#METABOLOMICS WORKBENCH mjosephkeller_20230926_123700 DATATRACK_ID:4336 STUDY_ID:ST002890 ANALYSIS_ID:AN004749 PROJECT_ID:PR001803 VERSION 1 CREATED_ON September 29, 2023, 6:40 pm #PROJECT PR:PROJECT_TITLE Characterization of the in vivo deuteration of native phospholipids by mass PR:PROJECT_TITLE spectrometry yields guidelines for their regiospecific customization PR:PROJECT_SUMMARY Customization of deuterated biomolecules is vital for many advanced biological PR:PROJECT_SUMMARY experiments, including neutron scattering. However, because it is challenging to PR:PROJECT_SUMMARY control the proportion and regiospecificity of deuterium incorporation in live PR:PROJECT_SUMMARY systems, often only two or three synthetic lipids are mixed together to form PR:PROJECT_SUMMARY simplistic model membranes. This limits the applicability and biological PR:PROJECT_SUMMARY accuracy of the results generated with these synthetic membranes. Despite some PR:PROJECT_SUMMARY limited prior examination of deuterating E. coli lipids in vivo, this approach PR:PROJECT_SUMMARY has not been widely implemented. Here, an extensive mass spectrometry-based PR:PROJECT_SUMMARY profiling of E. coli phospholipid deuteration states with several different PR:PROJECT_SUMMARY growth media was performed and a computational method to describe deuterium PR:PROJECT_SUMMARY distributions with a one-number summary is introduced. The deuteration states of PR:PROJECT_SUMMARY thirty-six lipid species were quantitatively profiled in fifteen different PR:PROJECT_SUMMARY growth conditions and tandem mass spectrometry was used to reveal deuterium PR:PROJECT_SUMMARY localization. Regressions were employed to enable the prediction of lipid PR:PROJECT_SUMMARY deuteration for untested conditions. Small-angle neutron scattering was PR:PROJECT_SUMMARY performed on select deuterated lipid samples, which validated the deuteration PR:PROJECT_SUMMARY states calculated from the mass spectral data. Based on these experiments, PR:PROJECT_SUMMARY guidelines for the design of specifically deuterated phospholipids are PR:PROJECT_SUMMARY described. This unlocks even greater capabilities from neutron-based techniques, PR:PROJECT_SUMMARY enabling experiments that were formerly impossible. PR:INSTITUTE University of Tennessee PR:DEPARTMENT Genome Science and Technology (Bredesen Center) PR:LAST_NAME Matthew PR:FIRST_NAME Keller PR:ADDRESS The Bredesen Center for Interdisciplinary Research and Graduate Education 444 PR:ADDRESS Greve Hall, 821 Volunteer Blvd PR:EMAIL qrh579@vols.utk.edu PR:PHONE 18659747999 PR:PUBLICATIONS In review at Analytical Chemistry PR:CONTRIBUTORS Qiu Zhang, Shuo Qian, Brian Sanders, Hugh O'Neill, Robert Hettich #STUDY ST:STUDY_TITLE Characterization of the in vivo deuteration of native phospholipids by mass ST:STUDY_TITLE spectrometry yields guidelines for their regiospecific customization ST:STUDY_SUMMARY Customization of deuterated biomolecules is vital for many advanced biological ST:STUDY_SUMMARY experiments, including neutron scattering. However, because it is challenging to ST:STUDY_SUMMARY control the proportion and regiospecificity of deuterium incorporation in live ST:STUDY_SUMMARY systems, often only two or three synthetic lipids are mixed together to form ST:STUDY_SUMMARY simplistic model membranes. This limits the applicability and biological ST:STUDY_SUMMARY accuracy of the results generated with these synthetic membranes. Despite some ST:STUDY_SUMMARY limited prior examination of deuterating E. coli lipids in vivo, this approach ST:STUDY_SUMMARY has not been widely implemented. Here, an extensive mass spectrometry-based ST:STUDY_SUMMARY profiling of E. coli phospholipid deuteration states with several different ST:STUDY_SUMMARY growth media was performed and a computational method to describe deuterium ST:STUDY_SUMMARY distributions with a one-number summary is introduced. The deuteration states of ST:STUDY_SUMMARY thirty-six lipid species were quantitatively profiled in fifteen different ST:STUDY_SUMMARY growth conditions and tandem mass spectrometry was used to reveal deuterium ST:STUDY_SUMMARY localization. Regressions were employed to enable the prediction of lipid ST:STUDY_SUMMARY deuteration for untested conditions. Small-angle neutron scattering was ST:STUDY_SUMMARY performed on select deuterated lipid samples, which validated the deuteration ST:STUDY_SUMMARY states calculated from the mass spectral data. Based on these experiments, ST:STUDY_SUMMARY guidelines for the design of specifically deuterated phospholipids are ST:STUDY_SUMMARY described. This unlocks even greater capabilities from neutron-based techniques, ST:STUDY_SUMMARY enabling experiments that were formerly impossible. ST:INSTITUTE University of Tennessee ST:DEPARTMENT Genome Science and Technology (Bredesen Center) ST:LAST_NAME Matthew ST:FIRST_NAME Keller ST:ADDRESS The Bredesen Center for Interdisciplinary Research and Graduate Education 444 ST:ADDRESS Greve Hall, 821 Volunteer Blvd. Knoxville, TN 37996-3394 ST:EMAIL qrh579@vols.utk.edu ST:PHONE 18659747999 #SUBJECT SU:SUBJECT_TYPE Bacteria SU:SUBJECT_SPECIES Escherichia coli SU:GENOTYPE_STRAIN BL21(DE3) #SUBJECT_SAMPLE_FACTORS: SUBJECT(optional)[tab]SAMPLE[tab]FACTORS(NAME:VALUE pairs separated by |)[tab]Raw file names and additional sample data SUBJECT_SAMPLE_FACTORS - 50D-Gly/0_1-neg Carbon source:H-Glucose | Percent D2O:100 | MS ionization mode:negative Technical replicate=1; RAW_FILE_NAME=50D-Gly_0_1-neg.mzML SUBJECT_SAMPLE_FACTORS - 50D-Gly/0_2-neg Carbon source:H-Glucose | Percent D2O:100 | MS ionization mode:negative Technical replicate=1; RAW_FILE_NAME=50D-Gly_0_2-neg.mzML SUBJECT_SAMPLE_FACTORS - 50D-Gly/0_3-neg Carbon source:H-Glucose | Percent D2O:100 | MS ionization mode:negative Technical replicate=1; RAW_FILE_NAME=50D-Gly_0_3-neg.mzML SUBJECT_SAMPLE_FACTORS - 50D-Gly/100_1-neg Carbon source:D-Glucose | Percent D2O:100 | MS ionization mode:negative Technical replicate=1; RAW_FILE_NAME=50D-Gly_100_1-neg.mzML SUBJECT_SAMPLE_FACTORS - 50D-Gly/100_2-neg Carbon source:D-Glucose | Percent D2O:100 | MS ionization mode:negative Technical replicate=1; RAW_FILE_NAME=50D-Gly_100_2-neg.mzML SUBJECT_SAMPLE_FACTORS - 50D-Gly/100_3-neg Carbon source:D-Glucose | Percent D2O:100 | MS ionization mode:negative Technical replicate=1; RAW_FILE_NAME=50D-Gly_100_3-neg.mzML SUBJECT_SAMPLE_FACTORS - D-Glu/0_1-neg Carbon source:H-Glucose | Percent D2O:25 | MS ionization mode:negative Technical replicate=1; RAW_FILE_NAME=D-Glu_0_1_neg.mzML SUBJECT_SAMPLE_FACTORS - D-Glu/0_2-neg Carbon source:H-Glucose | Percent D2O:25 | MS ionization mode:negative Technical replicate=1; RAW_FILE_NAME=D-Glu_0_2_neg.mzML SUBJECT_SAMPLE_FACTORS - D-Glu/0_3-neg Carbon source:H-Glucose | Percent D2O:25 | MS ionization mode:negative Technical replicate=1; RAW_FILE_NAME=D-Glu_0_3_neg.mzML SUBJECT_SAMPLE_FACTORS - D-Glu/100-neg_tech-rep1 Carbon source:D-Glucose | Percent D2O:0 | MS ionization mode:negative Technical replicate=1; RAW_FILE_NAME=D-Glu_100_tech1-neg.mzML SUBJECT_SAMPLE_FACTORS - D-Glu/100-neg_tech-rep2 Carbon source:D-Glucose | Percent D2O:0 | MS ionization mode:negative Technical replicate=2; RAW_FILE_NAME=D-Glu_100_tech2-neg.mzML SUBJECT_SAMPLE_FACTORS - D-Gly/0_1-neg Carbon source:H-Glucose | Percent D2O:50 | MS ionization mode:negative Technical replicate=1; RAW_FILE_NAME=D-Gly_0_1_neg.mzML SUBJECT_SAMPLE_FACTORS - D-Gly/0_2-neg Carbon source:H-Glucose | Percent D2O:50 | MS ionization mode:negative Technical replicate=1; RAW_FILE_NAME=D-Gly_0_2_neg.mzML SUBJECT_SAMPLE_FACTORS - D-Gly/0_3-neg Carbon source:H-Glucose | Percent D2O:50 | MS ionization mode:negative Technical replicate=1; RAW_FILE_NAME=D-Gly_0_3_neg.mzML SUBJECT_SAMPLE_FACTORS - D-Gly/100_1-neg Carbon source:H-Glucose | Percent D2O:75 | MS ionization mode:negative Technical replicate=1; RAW_FILE_NAME=D-Gly_100_1_neg.mzML SUBJECT_SAMPLE_FACTORS - D-Gly/100_2-neg Carbon source:H-Glucose | Percent D2O:75 | MS ionization mode:negative Technical replicate=1; RAW_FILE_NAME=D-Gly_100_2_neg.mzML SUBJECT_SAMPLE_FACTORS - D-Gly/100_3-neg Carbon source:H-Glucose | Percent D2O:75 | MS ionization mode:negative Technical replicate=1; RAW_FILE_NAME=D-Gly_100_3_neg.mzML SUBJECT_SAMPLE_FACTORS - H-Glu/100-neg_tech-rep1 Carbon source:D-Glycerol | Percent D2O:100 | MS ionization mode:negative Technical replicate=1; RAW_FILE_NAME=H-Glu_100_tech1-neg.mzML SUBJECT_SAMPLE_FACTORS - H-Glu/100-neg_tech-rep2 Carbon source:D-Glycerol | Percent D2O:100 | MS ionization mode:negative Technical replicate=2; RAW_FILE_NAME=H-Glu_100_tech2-neg.mzML SUBJECT_SAMPLE_FACTORS - H-Glu/25_1-neg Carbon source:50/50 H/D-Glycerol | Percent D2O:0 | MS ionization mode:negative Technical replicate=1; RAW_FILE_NAME=H-Glu_25_1-neg.mzML SUBJECT_SAMPLE_FACTORS - H-Glu/25_2-neg Carbon source:50/50 H/D-Glycerol | Percent D2O:0 | MS ionization mode:negative Technical replicate=1; RAW_FILE_NAME=H-Glu_25_2-neg.mzML SUBJECT_SAMPLE_FACTORS - H-Glu/25_3-neg Carbon source:50/50 H/D-Glycerol | Percent D2O:0 | MS ionization mode:negative Technical replicate=1; RAW_FILE_NAME=H-Glu_25_3-neg.mzML SUBJECT_SAMPLE_FACTORS - H-Glu/50_1-neg Carbon source:D-Glycerol | Percent D2O:0 | MS ionization mode:negative Technical replicate=1; RAW_FILE_NAME=H-Glu_50_1-neg.mzML SUBJECT_SAMPLE_FACTORS - H-Glu/50_2-neg Carbon source:D-Glycerol | Percent D2O:0 | MS ionization mode:negative Technical replicate=1; RAW_FILE_NAME=H-Glu_50_2-neg.mzML SUBJECT_SAMPLE_FACTORS - H-Glu/50_3-neg Carbon source:D-Glycerol | Percent D2O:0 | MS ionization mode:negative Technical replicate=1; RAW_FILE_NAME=H-Glu_50_3-neg.mzML SUBJECT_SAMPLE_FACTORS - H-Glu/75_1-neg Carbon source:50/50 H/D-Glycerol | Percent D2O:100 | MS ionization mode:negative Technical replicate=1; RAW_FILE_NAME=H-Glu_75_1-neg.mzML SUBJECT_SAMPLE_FACTORS - H-Glu/75_2-neg Carbon source:50/50 H/D-Glycerol | Percent D2O:100 | MS ionization mode:negative Technical replicate=1; RAW_FILE_NAME=H-Glu_75_2-neg.mzML SUBJECT_SAMPLE_FACTORS - H-Glu/75_3-neg Carbon source:50/50 H/D-Glycerol | Percent D2O:100 | MS ionization mode:negative Technical replicate=1; RAW_FILE_NAME=H-Glu_75_3-neg.mzML SUBJECT_SAMPLE_FACTORS - H-Glu/75_repeat_1-neg Carbon source:50/50 H/D-Glycerol | Percent D2O:100 | MS ionization mode:negative Technical replicate=1; RAW_FILE_NAME=H-Glu_75_1-neg_2ndbatch.mzML SUBJECT_SAMPLE_FACTORS - H-Glu/75_repeat_2-neg Carbon source:50/50 H/D-Glycerol | Percent D2O:100 | MS ionization mode:negative Technical replicate=1; RAW_FILE_NAME=H-Glu_75_2-neg_2ndbatch.mzML SUBJECT_SAMPLE_FACTORS - H-Glu/75_repeat_3-neg Carbon source:50/50 H/D-Glycerol | Percent D2O:100 | MS ionization mode:negative Technical replicate=1; RAW_FILE_NAME=H-Glu_75_3-neg_2ndbatch.mzML SUBJECT_SAMPLE_FACTORS - H-Gly/0-neg_tech-rep1 Carbon source:H-Glycerol | Percent D2O:0 | MS ionization mode:negative Technical replicate=1; RAW_FILE_NAME=H-Gly_0_tech1-neg.mzML SUBJECT_SAMPLE_FACTORS - H-Gly/0-neg_tech-rep2 Carbon source:H-Glycerol | Percent D2O:0 | MS ionization mode:negative Technical replicate=2; RAW_FILE_NAME=H-Gly_0_tech2-neg.mzML SUBJECT_SAMPLE_FACTORS - H-Gly/100_1-neg Carbon source:H-Glycerol | Percent D2O:100 | MS ionization mode:negative Technical replicate=1; RAW_FILE_NAME=H-Gly_100_1-neg.mzML SUBJECT_SAMPLE_FACTORS - H-Gly/100_2-neg Carbon source:H-Glycerol | Percent D2O:100 | MS ionization mode:negative Technical replicate=1; RAW_FILE_NAME=H-Gly_100_2-neg.mzML SUBJECT_SAMPLE_FACTORS - H-Gly/100_3-neg Carbon source:H-Glycerol | Percent D2O:100 | MS ionization mode:negative Technical replicate=1; RAW_FILE_NAME=H-Gly_100_3-neg.mzML SUBJECT_SAMPLE_FACTORS - H-Gly/25-neg_tech-rep1 Carbon source:H-Glycerol | Percent D2O:25 | MS ionization mode:negative Technical replicate=1; RAW_FILE_NAME=H-Gly_25_tech1-neg.mzML SUBJECT_SAMPLE_FACTORS - H-Gly/25-neg_tech-rep2 Carbon source:H-Glycerol | Percent D2O:25 | MS ionization mode:negative Technical replicate=2; RAW_FILE_NAME=H-Gly_25_tech2-neg.mzML SUBJECT_SAMPLE_FACTORS - H-Gly/50-neg_tech-rep1 Carbon source:H-Glycerol | Percent D2O:50 | MS ionization mode:negative Technical replicate=1; RAW_FILE_NAME=H-Gly_50_tech1-neg.mzML SUBJECT_SAMPLE_FACTORS - H-Gly/50-neg_tech-rep2 Carbon source:H-Glycerol | Percent D2O:50 | MS ionization mode:negative Technical replicate=2; RAW_FILE_NAME=H-Gly_50_tech2-neg.mzML SUBJECT_SAMPLE_FACTORS - H-Gly/75-neg_tech-rep1 Carbon source:H-Glycerol | Percent D2O:75 | MS ionization mode:negative Technical replicate=1; RAW_FILE_NAME=H-Gly_75_tech1-neg.mzML SUBJECT_SAMPLE_FACTORS - H-Gly/75-neg_tech-rep2 Carbon source:H-Glycerol | Percent D2O:75 | MS ionization mode:negative Technical replicate=2; RAW_FILE_NAME=H-Gly_75_tech2-neg.mzML SUBJECT_SAMPLE_FACTORS - 50D-Gly/0_1-pos Carbon source:H-Glucose | Percent D2O:100 | MS ionization mode:positive Technical replicate=1; RAW_FILE_NAME=50D-Gly_0_1-pos.mzML SUBJECT_SAMPLE_FACTORS - 50D-Gly/0_2-pos Carbon source:H-Glucose | Percent D2O:100 | MS ionization mode:positive Technical replicate=1; RAW_FILE_NAME=50D-Gly_0_2-pos.mzML SUBJECT_SAMPLE_FACTORS - 50D-Gly/0_3-pos Carbon source:H-Glucose | Percent D2O:100 | MS ionization mode:positive Technical replicate=1; RAW_FILE_NAME=50D-Gly_0_3-pos.mzML SUBJECT_SAMPLE_FACTORS - 50D-Gly/100_1-pos Carbon source:D-Glucose | Percent D2O:100 | MS ionization mode:positive Technical replicate=1; RAW_FILE_NAME=50D-Gly_100_1-pos.mzML SUBJECT_SAMPLE_FACTORS - 50D-Gly/100_2-pos Carbon source:D-Glucose | Percent D2O:100 | MS ionization mode:positive Technical replicate=1; RAW_FILE_NAME=50D-Gly_100_2-pos.mzML SUBJECT_SAMPLE_FACTORS - 50D-Gly/100_3-pos Carbon source:D-Glucose | Percent D2O:100 | MS ionization mode:positive Technical replicate=1; RAW_FILE_NAME=50D-Gly_100_3-pos.mzML SUBJECT_SAMPLE_FACTORS - D-Glu/0_1-pos Carbon source:H-Glucose | Percent D2O:25 | MS ionization mode:positive Technical replicate=1; RAW_FILE_NAME=D-Glu_0_1_pos.mzML SUBJECT_SAMPLE_FACTORS - D-Glu/0_2-pos Carbon source:H-Glucose | Percent D2O:25 | MS ionization mode:positive Technical replicate=1; RAW_FILE_NAME=D-Glu_0_2_pos.mzML SUBJECT_SAMPLE_FACTORS - D-Glu/0_3-pos Carbon source:H-Glucose | Percent D2O:25 | MS ionization mode:positive Technical replicate=1; RAW_FILE_NAME=D-Glu_0_3_pos.mzML SUBJECT_SAMPLE_FACTORS - D-Glu/100-pos Carbon source:D-Glucose | Percent D2O:0 | MS ionization mode:positive Technical replicate=1; RAW_FILE_NAME=D-Glu_100_pos.mzML SUBJECT_SAMPLE_FACTORS - D-Gly/0_1-pos Carbon source:H-Glucose | Percent D2O:50 | MS ionization mode:positive Technical replicate=1; RAW_FILE_NAME=D-Gly_0_1_pos.mzML SUBJECT_SAMPLE_FACTORS - D-Gly/0_2-pos Carbon source:H-Glucose | Percent D2O:50 | MS ionization mode:positive Technical replicate=1; RAW_FILE_NAME=D-Gly_0_2_pos.mzML SUBJECT_SAMPLE_FACTORS - D-Gly/0_3-pos Carbon source:H-Glucose | Percent D2O:50 | MS ionization mode:positive Technical replicate=1; RAW_FILE_NAME=D-Gly_0_3_pos.mzML SUBJECT_SAMPLE_FACTORS - D-Gly/100_1-pos Carbon source:H-Glucose | Percent D2O:75 | MS ionization mode:positive Technical replicate=1; RAW_FILE_NAME=D-Gly_100_1_pos.mzML SUBJECT_SAMPLE_FACTORS - D-Gly/100_2-pos Carbon source:H-Glucose | Percent D2O:75 | MS ionization mode:positive Technical replicate=1; RAW_FILE_NAME=D-Gly_100_2_pos.mzML SUBJECT_SAMPLE_FACTORS - D-Gly/100_3-pos Carbon source:H-Glucose | Percent D2O:75 | MS ionization mode:positive Technical replicate=1; RAW_FILE_NAME=D-Gly_100_3_pos.mzML SUBJECT_SAMPLE_FACTORS - H-Glu/100-pos Carbon source:D-Glycerol | Percent D2O:100 | MS ionization mode:positive Technical replicate=1; RAW_FILE_NAME=H-Glu_100_pos.mzML SUBJECT_SAMPLE_FACTORS - H-Glu/25_1-pos Carbon source:50/50 H/D-Glycerol | Percent D2O:0 | MS ionization mode:positive Technical replicate=1; RAW_FILE_NAME=H-Glu_25_1-pos.mzML SUBJECT_SAMPLE_FACTORS - H-Glu/25_2-pos Carbon source:50/50 H/D-Glycerol | Percent D2O:0 | MS ionization mode:positive Technical replicate=1; RAW_FILE_NAME=H-Glu_25_2-pos.mzML SUBJECT_SAMPLE_FACTORS - H-Glu/25_3-pos Carbon source:50/50 H/D-Glycerol | Percent D2O:0 | MS ionization mode:positive Technical replicate=1; RAW_FILE_NAME=H-Glu_25_3-pos.mzML SUBJECT_SAMPLE_FACTORS - H-Glu/50_1-pos Carbon source:D-Glycerol | Percent D2O:0 | MS ionization mode:positive Technical replicate=1; RAW_FILE_NAME=H-Glu_50_1-pos.mzML SUBJECT_SAMPLE_FACTORS - H-Glu/50_2-pos Carbon source:D-Glycerol | Percent D2O:0 | MS ionization mode:positive Technical replicate=1; RAW_FILE_NAME=H-Glu_50_2-pos.mzML SUBJECT_SAMPLE_FACTORS - H-Glu/50_3-pos Carbon source:D-Glycerol | Percent D2O:0 | MS ionization mode:positive Technical replicate=1; RAW_FILE_NAME=H-Glu_50_3-pos.mzML SUBJECT_SAMPLE_FACTORS - H-Glu/75_1-pos Carbon source:50/50 H/D-Glycerol | Percent D2O:100 | MS ionization mode:positive Technical replicate=1; RAW_FILE_NAME=H-Glu_75_1-pos.mzML SUBJECT_SAMPLE_FACTORS - H-Glu/75_2-pos Carbon source:50/50 H/D-Glycerol | Percent D2O:100 | MS ionization mode:positive Technical replicate=1; RAW_FILE_NAME=H-Glu_75_2-pos.mzML SUBJECT_SAMPLE_FACTORS - H-Glu/75_3-pos Carbon source:50/50 H/D-Glycerol | Percent D2O:100 | MS ionization mode:positive Technical replicate=1; RAW_FILE_NAME=H-Glu_75_3-pos.mzML SUBJECT_SAMPLE_FACTORS - H-Gly/0-pos Carbon source:H-Glycerol | Percent D2O:0 | MS ionization mode:positive Technical replicate=1; RAW_FILE_NAME=H-Gly_0_pos.mzML SUBJECT_SAMPLE_FACTORS - H-Gly/100_1-pos Carbon source:H-Glycerol | Percent D2O:100 | MS ionization mode:positive Technical replicate=1; RAW_FILE_NAME=H-Gly_100_1-pos.mzML SUBJECT_SAMPLE_FACTORS - H-Gly/100_2-pos Carbon source:H-Glycerol | Percent D2O:100 | MS ionization mode:positive Technical replicate=1; RAW_FILE_NAME=H-Gly_100_2-pos.mzML SUBJECT_SAMPLE_FACTORS - H-Gly/100_3-pos Carbon source:H-Glycerol | Percent D2O:100 | MS ionization mode:positive Technical replicate=1; RAW_FILE_NAME=H-Gly_100_3-pos.mzML SUBJECT_SAMPLE_FACTORS - H-Gly/25-pos Carbon source:H-Glycerol | Percent D2O:25 | MS ionization mode:positive Technical replicate=1; RAW_FILE_NAME=H-Gly_25_pos.mzML SUBJECT_SAMPLE_FACTORS - H-Gly/50-pos Carbon source:H-Glycerol | Percent D2O:50 | MS ionization mode:positive Technical replicate=1; RAW_FILE_NAME=H-Gly_50_pos.mzML SUBJECT_SAMPLE_FACTORS - H-Gly/75-pos Carbon source:H-Glycerol | Percent D2O:75 | MS ionization mode:positive Technical replicate=1; RAW_FILE_NAME=H-Gly_75_pos.mzML #COLLECTION CO:COLLECTION_SUMMARY Lipids were extracted from E coli cell pellets following the Matyash protocol CO:COLLECTION_SUMMARY with slight variations described in the manuscript supplemental. Cell lysis was CO:COLLECTION_SUMMARY performed with bead beating or ultrasonication. Extraction solvents were in the CO:COLLECTION_SUMMARY ratio 10:3:25 MTBE:methanol:water. See publication for more detail. CO:COLLECTION_PROTOCOL_FILENAME Deuterated_Lipids_Methods_Summary.pdf CO:SAMPLE_TYPE Bacterial cells #TREATMENT TR:TREATMENT_SUMMARY E. coli was grown in Enfors minimal media (deuterated or otherwise) with TR:TREATMENT_SUMMARY different carbon sources including glycerol, glucose, D-glycerol, and D-glucose. TR:CELL_MEDIA Enfors minimal media TR:CELL_HARVESTING 30 mL culture collected by centrifugation at 4k x g #SAMPLEPREP SP:SAMPLEPREP_SUMMARY Lipids were extracted from E coli cell pellets following the Matyash protocol SP:SAMPLEPREP_SUMMARY with slight variations described in the manuscript supplemental. Cell lysis was SP:SAMPLEPREP_SUMMARY performed with bead beating or ultrasonication. Extraction solvents were in the SP:SAMPLEPREP_SUMMARY ratio 10:3:25 MTBE:methanol:water. See publication for more detail. SP:SAMPLEPREP_PROTOCOL_FILENAME Deuterated_Lipids_Methods_Summary.pdf SP:EXTRACTION_METHOD Matyash (MTBE) varient SP:SAMPLE_RESUSPENSION 8:23:69 butanol:isopropanol:water #CHROMATOGRAPHY CH:CHROMATOGRAPHY_SUMMARY Because the columns were packed in-house, there is some variation in the total CH:CHROMATOGRAPHY_SUMMARY length (see column description below). CH:CHROMATOGRAPHY_TYPE Reversed phase CH:INSTRUMENT_NAME Thermo Dionex Ultimate 3000 RS CH:COLUMN_NAME In-house packed nano column (ID 100 μm, Kinetex 1.7 μm C18 (100 Å) CH:COLUMN_NAME [Phenomenex], 12-15 cm. CH:SOLVENT_A 60% acetonitrile/40% water; ~0.4g/L ammonium acetate CH:SOLVENT_B 90% sopropanol/10% acetonitrile; ~0.4g/L ammonium acetate CH:FLOW_GRADIENT Solvent Gradient: Time (min) 0 1 2.5 7.5 13.5 48.5 58.5 75.5 77.5 87 Solvent A CH:FLOW_GRADIENT (%) 99 99 70 65 45 30 1 1 99 99 Solvent B (%) 1 1 30 45 55 70 99 99 1 1 CH:FLOW_RATE Split flow nano-chromatography. The actual flow rate at the column is dependent CH:FLOW_RATE on a variety of factors and an accurate measurement of the flow rate is CH:FLOW_RATE impractical. The flow rate at the macro pumps were set at either 0.05 or 0.1 CH:FLOW_RATE mL/min depending on the waste line's backpressure. CH:COLUMN_TEMPERATURE room temp CH:METHODS_FILENAME Deuterated_Lipids_Methods_Summary.pdf #ANALYSIS AN:ANALYSIS_TYPE MS AN:ANALYSIS_PROTOCOL_FILE Deuterated_Lipids_Methods_Summary.pdf #MS MS:INSTRUMENT_NAME Thermo Velos Pro Orbitrap MS:INSTRUMENT_TYPE LTQ-FT MS:MS_TYPE ESI MS:ION_MODE POSITIVE MS:MS_COMMENTS Top 10 DDA acquisition: Oribitrap Full-Scan at 30k resolving power from 150-2000 MS:MS_COMMENTS m/z. Data-dependent collisional-induced dissociation (CID) fragmentation scans MS:MS_COMMENTS performed with the LTQ ion trap at 30 normalized collision energy with normal MS:MS_COMMENTS scan rate. #MS_METABOLITE_DATA MS_METABOLITE_DATA:UNITS Presence/Absence MS_METABOLITE_DATA_START Samples 50D-Gly/0_1-pos 50D-Gly/0_2-pos 50D-Gly/0_3-pos 50D-Gly/100_1-pos 50D-Gly/100_2-pos 50D-Gly/100_3-pos D-Glu/0_1-pos D-Glu/0_2-pos D-Glu/0_3-pos D-Glu/100-pos D-Gly/0_1-pos D-Gly/0_2-pos D-Gly/0_3-pos D-Gly/100_1-pos D-Gly/100_2-pos D-Gly/100_3-pos H-Glu/100-pos H-Glu/25_1-pos H-Glu/25_2-pos H-Glu/25_3-pos H-Glu/50_1-pos H-Glu/50_2-pos H-Glu/50_3-pos H-Glu/75_1-pos H-Glu/75_2-pos H-Glu/75_3-pos H-Gly/0-pos H-Gly/100_1-pos H-Gly/100_2-pos H-Gly/100_3-pos H-Gly/25-pos H-Gly/50-pos H-Gly/75-pos Factors Carbon source:H-Glucose | Percent D2O:100 | MS ionization mode:positive Carbon source:H-Glucose | Percent D2O:100 | MS ionization mode:positive Carbon source:H-Glucose | Percent D2O:100 | MS ionization mode:positive Carbon source:D-Glucose | Percent D2O:100 | MS ionization mode:positive Carbon source:D-Glucose | Percent D2O:100 | MS ionization mode:positive Carbon source:D-Glucose | Percent D2O:100 | MS ionization mode:positive Carbon source:H-Glucose | Percent D2O:25 | MS ionization mode:positive Carbon source:H-Glucose | Percent D2O:25 | MS ionization mode:positive Carbon source:H-Glucose | Percent D2O:25 | MS ionization mode:positive Carbon source:D-Glucose | Percent D2O:0 | MS ionization mode:positive Carbon source:H-Glucose | Percent D2O:50 | MS ionization mode:positive Carbon source:H-Glucose | Percent D2O:50 | MS ionization mode:positive Carbon source:H-Glucose | Percent D2O:50 | MS ionization mode:positive Carbon source:H-Glucose | Percent D2O:75 | MS ionization mode:positive Carbon source:H-Glucose | Percent D2O:75 | MS ionization mode:positive Carbon source:H-Glucose | Percent D2O:75 | MS ionization mode:positive Carbon source:D-Glycerol | Percent D2O:100 | MS ionization mode:positive Carbon source:50/50 H/D-Glycerol | Percent D2O:0 | MS ionization mode:positive Carbon source:50/50 H/D-Glycerol | Percent D2O:0 | MS ionization mode:positive Carbon source:50/50 H/D-Glycerol | Percent D2O:0 | MS ionization mode:positive Carbon source:D-Glycerol | Percent D2O:0 | MS ionization mode:positive Carbon source:D-Glycerol | Percent D2O:0 | MS ionization mode:positive Carbon source:D-Glycerol | Percent D2O:0 | MS ionization mode:positive Carbon source:50/50 H/D-Glycerol | Percent D2O:100 | MS ionization mode:positive Carbon source:50/50 H/D-Glycerol | Percent D2O:100 | MS ionization mode:positive Carbon source:50/50 H/D-Glycerol | Percent D2O:100 | MS ionization mode:positive Carbon source:H-Glycerol | Percent D2O:0 | MS ionization mode:positive Carbon source:H-Glycerol | Percent D2O:100 | MS ionization mode:positive Carbon source:H-Glycerol | Percent D2O:100 | MS ionization mode:positive Carbon source:H-Glycerol | Percent D2O:100 | MS ionization mode:positive Carbon source:H-Glycerol | Percent D2O:25 | MS ionization mode:positive Carbon source:H-Glycerol | Percent D2O:50 | MS ionization mode:positive Carbon source:H-Glycerol | Percent D2O:75 | MS ionization mode:positive PE 28:1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 PE 28:0 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 PE 29:1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 PE 29:0 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 PE 30:2 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 PE 30:1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 PE 30:0 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 PE 31:1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 PE 31:0 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 PE 32:2 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 PE 32:1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 PE 32:0 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 PE 33:2 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 PE 33:1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 PE 34:2 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 PE 34:1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 PE 34:0 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 PE 35:2 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 PE 35:1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 PE 36:2 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 PE 36:1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 PE 37:2 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 PE 37:1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 0 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 PE 38:2 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 MS_METABOLITE_DATA_END #METABOLITES METABOLITES_START metabolite_name Adduct Formula PE 28:1 [M+H]+ C33H64NO8P PE 28:0 [M+H]+ C33H66NO8P PE 29:1 [M+H]+ C34H66NO8P PE 29:0 [M+H]+ C34H68NO8P PE 30:2 [M+H]+ C35H66NO8P PE 30:1 [M+H]+ C35H68NO8P PE 30:0 [M+H]+ C35H70NO8P PE 31:1 [M+H]+ C36H70NO8P PE 31:0 [M+H]+ C36H72NO8P PE 32:2 [M+H]+ C37H70NO8P PE 32:1 [M+H]+ C37H72NO8P PE 32:0 [M+H]+ C37H74NO8P PE 33:2 [M+H]+ C38H72NO8P PE 33:1 [M+H]+ C38H74NO8P PE 34:2 [M+H]+ C39H74NO8P PE 34:1 [M+H]+ C39H76NO8P PE 34:0 [M+H]+ C39H78NO8P PE 35:2 [M+H]+ C40H76NO8P PE 35:1 [M+H]+ C40H78NO8P PE 36:2 [M+H]+ C41H78NO8P PE 36:1 [M+H]+ C41H80NO8P PE 37:2 [M+H]+ C42H80NO8P PE 37:1 [M+H]+ C42H82NO8P PE 38:2 [M+H]+ C43H82NO8P METABOLITES_END #END