Gene ontology annotations for PPIL1 |
|
Experiment description of studies that identified PPIL1 in exosomes |
1 |
Experiment ID |
489 |
MISEV standards |
✔
EM
|
Biophysical techniques |
✔
Cd9|Cd81|Cd63|Gapdh|Sdcbp|Lamp1|Aqp1|Rab5a|Icam1|Cd82|Itga2b|Tsg101|Lamp2|Rab35|Flot1|Flot2|Cd151|Rab5b|Tfrc|Uchl1
|
Enriched markers |
✔
Canx
|
Negative markers |
✔
NTA
|
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 |
|
|
2 |
Experiment ID |
490 |
MISEV standards |
✔
EM
|
Biophysical techniques |
✔
Cd9|Cd81|Cd63|Gapdh|Sdcbp|Lamp1|Aqp1|Rab5a|Icam1|Cd82|Itga2b|Tsg101|Lamp2|Rab35|Flot1|Flot2|Cd151|Rab5b|Tfrc|Uchl1
|
Enriched markers |
✔
Canx
|
Negative markers |
✔
NTA
|
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 |
|
|
3 |
Experiment ID |
491 |
MISEV standards |
✔
EM
|
Biophysical techniques |
✔
Cd9|Cd81|Cd63|Gapdh|Sdcbp|Lamp1|Aqp1|Rab5a|Icam1|Cd82|Itga2b|Tsg101|Lamp2|Rab35|Flot1|Flot2|Cd151|Rab5b|Tfrc|Uchl1
|
Enriched markers |
✔
Canx
|
Negative markers |
✔
NTA
|
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 |
|
|
4 |
Experiment ID |
492 |
MISEV standards |
✔
EM
|
Biophysical techniques |
✔
Cd9|Cd81|Cd63|Gapdh|Sdcbp|Lamp1|Aqp1|Rab5a|Icam1|Cd82|Itga2b|Tsg101|Lamp2|Rab35|Flot1|Flot2|Cd151|Rab5b|Tfrc|Uchl1
|
Enriched markers |
✔
Canx
|
Negative markers |
✔
NTA
|
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 |
|
|
5 |
Experiment ID |
412 |
MISEV standards |
✔
EM
|
Biophysical techniques |
✔
CD81|CD9|CD63|SDCBP|LAMP1|GAPDH|FLOT1|TFRC|FLOT2|TSG101|RAB35
|
Enriched markers |
✔
CANX|ACTB
|
Negative markers |
✔
NTA
|
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 |
|
|
6 |
Experiment ID |
414 |
MISEV standards |
✔
EM
|
Biophysical techniques |
✔
CD81|CD9|CD63|SDCBP|LAMP1|GAPDH|FLOT1|TFRC|FLOT2|TSG101|RAB35
|
Enriched markers |
✔
CANX
|
Negative markers |
✔
NTA
|
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 |
|
|
7 |
Experiment ID |
207 |
MISEV standards |
✔
EM
|
Biophysical techniques |
✔
TSG101|HSP70|FLOT1
|
Enriched markers |
✔
VDAC
|
Negative markers |
✔
NTA
|
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 |
|
|
8 |
Experiment ID |
208 |
MISEV standards |
✔
EM
|
Biophysical techniques |
✔
TSG101|HSP70|FLOT1
|
Enriched markers |
✔
VDAC
|
Negative markers |
✔
NTA
|
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 |
|
|
9 |
Experiment ID |
209 |
MISEV standards |
✘
|
Biophysical techniques |
✔
TSG101|HSP70|FLOT1
|
Enriched markers |
✔
VDAC
|
Negative markers |
✔
NTA
|
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 |
|
|
10 |
Experiment ID |
407 |
MISEV standards |
✔
EM
|
Biophysical techniques |
✔
CD9|CD63|CD81|SDCBP|TSG101|LAMP1|GAPDH|FLOT1|TFRC|FLOT2|RAB35
|
Enriched markers |
✔
CANX
|
Negative markers |
✔
NTA
|
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 |
|
|
11 |
Experiment ID |
405 |
MISEV standards |
✔
EM
|
Biophysical techniques |
✔
CD9|CD63|CD81|SDCBP|LAMP1|GAPDH|FLOT1|TFRC|FLOT2|TSG101|RAB35
|
Enriched markers |
✔
CANX
|
Negative markers |
✔
NTA
|
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 |
|
|
12 |
Experiment ID |
363 |
MISEV standards |
✘
|
Biophysical techniques |
✔
TSG101|GAPDH|AQP1|CD151|CD81|CD82|CD9|EPCAM|FLOT1|FLOT2|ICAM1|ITGA2B|LAMP2|RAB35|RAB5A|RAB5B|SDCBP|TFRC|UCHL1
|
Enriched markers |
✔
DCLK1
|
Negative markers |
✔
NTA
|
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 |
|
|
13 |
Experiment ID |
364 |
MISEV standards |
✘
|
Biophysical techniques |
✔
TSG101|GAPDH|AQP1|CD151|CD81|CD82|CD9|EPCAM|FLOT1|FLOT2|ICAM1|ITGA2B|LAMP2|RAB35|RAB5A|RAB5B|SDCBP|TFRC|UCHL1
|
Enriched markers |
✔
DCLK1
|
Negative markers |
✔
NTA
|
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 |
|
|
14 |
Experiment ID |
365 |
MISEV standards |
✘
|
Biophysical techniques |
✔
TSG101|GAPDH|AQP1|CD151|CD81|CD82|CD9|EPCAM|FLOT1|FLOT2|ICAM1|ITGA2B|LAMP2|RAB35|RAB5A|RAB5B|SDCBP|TFRC|UCHL1
|
Enriched markers |
✔
DCLK1
|
Negative markers |
✔
NTA
|
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 |
|
|
15 |
Experiment ID |
417 |
MISEV standards |
✔
EM
|
Biophysical techniques |
✔
CD81|CD63|SDCBP|LAMP1|CD9|GAPDH|FLOT1|TFRC|FLOT2|TSG101|RAB35
|
Enriched markers |
✔
CANX|ACTB
|
Negative markers |
✔
NTA
|
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 |
|
|
16 |
Experiment ID |
411 |
MISEV standards |
✔
EM
|
Biophysical techniques |
✔
CD81|CD9|CD63|SDCBP|LAMP1|GAPDH|FLOT1|TFRC|FLOT2|TSG101|RAB35
|
Enriched markers |
✔
CANX
|
Negative markers |
✔
NTA
|
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 |
|
|
17 |
Experiment ID |
488 |
MISEV standards |
✔
EM
|
Biophysical techniques |
✔
CD9|CD81|CD63|GAPDH|SDCBP|LAMP1|TFRC|UCHL1|FLOT2|LAMP2|FLOT1|ICAM1|RAB5B|CD151|RAB35|TSG101|RAB5A|CD82
|
Enriched markers |
✔
CANX
|
Negative markers |
✔
NTA
|
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 |
|
|
18 |
Experiment ID |
418 |
MISEV standards |
✔
EM
|
Biophysical techniques |
✔
CD81|CD9|CD63|SDCBP|LAMP1|GAPDH|FLOT1|TFRC|FLOT2|TSG101|RAB35
|
Enriched markers |
✔
CANX
|
Negative markers |
✔
NTA
|
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 |
|
|
19 |
Experiment ID |
418 |
MISEV standards |
✔
EM
|
Biophysical techniques |
✔
CD81|CD9|CD63|SDCBP|LAMP1|GAPDH|FLOT1|TFRC|FLOT2|TSG101|RAB35
|
Enriched markers |
✔
CANX
|
Negative markers |
✔
NTA
|
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 |
|
|
20 |
Experiment ID |
413 |
MISEV standards |
✔
EM
|
Biophysical techniques |
✔
CD81|CD9|CD63|SDCBP|LAMP1|GAPDH|FLOT1|TFRC|FLOT2|TSG101|RAB35
|
Enriched markers |
✔
CANX
|
Negative markers |
✔
NTA
|
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 |
|
|
21 |
Experiment ID |
406 |
MISEV standards |
✔
EM
|
Biophysical techniques |
✔
CD9|CD63|SDCBP|LAMP1|GAPDH|FLOT1|TFRC|FLOT2|TSG101|RAB35|CD81
|
Enriched markers |
✔
CANX
|
Negative markers |
✔
NTA
|
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 |
|
|
22 |
Experiment ID |
415 |
MISEV standards |
✔
EM
|
Biophysical techniques |
✔
CD81|CD9|CD63|SDCBP|LAMP1|GAPDH|FLOT1|TFRC|FLOT2|TSG101|RAB35
|
Enriched markers |
✔
CANX
|
Negative markers |
✔
NTA
|
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 |
|
|
23 |
Experiment ID |
408 |
MISEV standards |
✔
EM
|
Biophysical techniques |
✔
CD9|CD63|CD81|SDCBP|LAMP1|GAPDH|FLOT1|TFRC|FLOT2|TSG101|RAB35
|
Enriched markers |
✔
CANX|ACTB
|
Negative markers |
✔
NTA
|
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 |
|
|
24 |
Experiment ID |
409 |
MISEV standards |
✔
EM
|
Biophysical techniques |
✔
CD81|CD63|SDCBP|LAMP1|CD9|GAPDH|FLOT1|TFRC|FLOT2|TSG101|RAB35
|
Enriched markers |
✔
CANX
|
Negative markers |
✔
NTA
|
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 |
|
|
25 |
Experiment ID |
416 |
MISEV standards |
✔
EM
|
Biophysical techniques |
✔
CD81|CD9|CD63|SDCBP|LAMP1|GAPDH|FLOT1|TFRC|FLOT2|TSG101|RAB35
|
Enriched markers |
✔
CANX
|
Negative markers |
✔
NTA
|
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 |
|
|
26 |
Experiment ID |
410 |
MISEV standards |
✔
EM
|
Biophysical techniques |
✔
CD81|CD63|SDCBP|LAMP1|CD9|GAPDH|FLOT1|TFRC|FLOT2|TSG101|RAB35
|
Enriched markers |
✔
CANX
|
Negative markers |
✔
NTA
|
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 PPIL1 |
|
Protein Interactor |
ExoCarta ID |
Identification method |
PubMed |
Species |
1 |
UBE2H |
7328 |
Affinity Capture-MS |
|
Homo sapiens |
|
2 |
GCFC2 |
|
Affinity Capture-MS |
|
Homo sapiens |
|
3 |
RIT1 |
6016 |
Negative Genetic |
|
Homo sapiens |
|
4 |
PRR35 |
|
Two-hybrid |
|
Homo sapiens |
|
5 |
Prpf8 |
192159 |
Affinity Capture-MS |
|
Mus musculus |
|
6 |
RBM22 |
55696 |
Affinity Capture-MS |
|
Homo sapiens |
|
7 |
PPIE |
10450 |
Affinity Capture-MS |
|
Homo sapiens |
|
8 |
SRPK2 |
6733 |
Biochemical Activity |
|
Homo sapiens |
|
9 |
GADD45G |
|
Reconstituted Complex |
|
Homo sapiens |
|
10 |
LHX2 |
|
Two-hybrid |
|
Homo sapiens |
|
11 |
DHX35 |
|
Affinity Capture-MS |
|
Homo sapiens |
|
12 |
GPALPP1 |
|
Affinity Capture-MS |
|
Homo sapiens |
Affinity Capture-MS |
|
Homo sapiens |
|
13 |
AQR |
9716 |
Affinity Capture-MS |
|
Homo sapiens |
|
14 |
SYF2 |
|
Affinity Capture-MS |
|
Homo sapiens |
|
15 |
SNRPF |
6636 |
Affinity Capture-MS |
|
Homo sapiens |
|
16 |
PRR22 |
|
Two-hybrid |
|
Homo sapiens |
|
17 |
CRNKL1 |
51340 |
Affinity Capture-MS |
|
Homo sapiens |
|
18 |
GPATCH1 |
|
Affinity Capture-MS |
|
Homo sapiens |
|
19 |
Snw1 |
|
Affinity Capture-MS |
|
Mus musculus |
Affinity Capture-MS |
|
Mus musculus |
|
20 |
ISY1 |
57461 |
Affinity Capture-MS |
|
Homo sapiens |
|
21 |
WDR83 |
|
Two-hybrid |
|
Homo sapiens |
Affinity Capture-Luminescence |
|
Homo sapiens |
Two-hybrid |
|
Homo sapiens |
Affinity Capture-MS |
|
Homo sapiens |
|
22 |
PRC1 |
9055 |
Affinity Capture-MS |
|
Homo sapiens |
|
23 |
SRRM2 |
23524 |
Affinity Capture-MS |
|
Homo sapiens |
|
24 |
SNRPC |
6631 |
Affinity Capture-MS |
|
Homo sapiens |
|
25 |
TFIP11 |
|
Affinity Capture-MS |
|
Homo sapiens |
|
26 |
CWC15 |
|
Affinity Capture-MS |
|
Homo sapiens |
|
27 |
BMI1 |
|
Affinity Capture-MS |
|
Homo sapiens |
|
28 |
KPRP |
448834 |
Two-hybrid |
|
Homo sapiens |
|
29 |
VCAM1 |
7412 |
Affinity Capture-MS |
|
Homo sapiens |
|
30 |
MYCN |
|
Affinity Capture-MS |
|
Homo sapiens |
|
31 |
RBM42 |
|
Two-hybrid |
|
Homo sapiens |
Two-hybrid |
|
Homo sapiens |
|
32 |
BUD31 |
8896 |
Affinity Capture-MS |
|
Homo sapiens |
|
33 |
KIF14 |
9928 |
Affinity Capture-MS |
|
Homo sapiens |
|
34 |
KLF16 |
|
Proximity Label-MS |
|
Homo sapiens |
|
35 |
FOXA1 |
|
Affinity Capture-MS |
|
Homo sapiens |
|
36 |
PRPF8 |
10594 |
Proximity Label-MS |
|
Homo sapiens |
|
37 |
DERA |
51071 |
Affinity Capture-MS |
|
Homo sapiens |
Affinity Capture-MS |
|
Homo sapiens |
|
38 |
POU6F2 |
|
Two-hybrid |
|
Homo sapiens |
|
39 |
SAT2 |
112483 |
Affinity Capture-MS |
|
Homo sapiens |
|
40 |
PPP1R8 |
5511 |
Two-hybrid |
|
Homo sapiens |
Two-hybrid |
|
Homo sapiens |
|
41 |
U2AF2 |
11338 |
Affinity Capture-MS |
|
Homo sapiens |
|
42 |
SYNCRIP |
10492 |
Affinity Capture-MS |
|
Homo sapiens |
|
43 |
RPA4 |
|
Proximity Label-MS |
|
Homo sapiens |
|
44 |
SPDYE4 |
|
Two-hybrid |
|
Homo sapiens |
|
45 |
ITGA4 |
3676 |
Affinity Capture-MS |
|
Homo sapiens |
|
46 |
CEBPA |
|
Proximity Label-MS |
|
Homo sapiens |
|
47 |
SRPK1 |
6732 |
Biochemical Activity |
|
Homo sapiens |
|
48 |
CCDC12 |
|
Affinity Capture-MS |
|
Homo sapiens |
|
49 |
ADH5 |
128 |
Co-fractionation |
|
Homo sapiens |
|
50 |
CWF19L1 |
55280 |
Affinity Capture-MS |
|
Homo sapiens |
|
51 |
RBM39 |
9584 |
Affinity Capture-MS |
|
Homo sapiens |
|
52 |
FANCD2 |
|
Affinity Capture-MS |
|
Homo sapiens |
|
53 |
SNRPB |
6628 |
Affinity Capture-MS |
|
Homo sapiens |
|
54 |
ANXA1 |
301 |
Co-fractionation |
|
Homo sapiens |
|
55 |
XAB2 |
56949 |
Affinity Capture-MS |
|
Homo sapiens |
|
56 |
THOC5 |
8563 |
Two-hybrid |
|
Homo sapiens |
Two-hybrid |
|
Homo sapiens |
|
57 |
SNRPA |
6626 |
Affinity Capture-MS |
|
Homo sapiens |
|
58 |
HNRNPA1 |
3178 |
Two-hybrid |
|
Homo sapiens |
Two-hybrid |
|
Homo sapiens |
|
59 |
FUS |
2521 |
Affinity Capture-MS |
|
Homo sapiens |
|
60 |
HNRNPUL1 |
11100 |
Two-hybrid |
|
Homo sapiens |
Two-hybrid |
|
Homo sapiens |
|
61 |
FN1 |
2335 |
Affinity Capture-MS |
|
Homo sapiens |
|
62 |
SF3A1 |
10291 |
Affinity Capture-MS |
|
Homo sapiens |
|
63 |
SAAL1 |
113174 |
Affinity Capture-MS |
|
Homo sapiens |
|
64 |
MYC |
|
Affinity Capture-MS |
|
Homo sapiens |
|
65 |
RPA3 |
6119 |
Proximity Label-MS |
|
Homo sapiens |
|
66 |
ESD |
2098 |
Co-fractionation |
|
Homo sapiens |
|
67 |
TOP1 |
7150 |
Affinity Capture-MS |
|
Homo sapiens |
|
68 |
N4BP2L2 |
10443 |
Two-hybrid |
|
Homo sapiens |
|
69 |
BCAS2 |
10286 |
Affinity Capture-MS |
|
Homo sapiens |
|
70 |
SF3B3 |
23450 |
Two-hybrid |
|
Homo sapiens |
Two-hybrid |
|
Homo sapiens |
|
71 |
RAC2 |
5880 |
Co-fractionation |
|
Homo sapiens |
|
72 |
CPSF6 |
11052 |
Two-hybrid |
|
Homo sapiens |
Affinity Capture-MS |
|
Homo sapiens |
|
73 |
SF3B1 |
23451 |
Affinity Capture-MS |
|
Homo sapiens |
|
74 |
ALDH4A1 |
8659 |
Co-fractionation |
|
| | | |