometry |
|
|
21 |
Experiment ID |
405 |
MISEV standards |
✔
EM
|
EV Biophysical techniques |
✔
CD9|CD63|CD81|SDCBP|LAMP1|GAPDH|FLOT1|TFRC|FLOT2|TSG101|RAB35
|
EV Enriched markers |
✔
CANX
|
EV Negative markers |
✔
NTA
|
EV Particle analysis
|
|
Identified molecule |
Protein
|
Identification method |
Mass spectrometry
|
PubMed ID |
34108659
|
Organism |
Homo sapiens |
Experiment description |
Quantitative Proteomics Identifies the Core Proteome of Exosomes with Syntenin-1 as the highest abundant protein and a Putative Universal Biomarker |
Authors |
Kugeratski FG, Hodge K, Lilla S, McAndrews KM, Zhou X, Hwang RF, Zanivan S, Kalluri R. |
Journal name |
Nat Cell Biol
|
Publication year |
2021 |
Sample |
Foreskin fibroblasts |
Sample name |
BJ |
Isolation/purification methods |
Differential centrifugation Filtration Ultracentrifugation |
Flotation density |
-
|
Molecules identified in the study |
Protein mRNA |
Methods used in the study |
RT-qPCR Western blotting Mass spectrometry Flow cytometry |
|
|
22 |
Experiment ID |
363 |
MISEV standards |
✘
|
EV Biophysical techniques |
✔
TSG101|GAPDH|AQP1|CD151|CD81|CD82|CD9|EPCAM|FLOT1|FLOT2|ICAM1|ITGA2B|LAMP2|RAB35|RAB5A|RAB5B|SDCBP|TFRC|UCHL1
|
EV Enriched markers |
✔
DCLK1
|
EV Negative markers |
✔
NTA
|
EV Particle analysis
|
|
Identified molecule |
Protein
|
Identification method |
Mass spectrometry
|
PubMed ID |
33991177
|
Organism |
Homo sapiens |
Experiment description |
Cancer stem cell marker DCLK1 reprograms small extracellular vesicles toward migratory phenotype in gastric cancer cells |
Authors |
Carli ALE, Afshar-Sterle S, Rai A, Fang H, O'Keefe R, Tse J, Ferguson FM, Gray NS, Ernst M, Greening DW, Buchert M. |
Journal name |
Proteomics
|
Publication year |
2021 |
Sample |
Gastric cancer cells |
Sample name |
MKN1 - 100K pellet |
Isolation/purification methods |
Differential centrifugation Ultracentrifugation |
Flotation density |
-
|
Molecules identified in the study |
Protein |
Methods used in the study |
Western blotting Mass spectrometry |
|
|
23 |
Experiment ID |
364 |
MISEV standards |
✘
|
EV Biophysical techniques |
✔
TSG101|GAPDH|AQP1|CD151|CD81|CD82|CD9|EPCAM|FLOT1|FLOT2|ICAM1|ITGA2B|LAMP2|RAB35|RAB5A|RAB5B|SDCBP|TFRC|UCHL1
|
EV Enriched markers |
✔
DCLK1
|
EV Negative markers |
✔
NTA
|
EV Particle analysis
|
|
Identified molecule |
Protein
|
Identification method |
Mass spectrometry
|
PubMed ID |
33991177
|
Organism |
Homo sapiens |
Experiment description |
Cancer stem cell marker DCLK1 reprograms small extracellular vesicles toward migratory phenotype in gastric cancer cells |
Authors |
Carli ALE, Afshar-Sterle S, Rai A, Fang H, O'Keefe R, Tse J, Ferguson FM, Gray NS, Ernst M, Greening DW, Buchert M. |
Journal name |
Proteomics
|
Publication year |
2021 |
Sample |
Gastric cancer cells |
Sample name |
MKN1 - 100K pellet |
Isolation/purification methods |
Differential centrifugation Ultracentrifugation |
Flotation density |
-
|
Molecules identified in the study |
Protein |
Methods used in the study |
Western blotting Mass spectrometry |
|
|
24 |
Experiment ID |
365 |
MISEV standards |
✘
|
EV Biophysical techniques |
✔
TSG101|GAPDH|AQP1|CD151|CD81|CD82|CD9|EPCAM|FLOT1|FLOT2|ICAM1|ITGA2B|LAMP2|RAB35|RAB5A|RAB5B|SDCBP|TFRC|UCHL1
|
EV Enriched markers |
✔
DCLK1
|
EV Negative markers |
✔
NTA
|
EV Particle analysis
|
|
Identified molecule |
Protein
|
Identification method |
Mass spectrometry
|
PubMed ID |
33991177
|
Organism |
Homo sapiens |
Experiment description |
Cancer stem cell marker DCLK1 reprograms small extracellular vesicles toward migratory phenotype in gastric cancer cells |
Authors |
Carli ALE, Afshar-Sterle S, Rai A, Fang H, O'Keefe R, Tse J, Ferguson FM, Gray NS, Ernst M, Greening DW, Buchert M. |
Journal name |
Proteomics
|
Publication year |
2021 |
Sample |
Gastric cancer cells |
Sample name |
MKN1 - 100K pellet |
Isolation/purification methods |
Differential centrifugation Ultracentrifugation |
Flotation density |
-
|
Molecules identified in the study |
Protein |
Methods used in the study |
Western blotting Mass spectrometry |
|
|
25 |
Experiment ID |
417 |
MISEV standards |
✔
EM
|
EV Biophysical techniques |
✔
CD81|CD63|SDCBP|LAMP1|CD9|GAPDH|FLOT1|TFRC|FLOT2|TSG101|RAB35
|
EV Enriched markers |
✔
CANX|ACTB
|
EV Negative markers |
✔
NTA
|
EV Particle analysis
|
|
Identified molecule |
Protein
|
Identification method |
Mass spectrometry
|
PubMed ID |
34108659
|
Organism |
Homo sapiens |
Experiment description |
Quantitative Proteomics Identifies the Core Proteome of Exosomes with Syntenin-1 as the highest abundant protein and a Putative Universal Biomarker |
Authors |
Kugeratski FG, Hodge K, Lilla S, McAndrews KM, Zhou X, Hwang RF, Zanivan S, Kalluri R. |
Journal name |
Nat Cell Biol
|
Publication year |
2021 |
Sample |
Lymphoma cells |
Sample name |
Raji |
Isolation/purification methods |
Differential centrifugation Filtration Ultracentrifugation |
Flotation density |
-
|
Molecules identified in the study |
Protein mRNA |
Methods used in the study |
RT-qPCR Western blotting Mass spectrometry Flow cytometry |
|
|
26 |
Experiment ID |
411 |
MISEV standards |
✔
EM
|
EV Biophysical techniques |
✔
CD81|CD9|CD63|SDCBP|LAMP1|GAPDH|FLOT1|TFRC|FLOT2|TSG101|RAB35
|
EV Enriched markers |
✔
CANX
|
EV Negative markers |
✔
NTA
|
EV Particle analysis
|
|
Identified molecule |
Protein
|
Identification method |
Mass spectrometry
|
PubMed ID |
34108659
|
Organism |
Homo sapiens |
Experiment description |
Quantitative Proteomics Identifies the Core Proteome of Exosomes with Syntenin-1 as the highest abundant protein and a Putative Universal Biomarker |
Authors |
Kugeratski FG, Hodge K, Lilla S, McAndrews KM, Zhou X, Hwang RF, Zanivan S, Kalluri R. |
Journal name |
Nat Cell Biol
|
Publication year |
2021 |
Sample |
Mammary cancer-associated fibroblasts |
Sample name |
mCAF |
Isolation/purification methods |
Differential centrifugation Filtration Ultracentrifugation |
Flotation density |
-
|
Molecules identified in the study |
Protein mRNA |
Methods used in the study |
RT-qPCR Western blotting Mass spectrometry Flow cytometry |
|
|
27 |
Experiment ID |
488 |
MISEV standards |
✔
EM
|
EV Biophysical techniques |
✔
CD9|CD81|CD63|GAPDH|SDCBP|LAMP1|TFRC|UCHL1|FLOT2|LAMP2|FLOT1|ICAM1|RAB5B|CD151|RAB35|TSG101|RAB5A|CD82
|
EV Enriched markers |
✔
CANX
|
EV Negative markers |
✔
NTA
|
EV Particle analysis
|
|
Identified molecule |
Protein
|
Identification method |
Mass spectrometry
|
PubMed ID |
36408942
|
Organism |
Homo sapiens |
Experiment description |
Quantitative proteomic analysis of exosomes from umbilical cord mesenchymal stem cells and rat bone marrow stem cells |
Authors |
Xu X, Yin F, Guo M, Gan G, Lin G, Wen C, Wang J, Song P, Wang J, Qi ZQ, Zhong CQ. |
Journal name |
Proteomics
|
Publication year |
2023 |
Sample |
Mesenchymal stem cells |
Sample name |
UCMSC |
Isolation/purification methods |
Differential centrifugation Filtration Ultracentrifugation |
Flotation density |
-
|
Molecules identified in the study |
Protein |
Methods used in the study |
Western blotting Mass spectometry |
|
|
28 |
Experiment ID |
418 |
MISEV standards |
✔
EM
|
EV Biophysical techniques |
✔
CD81|CD9|CD63|SDCBP|LAMP1|GAPDH|FLOT1|TFRC|FLOT2|TSG101|RAB35
|
EV Enriched markers |
✔
CANX
|
EV Negative markers |
✔
NTA
|
EV Particle analysis
|
|
Identified molecule |
Protein
|
Identification method |
Mass spectrometry
|
PubMed ID |
34108659
|
Organism |
Homo sapiens |
Experiment description |
Quantitative Proteomics Identifies the Core Proteome of Exosomes with Syntenin-1 as the highest abundant protein and a Putative Universal Biomarker |
Authors |
Kugeratski FG, Hodge K, Lilla S, McAndrews KM, Zhou X, Hwang RF, Zanivan S, Kalluri R. |
Journal name |
Nat Cell Biol
|
Publication year |
2021 |
Sample |
Monocytic leukemia cells |
Sample name |
THP-1 |
Isolation/purification methods |
Differential centrifugation Filtration Ultracentrifugation |
Flotation density |
-
|
Molecules identified in the study |
Protein mRNA |
Methods used in the study |
RT-qPCR Western blotting Mass spectrometry Flow cytometry |
|
|
29 |
Experiment ID |
418 |
MISEV standards |
✔
EM
|
EV Biophysical techniques |
✔
CD81|CD9|CD63|SDCBP|LAMP1|GAPDH|FLOT1|TFRC|FLOT2|TSG101|RAB35
|
EV Enriched markers |
✔
CANX
|
EV Negative markers |
✔
NTA
|
EV Particle analysis
|
|
Identified molecule |
Protein
|
Identification method |
Mass spectrometry
|
PubMed ID |
34108659
|
Organism |
Homo sapiens |
Experiment description |
Quantitative Proteomics Identifies the Core Proteome of Exosomes with Syntenin-1 as the highest abundant protein and a Putative Universal Biomarker |
Authors |
Kugeratski FG, Hodge K, Lilla S, McAndrews KM, Zhou X, Hwang RF, Zanivan S, Kalluri R. |
Journal name |
Nat Cell Biol
|
Publication year |
2021 |
Sample |
Monocytic leukemia cells |
Sample name |
THP-1 |
Isolation/purification methods |
Differential centrifugation Filtration Ultracentrifugation |
Flotation density |
-
|
Molecules identified in the study |
Protein mRNA |
Methods used in the study |
RT-qPCR Western blotting Mass spectrometry Flow cytometry |
|
|
30 |
Experiment ID |
413 |
MISEV standards |
✔
EM
|
EV Biophysical techniques |
✔
CD81|CD9|CD63|SDCBP|LAMP1|GAPDH|FLOT1|TFRC|FLOT2|TSG101|RAB35
|
EV Enriched markers |
✔
CANX
|
EV Negative markers |
✔
NTA
|
EV Particle analysis
|
|
Identified molecule |
Protein
|
Identification method |
Mass spectrometry
|
PubMed ID |
34108659
|
Organism |
Homo sapiens |
Experiment description |
Quantitative Proteomics Identifies the Core Proteome of Exosomes with Syntenin-1 as the highest abundant protein and a Putative Universal Biomarker |
Authors |
Kugeratski FG, Hodge K, Lilla S, McAndrews KM, Zhou X, Hwang RF, Zanivan S, Kalluri R. |
Journal name |
Nat Cell Biol
|
Publication year |
2021 |
Sample |
Normal mammary epithelial cells |
Sample name |
MCF10A |
Isolation/purification methods |
Differential centrifugation Filtration Ultracentrifugation |
Flotation density |
-
|
Molecules identified in the study |
Protein mRNA |
Methods used in the study |
RT-qPCR Western blotting Mass spectrometry Flow cytometry |
|
|
31 |
Experiment ID |
211 |
MISEV standards |
✔
EM
|
EV Biophysical techniques |
✔
TSG101|Alix|EpCAM|TFRC
|
EV Enriched markers |
✔
cytochrome c|GOLGA2
|
EV Negative markers |
✘
|
EV Particle analysis
|
|
Identified molecule |
protein
|
Identification method |
Mass spectrometry
|
PubMed ID |
23333927
|
Organism |
Homo sapiens |
Experiment description |
Characterization and proteomic analysis of ovarian cancer-derived exosomes. |
Authors |
Liang B, Peng P, Chen S, Li L, Zhang M, Cao D, Yang J, Li H, Gui T, Li X, Shen K. |
Journal name |
J Proteomics
|
Publication year |
2013 |
Sample |
Ovarian cancer cells |
Sample name |
IGROV1 |
Isolation/purification methods |
Differential centrifugation Ultracentrifugation Sucrose density gradient |
Flotation density |
1.09-1.15 g/mL
|
Molecules identified in the study |
Protein |
Methods used in the study |
Mass spectrometry |
|
|
32 |
Experiment ID |
212 |
MISEV standards |
✔
CEM
|
EV Biophysical techniques |
✔
TSG101|Alix|EpCAM|TFRC
|
EV Enriched markers |
✔
Cytochrome C|GOLGA2
|
EV Negative markers |
✘
|
EV Particle analysis
|
|
Identified molecule |
protein
|
Identification method |
Mass spectrometry
|
PubMed ID |
23333927
|
Organism |
Homo sapiens |
Experiment description |
Characterization and proteomic analysis of ovarian cancer-derived exosomes. |
Authors |
Liang B, Peng P, Chen S, Li L, Zhang M, Cao D, Yang J, Li H, Gui T, Li X, Shen K. |
Journal name |
J Proteomics
|
Publication year |
2013 |
Sample |
Ovarian cancer cells |
Sample name |
OVCAR-3 |
Isolation/purification methods |
Differential centrifugation Ultracentrifugation Sucrose density gradient |
Flotation density |
1.09-1.15 g/mL
|
Molecules identified in the study |
Protein |
Methods used in the study |
Mass spectrometry |
|
|
33 |
Experiment ID |
406 |
MISEV standards |
✔
EM
|
EV Biophysical techniques |
✔
CD9|CD63|SDCBP|LAMP1|GAPDH|FLOT1|TFRC|FLOT2|TSG101|RAB35|CD81
|
EV Enriched markers |
✔
CANX
|
EV Negative markers |
✔
NTA
|
EV Particle analysis
|
|
Identified molecule |
Protein
|
Identification method |
Mass spectrometry
|
PubMed ID |
34108659
|
Organism |
Homo sapiens |
Experiment description |
Quantitative Proteomics Identifies the Core Proteome of Exosomes with Syntenin-1 as the highest abundant protein and a Putative Universal Biomarker |
Authors |
Kugeratski FG, Hodge K, Lilla S, McAndrews KM, Zhou X, Hwang RF, Zanivan S, Kalluri R. |
Journal name |
Nat Cell Biol
|
Publication year |
2021 |
Sample |
Pancreatic cancer cells |
Sample name |
BxPC3 |
Isolation/purification methods |
Differential centrifugation Filtration Ultracentrifugation |
Flotation density |
-
|
Molecules identified in the study |
Protein mRNA |
Methods used in the study |
RT-qPCR Western blotting Mass spectrometry Flow cytometry |
|
|
34 |
Experiment ID |
415 |
MISEV standards |
✔
EM
|
EV Biophysical techniques |
✔
CD81|CD9|CD63|SDCBP|LAMP1|GAPDH|FLOT1|TFRC|FLOT2|TSG101|RAB35
|
EV Enriched markers |
✔
CANX
|
EV Negative markers |
✔
NTA
|
EV Particle analysis
|
|
Identified molecule |
Protein
|
Identification method |
Mass spectrometry
|
PubMed ID |
34108659
|
Organism |
Homo sapiens |
Experiment description |
Quantitative Proteomics Identifies the Core Proteome of Exosomes with Syntenin-1 as the highest abundant protein and a Putative Universal Biomarker |
Authors |
Kugeratski FG, Hodge K, Lilla S, McAndrews KM, Zhou X, Hwang RF, Zanivan S, Kalluri R. |
Journal name |
Nat Cell Biol
|
Publication year |
2021 |
Sample |
Pancreatic cancer cells |
Sample name |
PANC-1 |
Isolation/purification methods |
Differential centrifugation Filtration Ultracentrifugation |
Flotation density |
-
|
Molecules identified in the study |
Protein mRNA |
Methods used in the study |
RT-qPCR Western blotting Mass spectrometry Flow cytometry |
|
|
35 |
Experiment ID |
434 |
MISEV standards |
✘
|
EV Biophysical techniques |
✔
SDCBP|FLOT1|CD81|CD9|CD151|FLOT2|TSG101|LAMP1|TFRC|RAB5A|RAB35|GAPDH|UCHL1|ICAM1
|
EV Enriched markers |
✔
CANX
|
EV Negative markers |
✘
|
EV Particle analysis
|
|
Identified molecule |
Protein
|
Identification method |
Mass spectrometry
|
PubMed ID |
34108659
|
Organism |
Homo sapiens |
Experiment description |
Quantitative Proteomics Identifies the Core Proteome of Exosomes with Syntenin-1 as the highest abundant protein and a Putative Universal Biomarker |
Authors |
Kugeratski FG, Hodge K, Lilla S, McAndrews KM, Zhou X, Hwang RF, Zanivan S, Kalluri R. |
Journal name |
Nat Cell Biol
|
Publication year |
2021 |
Sample |
Pancreatic cancer cells |
Sample name |
PANC-1 - Exo-rich fractions 7-10 pooled |
Isolation/purification methods |
Differential centrifugation Filtration Ultracentrifugation Size exclusion chromatography |
Flotation density |
-
|
Molecules identified in the study |
Protein |
Methods used in the study |
Western blotting Mass spectrometry |
|
|
36 |
Experiment ID |
435 |
MISEV standards |
✘
|
EV Biophysical techniques |
✔
CD81|SDCBP|FLOT1|CD9|CD151|FLOT2|TSG101|LAMP1|TFRC|RAB5A|RAB35|GAPDH|UCHL1|ICAM1
|
EV Enriched markers |
✔
CANX
|
EV Negative markers |
✘
|
EV Particle analysis
|
|
Identified molecule |
Protein
|
Identification method |
Mass spectrometry
|
PubMed ID |
34108659
|
Organism |
Homo sapiens |
Experiment description |
Quantitative Proteomics Identifies the Core Proteome of Exosomes with Syntenin-1 as the highest abundant protein and a Putative Universal Biomarker |
Authors |
Kugeratski FG, Hodge K, Lilla S, McAndrews KM, Zhou X, Hwang RF, Zanivan S, Kalluri R. |
Journal name |
Nat Cell Biol
|
Publication year |
2021 |
Sample |
Pancreatic cancer cells |
Sample name |
PANC-1 - Exo-rich fractions 1-6 pooled |
Isolation/purification methods |
Differential centrifugation Filtration Ultracentrifugation OptiPrep density gradient centrifugation |
Flotation density |
-
|
Molecules identified in the study |
Protein |
Methods used in the study |
Mass spectrometry |
|
|
37 |
Experiment ID |
408 |
MISEV standards |
✔
EM
|
EV Biophysical techniques |
✔
CD9|CD63|CD81|SDCBP|LAMP1|GAPDH|FLOT1|TFRC|FLOT2|TSG101|RAB35
|
EV Enriched markers |
✔
CANX|ACTB
|
EV Negative markers |
✔
NTA
|
EV Particle analysis
|
|
Identified molecule |
Protein
|
Identification method |
Mass spectrometry
|
PubMed ID |
34108659
|
Organism |
Homo sapiens |
Experiment description |
Quantitative Proteomics Identifies the Core Proteome of Exosomes with Syntenin-1 as the highest abundant protein and a Putative Universal Biomarker |
Authors |
Kugeratski FG, Hodge K, Lilla S, McAndrews KM, Zhou X, Hwang RF, Zanivan S, Kalluri R. |
Journal name |
Nat Cell Biol
|
Publication year |
2021 |
Sample |
Pancreatic duct epithalial cells |
Sample name |
HPDE |
Isolation/purification methods |
Differential centrifugation Filtration Ultracentrifugation |
Flotation density |
-
|
Molecules identified in the study |
Protein mRNA |
Methods used in the study |
RT-qPCR Western blotting Mass spectrometry Flow cytometry |
|
|
38 |
Experiment ID |
409 |
MISEV standards |
✔
EM
|
EV Biophysical techniques |
✔
CD81|CD63|SDCBP|LAMP1|CD9|GAPDH|FLOT1|TFRC|FLOT2|TSG101|RAB35
|
EV Enriched markers |
✔
CANX
|
EV Negative markers |
✔
NTA
|
EV Particle analysis
|
|
Identified molecule |
Protein
|
Identification method |
Mass spectrometry
|
PubMed ID |
34108659
|
Organism |
Homo sapiens |
Experiment description |
Quantitative Proteomics Identifies the Core Proteome of Exosomes with Syntenin-1 as the highest abundant protein and a Putative Universal Biomarker |
Authors |
Kugeratski FG, Hodge K, Lilla S, McAndrews KM, Zhou X, Hwang RF, Zanivan S, Kalluri R. |
Journal name |
Nat Cell Biol
|
Publication year |
2021 |
Sample |
Pancreatic duct epithalial cells |
Sample name |
HPNE |
Isolation/purification methods |
Differential centrifugation Filtration Ultracentrifugation |
Flotation density |
-
|
Molecules identified in the study |
Protein mRNA |
Methods used in the study |
RT-qPCR Western blotting Mass spectrometry Flow cytometry |
|
|
39 |
Experiment ID |
416 |
MISEV standards |
✔
EM
|
EV Biophysical techniques |
✔
CD81|CD9|CD63|SDCBP|LAMP1|GAPDH|FLOT1|TFRC|FLOT2|TSG101|RAB35
|
EV Enriched markers |
✔
CANX
|
EV Negative markers |
✔
NTA
|
EV Particle analysis
|
|
Identified molecule |
Protein
|
Identification method |
Mass spectrometry
|
PubMed ID |
34108659
|
Organism |
Homo sapiens |
Experiment description |
Quantitative Proteomics Identifies the Core Proteome of Exosomes with Syntenin-1 as the highest abundant protein and a Putative Universal Biomarker |
Authors |
Kugeratski FG, Hodge K, Lilla S, McAndrews KM, Zhou X, Hwang RF, Zanivan S, Kalluri R. |
Journal name |
Nat Cell Biol
|
Publication year |
2021 |
Sample |
Pluripotent stem cells |
Sample name |
PSC |
Isolation/purification methods |
Differential centrifugation Filtration Ultracentrifugation |
Flotation density |
-
|
Molecules identified in the study |
Protein mRNA |
Methods used in the study |
RT-qPCR Western blotting Mass spectrometry Flow cytometry |
|
|
40 |
Experiment ID |
834 |
MISEV standards |
✔
EM
|
EV Biophysical techniques |
✔
LAMP2|CD63|FLOT1|ITGA2B|ICAM1|CD9|CD151|TFRC|RAB5A|GAPDH|AQP1|TSG101
|
EV Enriched markers |
✔
CANX
|
EV Negative markers |
✔
NTA
|
EV Particle analysis
|
|
Identified molecule |
Protein
|
Identification method |
Mass spectrometry
|
PubMed ID |
35333565
|
Organism |
Homo sapiens |
Experiment description |
LAMP2A regulates the loading of proteins into exosomes |
Authors |
Ferreira 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 year |
2022 |
Sample |
Retinal pigment epithelial cells |
Sample name |
ARPE-19 |
Isolation/purification methods |
Differential centrifugation Filtration Ultracentrifugation |
Flotation density |
-
|
Molecules identified in the study |
Protein |
Methods used in the study |
Western blotting Mass spectrometry |
|
|
41 |
Experiment ID |
835 |
MISEV standards |
✔
EM
|
EV Biophysical techniques |
✔
CD63|FLOT1|ITGA2B|ICAM1|CD9|CD151|TFRC|RAB5A|GAPDH|AQP1|TSG101
|
EV Enriched markers |
✔
CANX
|
EV Negative markers |
✔
NTA
|
EV Particle analysis
|
|
Identified molecule |
Protein
|
Identification method |
Mass spectrometry
|
PubMed ID |
35333565
|
Organism |
Homo sapiens |
Experiment description |
LAMP2A regulates the loading of proteins into exosomes |
Authors |
Ferreira 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 year |
2022 |
Sample |
Retinal pigment epithelial cells |
Sample name |
ARPE-19 |
Isolation/purification methods |
Differential centrifugation Filtration Ultracentrifugation |
Flotation density |
-
|
Molecules identified in the study |
Protein |
Methods used in the study |
Western blotting Mass spectrometry |
|
|
42 |
Experiment ID |
191 |
MISEV standards |
✘
|
EV Biophysical techniques |
✔
Alix|CD81|CD9
|
EV Enriched markers |
✘
|
EV Negative markers |
✘
|
EV Particle analysis
|
|
Identified molecule |
protein
|
Identification method |
Mass spectrometry
|
PubMed ID |
20124223
|
Organism |
Homo sapiens |
Experiment description |
Hypoxic tumor cell modulates its microenvironment to enhance angiogenic and metastatic potential by secretion of proteins and exosomes. |
Authors |
Park JE, Tan HS, Datta A, Lai RC, Zhang H, Meng W, Lim SK, Sze SK. |
Journal name |
Mol Cell Proteomics
|
Publication year |
2010 |
Sample |
Squamous carcinoma cells |
Sample name |
Squamous carcinoma cell (A431) |
Isolation/purification methods |
Differential centrifugation |
Flotation density |
-
|
Molecules identified in the study |
Protein |
Methods used in the study |
Mass spectrometry |
|
|
43 |
Experiment ID |
410 |
MISEV standards |
✔
EM
|
EV Biophysical techniques |
✔
CD81|CD63|SDCBP|LAMP1|CD9|GAPDH|FLOT1|TFRC|FLOT2|TSG101|RAB35
|
EV Enriched markers |
✔
CANX
|
EV Negative markers |
✔
NTA
|
EV Particle analysis
|
|
Identified molecule |
Protein
|
Identification method |
Mass spectrometry
|
PubMed ID |
34108659
|
Organism |
Homo sapiens |
Experiment description |
Quantitative Proteomics Identifies the Core Proteome of Exosomes with Syntenin-1 as the highest abundant protein and a Putative Universal Biomarker |
Authors |
Kugeratski FG, Hodge K, Lilla S, McAndrews KM, Zhou X, Hwang RF, Zanivan S, Kalluri R. |
Journal name |
Nat Cell Biol
|
Publication year |
2021 |
Sample |
T lymphocytes |
Sample name |
Jurkat |
Isolation/purification methods |
Differential centrifugation Filtration Ultracentrifugation |
Flotation density |
-
|
Molecules identified in the study |
Protein mRNA |
Methods used in the study |
RT-qPCR Western blotting Mass spectrometry Flow cytometry |
|
|
Protein-protein interactions for DPP3 |
|
Pathways in which DPP3 is involved |
No pathways found
|
|
|