Summary of Study ST002244

This data is available at the NIH Common Fund's National Metabolomics Data Repository (NMDR) website, the Metabolomics Workbench, https://www.metabolomicsworkbench.org, where it has been assigned Project ID PR001432. The data can be accessed directly via it's Project DOI: 10.21228/M8MQ5M This work is supported by NIH grant, U2C- DK119886.

See: https://www.metabolomicsworkbench.org/about/howtocite.php

This study contains a large results data set and is not available in the mwTab file. It is only available for download via FTP as data file(s) here.

Study ID	ST002244
Study Title	Metabolomics analysis of Friedreich's ataxia (FRDA) (part I)
Study Type	Untargeted and targeted (PRM) analysis
Study Summary	Friedreich’s Ataxia (FRDA) is an autosomal neurodegenerative disease caused by the deficiency of protein frataxin. Frataxin functions in the assembly of iron-sulfur clusters that are important for iron homeostasis and metabolic functions. To identify metabolic features that can be used for potential biomarkers in FRDA plasma, we performed a targeted multi-omics (metabolomics, lipidomics, and proteomics) analysis using discovery-validation cohort design. Muti-omics analysis revealed that FRDA patients had dysregulated sphingolipid metabolism, phospholipid metabolism, citric acid cycle, amino acid metabolism, and apolipoprotein metabolism. Sphingolipid dysfunctions were revealed by decreased very long chain ceramides but unchanged long chain ceramides in FRDA plasma, which resulted in the increased ratio of long chain ceramides to very long chain ceramides. Decreased very long chain ceramides distinguished FRDA patients from healthy controls and showed good predictive capacities with AUC values from 0.75 to 0.85. Furthermore, by performing lipidomic and stable isotope tracing experiment in induced pluripotent stem cell differentiated cardiomyocytes (iPSC-CMs, we demonstrated that frataxin deficiency affected ceramide synthase (CerS2), and preferentially enriched long chain ceramides and depleted very long chain ceramides. Moreover, ceramide metabolism was differentially regulated in a tissue-specific manner. Finally, machine learning model increased the prediction of FRDA using the combination of three metabolites (AUC > 0.9). In conclusion, decreased very long chain ceramides are potential biomarkers and therapeutic target in FRDA patients.
Institute	University of Pennsylvania
Last Name	Wang
First Name	Dezhen
Address	421 Curie Blvd, Philadelphia, PA, 19104, USA
Email	dezhen.wang@pennmedicine.upenn.edu
Phone	5312185610
Submit Date	2022-07-29
Raw Data Available	Yes
Raw Data File Type(s)	raw(Thermo)
Analysis Type Detail	LC-MS
Release Date	2022-08-22
Release Version	1

Select appropriate tab below to view additional metadata details:

Project:

Project ID:	PR001432
Project DOI:	doi: 10.21228/M8MQ5M
Project Title:	Multi-omics study of Friedreich's ataxia (FRDA)
Project Type:	Untargeted and targeted (PRM) analysis
Project Summary:	Multi-omics study of plasma samples from FRDA patients and healthy controls
Institute:	University of Pennsylvania
Last Name:	Wang
First Name:	Dezhen
Address:	421 Curie Blvd, Philadelphia, PA, 19104, USA
Email:	dezhen.wang@pennmedicine.upenn.edu
Phone:	5312185610

Subject:

Subject ID:	SU002330
Subject Type:	Human
Subject Species:	Homo sapiens
Taxonomy ID:	9606

Factors:

Subject type: Human; Subject species: Homo sapiens (Factor headings shown in green)

mb_sample_id	local_sample_id	Group
SA214388	Negative_QC_13	-
SA214389	Negative_QC_14	-
SA214390	Negative_QC_15	-
SA214391	Negative_QC_1	-
SA214392	Negative_QC_12	-
SA214393	Negative_QC_10	-
SA214394	Negative_QC_11	-
SA214395	Negative_QC_16	-
SA214396	Negative_QC_2	-
SA214397	Negative_QC_7	-
SA214398	Negative_QC_6	-
SA214399	Negative_QC_8	-
SA214400	Negative_QC_9	-
SA214401	Negative_QC_3	-
SA214402	Negative_QC_4	-
SA214403	Positive_QC_1	-
SA214404	Positive_QC_10	-
SA214405	Positive_QC_5	-
SA214406	Positive_QC_4	-
SA214407	Positive_QC_6	-
SA214408	Positive_QC_7	-
SA214409	Positive_QC_9	-
SA214410	Positive_QC_8	-
SA214411	Positive_QC_3	-
SA214412	Positive_QC_2	-
SA214413	Positive_QC_12	-
SA214414	Positive_QC_11	-
SA214415	Positive_QC_13	-
SA214416	Positive_QC_14	-
SA214417	Positive_QC_16	-
SA214418	Positive_QC_15	-
SA214419	Negative_QC_5	-
SA214420	Carrier_Positive_P-23	Carrier
SA214421	Carrier_Positive_P-22	Carrier
SA214422	Carrier_Positive_P-24	Carrier
SA214423	Carrier_Positive_P-25	Carrier
SA214424	Carrier_Positive_P-26	Carrier
SA214425	Carrier_Positive_P-21	Carrier
SA214426	Carrier_Positive_P-20	Carrier
SA214427	Carrier_Positive_P-17	Carrier
SA214428	Carrier_Positive_P-18	Carrier
SA214429	Carrier_Positive_P-19	Carrier
SA214430	Carrier_Negative_P-16	Carrier
SA214431	Carrier_Positive_P-16	Carrier
SA214432	Carrier_Negative_P-22	Carrier
SA214433	Carrier_Negative_P-23	Carrier
SA214434	Carrier_Negative_P-24	Carrier
SA214435	Carrier_Negative_P-25	Carrier
SA214436	Carrier_Negative_P-21	Carrier
SA214437	Carrier_Negative_P-26	Carrier
SA214438	Carrier_Negative_P-17	Carrier
SA214439	Carrier_Negative_P-20	Carrier
SA214440	Carrier_Negative_P-18	Carrier
SA214441	Carrier_Negative_P-19	Carrier
SA214442	Control_Negative_OP_40	Control
SA214443	Control_Positive_OP_14	Control
SA214444	Control_Negative_OP_8	Control
SA214445	Control_Positive_OP_15	Control
SA214446	Control_Negative_OP_42	Control
SA214447	Control_Negative_OP_41	Control
SA214448	Control_Positive_OP_18	Control
SA214449	Control_Negative_OP_9	Control
SA214450	Control_Positive_OP_35	Control
SA214451	Control_Positive_OP_19	Control
SA214452	Control_Positive_OP_17	Control
SA214453	Control_Positive_OP_16	Control
SA214454	Control_Negative_P-06	Control
SA214455	Control_Negative_P-09	Control
SA214456	Control_Negative_P-08	Control
SA214457	Control_Negative_P-10	Control
SA214458	Control_Negative_P-11	Control
SA214459	Control_Negative_P-12	Control
SA214460	Control_Negative_P-07	Control
SA214461	Control_Positive_OP_40	Control
SA214462	Control_Negative_P-02	Control
SA214463	Control_Negative_P-03	Control
SA214464	Control_Negative_P-04	Control
SA214465	Control_Negative_P-05	Control
SA214466	Control_Negative_P-01	Control
SA214467	Control_Positive_P-03	Control
SA214468	Control_Positive_P-14	Control
SA214469	Control_Negative_OP_35	Control
SA214470	Control_Positive_P-13	Control
SA214471	Control_Positive_P-12	Control
SA214472	Control_Positive_P-11	Control
SA214473	Control_Negative_OP_19	Control
SA214474	Control_Negative_OP_18	Control
SA214475	Control_Negative_OP_14	Control
SA214476	Control_Negative_OP_15	Control
SA214477	Control_Negative_OP_16	Control
SA214478	Control_Negative_OP_17	Control
SA214479	Control_Positive_P-10	Control
SA214480	Control_Positive_P-09	Control
SA214481	Control_Positive_P-02	Control
SA214482	Control_Positive_P-01	Control
SA214483	Control_Positive_OP_8	Control
SA214484	Control_Positive_OP_42	Control
SA214485	Control_Negative_P-13	Control
SA214486	Control_Positive_P-04	Control
SA214487	Control_Positive_P-08	Control

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Collection:

Collection ID:	CO002323
Collection Summary:	Venous blood was drawn in 8.5 mL purple cap Vacutainer EDTA tubes and gently invert to mix. Plasma was collected after centrifugation at 1000 g for 15 min. All samples were immediately aliquoted to Eppendorf tubes and frozen at -80 ºC until analysis.
Sample Type:	Blood (plasma)
Storage Conditions:	-80℃

Treatment:

Treatment ID:	TR002342
Treatment Summary:	NA

Sample Preparation:

Sampleprep ID:	SP002336
Sampleprep Summary:	20 μL plasma, was mixed with 30 μL internal standard working solution, and extracted with 200 μL methanol for 10 min, and precipitated protein at -20℃ for 1h. After centrifugation at 14000xg for 10 min at 4 ℃, the supernatant was transferred into a new tube, dried under nitrogen, and resuspended in 50 μL acetonitrile/water (75/25, v/v). 5 μL of each sample was combined to make a pooled quality control (QC) sample and ran every ten samples in the long sequence to monitor retention time and signal intensity drift. The remaining samples (30 μL) were transferred into injection vials for metabolomic analysis.

Sampleprep ID:

SP002336

Sampleprep Summary:

20 μL plasma, was mixed with 30 μL internal standard working solution, and extracted with 200 μL methanol for 10 min, and precipitated protein at -20℃ for 1h. After centrifugation at 14000xg for 10 min at 4 ℃, the supernatant was transferred into a new tube, dried under nitrogen, and resuspended in 50 μL acetonitrile/water (75/25, v/v). 5 μL of each sample was combined to make a pooled quality control (QC) sample and ran every ten samples in the long sequence to monitor retention time and signal intensity drift. The remaining samples (30 μL) were transferred into injection vials for metabolomic analysis.

Combined analysis:

Analysis ID	AN003663	AN003664
Analysis type	MS	MS
Chromatography type	HILIC	HILIC
Chromatography system	Thermo Dionex Ultimate 3000	Thermo Dionex Ultimate 3000
Column	Ascentis Express HILIC HPLC (150 x 2.1mm,2.7um)	Ascentis Express HILIC HPLC (150 x 2.1mm,2.7um)
MS Type	ESI	ESI
MS instrument type	Orbitrap	Orbitrap
MS instrument name	Thermo Q Exactive HF hybrid Orbitrap	Thermo Q Exactive HF hybrid Orbitrap
Ion Mode	POSITIVE	NEGATIVE
Units	intensity	intensity

Chromatography:

Chromatography ID:	CH002714
Instrument Name:	Thermo Dionex Ultimate 3000
Column Name:	Ascentis Express HILIC HPLC (150 x 2.1mm,2.7um)
Column Temperature:	35
Flow Gradient:	10% B for 2 min, and ramped to 30% B in 8 min, and ramped to 100 % B in 5 min, and maintained at 100 % B for 3 min, and back to initial 10 % B in 1 min, and equilibrate at initial condition for 7 min.
Flow Rate:	0.25 ml/min
Injection Temperature:	4
Solvent A:	95% acetonitrile/5% water; 0.1% acetic acid; 10 mM ammonium acetate
Solvent B:	95% water/5% acetonitrile; 0.1% acetic acid; 10 mM ammonium acetate
Analytical Time:	26min
Chromatography Type:	HILIC

MS:

MS ID:	MS003414
Analysis ID:	AN003663
Instrument Name:	Thermo Q Exactive HF hybrid Orbitrap
Instrument Type:	Orbitrap
MS Type:	ESI
MS Comments:	Samples were analyzed using a Q Exactive HF (QE-HF) (Thermo Scientific, Waltham, MA) equipped with a heated electro-spray ionization (HESI) source operated in both positive and negative ion mode. To build up metabolite spectral library for targeted analysis, we ran the pooled QC samples in full scan/ddMS2 mode (untargeted metabolomics). The Full Scan settings were as follows: AGC target, 1e6; Maximum IT, 200 ms; scan range, 60 to 900 m/z. Top 20 MS/MS spectral (dd-MS2) @ 15000 were generated with AGC target = 2e5, Maximum IT=25 ms, and (N)CE/stepped nce = 20, 30, 40v. Metabolites detection and identification were performed using Compound Discovery 2.1 (Thermo Scientific, Waltham, MA) by searching against online database (mzCloud) and in-house database built on Sigma metabolomics library (LSMLS, Sigma-Aldrich) (mzValut). Well annotated metabolites (MS spectral match and retention time match) were used to generate an inclusion list (Supplementary Table 3) for targeted PRM analysis. Final data acquisition was performed in Full scan + PRM modes. The PRM settings were as follows: resolution = 15000, AGC target = 2e5, Maximum IT=25 ms, loop count = 20, isolation window = 2.0, (N)CE was optimized for each metabolite.
Ion Mode:	POSITIVE
Capillary Temperature:	325
Spray Voltage:	3500

MS ID:	MS003415
Analysis ID:	AN003664
Instrument Name:	Thermo Q Exactive HF hybrid Orbitrap
Instrument Type:	Orbitrap
MS Type:	ESI
MS Comments:	Samples were analyzed using a Q Exactive HF (QE-HF) (Thermo Scientific, Waltham, MA) equipped with a heated electro-spray ionization (HESI) source operated in both positive and negative ion mode. To build up metabolite spectral library for targeted analysis, we ran the pooled QC samples in full scan/ddMS2 mode (untargeted metabolomics). The Full Scan settings were as follows: AGC target, 1e6; Maximum IT, 200 ms; scan range, 60 to 900 m/z. Top 20 MS/MS spectral (dd-MS2) @ 15000 were generated with AGC target = 2e5, Maximum IT=25 ms, and (N)CE/stepped nce = 20, 30, 40v. Metabolites detection and identification were performed using Compound Discovery 2.1 (Thermo Scientific, Waltham, MA) by searching against online database (mzCloud) and in-house database built on Sigma metabolomics library (LSMLS, Sigma-Aldrich) (mzValut). Well annotated metabolites (MS spectral match and retention time match) were used to generate an inclusion list (Supplementary Table 3) for targeted PRM analysis. Final data acquisition was performed in Full scan + PRM modes. The PRM settings were as follows: resolution = 15000, AGC target = 2e5, Maximum IT=25 ms, loop count = 20, isolation window = 2.0, (N)CE was optimized for each metabolite.
Ion Mode:	NEGATIVE
Capillary Temperature:	325
Spray Voltage:	3000