Summary of Study ST002814

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 PR001761. The data can be accessed directly via it's Project DOI: 10.21228/M83139 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.

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Study IDST002814
Study TitleAtlas of fetal metabolism during mid-to-late gestation and diabetic pregnancy
Study SummaryMounting evidence supports an instructive role for metabolism in stem cell fate decisions. However, much is yet unknown about how fetal metabolism changes during mammalian development and how altered maternal metabolism shapes fetal metabolism. Here, we present a descriptive atlas of in vivo fetal murine metabolism during mid-to-late gestation in normal and diabetic pregnancy. Using 13C-glucose and LC-MS, we profiled the metabolism of fetal brains, hearts, livers, and placentas harvested from pregnant dams between embryonic days (E)10.5 and 18.5. Comparative analysis of our large metabolomics dataset revealed metabolic features specific to fetal tissues developed under a hyperglycemic environment as well as metabolic signatures that may denote developmental transitions during euglycemic development. We observed sorbitol accumulation in fetal tissues and altered neurotransmitter levels in fetal brains isolated from dams with maternal hyperglycemia. Tracing 13C-glucose revealed disparate nutrient sourcing in fetuses depending on maternal glycemic states. Regardless of glycemic state, histidine-derived metabolites accumulated during late development in fetal tissues and maternal plasma. Our rich dataset presents a comprehensive overview of in vivo fetal tissue metabolism and alterations occurring as a result of maternal hyperglycemia.
Institute
University of California, Los Angeles
DepartmentBiological Chemistry
LaboratoryHeather Christofk
Last NameMatulionis
First NameNedas
Address615 Charles E Young Drive South Los Angeles, CA, 90095
Emailnmatulionis@mednet.ucla.edu
Phone3102060163
Submit Date2023-08-29
Raw Data AvailableYes
Raw Data File Type(s)raw(Thermo)
Analysis Type DetailLC-MS
Release Date2023-12-08
Release Version1
Nedas Matulionis Nedas Matulionis
https://dx.doi.org/10.21228/M83139
ftp://www.metabolomicsworkbench.org/Studies/ application/zip

Select appropriate tab below to view additional metadata details:

Project:

Project ID:PR001761
Project DOI:doi: 10.21228/M83139
Project Title:Atlas of fetal metabolism during mid-to-late gestation and diabetic pregnancy
Project Summary:Mounting evidence supports an instructive role for metabolism in stem cell fate decisions. However, much is yet unknown about how fetal metabolism changes during mammalian development and how altered maternal metabolism shapes fetal metabolism. Here, we present a descriptive atlas of in vivo fetal murine metabolism during mid-to-late gestation in normal and diabetic pregnancy. Using 13C-glucose and LC-MS, we profiled the metabolism of fetal brains, hearts, livers, and placentas harvested from pregnant dams between embryonic days (E)10.5 and 18.5. Comparative analysis of our large metabolomics dataset revealed metabolic features specific to fetal tissues developed under a hyperglycemic environment as well as metabolic signatures that may denote developmental transitions during euglycemic development. We observed sorbitol accumulation in fetal tissues and altered neurotransmitter levels in fetal brains isolated from dams with maternal hyperglycemia. Tracing 13C-glucose revealed disparate nutrient sourcing in fetuses depending on maternal glycemic states. Regardless of glycemic state, histidine-derived metabolites accumulated during late development in fetal tissues and maternal plasma. Our rich dataset presents a comprehensive overview of in vivo fetal tissue metabolism and alterations occurring as a result of maternal hyperglycemia.
Institute:University of California, Los Angeles
Department:Biological Chemistry
Laboratory:Heather Christofk
Last Name:Matulionis
First Name:Nedas
Address:615 Charles E Young Drive South Los Angeles, CA, 90095
Email:nmatulionis@mednet.ucla.edu
Phone:3102060163

Subject:

Subject ID:SU002983
Subject Type:Mammal
Subject Species:Mus musculus
Taxonomy ID:10090

Factors:

Subject type: Mammal; Subject species: Mus musculus (Factor headings shown in green)

mb_sample_id local_sample_id Genotype Tissue
SA313162brain-AK-E12-D-04AK brain
SA313163brain-AK-E15-A-01AK brain
SA313164brain-AK-E12-D-03AK brain
SA313165brain-AK-E12-D-01AK brain
SA313166brain-AK-E12-C-04AK brain
SA313167brain-AK-E15-A-02AK brain
SA313168brain-AK-E12-D-02AK brain
SA313169brain-AK-E15-B-01AK brain
SA313170brain-AK-E15-D-01AK brain
SA313171brain-AK-E15-D-02AK brain
SA313172brain-AK-E15-B-04AK brain
SA313173brain-AK-E15-B-03AK brain
SA313174brain-AK-E12-C-03AK brain
SA313175brain-AK-E15-B-02AK brain
SA313176brain-AK-E15-A-04AK brain
SA313177brain-AK-E12-C-01AK brain
SA313178brain-AK-E10-C-04AK brain
SA313179brain-AK-E12-A-01AK brain
SA313180brain-AK-E10-C-03AK brain
SA313181brain-AK-E10-C-02AK brain
SA313182brain-AK-E10-B-04AK brain
SA313183brain-AK-E10-C-01AK brain
SA313184brain-AK-E12-A-02AK brain
SA313185brain-AK-E12-A-03AK brain
SA313186brain-AK-E12-B-04AK brain
SA313187brain-AK-E15-D-03AK brain
SA313188brain-AK-E12-B-03AK brain
SA313189brain-AK-E12-B-02AK brain
SA313190brain-AK-E12-A-04AK brain
SA313191brain-AK-E12-B-01AK brain
SA313192brain-AK-E12-C-02AK brain
SA313193brain-AK-E15-A-03AK brain
SA313194brain-AK-E18-D-04AK brain
SA313195brain-AK-E15-D-04AK brain
SA313196brain-AK-E18-D-03AK brain
SA313197brain-AK-E18-D-02AK brain
SA313198brain-AK-E18-D-01AK brain
SA313199brain-AK-E10-B-02AK brain
SA313200brain-AK-E10-B-01AK brain
SA313201brain-AK-E10-A-01AK brain
SA313202brain-AK-E10-A-02AK brain
SA313203brain-AK-E10-A-03AK brain
SA313204brain-AK-E10-A-04AK brain
SA313205brain-AK-E18-C-04AK brain
SA313206brain-AK-E10-B-03AK brain
SA313207brain-AK-E18-B-01AK brain
SA313208brain-AK-E18-B-02AK brain
SA313209brain-AK-E18-A-04AK brain
SA313210brain-AK-E18-A-03AK brain
SA313211brain-AK-E18-C-03AK brain
SA313212brain-AK-E18-A-02AK brain
SA313213brain-AK-E18-B-03AK brain
SA313214brain-AK-E18-A-01AK brain
SA313215brain-AK-E18-C-02AK brain
SA313216brain-AK-E18-C-01AK brain
SA313217heart-AK-E12-B-03AK heart
SA313218heart-AK-E12-B-02AK heart
SA313219heart-AK-E12-B-01AK heart
SA313220heart-AK-E12-A-03AK heart
SA313221heart-AK-E12-A-04AK heart
SA313222heart-AK-E12-B-04AK heart
SA313223heart-AK-E12-C-01AK heart
SA313224heart-AK-E12-D-02AK heart
SA313225heart-AK-E12-D-03AK heart
SA313226heart-AK-E12-D-01AK heart
SA313227heart-AK-E12-C-04AK heart
SA313228heart-AK-E12-C-02AK heart
SA313229heart-AK-E12-C-03AK heart
SA313230heart-AK-E12-A-02AK heart
SA313231heart-AK-E10-C-04AK heart
SA313232heart-AK-E10-B-01AK heart
SA313233heart-AK-E10-B-02AK heart
SA313234heart-AK-E10-A-01AK heart
SA313235heart-AK-E10-A-02AK heart
SA313236heart-AK-E10-A-03AK heart
SA313237heart-AK-E10-B-03AK heart
SA313238heart-AK-E10-B-04AK heart
SA313239heart-AK-E10-C-03AK heart
SA313240heart-AK-E10-A-04AK heart
SA313241heart-AK-E10-C-02AK heart
SA313242heart-AK-E10-C-01AK heart
SA313243heart-AK-E12-D-04AK heart
SA313244heart-AK-E12-A-01AK heart
SA313245heart-AK-E18-A-01AK heart
SA313246heart-AK-E18-B-04AK heart
SA313247heart-AK-E18-C-01AK heart
SA313248heart-AK-E18-B-03AK heart
SA313249heart-AK-E18-B-02AK heart
SA313250heart-AK-E18-B-01AK heart
SA313251heart-AK-E18-C-02AK heart
SA313252heart-AK-E18-C-04AK heart
SA313253heart-AK-E18-D-04AK heart
SA313254heart-AK-E15-A-01AK heart
SA313255heart-AK-E18-D-03AK heart
SA313256heart-AK-E18-D-02AK heart
SA313257heart-AK-E18-D-01AK heart
SA313258heart-AK-E18-A-04AK heart
SA313259heart-AK-E18-C-03AK heart
SA313260heart-AK-E15-B-01AK heart
SA313261heart-AK-E15-B-02AK heart
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Collection:

Collection ID:CO002976
Collection Summary:Healthy wildtype and Akita dams were set up for mating. The following morning, females displaying vaginal plugs were identified as pregnant, recorded as embryonic day (E) 0.5 and moved to a new cage until the appropriate embryonic day to be interrogated.
Sample Type:Embryo

Treatment:

Treatment ID:TR002992
Treatment Summary:Labeled glucose solution was prepared at a concentration of 100 mg/mL in filtered 0.9% sodium chloride solution. After overnight fasting (from 18:00 the day before), infusions took place around between 09:00 and 10:00 for all pregnant dams. Mice were anesthetized using isoflurane gas at 5% and placed on a warm pad. Mice were then kept under 2.5% isoflurane for the duration of infusion. For catheter placement, a 28-gauge insulin syringe needle was connected via polyethylene tubing (PE-10) to a syringe (containing glucose solution) placed on an infusion pump (Harvard Apparatus). At the start of the infusion, the 28-gauge needle was inserted into the tail vein. A glucose bolus of 4 µL/gBW was administered. Right after bolus administration, infusion rate was set at a continuous 0.085ul/gBW for a total infusion time of 3 hours.

Sample Preparation:

Sampleprep ID:SP002989
Sampleprep Summary:Fetal tissue extraction: Following infusion, mice were euthanized and blood was collected via heart puncture. Fetal tissues (placenta, brain, liver, and heart) were dissected in ice-cold sterile PBS. Immediately after dissection, weight was recorded and fetal tissue was placed in a pre-filled bead mill tube containing metal beads and 500 µL of methanol:water (80:20) solution kept cold on dry ice. Fetal tissues were homogenized using a Fisherbrand™ Bead Mill Homogenizer. Samples were spun twice at >17,000 g (4 °C) to remove precipitated cell material (protein/DNA). Supernatants were collected, transferred to a clean tube, and evaporated using a Nitrogen evaporator (Organomation). Evaporated samples were stored at -80 °C. Pellets containing protein/DNA were dried on a heat block (55 °C) and stored at -80 °C. Serum extraction: Collected blood was centrifuged at 5,000g to collect serum. Serum was snap frozen in liquid nitrogen and stored until extraction. For metabolite extraction 5 µL serum was mixed with 500 µL 100% MeOH (-80 °C). Samples were centrifuged for 10 min at >17,000 g (4 °C) and 450 µL of each sample evaporated using a Nitrogen evaporator (Organomation). Evaporated samples were stored at -80 °C.
Processing Storage Conditions:On ice
Extract Storage:-80℃

Combined analysis:

Analysis ID AN004705 AN004706
Analysis type MS MS
Chromatography type HILIC HILIC
Chromatography system Thermo Vanquish Thermo Vanquish
Column SeQuant ZIC-HILIC (150 x 2.1mm,5um) SeQuant ZIC-HILIC (150 x 2.1mm,5um)
MS Type ESI ESI
MS instrument type Orbitrap Orbitrap
MS instrument name Thermo Q Exactive Orbitrap Thermo Q Exactive Orbitrap
Ion Mode POSITIVE NEGATIVE
Units Peak Area Peak Area

Chromatography:

Chromatography ID:CH003543
Chromatography Summary:Dried metabolites were reconstituted in 100 µL of a 50% acetonitrile (ACN) 50% dH20 solution. Samples were vortexed and spun down for 10 min at 17,000g. 70 µL of the supernatant was then transferred to HPLC glass vials. 10 µL of these metabolite solutions were injected per analysis. Samples were run on a Vanquish (Thermo Scientific) UHPLC system with mobile phase A (20mM ammonium carbonate, pH 9.7) and mobile phase B (100% ACN) at a flow rate of 150 µL/min on a SeQuant ZIC-pHILIC Polymeric column (2.1 × 150 mm 5 μm, EMD Millipore) at 35°C. Separation was achieved with a linear gradient from 20% A to 80% A in 20 min followed by a linear gradient from 80% A to 20% A from 20 min to 20.5 min. 20% A was then held from 20.5 min to 28 min.
Instrument Name:Thermo Vanquish
Column Name:SeQuant ZIC-HILIC (150 x 2.1mm,5um)
Column Temperature:35°C
Flow Gradient:Separation was achieved with a linear gradient from 20% A to 80% A in 20 min followed by a linear gradient from 80% A to 20% A from 20 min to 20.5 min. 20% A was then held from 20.5 min to 28 min.
Flow Rate:150 µL/min
Solvent A:100% water; 20 mM ammonium carbonate, pH 9.7
Solvent B:100% acetonitrile
Chromatography Type:HILIC

MS:

MS ID:MS004451
Analysis ID:AN004705
Instrument Name:Thermo Q Exactive Orbitrap
Instrument Type:Orbitrap
MS Type:ESI
MS Comments:The UHPLC was coupled to a Q-Exactive (Thermo Scientific) mass analyzer running in polarity switching mode with spray-voltage=3.2kV, sheath-gas=40, aux-gas=15, sweep-gas=1, aux-gas-temp=350°C, and capillary-temp=275°C. For both polarities mass scan settings were kept at full-scan-range = (70-1000), ms1-resolution=70,000, max-injection-time=250ms, and AGC-target=1E6. MS2 data was also collected from the top three most abundant singly-charged ions in each scan with normalized-collision-energy=35. Each of the resulting “.RAW” files was then centroided and converted into two “.mzXML” files (one for positive scans and one for negative scans) using msconvert from ProteoWizard. These “.mzXML” files were imported into the MZmine 2 software package. Ion chromatograms were generated from MS1 spectra via the built-in Automated Data Analysis Pipeline (ADAP) chromatogram module and peaks were detected via the ADAP wavelets algorithm. Peaks were aligned across all samples via the Random sample consensus aligner module, gap-filled, and assigned identities using an exact mass MS1(+/-15ppm) and retention time RT (+/-0.5min) search of our in-house MS1-RT database. Peak boundaries and identifications were then further refined by manual curation. Peaks were quantified by area under the curve integration and exported as CSV files. If stable isotope tracing was used in the experiment, the peak areas were additionally processed via the R package AccuCor 2 to correct for natural isotope abundance. Peak areas for each sample were normalized by the measured area of the internal standard trifluoromethanesulfonate (present in the extraction buffer) and by the number of cells present in the extracted well.
Ion Mode:POSITIVE
  
MS ID:MS004452
Analysis ID:AN004706
Instrument Name:Thermo Q Exactive Orbitrap
Instrument Type:Orbitrap
MS Type:ESI
MS Comments:The UHPLC was coupled to a Q-Exactive (Thermo Scientific) mass analyzer running in polarity switching mode with spray-voltage=3.2kV, sheath-gas=40, aux-gas=15, sweep-gas=1, aux-gas-temp=350°C, and capillary-temp=275°C. For both polarities mass scan settings were kept at full-scan-range = (70-1000), ms1-resolution=70,000, max-injection-time=250ms, and AGC-target=1E6. MS2 data was also collected from the top three most abundant singly-charged ions in each scan with normalized-collision-energy=35. Each of the resulting “.RAW” files was then centroided and converted into two “.mzXML” files (one for positive scans and one for negative scans) using msconvert from ProteoWizard. These “.mzXML” files were imported into the MZmine 2 software package. Ion chromatograms were generated from MS1 spectra via the built-in Automated Data Analysis Pipeline (ADAP) chromatogram module and peaks were detected via the ADAP wavelets algorithm. Peaks were aligned across all samples via the Random sample consensus aligner module, gap-filled, and assigned identities using an exact mass MS1(+/-15ppm) and retention time RT (+/-0.5min) search of our in-house MS1-RT database. Peak boundaries and identifications were then further refined by manual curation. Peaks were quantified by area under the curve integration and exported as CSV files. If stable isotope tracing was used in the experiment, the peak areas were additionally processed via the R package AccuCor 2 to correct for natural isotope abundance. Peak areas for each sample were normalized by the measured area of the internal standard trifluoromethanesulfonate (present in the extraction buffer) and by the number of cells present in the extracted well.
Ion Mode:NEGATIVE
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