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You searched for: EV200036 (EV-TRACK ID)

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Experiment number
  • If needed, multiple experiments were identified in a single publication based on differing sample types, separation protocols and/or vesicle types of interest.
Species
  • Species of origin of the EVs.
Separation protocol
  • Gives a short, non-chronological overview of the different steps of the separation protocol.
    • dUC = (Differential) (ultra)centrifugation
    • DG = density gradient
    • UF = ultrafiltration
    • SEC = size-exclusion chromatography
Details EV-TRACK ID Experiment nr. Species Sample type separation protocol First author Year EV-METRIC
EV200036 1/16 Homo sapiens Cell culture supernatant Density gradient
(Differential) (ultra)centrifugation
Commercial method
Juan Antonio Fafián-Labora 2020 78%

Study summary

Full title
All authors
Juan Antonio Fafián-Labora, Jose Antonio Rodríguez-Navarro, Ana O'Loghlen
Journal
Cell metab
Abstract
Aging is a process of cellular and tissue dysfunction characterized by different hallmarks, includin (show more...)Aging is a process of cellular and tissue dysfunction characterized by different hallmarks, including cellular senescence. However, there is proof that certain features of aging and senescence can be ameliorated. Here, we provide evidence that small extracellular vesicles (sEVs) isolated from primary fibroblasts of young human donors ameliorate certain biomarkers of senescence in cells derived from old and Hutchinson-Gilford progeria syndrome donors. Importantly, sEVs from young cells ameliorate senescence in a variety of tissues in old mice. Mechanistically, we identified sEVs to have intrinsic glutathione-S-transferase activity partially due to the high levels of expression of the glutathione-related protein (GSTM2). Transfection of recombinant GSTM2 into sEVs derived from old fibroblasts restores their antioxidant capacity. sEVs increase the levels of reduced glutathione and decrease oxidative stress and lipid peroxidation both in vivo and in vitro. Altogether, our data provide an indication of the potential of sEVs as regenerative therapy in aging. (hide)
EV-METRIC
78% (97th percentile of all experiments on the same sample type)
 Reported
 Not reported
 Not applicable
EV-enriched proteins
Protein analysis: analysis of three or more EV-enriched proteins
non EV-enriched protein
Protein analysis: assessment of a non-EV-enriched protein
qualitative and quantitative analysis
Particle analysis: implementation of both qualitative and quantitative methods
electron microscopy images
Particle analysis: inclusion of a widefield and close-up electron microscopy image
density gradient
Separation method: density gradient, at least as validation of results attributed to EVs
EV density
Separation method: reporting of obtained EV density
ultracentrifugation specifics
Separation method: reporting of g-forces, duration and rotor type of ultracentrifugation steps
antibody specifics
Protein analysis: antibody clone/reference number and dilution
lysate preparation
Protein analysis: lysis buffer composition
Study data
Sample type
Cell culture supernatant
Sample origin
Young donors
Focus vesicles
extracellular vesicle
Separation protocol
Separation protocol
  • Gives a short, non-chronological overview of the
    different steps of the separation protocol.
    • dUC = (Differential) (ultra)centrifugation
    • DG = density gradient
    • UF = ultrafiltration
    • SEC = size-exclusion chromatography
Density gradient + (Differential) (ultra)centrifugation + Commercial method
Protein markers
EV: Alix/ TSG101/ GSTM2
non-EV: Calnexin/ Actin-beta
Proteomics
no
EV density (g/ml)
1.074-1.106
Show all info
Study aim
Function
Sample
Species
Homo sapiens
Sample Type
Cell culture supernatant
Sample Condition
Young donors
EV-producing cells
human skin primary fibroblasts
EV-harvesting Medium
EV-depleted medium
Preparation of EDS
overnight (16h) at >= 100,000g
Separation Method
(Differential) (ultra)centrifugation
dUC: centrifugation steps
Between 800 g and 10,000 g
Between 10,000 g and 50,000 g
Between 100,000 g and 150,000 g
Pelleting: time(min)
80
Pelleting: rotor type
T-865
Pelleting: speed (g)
100000
Wash: volume per pellet (ml)
15
Wash: time (min)
80
Wash: Rotor Type
T-865
Wash: speed (g)
100000
Density gradient
Density medium
Iodixanol
Type
Discontinuous
Number of initial discontinuous layers
3
Lowest density fraction
10%
Highest density fraction
60%
Total gradient volume, incl. sample (mL)
5.5
Sample volume (mL)
1.5
Orientation
Bottom-up
Rotor type
T-865
Speed (g)
100000
Duration (min)
720
Fraction volume (mL)
0.7
Fraction processing
Centrifugation
Pelleting: volume per fraction
15
Pelleting: duration (min)
80
Pelleting: rotor type
T-865
Pelleting: speed (g)
100000
Pelleting-wash: volume per pellet (mL)
15
Pelleting-wash: duration (min)
80
Pelleting-wash: speed (g)
T-865
Commercial kit
qEV
EV-subtype
Distinction between multiple subtypes
Size
Used subtypes
<200 nm
Characterization: Protein analysis
Western Blot
Detected EV-associated proteins
Alix/ TSG101/ GSTM2
Not detected contaminants
Calnexin/ Actin-beta
Characterization: Particle analysis
NA
NTA
Report type
Mean
Reported size (nm)
<200
EV concentration
Yes
Particle yield
Number of particles of starting sample E08-E09
EV200036 3/16 Homo sapiens Cell culture supernatant Density gradient
(Differential) (ultra)centrifugation
Commercial method
Juan Antonio Fafián-Labora 2020 78%

Study summary

Full title
All authors
Juan Antonio Fafián-Labora, Jose Antonio Rodríguez-Navarro, Ana O'Loghlen
Journal
Cell metab
Abstract
Aging is a process of cellular and tissue dysfunction characterized by different hallmarks, includin (show more...)Aging is a process of cellular and tissue dysfunction characterized by different hallmarks, including cellular senescence. However, there is proof that certain features of aging and senescence can be ameliorated. Here, we provide evidence that small extracellular vesicles (sEVs) isolated from primary fibroblasts of young human donors ameliorate certain biomarkers of senescence in cells derived from old and Hutchinson-Gilford progeria syndrome donors. Importantly, sEVs from young cells ameliorate senescence in a variety of tissues in old mice. Mechanistically, we identified sEVs to have intrinsic glutathione-S-transferase activity partially due to the high levels of expression of the glutathione-related protein (GSTM2). Transfection of recombinant GSTM2 into sEVs derived from old fibroblasts restores their antioxidant capacity. sEVs increase the levels of reduced glutathione and decrease oxidative stress and lipid peroxidation both in vivo and in vitro. Altogether, our data provide an indication of the potential of sEVs as regenerative therapy in aging. (hide)
EV-METRIC
78% (97th percentile of all experiments on the same sample type)
 Reported
 Not reported
 Not applicable
EV-enriched proteins
Protein analysis: analysis of three or more EV-enriched proteins
non EV-enriched protein
Protein analysis: assessment of a non-EV-enriched protein
qualitative and quantitative analysis
Particle analysis: implementation of both qualitative and quantitative methods
electron microscopy images
Particle analysis: inclusion of a widefield and close-up electron microscopy image
density gradient
Separation method: density gradient, at least as validation of results attributed to EVs
EV density
Separation method: reporting of obtained EV density
ultracentrifugation specifics
Separation method: reporting of g-forces, duration and rotor type of ultracentrifugation steps
antibody specifics
Protein analysis: antibody clone/reference number and dilution
lysate preparation
Protein analysis: lysis buffer composition
Study data
Sample type
Cell culture supernatant
Sample origin
Old donors
Focus vesicles
extracellular vesicle
Separation protocol
Separation protocol
  • Gives a short, non-chronological overview of the
    different steps of the separation protocol.
    • dUC = (Differential) (ultra)centrifugation
    • DG = density gradient
    • UF = ultrafiltration
    • SEC = size-exclusion chromatography
Density gradient + (Differential) (ultra)centrifugation + Commercial method
Protein markers
EV: Alix/ TSG101/ GSTM2
non-EV: Calnexin/ Actin-beta
Proteomics
no
EV density (g/ml)
1.074-1.106
Show all info
Study aim
Function
Sample
Species
Homo sapiens
Sample Type
Cell culture supernatant
Sample Condition
Old donors
EV-producing cells
human skin primary fibroblasts
EV-harvesting Medium
EV-depleted medium
Preparation of EDS
overnight (16h) at >= 100,000g
Separation Method
(Differential) (ultra)centrifugation
dUC: centrifugation steps
Between 800 g and 10,000 g
Between 10,000 g and 50,000 g
Between 100,000 g and 150,000 g
Pelleting: time(min)
80
Pelleting: rotor type
T-865
Pelleting: speed (g)
100000
Wash: volume per pellet (ml)
15
Wash: time (min)
80
Wash: Rotor Type
T-865
Wash: speed (g)
100000
Density gradient
Density medium
Iodixanol
Type
Discontinuous
Number of initial discontinuous layers
3
Lowest density fraction
10%
Highest density fraction
60%
Total gradient volume, incl. sample (mL)
5.5
Sample volume (mL)
1.5
Orientation
Bottom-up
Rotor type
T-865
Speed (g)
100000
Duration (min)
720
Fraction volume (mL)
0.7
Fraction processing
Centrifugation
Pelleting: volume per fraction
15
Pelleting: duration (min)
80
Pelleting: rotor type
T-865
Pelleting: speed (g)
100000
Pelleting-wash: volume per pellet (mL)
15
Pelleting-wash: duration (min)
80
Pelleting-wash: speed (g)
T-865
Commercial kit
qEV
EV-subtype
Distinction between multiple subtypes
Size
Used subtypes
<200 nm
Characterization: Protein analysis
Western Blot
Detected EV-associated proteins
Alix/ TSG101/ GSTM2
Not detected contaminants
Calnexin/ Actin-beta
Characterization: Particle analysis
NA
NTA
Report type
Mean
Reported size (nm)
<200
EV concentration
Yes
Particle yield
Number of particles of starting sample E08-E09
EV200036 5/16 Homo sapiens Cell culture supernatant Density gradient
(Differential) (ultra)centrifugation
Commercial method
Juan Antonio Fafián-Labora 2020 56%

Study summary

Full title
All authors
Juan Antonio Fafián-Labora, Jose Antonio Rodríguez-Navarro, Ana O'Loghlen
Journal
Cell metab
Abstract
Aging is a process of cellular and tissue dysfunction characterized by different hallmarks, includin (show more...)Aging is a process of cellular and tissue dysfunction characterized by different hallmarks, including cellular senescence. However, there is proof that certain features of aging and senescence can be ameliorated. Here, we provide evidence that small extracellular vesicles (sEVs) isolated from primary fibroblasts of young human donors ameliorate certain biomarkers of senescence in cells derived from old and Hutchinson-Gilford progeria syndrome donors. Importantly, sEVs from young cells ameliorate senescence in a variety of tissues in old mice. Mechanistically, we identified sEVs to have intrinsic glutathione-S-transferase activity partially due to the high levels of expression of the glutathione-related protein (GSTM2). Transfection of recombinant GSTM2 into sEVs derived from old fibroblasts restores their antioxidant capacity. sEVs increase the levels of reduced glutathione and decrease oxidative stress and lipid peroxidation both in vivo and in vitro. Altogether, our data provide an indication of the potential of sEVs as regenerative therapy in aging. (hide)
EV-METRIC
56% (88th percentile of all experiments on the same sample type)
 Reported
 Not reported
 Not applicable
EV-enriched proteins
Protein analysis: analysis of three or more EV-enriched proteins
non EV-enriched protein
Protein analysis: assessment of a non-EV-enriched protein
qualitative and quantitative analysis
Particle analysis: implementation of both qualitative and quantitative methods
electron microscopy images
Particle analysis: inclusion of a widefield and close-up electron microscopy image
density gradient
Separation method: density gradient, at least as validation of results attributed to EVs
EV density
Separation method: reporting of obtained EV density
ultracentrifugation specifics
Separation method: reporting of g-forces, duration and rotor type of ultracentrifugation steps
antibody specifics
Protein analysis: antibody clone/reference number and dilution
lysate preparation
Protein analysis: lysis buffer composition
Study data
Sample type
Cell culture supernatant
Sample origin
Progeria patients
Focus vesicles
extracellular vesicle
Separation protocol
Separation protocol
  • Gives a short, non-chronological overview of the
    different steps of the separation protocol.
    • dUC = (Differential) (ultra)centrifugation
    • DG = density gradient
    • UF = ultrafiltration
    • SEC = size-exclusion chromatography
Density gradient + (Differential) (ultra)centrifugation + Commercial method
Protein markers
EV: Alix/ GSTM2
non-EV: None
Proteomics
no
EV density (g/ml)
1.074-1.106
Show all info
Study aim
Function
Sample
Species
Homo sapiens
Sample Type
Cell culture supernatant
Sample Condition
Progeria patients
EV-producing cells
human skin primary fibroblasts
EV-harvesting Medium
EV-depleted medium
Preparation of EDS
overnight (16h) at >= 100,000g
Separation Method
(Differential) (ultra)centrifugation
dUC: centrifugation steps
Between 800 g and 10,000 g
Between 10,000 g and 50,000 g
Between 100,000 g and 150,000 g
Pelleting: time(min)
80
Pelleting: rotor type
T-865
Pelleting: speed (g)
100000
Wash: volume per pellet (ml)
15
Wash: time (min)
80
Wash: Rotor Type
T-865
Wash: speed (g)
100000
Density gradient
Density medium
Iodixanol
Type
Discontinuous
Number of initial discontinuous layers
3
Lowest density fraction
10%
Highest density fraction
60%
Total gradient volume, incl. sample (mL)
5.5
Sample volume (mL)
1.5
Orientation
Bottom-up
Rotor type
T-865
Speed (g)
100000
Duration (min)
720
Fraction volume (mL)
0.7
Fraction processing
Centrifugation
Pelleting: volume per fraction
15
Pelleting: duration (min)
80
Pelleting: rotor type
T-865
Pelleting: speed (g)
100000
Pelleting-wash: volume per pellet (mL)
15
Pelleting-wash: duration (min)
80
Pelleting-wash: speed (g)
T-865
Commercial kit
qEV
EV-subtype
Distinction between multiple subtypes
Size
Used subtypes
<200 nm
Characterization: Protein analysis
Western Blot
Detected EV-associated proteins
Alix/ GSTM2
Characterization: Particle analysis
NA
NTA
Report type
Mean
Reported size (nm)
<200
EV concentration
Yes
Particle yield
Number of particles of starting sample E08-E09
EV200036 7/16 Homo sapiens Cell culture supernatant Density gradient
(Differential) (ultra)centrifugation
Commercial method
Juan Antonio Fafián-Labora 2020 56%

Study summary

Full title
All authors
Juan Antonio Fafián-Labora, Jose Antonio Rodríguez-Navarro, Ana O'Loghlen
Journal
Cell metab
Abstract
Aging is a process of cellular and tissue dysfunction characterized by different hallmarks, includin (show more...)Aging is a process of cellular and tissue dysfunction characterized by different hallmarks, including cellular senescence. However, there is proof that certain features of aging and senescence can be ameliorated. Here, we provide evidence that small extracellular vesicles (sEVs) isolated from primary fibroblasts of young human donors ameliorate certain biomarkers of senescence in cells derived from old and Hutchinson-Gilford progeria syndrome donors. Importantly, sEVs from young cells ameliorate senescence in a variety of tissues in old mice. Mechanistically, we identified sEVs to have intrinsic glutathione-S-transferase activity partially due to the high levels of expression of the glutathione-related protein (GSTM2). Transfection of recombinant GSTM2 into sEVs derived from old fibroblasts restores their antioxidant capacity. sEVs increase the levels of reduced glutathione and decrease oxidative stress and lipid peroxidation both in vivo and in vitro. Altogether, our data provide an indication of the potential of sEVs as regenerative therapy in aging. (hide)
EV-METRIC
56% (88th percentile of all experiments on the same sample type)
 Reported
 Not reported
 Not applicable
EV-enriched proteins
Protein analysis: analysis of three or more EV-enriched proteins
non EV-enriched protein
Protein analysis: assessment of a non-EV-enriched protein
qualitative and quantitative analysis
Particle analysis: implementation of both qualitative and quantitative methods
electron microscopy images
Particle analysis: inclusion of a widefield and close-up electron microscopy image
density gradient
Separation method: density gradient, at least as validation of results attributed to EVs
EV density
Separation method: reporting of obtained EV density
ultracentrifugation specifics
Separation method: reporting of g-forces, duration and rotor type of ultracentrifugation steps
antibody specifics
Protein analysis: antibody clone/reference number and dilution
lysate preparation
Protein analysis: lysis buffer composition
Study data
Sample type
Cell culture supernatant
Sample origin
Control condition
Focus vesicles
extracellular vesicle
Separation protocol
Separation protocol
  • Gives a short, non-chronological overview of the
    different steps of the separation protocol.
    • dUC = (Differential) (ultra)centrifugation
    • DG = density gradient
    • UF = ultrafiltration
    • SEC = size-exclusion chromatography
Density gradient + (Differential) (ultra)centrifugation + Commercial method
Protein markers
EV: Alix/ GSTM2
non-EV: None
Proteomics
no
EV density (g/ml)
1.074-1.106
Show all info
Study aim
Function
Sample
Species
Homo sapiens
Sample Type
Cell culture supernatant
Sample Condition
Control condition
EV-producing cells
primary human foreskin fibroblasts
EV-harvesting Medium
EV-depleted medium
Preparation of EDS
overnight (16h) at >= 100,000g
Separation Method
(Differential) (ultra)centrifugation
dUC: centrifugation steps
Between 800 g and 10,000 g
Between 10,000 g and 50,000 g
Between 100,000 g and 150,000 g
Pelleting: time(min)
80
Pelleting: rotor type
T-865
Pelleting: speed (g)
100000
Wash: volume per pellet (ml)
15
Wash: time (min)
80
Wash: Rotor Type
T-865
Wash: speed (g)
100000
Density gradient
Density medium
Iodixanol
Type
Discontinuous
Number of initial discontinuous layers
3
Lowest density fraction
10%
Highest density fraction
60%
Total gradient volume, incl. sample (mL)
5.5
Sample volume (mL)
1.5
Orientation
Bottom-up
Rotor type
T-865
Speed (g)
100000
Duration (min)
720
Fraction volume (mL)
0.7
Fraction processing
Centrifugation
Pelleting: volume per fraction
15
Pelleting: duration (min)
80
Pelleting: rotor type
T-865
Pelleting: speed (g)
100000
Pelleting-wash: volume per pellet (mL)
15
Pelleting-wash: duration (min)
80
Pelleting-wash: speed (g)
T-865
Commercial kit
qEV
EV-subtype
Distinction between multiple subtypes
Size
Used subtypes
<200 nm
Characterization: Protein analysis
Western Blot
Detected EV-associated proteins
Alix/ GSTM2
Characterization: Particle analysis
NA
NTA
Report type
Mean
Reported size (nm)
<200
EV concentration
Yes
Particle yield
Number of particles of starting sample E08-E09
EV200036 9/16 Homo sapiens Cell culture supernatant Density gradient
(Differential) (ultra)centrifugation
Commercial method
Juan Antonio Fafián-Labora 2020 56%

Study summary

Full title
All authors
Juan Antonio Fafián-Labora, Jose Antonio Rodríguez-Navarro, Ana O'Loghlen
Journal
Cell metab
Abstract
Aging is a process of cellular and tissue dysfunction characterized by different hallmarks, includin (show more...)Aging is a process of cellular and tissue dysfunction characterized by different hallmarks, including cellular senescence. However, there is proof that certain features of aging and senescence can be ameliorated. Here, we provide evidence that small extracellular vesicles (sEVs) isolated from primary fibroblasts of young human donors ameliorate certain biomarkers of senescence in cells derived from old and Hutchinson-Gilford progeria syndrome donors. Importantly, sEVs from young cells ameliorate senescence in a variety of tissues in old mice. Mechanistically, we identified sEVs to have intrinsic glutathione-S-transferase activity partially due to the high levels of expression of the glutathione-related protein (GSTM2). Transfection of recombinant GSTM2 into sEVs derived from old fibroblasts restores their antioxidant capacity. sEVs increase the levels of reduced glutathione and decrease oxidative stress and lipid peroxidation both in vivo and in vitro. Altogether, our data provide an indication of the potential of sEVs as regenerative therapy in aging. (hide)
EV-METRIC
56% (88th percentile of all experiments on the same sample type)
 Reported
 Not reported
 Not applicable
EV-enriched proteins
Protein analysis: analysis of three or more EV-enriched proteins
non EV-enriched protein
Protein analysis: assessment of a non-EV-enriched protein
qualitative and quantitative analysis
Particle analysis: implementation of both qualitative and quantitative methods
electron microscopy images
Particle analysis: inclusion of a widefield and close-up electron microscopy image
density gradient
Separation method: density gradient, at least as validation of results attributed to EVs
EV density
Separation method: reporting of obtained EV density
ultracentrifugation specifics
Separation method: reporting of g-forces, duration and rotor type of ultracentrifugation steps
antibody specifics
Protein analysis: antibody clone/reference number and dilution
lysate preparation
Protein analysis: lysis buffer composition
Study data
Sample type
Cell culture supernatant
Sample origin
iRas
Focus vesicles
extracellular vesicle
Separation protocol
Separation protocol
  • Gives a short, non-chronological overview of the
    different steps of the separation protocol.
    • dUC = (Differential) (ultra)centrifugation
    • DG = density gradient
    • UF = ultrafiltration
    • SEC = size-exclusion chromatography
Density gradient + (Differential) (ultra)centrifugation + Commercial method
Protein markers
EV: Alix/ GSTM2
non-EV: None
Proteomics
no
EV density (g/ml)
1.074-1.106
Show all info
Study aim
Function
Sample
Species
Homo sapiens
Sample Type
Cell culture supernatant
Sample Condition
iRas
EV-producing cells
primary human foreskin fibroblasts
EV-harvesting Medium
EV-depleted medium
Preparation of EDS
overnight (16h) at >= 100,000g
Separation Method
(Differential) (ultra)centrifugation
dUC: centrifugation steps
Between 800 g and 10,000 g
Between 10,000 g and 50,000 g
Between 100,000 g and 150,000 g
Pelleting: time(min)
80
Pelleting: rotor type
T-865
Pelleting: speed (g)
100000
Wash: volume per pellet (ml)
15
Wash: time (min)
80
Wash: Rotor Type
T-865
Wash: speed (g)
100000
Density gradient
Density medium
Iodixanol
Type
Discontinuous
Number of initial discontinuous layers
3
Lowest density fraction
10%
Highest density fraction
60%
Total gradient volume, incl. sample (mL)
5.5
Sample volume (mL)
1.5
Orientation
Bottom-up
Rotor type
T-865
Speed (g)
100000
Duration (min)
720
Fraction volume (mL)
0.7
Fraction processing
Centrifugation
Pelleting: volume per fraction
15
Pelleting: duration (min)
80
Pelleting: rotor type
T-865
Pelleting: speed (g)
100000
Pelleting-wash: volume per pellet (mL)
15
Pelleting-wash: duration (min)
80
Pelleting-wash: speed (g)
T-865
Commercial kit
qEV
EV-subtype
Distinction between multiple subtypes
Size
Used subtypes
<200 nm
Characterization: Protein analysis
Western Blot
Detected EV-associated proteins
Alix/ GSTM2
Characterization: Particle analysis
NA
NTA
Report type
Mean
Reported size (nm)
<200
EV concentration
Yes
Particle yield
Number of particles of starting sample E08-E09
EV200036 11/16 Homo sapiens Cell culture supernatant Density gradient
(Differential) (ultra)centrifugation
Commercial method
Juan Antonio Fafián-Labora 2020 56%

Study summary

Full title
All authors
Juan Antonio Fafián-Labora, Jose Antonio Rodríguez-Navarro, Ana O'Loghlen
Journal
Cell metab
Abstract
Aging is a process of cellular and tissue dysfunction characterized by different hallmarks, includin (show more...)Aging is a process of cellular and tissue dysfunction characterized by different hallmarks, including cellular senescence. However, there is proof that certain features of aging and senescence can be ameliorated. Here, we provide evidence that small extracellular vesicles (sEVs) isolated from primary fibroblasts of young human donors ameliorate certain biomarkers of senescence in cells derived from old and Hutchinson-Gilford progeria syndrome donors. Importantly, sEVs from young cells ameliorate senescence in a variety of tissues in old mice. Mechanistically, we identified sEVs to have intrinsic glutathione-S-transferase activity partially due to the high levels of expression of the glutathione-related protein (GSTM2). Transfection of recombinant GSTM2 into sEVs derived from old fibroblasts restores their antioxidant capacity. sEVs increase the levels of reduced glutathione and decrease oxidative stress and lipid peroxidation both in vivo and in vitro. Altogether, our data provide an indication of the potential of sEVs as regenerative therapy in aging. (hide)
EV-METRIC
56% (88th percentile of all experiments on the same sample type)
 Reported
 Not reported
 Not applicable
EV-enriched proteins
Protein analysis: analysis of three or more EV-enriched proteins
non EV-enriched protein
Protein analysis: assessment of a non-EV-enriched protein
qualitative and quantitative analysis
Particle analysis: implementation of both qualitative and quantitative methods
electron microscopy images
Particle analysis: inclusion of a widefield and close-up electron microscopy image
density gradient
Separation method: density gradient, at least as validation of results attributed to EVs
EV density
Separation method: reporting of obtained EV density
ultracentrifugation specifics
Separation method: reporting of g-forces, duration and rotor type of ultracentrifugation steps
antibody specifics
Protein analysis: antibody clone/reference number and dilution
lysate preparation
Protein analysis: lysis buffer composition
Study data
Sample type
Cell culture supernatant
Sample origin
iRas+GSTM2
Focus vesicles
extracellular vesicle
Separation protocol
Separation protocol
  • Gives a short, non-chronological overview of the
    different steps of the separation protocol.
    • dUC = (Differential) (ultra)centrifugation
    • DG = density gradient
    • UF = ultrafiltration
    • SEC = size-exclusion chromatography
Density gradient + (Differential) (ultra)centrifugation + Commercial method
Protein markers
EV: Alix/ GSTM2
non-EV: None
Proteomics
no
EV density (g/ml)
1.074-1.106
Show all info
Study aim
Function
Sample
Species
Homo sapiens
Sample Type
Cell culture supernatant
Sample Condition
iRas+GSTM2
EV-producing cells
primary human foreskin fibroblasts
EV-harvesting Medium
EV-depleted medium
Preparation of EDS
overnight (16h) at >= 100,000g
Separation Method
(Differential) (ultra)centrifugation
dUC: centrifugation steps
Between 800 g and 10,000 g
Between 10,000 g and 50,000 g
Between 100,000 g and 150,000 g
Pelleting: time(min)
80
Pelleting: rotor type
T-865
Pelleting: speed (g)
100000
Wash: volume per pellet (ml)
15
Wash: time (min)
80
Wash: Rotor Type
T-865
Wash: speed (g)
100000
Density gradient
Density medium
Iodixanol
Type
Discontinuous
Number of initial discontinuous layers
3
Lowest density fraction
10%
Highest density fraction
60%
Total gradient volume, incl. sample (mL)
5.5
Sample volume (mL)
1.5
Orientation
Bottom-up
Rotor type
T-865
Speed (g)
100000
Duration (min)
720
Fraction volume (mL)
0.7
Fraction processing
Centrifugation
Pelleting: volume per fraction
15
Pelleting: duration (min)
80
Pelleting: rotor type
T-865
Pelleting: speed (g)
100000
Pelleting-wash: volume per pellet (mL)
15
Pelleting-wash: duration (min)
80
Pelleting-wash: speed (g)
T-865
Commercial kit
qEV
EV-subtype
Distinction between multiple subtypes
Size
Used subtypes
<200 nm
Characterization: Protein analysis
Western Blot
Detected EV-associated proteins
Alix/ GSTM2
Characterization: Particle analysis
NA
NTA
Report type
Mean
Reported size (nm)
<200
EV concentration
Yes
Particle yield
Number of particles of starting sample E08-E09
EV200036 13/16 Homo sapiens Cell culture supernatant Density gradient
(Differential) (ultra)centrifugation
Commercial method
Juan Antonio Fafián-Labora 2020 56%

Study summary

Full title
All authors
Juan Antonio Fafián-Labora, Jose Antonio Rodríguez-Navarro, Ana O'Loghlen
Journal
Cell metab
Abstract
Aging is a process of cellular and tissue dysfunction characterized by different hallmarks, includin (show more...)Aging is a process of cellular and tissue dysfunction characterized by different hallmarks, including cellular senescence. However, there is proof that certain features of aging and senescence can be ameliorated. Here, we provide evidence that small extracellular vesicles (sEVs) isolated from primary fibroblasts of young human donors ameliorate certain biomarkers of senescence in cells derived from old and Hutchinson-Gilford progeria syndrome donors. Importantly, sEVs from young cells ameliorate senescence in a variety of tissues in old mice. Mechanistically, we identified sEVs to have intrinsic glutathione-S-transferase activity partially due to the high levels of expression of the glutathione-related protein (GSTM2). Transfection of recombinant GSTM2 into sEVs derived from old fibroblasts restores their antioxidant capacity. sEVs increase the levels of reduced glutathione and decrease oxidative stress and lipid peroxidation both in vivo and in vitro. Altogether, our data provide an indication of the potential of sEVs as regenerative therapy in aging. (hide)
EV-METRIC
56% (88th percentile of all experiments on the same sample type)
 Reported
 Not reported
 Not applicable
EV-enriched proteins
Protein analysis: analysis of three or more EV-enriched proteins
non EV-enriched protein
Protein analysis: assessment of a non-EV-enriched protein
qualitative and quantitative analysis
Particle analysis: implementation of both qualitative and quantitative methods
electron microscopy images
Particle analysis: inclusion of a widefield and close-up electron microscopy image
density gradient
Separation method: density gradient, at least as validation of results attributed to EVs
EV density
Separation method: reporting of obtained EV density
ultracentrifugation specifics
Separation method: reporting of g-forces, duration and rotor type of ultracentrifugation steps
antibody specifics
Protein analysis: antibody clone/reference number and dilution
lysate preparation
Protein analysis: lysis buffer composition
Study data
Sample type
Cell culture supernatant
Sample origin
iC+GSTM2
Focus vesicles
extracellular vesicle
Separation protocol
Separation protocol
  • Gives a short, non-chronological overview of the
    different steps of the separation protocol.
    • dUC = (Differential) (ultra)centrifugation
    • DG = density gradient
    • UF = ultrafiltration
    • SEC = size-exclusion chromatography
Density gradient + (Differential) (ultra)centrifugation + Commercial method
Protein markers
EV: Alix/ GSTM2
non-EV: None
Proteomics
no
EV density (g/ml)
1.074-1.106
Show all info
Study aim
Function
Sample
Species
Homo sapiens
Sample Type
Cell culture supernatant
Sample Condition
iC+GSTM2
EV-producing cells
primary human foreskin fibroblasts
EV-harvesting Medium
EV-depleted medium
Preparation of EDS
overnight (16h) at >= 100,000g
Separation Method
(Differential) (ultra)centrifugation
dUC: centrifugation steps
Between 800 g and 10,000 g
Between 10,000 g and 50,000 g
Between 100,000 g and 150,000 g
Pelleting: time(min)
80
Pelleting: rotor type
T-865
Pelleting: speed (g)
100000
Wash: volume per pellet (ml)
15
Wash: time (min)
80
Wash: Rotor Type
T-865
Wash: speed (g)
100000
Density gradient
Density medium
Iodixanol
Type
Discontinuous
Number of initial discontinuous layers
3
Lowest density fraction
10%
Highest density fraction
60%
Total gradient volume, incl. sample (mL)
5.5
Sample volume (mL)
1.5
Orientation
Bottom-up
Rotor type
T-865
Speed (g)
100000
Duration (min)
720
Fraction volume (mL)
0.7
Fraction processing
Centrifugation
Pelleting: volume per fraction
15
Pelleting: duration (min)
80
Pelleting: rotor type
T-865
Pelleting: speed (g)
100000
Pelleting-wash: volume per pellet (mL)
15
Pelleting-wash: duration (min)
80
Pelleting-wash: speed (g)
T-865
Commercial kit
qEV
EV-subtype
Distinction between multiple subtypes
Size
Used subtypes
<200 nm
Characterization: Protein analysis
Western Blot
Detected EV-associated proteins
Alix/ GSTM2
Characterization: Particle analysis
NA
NTA
Report type
Mean
Reported size (nm)
<200
EV concentration
Yes
Particle yield
Number of particles of starting sample E08-E09
EV200036 15/16 Homo sapiens Cell culture supernatant Density gradient
(Differential) (ultra)centrifugation
Commercial method
Juan Antonio Fafián-Labora 2020 56%

Study summary

Full title
All authors
Juan Antonio Fafián-Labora, Jose Antonio Rodríguez-Navarro, Ana O'Loghlen
Journal
Cell metab
Abstract
Aging is a process of cellular and tissue dysfunction characterized by different hallmarks, includin (show more...)Aging is a process of cellular and tissue dysfunction characterized by different hallmarks, including cellular senescence. However, there is proof that certain features of aging and senescence can be ameliorated. Here, we provide evidence that small extracellular vesicles (sEVs) isolated from primary fibroblasts of young human donors ameliorate certain biomarkers of senescence in cells derived from old and Hutchinson-Gilford progeria syndrome donors. Importantly, sEVs from young cells ameliorate senescence in a variety of tissues in old mice. Mechanistically, we identified sEVs to have intrinsic glutathione-S-transferase activity partially due to the high levels of expression of the glutathione-related protein (GSTM2). Transfection of recombinant GSTM2 into sEVs derived from old fibroblasts restores their antioxidant capacity. sEVs increase the levels of reduced glutathione and decrease oxidative stress and lipid peroxidation both in vivo and in vitro. Altogether, our data provide an indication of the potential of sEVs as regenerative therapy in aging. (hide)
EV-METRIC
56% (88th percentile of all experiments on the same sample type)
 Reported
 Not reported
 Not applicable
EV-enriched proteins
Protein analysis: analysis of three or more EV-enriched proteins
non EV-enriched protein
Protein analysis: assessment of a non-EV-enriched protein
qualitative and quantitative analysis
Particle analysis: implementation of both qualitative and quantitative methods
electron microscopy images
Particle analysis: inclusion of a widefield and close-up electron microscopy image
density gradient
Separation method: density gradient, at least as validation of results attributed to EVs
EV density
Separation method: reporting of obtained EV density
ultracentrifugation specifics
Separation method: reporting of g-forces, duration and rotor type of ultracentrifugation steps
antibody specifics
Protein analysis: antibody clone/reference number and dilution
lysate preparation
Protein analysis: lysis buffer composition
Study data
Sample type
Cell culture supernatant
Sample origin
mCherry-CD63
Focus vesicles
extracellular vesicle
Separation protocol
Separation protocol
  • Gives a short, non-chronological overview of the
    different steps of the separation protocol.
    • dUC = (Differential) (ultra)centrifugation
    • DG = density gradient
    • UF = ultrafiltration
    • SEC = size-exclusion chromatography
Density gradient + (Differential) (ultra)centrifugation + Commercial method
Protein markers
EV: Alix/ GSTM2
non-EV: None
Proteomics
no
EV density (g/ml)
1.074-1.106
Show all info
Study aim
Function
Sample
Species
Homo sapiens
Sample Type
Cell culture supernatant
Sample Condition
mCherry-CD63
EV-producing cells
primary human foreskin fibroblasts
EV-harvesting Medium
EV-depleted medium
Preparation of EDS
overnight (16h) at >= 100,000g
Separation Method
(Differential) (ultra)centrifugation
dUC: centrifugation steps
Between 800 g and 10,000 g
Between 10,000 g and 50,000 g
Between 100,000 g and 150,000 g
Pelleting: time(min)
80
Pelleting: rotor type
T-865
Pelleting: speed (g)
100000
Wash: volume per pellet (ml)
15
Wash: time (min)
80
Wash: Rotor Type
T-865
Wash: speed (g)
100000
Density gradient
Density medium
Iodixanol
Type
Discontinuous
Number of initial discontinuous layers
3
Lowest density fraction
10%
Highest density fraction
60%
Total gradient volume, incl. sample (mL)
5.5
Sample volume (mL)
1.5
Orientation
Bottom-up
Rotor type
T-865
Speed (g)
100000
Duration (min)
720
Fraction volume (mL)
0.7
Fraction processing
Centrifugation
Pelleting: volume per fraction
15
Pelleting: duration (min)
80
Pelleting: rotor type
T-865
Pelleting: speed (g)
100000
Pelleting-wash: volume per pellet (mL)
15
Pelleting-wash: duration (min)
80
Pelleting-wash: speed (g)
T-865
Commercial kit
qEV
EV-subtype
Distinction between multiple subtypes
Size
Used subtypes
<200 nm
Characterization: Protein analysis
Western Blot
Detected EV-associated proteins
Alix/ GSTM2
Characterization: Particle analysis
NA
NTA
Report type
Mean
Reported size (nm)
<200
EV concentration
Yes
Particle yield
Number of particles of starting sample E08-E09
EV200036 2/16 Homo sapiens Cell culture supernatant Density gradient
(Differential) (ultra)centrifugation
Commercial method
Juan Antonio Fafián-Labora 2020 43%

Study summary

Full title
All authors
Juan Antonio Fafián-Labora, Jose Antonio Rodríguez-Navarro, Ana O'Loghlen
Journal
Cell metab
Abstract
Aging is a process of cellular and tissue dysfunction characterized by different hallmarks, includin (show more...)Aging is a process of cellular and tissue dysfunction characterized by different hallmarks, including cellular senescence. However, there is proof that certain features of aging and senescence can be ameliorated. Here, we provide evidence that small extracellular vesicles (sEVs) isolated from primary fibroblasts of young human donors ameliorate certain biomarkers of senescence in cells derived from old and Hutchinson-Gilford progeria syndrome donors. Importantly, sEVs from young cells ameliorate senescence in a variety of tissues in old mice. Mechanistically, we identified sEVs to have intrinsic glutathione-S-transferase activity partially due to the high levels of expression of the glutathione-related protein (GSTM2). Transfection of recombinant GSTM2 into sEVs derived from old fibroblasts restores their antioxidant capacity. sEVs increase the levels of reduced glutathione and decrease oxidative stress and lipid peroxidation both in vivo and in vitro. Altogether, our data provide an indication of the potential of sEVs as regenerative therapy in aging. (hide)
EV-METRIC
43% (73rd percentile of all experiments on the same sample type)
 Reported
 Not reported
 Not applicable
EV-enriched proteins
Protein analysis: analysis of three or more EV-enriched proteins
non EV-enriched protein
Protein analysis: assessment of a non-EV-enriched protein
qualitative and quantitative analysis
Particle analysis: implementation of both qualitative and quantitative methods
electron microscopy images
Particle analysis: inclusion of a widefield and close-up electron microscopy image
density gradient
Separation method: density gradient, at least as validation of results attributed to EVs
EV density
Separation method: reporting of obtained EV density
ultracentrifugation specifics
Separation method: reporting of g-forces, duration and rotor type of ultracentrifugation steps
antibody specifics
Protein analysis: antibody clone/reference number and dilution
lysate preparation
Protein analysis: lysis buffer composition
Study data
Sample type
Cell culture supernatant
Sample origin
Young donors
Focus vesicles
extracellular vesicle
Separation protocol
Separation protocol
  • Gives a short, non-chronological overview of the
    different steps of the separation protocol.
    • dUC = (Differential) (ultra)centrifugation
    • DG = density gradient
    • UF = ultrafiltration
    • SEC = size-exclusion chromatography
Density gradient + (Differential) (ultra)centrifugation + Commercial method
Protein markers
EV: None
non-EV: None
Proteomics
no
EV density (g/ml)
1.074-1.106
Show all info
Study aim
Function
Sample
Species
Homo sapiens
Sample Type
Cell culture supernatant
Sample Condition
Young donors
EV-producing cells
human skin primary fibroblasts
EV-harvesting Medium
EV-depleted medium
Preparation of EDS
overnight (16h) at >= 100,000g
Separation Method
(Differential) (ultra)centrifugation
dUC: centrifugation steps
Between 800 g and 10,000 g
Between 10,000 g and 50,000 g
Between 100,000 g and 150,000 g
Pelleting: time(min)
80
Pelleting: rotor type
T-865
Pelleting: speed (g)
100000
Wash: volume per pellet (ml)
15
Wash: time (min)
80
Wash: Rotor Type
T-865
Wash: speed (g)
100000
Density gradient
Density medium
Iodixanol
Type
Discontinuous
Number of initial discontinuous layers
3
Lowest density fraction
10%
Highest density fraction
60%
Total gradient volume, incl. sample (mL)
5.5
Sample volume (mL)
1.5
Orientation
Bottom-up
Rotor type
T-865
Speed (g)
100000
Duration (min)
720
Fraction volume (mL)
0.7
Fraction processing
Centrifugation
Pelleting: volume per fraction
15
Pelleting: duration (min)
80
Pelleting: rotor type
T-865
Pelleting: speed (g)
100000
Pelleting-wash: volume per pellet (mL)
15
Pelleting-wash: duration (min)
80
Pelleting-wash: speed (g)
T-865
Commercial kit
qEV
EV-subtype
Distinction between multiple subtypes
Size
Used subtypes
>200 nm
Characterization: Particle analysis
NA
NTA
Report type
Mean
Reported size (nm)
>200
EV concentration
Yes
Particle yield
Number of particles of starting sample E08-E09
EV200036 4/16 Homo sapiens Cell culture supernatant Density gradient
(Differential) (ultra)centrifugation
Commercial method
Juan Antonio Fafián-Labora 2020 43%

Study summary

Full title
All authors
Juan Antonio Fafián-Labora, Jose Antonio Rodríguez-Navarro, Ana O'Loghlen
Journal
Cell metab
Abstract
Aging is a process of cellular and tissue dysfunction characterized by different hallmarks, includin (show more...)Aging is a process of cellular and tissue dysfunction characterized by different hallmarks, including cellular senescence. However, there is proof that certain features of aging and senescence can be ameliorated. Here, we provide evidence that small extracellular vesicles (sEVs) isolated from primary fibroblasts of young human donors ameliorate certain biomarkers of senescence in cells derived from old and Hutchinson-Gilford progeria syndrome donors. Importantly, sEVs from young cells ameliorate senescence in a variety of tissues in old mice. Mechanistically, we identified sEVs to have intrinsic glutathione-S-transferase activity partially due to the high levels of expression of the glutathione-related protein (GSTM2). Transfection of recombinant GSTM2 into sEVs derived from old fibroblasts restores their antioxidant capacity. sEVs increase the levels of reduced glutathione and decrease oxidative stress and lipid peroxidation both in vivo and in vitro. Altogether, our data provide an indication of the potential of sEVs as regenerative therapy in aging. (hide)
EV-METRIC
43% (73rd percentile of all experiments on the same sample type)
 Reported
 Not reported
 Not applicable
EV-enriched proteins
Protein analysis: analysis of three or more EV-enriched proteins
non EV-enriched protein
Protein analysis: assessment of a non-EV-enriched protein
qualitative and quantitative analysis
Particle analysis: implementation of both qualitative and quantitative methods
electron microscopy images
Particle analysis: inclusion of a widefield and close-up electron microscopy image
density gradient
Separation method: density gradient, at least as validation of results attributed to EVs
EV density
Separation method: reporting of obtained EV density
ultracentrifugation specifics
Separation method: reporting of g-forces, duration and rotor type of ultracentrifugation steps
antibody specifics
Protein analysis: antibody clone/reference number and dilution
lysate preparation
Protein analysis: lysis buffer composition
Study data
Sample type
Cell culture supernatant
Sample origin
Old donors
Focus vesicles
extracellular vesicle
Separation protocol
Separation protocol
  • Gives a short, non-chronological overview of the
    different steps of the separation protocol.
    • dUC = (Differential) (ultra)centrifugation
    • DG = density gradient
    • UF = ultrafiltration
    • SEC = size-exclusion chromatography
Density gradient + (Differential) (ultra)centrifugation + Commercial method
Protein markers
EV: None
non-EV: None
Proteomics
no
EV density (g/ml)
1.074-1.106
Show all info
Study aim
Function
Sample
Species
Homo sapiens
Sample Type
Cell culture supernatant
Sample Condition
Old donors
EV-producing cells
human skin primary fibroblasts
EV-harvesting Medium
EV-depleted medium
Preparation of EDS
overnight (16h) at >= 100,000g
Separation Method
(Differential) (ultra)centrifugation
dUC: centrifugation steps
Between 800 g and 10,000 g
Between 10,000 g and 50,000 g
Between 100,000 g and 150,000 g
Pelleting: time(min)
80
Pelleting: rotor type
T-865
Pelleting: speed (g)
100000
Wash: volume per pellet (ml)
15
Wash: time (min)
80
Wash: Rotor Type
T-865
Wash: speed (g)
100000
Density gradient
Density medium
Iodixanol
Type
Discontinuous
Number of initial discontinuous layers
3
Lowest density fraction
10%
Highest density fraction
60%
Total gradient volume, incl. sample (mL)
5.5
Sample volume (mL)
1.5
Orientation
Bottom-up
Rotor type
T-865
Speed (g)
100000
Duration (min)
720
Fraction volume (mL)
0.7
Fraction processing
Centrifugation
Pelleting: volume per fraction
15
Pelleting: duration (min)
80
Pelleting: rotor type
T-865
Pelleting: speed (g)
100000
Pelleting-wash: volume per pellet (mL)
15
Pelleting-wash: duration (min)
80
Pelleting-wash: speed (g)
T-865
Commercial kit
qEV
EV-subtype
Distinction between multiple subtypes
Size
Used subtypes
>200 nm
Characterization: Particle analysis
NA
NTA
Report type
Mean
Reported size (nm)
>200
EV concentration
Yes
Particle yield
Number of particles of starting sample E08-E09
EV200036 6/16 Homo sapiens Cell culture supernatant Density gradient
(Differential) (ultra)centrifugation
Commercial method
Juan Antonio Fafián-Labora 2020 43%

Study summary

Full title
All authors
Juan Antonio Fafián-Labora, Jose Antonio Rodríguez-Navarro, Ana O'Loghlen
Journal
Cell metab
Abstract
Aging is a process of cellular and tissue dysfunction characterized by different hallmarks, includin (show more...)Aging is a process of cellular and tissue dysfunction characterized by different hallmarks, including cellular senescence. However, there is proof that certain features of aging and senescence can be ameliorated. Here, we provide evidence that small extracellular vesicles (sEVs) isolated from primary fibroblasts of young human donors ameliorate certain biomarkers of senescence in cells derived from old and Hutchinson-Gilford progeria syndrome donors. Importantly, sEVs from young cells ameliorate senescence in a variety of tissues in old mice. Mechanistically, we identified sEVs to have intrinsic glutathione-S-transferase activity partially due to the high levels of expression of the glutathione-related protein (GSTM2). Transfection of recombinant GSTM2 into sEVs derived from old fibroblasts restores their antioxidant capacity. sEVs increase the levels of reduced glutathione and decrease oxidative stress and lipid peroxidation both in vivo and in vitro. Altogether, our data provide an indication of the potential of sEVs as regenerative therapy in aging. (hide)
EV-METRIC
43% (73rd percentile of all experiments on the same sample type)
 Reported
 Not reported
 Not applicable
EV-enriched proteins
Protein analysis: analysis of three or more EV-enriched proteins
non EV-enriched protein
Protein analysis: assessment of a non-EV-enriched protein
qualitative and quantitative analysis
Particle analysis: implementation of both qualitative and quantitative methods
electron microscopy images
Particle analysis: inclusion of a widefield and close-up electron microscopy image
density gradient
Separation method: density gradient, at least as validation of results attributed to EVs
EV density
Separation method: reporting of obtained EV density
ultracentrifugation specifics
Separation method: reporting of g-forces, duration and rotor type of ultracentrifugation steps
antibody specifics
Protein analysis: antibody clone/reference number and dilution
lysate preparation
Protein analysis: lysis buffer composition
Study data
Sample type
Cell culture supernatant
Sample origin
Progeria patients
Focus vesicles
extracellular vesicle
Separation protocol
Separation protocol
  • Gives a short, non-chronological overview of the
    different steps of the separation protocol.
    • dUC = (Differential) (ultra)centrifugation
    • DG = density gradient
    • UF = ultrafiltration
    • SEC = size-exclusion chromatography
Density gradient + (Differential) (ultra)centrifugation + Commercial method
Protein markers
EV: None
non-EV: None
Proteomics
no
EV density (g/ml)
1.074-1.106
Show all info
Study aim
Function
Sample
Species
Homo sapiens
Sample Type
Cell culture supernatant
Sample Condition
Progeria patients
EV-producing cells
human skin primary fibroblasts
EV-harvesting Medium
EV-depleted medium
Preparation of EDS
overnight (16h) at >= 100,000g
Separation Method
(Differential) (ultra)centrifugation
dUC: centrifugation steps
Between 800 g and 10,000 g
Between 10,000 g and 50,000 g
Between 100,000 g and 150,000 g
Pelleting: time(min)
80
Pelleting: rotor type
T-865
Pelleting: speed (g)
100000
Wash: volume per pellet (ml)
15
Wash: time (min)
80
Wash: Rotor Type
T-865
Wash: speed (g)
100000
Density gradient
Density medium
Iodixanol
Type
Discontinuous
Number of initial discontinuous layers
3
Lowest density fraction
10%
Highest density fraction
60%
Total gradient volume, incl. sample (mL)
5.5
Sample volume (mL)
1.5
Orientation
Bottom-up
Rotor type
T-865
Speed (g)
100000
Duration (min)
720
Fraction volume (mL)
0.7
Fraction processing
Centrifugation
Pelleting: volume per fraction
15
Pelleting: duration (min)
80
Pelleting: rotor type
T-865
Pelleting: speed (g)
100000
Pelleting-wash: volume per pellet (mL)
15
Pelleting-wash: duration (min)
80
Pelleting-wash: speed (g)
T-865
Commercial kit
qEV
EV-subtype
Distinction between multiple subtypes
Size
Used subtypes
>200 nm
Characterization: Particle analysis
NA
EV200036 8/16 Homo sapiens Cell culture supernatant Density gradient
(Differential) (ultra)centrifugation
Commercial method
Juan Antonio Fafián-Labora 2020 43%

Study summary

Full title
All authors
Juan Antonio Fafián-Labora, Jose Antonio Rodríguez-Navarro, Ana O'Loghlen
Journal
Cell metab
Abstract
Aging is a process of cellular and tissue dysfunction characterized by different hallmarks, includin (show more...)Aging is a process of cellular and tissue dysfunction characterized by different hallmarks, including cellular senescence. However, there is proof that certain features of aging and senescence can be ameliorated. Here, we provide evidence that small extracellular vesicles (sEVs) isolated from primary fibroblasts of young human donors ameliorate certain biomarkers of senescence in cells derived from old and Hutchinson-Gilford progeria syndrome donors. Importantly, sEVs from young cells ameliorate senescence in a variety of tissues in old mice. Mechanistically, we identified sEVs to have intrinsic glutathione-S-transferase activity partially due to the high levels of expression of the glutathione-related protein (GSTM2). Transfection of recombinant GSTM2 into sEVs derived from old fibroblasts restores their antioxidant capacity. sEVs increase the levels of reduced glutathione and decrease oxidative stress and lipid peroxidation both in vivo and in vitro. Altogether, our data provide an indication of the potential of sEVs as regenerative therapy in aging. (hide)
EV-METRIC
43% (73rd percentile of all experiments on the same sample type)
 Reported
 Not reported
 Not applicable
EV-enriched proteins
Protein analysis: analysis of three or more EV-enriched proteins
non EV-enriched protein
Protein analysis: assessment of a non-EV-enriched protein
qualitative and quantitative analysis
Particle analysis: implementation of both qualitative and quantitative methods
electron microscopy images
Particle analysis: inclusion of a widefield and close-up electron microscopy image
density gradient
Separation method: density gradient, at least as validation of results attributed to EVs
EV density
Separation method: reporting of obtained EV density
ultracentrifugation specifics
Separation method: reporting of g-forces, duration and rotor type of ultracentrifugation steps
antibody specifics
Protein analysis: antibody clone/reference number and dilution
lysate preparation
Protein analysis: lysis buffer composition
Study data
Sample type
Cell culture supernatant
Sample origin
Control condition
Focus vesicles
extracellular vesicle
Separation protocol
Separation protocol
  • Gives a short, non-chronological overview of the
    different steps of the separation protocol.
    • dUC = (Differential) (ultra)centrifugation
    • DG = density gradient
    • UF = ultrafiltration
    • SEC = size-exclusion chromatography
Density gradient + (Differential) (ultra)centrifugation + Commercial method
Protein markers
EV: None
non-EV: None
Proteomics
no
EV density (g/ml)
1.074-1.106
Show all info
Study aim
Function
Sample
Species
Homo sapiens
Sample Type
Cell culture supernatant
Sample Condition
Control condition
EV-producing cells
primary human foreskin fibroblasts
EV-harvesting Medium
EV-depleted medium
Preparation of EDS
overnight (16h) at >= 100,000g
Separation Method
(Differential) (ultra)centrifugation
dUC: centrifugation steps
Between 800 g and 10,000 g
Between 10,000 g and 50,000 g
Between 100,000 g and 150,000 g
Pelleting: time(min)
80
Pelleting: rotor type
T-865
Pelleting: speed (g)
100000
Wash: volume per pellet (ml)
15
Wash: time (min)
80
Wash: Rotor Type
T-865
Wash: speed (g)
100000
Density gradient
Density medium
Iodixanol
Type
Discontinuous
Number of initial discontinuous layers
3
Lowest density fraction
10%
Highest density fraction
60%
Total gradient volume, incl. sample (mL)
5.5
Sample volume (mL)
1.5
Orientation
Bottom-up
Rotor type
T-865
Speed (g)
100000
Duration (min)
720
Fraction volume (mL)
0.7
Fraction processing
Centrifugation
Pelleting: volume per fraction
15
Pelleting: duration (min)
80
Pelleting: rotor type
T-865
Pelleting: speed (g)
100000
Pelleting-wash: volume per pellet (mL)
15
Pelleting-wash: duration (min)
80
Pelleting-wash: speed (g)
T-865
Commercial kit
qEV
EV-subtype
Distinction between multiple subtypes
Size
Used subtypes
>200 nm
Characterization: Particle analysis
NA
NTA
Report type
Mean
Reported size (nm)
>200
EV concentration
Yes
Particle yield
Number of particles of starting sample E08-E09
EV200036 10/16 Homo sapiens Cell culture supernatant Density gradient
(Differential) (ultra)centrifugation
Commercial method
Juan Antonio Fafián-Labora 2020 43%

Study summary

Full title
All authors
Juan Antonio Fafián-Labora, Jose Antonio Rodríguez-Navarro, Ana O'Loghlen
Journal
Cell metab
Abstract
Aging is a process of cellular and tissue dysfunction characterized by different hallmarks, includin (show more...)Aging is a process of cellular and tissue dysfunction characterized by different hallmarks, including cellular senescence. However, there is proof that certain features of aging and senescence can be ameliorated. Here, we provide evidence that small extracellular vesicles (sEVs) isolated from primary fibroblasts of young human donors ameliorate certain biomarkers of senescence in cells derived from old and Hutchinson-Gilford progeria syndrome donors. Importantly, sEVs from young cells ameliorate senescence in a variety of tissues in old mice. Mechanistically, we identified sEVs to have intrinsic glutathione-S-transferase activity partially due to the high levels of expression of the glutathione-related protein (GSTM2). Transfection of recombinant GSTM2 into sEVs derived from old fibroblasts restores their antioxidant capacity. sEVs increase the levels of reduced glutathione and decrease oxidative stress and lipid peroxidation both in vivo and in vitro. Altogether, our data provide an indication of the potential of sEVs as regenerative therapy in aging. (hide)
EV-METRIC
43% (73rd percentile of all experiments on the same sample type)
 Reported
 Not reported
 Not applicable
EV-enriched proteins
Protein analysis: analysis of three or more EV-enriched proteins
non EV-enriched protein
Protein analysis: assessment of a non-EV-enriched protein
qualitative and quantitative analysis
Particle analysis: implementation of both qualitative and quantitative methods
electron microscopy images
Particle analysis: inclusion of a widefield and close-up electron microscopy image
density gradient
Separation method: density gradient, at least as validation of results attributed to EVs
EV density
Separation method: reporting of obtained EV density
ultracentrifugation specifics
Separation method: reporting of g-forces, duration and rotor type of ultracentrifugation steps
antibody specifics
Protein analysis: antibody clone/reference number and dilution
lysate preparation
Protein analysis: lysis buffer composition
Study data
Sample type
Cell culture supernatant
Sample origin
iRas
Focus vesicles
extracellular vesicle
Separation protocol
Separation protocol
  • Gives a short, non-chronological overview of the
    different steps of the separation protocol.
    • dUC = (Differential) (ultra)centrifugation
    • DG = density gradient
    • UF = ultrafiltration
    • SEC = size-exclusion chromatography
Density gradient + (Differential) (ultra)centrifugation + Commercial method
Protein markers
EV: None
non-EV: None
Proteomics
no
EV density (g/ml)
1.074-1.106
Show all info
Study aim
Function
Sample
Species
Homo sapiens
Sample Type
Cell culture supernatant
Sample Condition
iRas
EV-producing cells
primary human foreskin fibroblasts
EV-harvesting Medium
EV-depleted medium
Preparation of EDS
overnight (16h) at >= 100,000g
Separation Method
(Differential) (ultra)centrifugation
dUC: centrifugation steps
Between 800 g and 10,000 g
Between 10,000 g and 50,000 g
Between 100,000 g and 150,000 g
Pelleting: time(min)
80
Pelleting: rotor type
T-865
Pelleting: speed (g)
100000
Wash: volume per pellet (ml)
15
Wash: time (min)
80
Wash: Rotor Type
T-865
Wash: speed (g)
100000
Density gradient
Density medium
Iodixanol
Type
Discontinuous
Number of initial discontinuous layers
3
Lowest density fraction
10%
Highest density fraction
60%
Total gradient volume, incl. sample (mL)
5.5
Sample volume (mL)
1.5
Orientation
Bottom-up
Rotor type
T-865
Speed (g)
100000
Duration (min)
720
Fraction volume (mL)
0.7
Fraction processing
Centrifugation
Pelleting: volume per fraction
15
Pelleting: duration (min)
80
Pelleting: rotor type
T-865
Pelleting: speed (g)
100000
Pelleting-wash: volume per pellet (mL)
15
Pelleting-wash: duration (min)
80
Pelleting-wash: speed (g)
T-865
Commercial kit
qEV
EV-subtype
Distinction between multiple subtypes
Size
Used subtypes
>200 nm
Characterization: Particle analysis
NA
NTA
Report type
Mean
Reported size (nm)
>200
EV concentration
Yes
Particle yield
Number of particles of starting sample E08-E09
EV200036 12/16 Homo sapiens Cell culture supernatant Density gradient
(Differential) (ultra)centrifugation
Commercial method
Juan Antonio Fafián-Labora 2020 43%

Study summary

Full title
All authors
Juan Antonio Fafián-Labora, Jose Antonio Rodríguez-Navarro, Ana O'Loghlen
Journal
Cell metab
Abstract
Aging is a process of cellular and tissue dysfunction characterized by different hallmarks, includin (show more...)Aging is a process of cellular and tissue dysfunction characterized by different hallmarks, including cellular senescence. However, there is proof that certain features of aging and senescence can be ameliorated. Here, we provide evidence that small extracellular vesicles (sEVs) isolated from primary fibroblasts of young human donors ameliorate certain biomarkers of senescence in cells derived from old and Hutchinson-Gilford progeria syndrome donors. Importantly, sEVs from young cells ameliorate senescence in a variety of tissues in old mice. Mechanistically, we identified sEVs to have intrinsic glutathione-S-transferase activity partially due to the high levels of expression of the glutathione-related protein (GSTM2). Transfection of recombinant GSTM2 into sEVs derived from old fibroblasts restores their antioxidant capacity. sEVs increase the levels of reduced glutathione and decrease oxidative stress and lipid peroxidation both in vivo and in vitro. Altogether, our data provide an indication of the potential of sEVs as regenerative therapy in aging. (hide)
EV-METRIC
43% (73rd percentile of all experiments on the same sample type)
 Reported
 Not reported
 Not applicable
EV-enriched proteins
Protein analysis: analysis of three or more EV-enriched proteins
non EV-enriched protein
Protein analysis: assessment of a non-EV-enriched protein
qualitative and quantitative analysis
Particle analysis: implementation of both qualitative and quantitative methods
electron microscopy images
Particle analysis: inclusion of a widefield and close-up electron microscopy image
density gradient
Separation method: density gradient, at least as validation of results attributed to EVs
EV density
Separation method: reporting of obtained EV density
ultracentrifugation specifics
Separation method: reporting of g-forces, duration and rotor type of ultracentrifugation steps
antibody specifics
Protein analysis: antibody clone/reference number and dilution
lysate preparation
Protein analysis: lysis buffer composition
Study data
Sample type
Cell culture supernatant
Sample origin
iRas+GSTM2
Focus vesicles
extracellular vesicle
Separation protocol
Separation protocol
  • Gives a short, non-chronological overview of the
    different steps of the separation protocol.
    • dUC = (Differential) (ultra)centrifugation
    • DG = density gradient
    • UF = ultrafiltration
    • SEC = size-exclusion chromatography
Density gradient + (Differential) (ultra)centrifugation + Commercial method
Protein markers
EV: None
non-EV: None
Proteomics
no
EV density (g/ml)
1.074-1.106
Show all info
Study aim
Function
Sample
Species
Homo sapiens
Sample Type
Cell culture supernatant
Sample Condition
iRas+GSTM2
EV-producing cells
primary human foreskin fibroblasts
EV-harvesting Medium
EV-depleted medium
Preparation of EDS
overnight (16h) at >= 100,000g
Separation Method
(Differential) (ultra)centrifugation
dUC: centrifugation steps
Between 800 g and 10,000 g
Between 10,000 g and 50,000 g
Between 100,000 g and 150,000 g
Pelleting: time(min)
80
Pelleting: rotor type
T-865
Pelleting: speed (g)
100000
Wash: volume per pellet (ml)
15
Wash: time (min)
80
Wash: Rotor Type
T-865
Wash: speed (g)
100000
Density gradient
Density medium
Iodixanol
Type
Discontinuous
Number of initial discontinuous layers
3
Lowest density fraction
10%
Highest density fraction
60%
Total gradient volume, incl. sample (mL)
5.5
Sample volume (mL)
1.5
Orientation
Bottom-up
Rotor type
T-865
Speed (g)
100000
Duration (min)
720
Fraction volume (mL)
0.7
Fraction processing
Centrifugation
Pelleting: volume per fraction
15
Pelleting: duration (min)
80
Pelleting: rotor type
T-865
Pelleting: speed (g)
100000
Pelleting-wash: volume per pellet (mL)
15
Pelleting-wash: duration (min)
80
Pelleting-wash: speed (g)
T-865
Commercial kit
qEV
EV-subtype
Distinction between multiple subtypes
Size
Used subtypes
>200 nm
Characterization: Particle analysis
NA
NTA
Report type
Mean
Reported size (nm)
>200
EV concentration
Yes
Particle yield
Number of particles of starting sample E08-E09
EV200036 14/16 Homo sapiens Cell culture supernatant Density gradient
(Differential) (ultra)centrifugation
Commercial method
Juan Antonio Fafián-Labora 2020 43%

Study summary

Full title
All authors
Juan Antonio Fafián-Labora, Jose Antonio Rodríguez-Navarro, Ana O'Loghlen
Journal
Cell metab
Abstract
Aging is a process of cellular and tissue dysfunction characterized by different hallmarks, includin (show more...)Aging is a process of cellular and tissue dysfunction characterized by different hallmarks, including cellular senescence. However, there is proof that certain features of aging and senescence can be ameliorated. Here, we provide evidence that small extracellular vesicles (sEVs) isolated from primary fibroblasts of young human donors ameliorate certain biomarkers of senescence in cells derived from old and Hutchinson-Gilford progeria syndrome donors. Importantly, sEVs from young cells ameliorate senescence in a variety of tissues in old mice. Mechanistically, we identified sEVs to have intrinsic glutathione-S-transferase activity partially due to the high levels of expression of the glutathione-related protein (GSTM2). Transfection of recombinant GSTM2 into sEVs derived from old fibroblasts restores their antioxidant capacity. sEVs increase the levels of reduced glutathione and decrease oxidative stress and lipid peroxidation both in vivo and in vitro. Altogether, our data provide an indication of the potential of sEVs as regenerative therapy in aging. (hide)
EV-METRIC
43% (73rd percentile of all experiments on the same sample type)
 Reported
 Not reported
 Not applicable
EV-enriched proteins
Protein analysis: analysis of three or more EV-enriched proteins
non EV-enriched protein
Protein analysis: assessment of a non-EV-enriched protein
qualitative and quantitative analysis
Particle analysis: implementation of both qualitative and quantitative methods
electron microscopy images
Particle analysis: inclusion of a widefield and close-up electron microscopy image
density gradient
Separation method: density gradient, at least as validation of results attributed to EVs
EV density
Separation method: reporting of obtained EV density
ultracentrifugation specifics
Separation method: reporting of g-forces, duration and rotor type of ultracentrifugation steps
antibody specifics
Protein analysis: antibody clone/reference number and dilution
lysate preparation
Protein analysis: lysis buffer composition
Study data
Sample type
Cell culture supernatant
Sample origin
iC+GSTM2
Focus vesicles
extracellular vesicle
Separation protocol
Separation protocol
  • Gives a short, non-chronological overview of the
    different steps of the separation protocol.
    • dUC = (Differential) (ultra)centrifugation
    • DG = density gradient
    • UF = ultrafiltration
    • SEC = size-exclusion chromatography
Density gradient + (Differential) (ultra)centrifugation + Commercial method
Protein markers
EV: None
non-EV: None
Proteomics
no
EV density (g/ml)
1.074-1.106
Show all info
Study aim
Function
Sample
Species
Homo sapiens
Sample Type
Cell culture supernatant
Sample Condition
iC+GSTM2
EV-producing cells
primary human foreskin fibroblasts
EV-harvesting Medium
EV-depleted medium
Preparation of EDS
overnight (16h) at >= 100,000g
Separation Method
(Differential) (ultra)centrifugation
dUC: centrifugation steps
Between 800 g and 10,000 g
Between 10,000 g and 50,000 g
Between 100,000 g and 150,000 g
Pelleting: time(min)
80
Pelleting: rotor type
T-865
Pelleting: speed (g)
100000
Wash: volume per pellet (ml)
15
Wash: time (min)
80
Wash: Rotor Type
T-865
Wash: speed (g)
100000
Density gradient
Density medium
Iodixanol
Type
Discontinuous
Number of initial discontinuous layers
3
Lowest density fraction
10%
Highest density fraction
60%
Total gradient volume, incl. sample (mL)
5.5
Sample volume (mL)
1.5
Orientation
Bottom-up
Rotor type
T-865
Speed (g)
100000
Duration (min)
720
Fraction volume (mL)
0.7
Fraction processing
Centrifugation
Pelleting: volume per fraction
15
Pelleting: duration (min)
80
Pelleting: rotor type
T-865
Pelleting: speed (g)
100000
Pelleting-wash: volume per pellet (mL)
15
Pelleting-wash: duration (min)
80
Pelleting-wash: speed (g)
T-865
Commercial kit
qEV
EV-subtype
Distinction between multiple subtypes
Size
Used subtypes
>200 nm
Characterization: Particle analysis
NA
NTA
Report type
Mean
Reported size (nm)
>200
EV concentration
Yes
Particle yield
Number of particles of starting sample E08-E09
EV200036 16/16 Homo sapiens Cell culture supernatant Density gradient
(Differential) (ultra)centrifugation
Commercial method
Juan Antonio Fafián-Labora 2020 43%

Study summary

Full title
All authors
Juan Antonio Fafián-Labora, Jose Antonio Rodríguez-Navarro, Ana O'Loghlen
Journal
Cell metab
Abstract
Aging is a process of cellular and tissue dysfunction characterized by different hallmarks, includin (show more...)Aging is a process of cellular and tissue dysfunction characterized by different hallmarks, including cellular senescence. However, there is proof that certain features of aging and senescence can be ameliorated. Here, we provide evidence that small extracellular vesicles (sEVs) isolated from primary fibroblasts of young human donors ameliorate certain biomarkers of senescence in cells derived from old and Hutchinson-Gilford progeria syndrome donors. Importantly, sEVs from young cells ameliorate senescence in a variety of tissues in old mice. Mechanistically, we identified sEVs to have intrinsic glutathione-S-transferase activity partially due to the high levels of expression of the glutathione-related protein (GSTM2). Transfection of recombinant GSTM2 into sEVs derived from old fibroblasts restores their antioxidant capacity. sEVs increase the levels of reduced glutathione and decrease oxidative stress and lipid peroxidation both in vivo and in vitro. Altogether, our data provide an indication of the potential of sEVs as regenerative therapy in aging. (hide)
EV-METRIC
43% (73rd percentile of all experiments on the same sample type)
 Reported
 Not reported
 Not applicable
EV-enriched proteins
Protein analysis: analysis of three or more EV-enriched proteins
non EV-enriched protein
Protein analysis: assessment of a non-EV-enriched protein
qualitative and quantitative analysis
Particle analysis: implementation of both qualitative and quantitative methods
electron microscopy images
Particle analysis: inclusion of a widefield and close-up electron microscopy image
density gradient
Separation method: density gradient, at least as validation of results attributed to EVs
EV density
Separation method: reporting of obtained EV density
ultracentrifugation specifics
Separation method: reporting of g-forces, duration and rotor type of ultracentrifugation steps
antibody specifics
Protein analysis: antibody clone/reference number and dilution
lysate preparation
Protein analysis: lysis buffer composition
Study data
Sample type
Cell culture supernatant
Sample origin
mCherry-CD63
Focus vesicles
extracellular vesicle
Separation protocol
Separation protocol
  • Gives a short, non-chronological overview of the
    different steps of the separation protocol.
    • dUC = (Differential) (ultra)centrifugation
    • DG = density gradient
    • UF = ultrafiltration
    • SEC = size-exclusion chromatography
Density gradient + (Differential) (ultra)centrifugation + Commercial method
Protein markers
EV: None
non-EV: None
Proteomics
no
EV density (g/ml)
1.074-1.106
Show all info
Study aim
Function
Sample
Species
Homo sapiens
Sample Type
Cell culture supernatant
Sample Condition
mCherry-CD63
EV-producing cells
primary human foreskin fibroblasts
EV-harvesting Medium
EV-depleted medium
Preparation of EDS
overnight (16h) at >= 100,000g
Separation Method
(Differential) (ultra)centrifugation
dUC: centrifugation steps
Between 800 g and 10,000 g
Between 10,000 g and 50,000 g
Between 100,000 g and 150,000 g
Pelleting: time(min)
80
Pelleting: rotor type
T-865
Pelleting: speed (g)
100000
Wash: volume per pellet (ml)
15
Wash: time (min)
80
Wash: Rotor Type
T-865
Wash: speed (g)
100000
Density gradient
Density medium
Iodixanol
Type
Discontinuous
Number of initial discontinuous layers
3
Lowest density fraction
10%
Highest density fraction
60%
Total gradient volume, incl. sample (mL)
5.5
Sample volume (mL)
1.5
Orientation
Bottom-up
Rotor type
T-865
Speed (g)
100000
Duration (min)
720
Fraction volume (mL)
0.7
Fraction processing
Centrifugation
Pelleting: volume per fraction
15
Pelleting: duration (min)
80
Pelleting: rotor type
T-865
Pelleting: speed (g)
100000
Pelleting-wash: volume per pellet (mL)
15
Pelleting-wash: duration (min)
80
Pelleting-wash: speed (g)
T-865
Commercial kit
qEV
EV-subtype
Distinction between multiple subtypes
Size
Used subtypes
>200 nm
Characterization: Particle analysis
NA
NTA
Report type
Mean
Reported size (nm)
>200
EV concentration
Yes
Particle yield
Number of particles of starting sample E08-E09
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