#METABOLOMICS WORKBENCH jssacks_20250703_133942 DATATRACK_ID:6131 STUDY_ID:ST004081 ANALYSIS_ID:AN006758 PROJECT_ID:PR002562 VERSION 1 CREATED_ON July 29, 2025, 11:44 am #PROJECT PR:PROJECT_TITLE Remodeling of Prochlorococcus metabolism during viral infection PR:PROJECT_TYPE Marine Microbial Metabolomics PR:PROJECT_SUMMARY The marine cyanobacterium Prochlorococcus is the most abundant photoautotroph in PR:PROJECT_SUMMARY the world and is a major contributor to oceanic primary productivity. Viruses PR:PROJECT_SUMMARY are important controls on Prochlorococcus populations with up to 10% of PR:PROJECT_SUMMARY Prochlorococcus cells infected. During infection, viruses remodel their host’s PR:PROJECT_SUMMARY metabolic machinery, creating metabolically distinct cells, termed virocells. PR:PROJECT_SUMMARY However, the specific consequences of viral infection on Prochlorococcus PR:PROJECT_SUMMARY metabolism remain poorly understood. Here, we characterize the infection of PR:PROJECT_SUMMARY non-axenic cultures of Prochlorococcus MED4 by the T7-like virus P-SSP7 using a PR:PROJECT_SUMMARY combination of metabolomics, transcriptomics, and population modeling PR:PROJECT_SUMMARY approaches. P-SSP7 infection dramatically altered the metabolome of PR:PROJECT_SUMMARY Prochlorococcus with 25% of metabolites showing differential abundance. Infected PR:PROJECT_SUMMARY cells exhibited decreased carbon fixation and the draw down of intracellular PR:PROJECT_SUMMARY stores of carbon structures and energy such as glycogen and the osmolytes PR:PROJECT_SUMMARY sucrose and aspartic acid. In contrast, another osmolyte, glucosylglycerol, was PR:PROJECT_SUMMARY accumulated in high concentrations and came to dominate the virocell metabolome. PR:PROJECT_SUMMARY Infected cells also experienced pseudocobalamin (pB12) stress, as evidenced by PR:PROJECT_SUMMARY reduced pB12 concentrations, increased expression of genes to synthesize pB12, PR:PROJECT_SUMMARY and depletion of metabolites whose synthesis relies on pB12 including PR:PROJECT_SUMMARY S-adnosylmethionine (SAM) and the antioxidant glutathione. Collectively, our PR:PROJECT_SUMMARY results suggest that the observed metabolic remodeling is driven by the demand PR:PROJECT_SUMMARY for carbon and energy for virion production and infection-induced oxidative PR:PROJECT_SUMMARY stress. Viral infection changes the substrate and vitamin pools provided by PR:PROJECT_SUMMARY Prochlorococcus to the microbial community, potentially altering the speciation PR:PROJECT_SUMMARY and flux of organic matter in marine systems and acting as a selective force on PR:PROJECT_SUMMARY microbial community composition and function. PR:INSTITUTE University of Washington PR:DEPARTMENT School of Oceanography PR:LABORATORY Ingalls Lab PR:LAST_NAME Sacks PR:FIRST_NAME Joshua PR:ADDRESS Box 355351 School of Oceanography University of Washington, Seattle WA 98115 PR:EMAIL jssacks@uw.edu PR:PHONE 206 221 6750 PR:FUNDING_SOURCE Simons Foundation PR:PUBLICATIONS Sacks et al. in prep #STUDY ST:STUDY_TITLE Remodeling of Prochlorococcus metabolism during viral infection ST:STUDY_TYPE Marine Microbial Metabolomics ST:STUDY_SUMMARY The marine cyanobacterium Prochlorococcus is the most abundant photoautotroph in ST:STUDY_SUMMARY the world and is a major contributor to oceanic primary productivity. Viruses ST:STUDY_SUMMARY are important controls on Prochlorococcus populations with up to 10% of ST:STUDY_SUMMARY Prochlorococcus cells infected. During infection, viruses remodel their host’s ST:STUDY_SUMMARY metabolic machinery, creating metabolically distinct cells, termed virocells. ST:STUDY_SUMMARY However, the specific consequences of viral infection on Prochlorococcus ST:STUDY_SUMMARY metabolism remain poorly understood. Here, we characterize the infection of ST:STUDY_SUMMARY non-axenic cultures of Prochlorococcus MED4 by the T7-like virus P-SSP7 using a ST:STUDY_SUMMARY combination of metabolomics, transcriptomics, and population modeling ST:STUDY_SUMMARY approaches. Three biological replicates (Replicates A, B, and C) of ST:STUDY_SUMMARY Prochlorococcus MED4 and associated heterotrophic bacteria were inoculated with ST:STUDY_SUMMARY 3 different levels of the virus P-SSP7 at the beginning of the experiment. The ST:STUDY_SUMMARY treatments were as follows: Control (C), no virus added; Low Virus (LV), viruses ST:STUDY_SUMMARY added in a 1:0.001 host:virus ratio; and High Virus (HV), viruses add in a 1:0.7 ST:STUDY_SUMMARY host:virus ratio. The experiment was run for 48 hours with metabolomics samples ST:STUDY_SUMMARY collected at timepoints of 0, 12, 24, 36, and 48 hours for the LV and HV ST:STUDY_SUMMARY treatments and 0, 6, 12, 18, 24, 30, 36, 42, 48 hours for the C treatment. ST:STUDY_SUMMARY P-SSP7 infection dramatically altered the metabolome of Prochlorococcus with 25% ST:STUDY_SUMMARY of metabolites showing differential abundance. Infected cells exhibited ST:STUDY_SUMMARY decreased carbon fixation and the draw down of intracellular stores of carbon ST:STUDY_SUMMARY structures and energy such as glycogen and the osmolytes sucrose and aspartic ST:STUDY_SUMMARY acid. In contrast, another osmolyte, glucosylglycerol, was accumulated in high ST:STUDY_SUMMARY concentrations and came to dominate the virocell metabolome. Infected cells also ST:STUDY_SUMMARY experienced pseudocobalamin (pB12) stress, as evidenced by reduced pB12 ST:STUDY_SUMMARY concentrations, increased expression of genes to synthesize pB12, and depletion ST:STUDY_SUMMARY of metabolites whose synthesis relies on pB12 including S-adnosylmethionine ST:STUDY_SUMMARY (SAM) and the antioxidant glutathione. Collectively, our results suggest that ST:STUDY_SUMMARY the observed metabolic remodeling is driven by the demand for carbon and energy ST:STUDY_SUMMARY for virion production and infection-induced oxidative stress. Viral infection ST:STUDY_SUMMARY changes the substrate and vitamin pools provided by Prochlorococcus to the ST:STUDY_SUMMARY microbial community, potentially altering the speciation and flux of organic ST:STUDY_SUMMARY matter in marine systems and acting as a selective force on microbial community ST:STUDY_SUMMARY composition and function. ST:INSTITUTE University of Washington ST:DEPARTMENT School of Oceanography ST:LABORATORY Ingalls Lab ST:LAST_NAME Sacks ST:FIRST_NAME Joshua ST:ADDRESS Box 355351 School of Oceanography University of Washington, Seattle WA 98115 ST:EMAIL jssacks@uw.edu ST:PHONE 4074090052 #SUBJECT SU:SUBJECT_TYPE Bacteria SU:SUBJECT_SPECIES Prochlorococcus marinus SU:TAXONOMY_ID 59919 SU:GENOTYPE_STRAIN MED4 SU:GENDER Not applicable #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 - A_C_0 Sample source:Marine Microbe Culture | Treatment:C | Timepoint_h:0 Replicate=A; Volume_mL=50; RAW_FILE_NAME(HILIC_SampID)=200929_Smp_A_1C_T0; RAW_FILE_NAME(RP_SampID)=201006_Smp_A_1C_T0; RAW_FILE_NAME(Vitamin_SampID)=230511_Smp_A_1C_T0 SUBJECT_SAMPLE_FACTORS - A_C_12 Sample source:Marine Microbe Culture | Treatment:C | Timepoint_h:12 Replicate=A; Volume_mL=50; RAW_FILE_NAME(HILIC_SampID)=200929_Smp_A_1C_T12; RAW_FILE_NAME(RP_SampID)=201006_Smp_A_1C_T12; RAW_FILE_NAME(Vitamin_SampID)=230511_Smp_A_1C_T12 SUBJECT_SAMPLE_FACTORS - A_C_18 Sample source:Marine Microbe Culture | Treatment:C | Timepoint_h:18 Replicate=A; Volume_mL=50; RAW_FILE_NAME(HILIC_SampID)=200929_Smp_A_1C_T18; RAW_FILE_NAME(RP_SampID)=201006_Smp_A_1C_T18; RAW_FILE_NAME(Vitamin_SampID)=230511_Smp_A_1C_T18 SUBJECT_SAMPLE_FACTORS - A_C_24 Sample source:Marine Microbe Culture | Treatment:C | Timepoint_h:24 Replicate=A; Volume_mL=100; RAW_FILE_NAME(HILIC_SampID)=200929_Smp_A_1C_T24; RAW_FILE_NAME(RP_SampID)=201006_Smp_A_1C_T24; RAW_FILE_NAME(Vitamin_SampID)=230511_Smp_A_1C_T24 SUBJECT_SAMPLE_FACTORS - A_C_30 Sample source:Marine Microbe Culture | Treatment:C | Timepoint_h:30 Replicate=A; Volume_mL=50; RAW_FILE_NAME(HILIC_SampID)=200929_Smp_A_1C_T30; RAW_FILE_NAME(RP_SampID)=201006_Smp_A_1C_T30; RAW_FILE_NAME(Vitamin_SampID)=230511_Smp_A_1C_T30 SUBJECT_SAMPLE_FACTORS - A_C_36 Sample source:Marine Microbe Culture | Treatment:C | Timepoint_h:36 Replicate=A; Volume_mL=300; RAW_FILE_NAME(HILIC_SampID)=200929_Smp_A_1C_T36; RAW_FILE_NAME(RP_SampID)=201006_Smp_A_1C_T36; RAW_FILE_NAME(Vitamin_SampID)=230511_Smp_A_1C_T36 SUBJECT_SAMPLE_FACTORS - A_C_42 Sample source:Marine Microbe Culture | Treatment:C | Timepoint_h:42 Replicate=A; Volume_mL=50; RAW_FILE_NAME(HILIC_SampID)=200929_Smp_A_1C_T42; RAW_FILE_NAME(RP_SampID)=201006_Smp_A_1C_T42; RAW_FILE_NAME(Vitamin_SampID)=230511_Smp_A_1C_T42 SUBJECT_SAMPLE_FACTORS - A_C_48 Sample source:Marine Microbe Culture | Treatment:C | Timepoint_h:48 Replicate=A; Volume_mL=100; RAW_FILE_NAME(HILIC_SampID)=200929_Smp_A_1C_T48; RAW_FILE_NAME(RP_SampID)=201006_Smp_A_1C_T48; RAW_FILE_NAME(Vitamin_SampID)=230511_Smp_A_1C_T48 SUBJECT_SAMPLE_FACTORS - A_C_6 Sample source:Marine Microbe Culture | Treatment:C | Timepoint_h:6 Replicate=A; Volume_mL=50; RAW_FILE_NAME(HILIC_SampID)=200929_Smp_A_1C_T6; RAW_FILE_NAME(RP_SampID)=201006_Smp_A_1C_T6; RAW_FILE_NAME(Vitamin_SampID)=230511_Smp_A_1C_T6 SUBJECT_SAMPLE_FACTORS - A_LV_0 Sample source:Marine Microbe Culture | Treatment:LV | Timepoint_h:0 Replicate=A; Volume_mL=50; RAW_FILE_NAME(HILIC_SampID)=200929_Smp_A_3LV_T0; RAW_FILE_NAME(RP_SampID)=201006_Smp_A_3LV_T0; RAW_FILE_NAME(Vitamin_SampID)=230511_Smp_A_3LV_T0 SUBJECT_SAMPLE_FACTORS - A_LV_12 Sample source:Marine Microbe Culture | Treatment:LV | Timepoint_h:12 Replicate=A; Volume_mL=50; RAW_FILE_NAME(HILIC_SampID)=200929_Smp_A_3LV_T12; RAW_FILE_NAME(RP_SampID)=201006_Smp_A_3LV_T12; RAW_FILE_NAME(Vitamin_SampID)=230511_Smp_A_3LV_T12 SUBJECT_SAMPLE_FACTORS - A_LV_24 Sample source:Marine Microbe Culture | Treatment:LV | Timepoint_h:24 Replicate=A; Volume_mL=100; RAW_FILE_NAME(HILIC_SampID)=200929_Smp_A_3LV_T24; RAW_FILE_NAME(RP_SampID)=201006_Smp_A_3LV_T24; RAW_FILE_NAME(Vitamin_SampID)=230511_Smp_A_3LV_T24 SUBJECT_SAMPLE_FACTORS - A_LV_36 Sample source:Marine Microbe Culture | Treatment:LV | Timepoint_h:36 Replicate=A; Volume_mL=300; RAW_FILE_NAME(HILIC_SampID)=200929_Smp_A_3LV_T36; RAW_FILE_NAME(RP_SampID)=201006_Smp_A_3LV_T36; RAW_FILE_NAME(Vitamin_SampID)=230511_Smp_A_3LV_T36 SUBJECT_SAMPLE_FACTORS - A_LV_48 Sample source:Marine Microbe Culture | Treatment:LV | Timepoint_h:48 Replicate=A; Volume_mL=100; RAW_FILE_NAME(HILIC_SampID)=200929_Smp_A_3LV_T48; RAW_FILE_NAME(RP_SampID)=201006_Smp_A_3LV_T48; RAW_FILE_NAME(Vitamin_SampID)=230511_Smp_A_3LV_T48 SUBJECT_SAMPLE_FACTORS - A_HV_0 Sample source:Marine Microbe Culture | Treatment:HV | Timepoint_h:0 Replicate=A; Volume_mL=50; RAW_FILE_NAME(HILIC_SampID)=200929_Smp_A_6HV_T0; RAW_FILE_NAME(RP_SampID)=201006_Smp_A_6HV_T0; RAW_FILE_NAME(Vitamin_SampID)=230511_Smp_A_6HV_T0 SUBJECT_SAMPLE_FACTORS - A_HV_12 Sample source:Marine Microbe Culture | Treatment:HV | Timepoint_h:12 Replicate=A; Volume_mL=50; RAW_FILE_NAME(HILIC_SampID)=200929_Smp_A_6HV_T12; RAW_FILE_NAME(RP_SampID)=201006_Smp_A_6HV_T12; RAW_FILE_NAME(Vitamin_SampID)=230511_Smp_A_6HV_T12 SUBJECT_SAMPLE_FACTORS - A_HV_24 Sample source:Marine Microbe Culture | Treatment:HV | Timepoint_h:24 Replicate=A; Volume_mL=100; RAW_FILE_NAME(HILIC_SampID)=200929_Smp_A_6HV_T24; RAW_FILE_NAME(RP_SampID)=201006_Smp_A_6HV_T24; RAW_FILE_NAME(Vitamin_SampID)=230511_Smp_A_6HV_T24 SUBJECT_SAMPLE_FACTORS - A_HV_36 Sample source:Marine Microbe Culture | Treatment:HV | Timepoint_h:36 Replicate=A; Volume_mL=300; RAW_FILE_NAME(HILIC_SampID)=200929_Smp_A_6HV_T36; RAW_FILE_NAME(RP_SampID)=201006_Smp_A_6HV_T36; RAW_FILE_NAME(Vitamin_SampID)=230511_Smp_A_6HV_T36 SUBJECT_SAMPLE_FACTORS - A_HV_48 Sample source:Marine Microbe Culture | Treatment:HV | Timepoint_h:48 Replicate=A; Volume_mL=100; RAW_FILE_NAME(HILIC_SampID)=200929_Smp_A_6HV_T48; RAW_FILE_NAME(RP_SampID)=201006_Smp_A_6HV_T48; RAW_FILE_NAME(Vitamin_SampID)=230511_Smp_A_6HV_T48 SUBJECT_SAMPLE_FACTORS - B_C_0 Sample source:Marine Microbe Culture | Treatment:C | Timepoint_h:0 Replicate=B; Volume_mL=50; RAW_FILE_NAME(HILIC_SampID)=200929_Smp_B_1C_T0; RAW_FILE_NAME(RP_SampID)=201006_Smp_B_1C_T0; RAW_FILE_NAME(Vitamin_SampID)=230511_Smp_B_1C_T0 SUBJECT_SAMPLE_FACTORS - B_C_12 Sample source:Marine Microbe Culture | Treatment:C | Timepoint_h:12 Replicate=B; Volume_mL=50; RAW_FILE_NAME(HILIC_SampID)=200929_Smp_B_1C_T12; RAW_FILE_NAME(RP_SampID)=201006_Smp_B_1C_T12; RAW_FILE_NAME(Vitamin_SampID)=230511_Smp_B_1C_T12 SUBJECT_SAMPLE_FACTORS - B_C_18 Sample source:Marine Microbe Culture | Treatment:C | Timepoint_h:18 Replicate=B; Volume_mL=50; RAW_FILE_NAME(HILIC_SampID)=200929_Smp_B_1C_T18; RAW_FILE_NAME(RP_SampID)=201006_Smp_B_1C_T18; RAW_FILE_NAME(Vitamin_SampID)=230511_Smp_B_1C_T18 SUBJECT_SAMPLE_FACTORS - B_C_24 Sample source:Marine Microbe Culture | Treatment:C | Timepoint_h:24 Replicate=B; Volume_mL=100; RAW_FILE_NAME(HILIC_SampID)=200929_Smp_B_1C_T24; RAW_FILE_NAME(RP_SampID)=201006_Smp_B_1C_T24; RAW_FILE_NAME(Vitamin_SampID)=230511_Smp_B_1C_T24 SUBJECT_SAMPLE_FACTORS - B_C_30 Sample source:Marine Microbe Culture | Treatment:C | Timepoint_h:30 Replicate=B; Volume_mL=50; RAW_FILE_NAME(HILIC_SampID)=200929_Smp_B_1C_T30; RAW_FILE_NAME(RP_SampID)=201006_Smp_B_1C_T30; RAW_FILE_NAME(Vitamin_SampID)=230511_Smp_B_1C_T30 SUBJECT_SAMPLE_FACTORS - B_C_36 Sample source:Marine Microbe Culture | Treatment:C | Timepoint_h:36 Replicate=B; Volume_mL=300; RAW_FILE_NAME(HILIC_SampID)=200929_Smp_B_1C_T36; RAW_FILE_NAME(RP_SampID)=201006_Smp_B_1C_T36; RAW_FILE_NAME(Vitamin_SampID)=230511_Smp_B_1C_T36 SUBJECT_SAMPLE_FACTORS - B_C_42 Sample source:Marine Microbe Culture | Treatment:C | Timepoint_h:42 Replicate=B; Volume_mL=50; RAW_FILE_NAME(HILIC_SampID)=200929_Smp_B_1C_T42; RAW_FILE_NAME(RP_SampID)=201006_Smp_B_1C_T42; RAW_FILE_NAME(Vitamin_SampID)=230511_Smp_B_1C_T42 SUBJECT_SAMPLE_FACTORS - B_C_48 Sample source:Marine Microbe Culture | Treatment:C | Timepoint_h:48 Replicate=B; Volume_mL=100; RAW_FILE_NAME(HILIC_SampID)=200929_Smp_B_1C_T48; RAW_FILE_NAME(RP_SampID)=201006_Smp_B_1C_T48; RAW_FILE_NAME(Vitamin_SampID)=230511_Smp_B_1C_T48 SUBJECT_SAMPLE_FACTORS - B_C_6 Sample source:Marine Microbe Culture | Treatment:C | Timepoint_h:6 Replicate=B; Volume_mL=50; RAW_FILE_NAME(HILIC_SampID)=200929_Smp_B_1C_T6; RAW_FILE_NAME(RP_SampID)=201006_Smp_B_1C_T6; RAW_FILE_NAME(Vitamin_SampID)=230511_Smp_B_1C_T6 SUBJECT_SAMPLE_FACTORS - B_LV_0 Sample source:Marine Microbe Culture | Treatment:LV | Timepoint_h:0 Replicate=B; Volume_mL=50; RAW_FILE_NAME(HILIC_SampID)=200929_Smp_B_3LV_T0; RAW_FILE_NAME(RP_SampID)=201006_Smp_B_3LV_T0; RAW_FILE_NAME(Vitamin_SampID)=230511_Smp_B_3LV_T0 SUBJECT_SAMPLE_FACTORS - B_LV_12 Sample source:Marine Microbe Culture | Treatment:LV | Timepoint_h:12 Replicate=B; Volume_mL=50; RAW_FILE_NAME(HILIC_SampID)=200929_Smp_B_3LV_T12; RAW_FILE_NAME(RP_SampID)=201006_Smp_B_3LV_T12; RAW_FILE_NAME(Vitamin_SampID)=230511_Smp_B_3LV_T12 SUBJECT_SAMPLE_FACTORS - B_LV_24 Sample source:Marine Microbe Culture | Treatment:LV | Timepoint_h:24 Replicate=B; Volume_mL=100; RAW_FILE_NAME(HILIC_SampID)=200929_Smp_B_3LV_T24; RAW_FILE_NAME(RP_SampID)=201006_Smp_B_3LV_T24; RAW_FILE_NAME(Vitamin_SampID)=230511_Smp_B_3LV_T24 SUBJECT_SAMPLE_FACTORS - B_LV_36 Sample source:Marine Microbe Culture | Treatment:LV | Timepoint_h:36 Replicate=B; Volume_mL=300; RAW_FILE_NAME(HILIC_SampID)=200929_Smp_B_3LV_T36; RAW_FILE_NAME(RP_SampID)=201006_Smp_B_3LV_T36; RAW_FILE_NAME(Vitamin_SampID)=230511_Smp_B_3LV_T36 SUBJECT_SAMPLE_FACTORS - B_LV_48 Sample source:Marine Microbe Culture | Treatment:LV | Timepoint_h:48 Replicate=B; Volume_mL=100; RAW_FILE_NAME(HILIC_SampID)=200929_Smp_B_3LV_T48; RAW_FILE_NAME(RP_SampID)=201006_Smp_B_3LV_T48; RAW_FILE_NAME(Vitamin_SampID)=230511_Smp_B_3LV_T48 SUBJECT_SAMPLE_FACTORS - B_HV_0 Sample source:Marine Microbe Culture | Treatment:HV | Timepoint_h:0 Replicate=B; Volume_mL=50; RAW_FILE_NAME(HILIC_SampID)=200929_Smp_B_6HV_T0; RAW_FILE_NAME(RP_SampID)=201006_Smp_B_6HV_T0; RAW_FILE_NAME(Vitamin_SampID)=230511_Smp_B_6HV_T0 SUBJECT_SAMPLE_FACTORS - B_HV_12 Sample source:Marine Microbe Culture | Treatment:HV | Timepoint_h:12 Replicate=B; Volume_mL=50; RAW_FILE_NAME(HILIC_SampID)=200929_Smp_B_6HV_T12; RAW_FILE_NAME(RP_SampID)=201006_Smp_B_6HV_T12; RAW_FILE_NAME(Vitamin_SampID)=230511_Smp_B_6HV_T12 SUBJECT_SAMPLE_FACTORS - B_HV_24 Sample source:Marine Microbe Culture | Treatment:HV | Timepoint_h:24 Replicate=B; Volume_mL=100; RAW_FILE_NAME(HILIC_SampID)=200929_Smp_B_6HV_T24; RAW_FILE_NAME(RP_SampID)=201006_Smp_B_6HV_T24; RAW_FILE_NAME(Vitamin_SampID)=230511_Smp_B_6HV_T24 SUBJECT_SAMPLE_FACTORS - B_HV_36 Sample source:Marine Microbe Culture | Treatment:HV | Timepoint_h:36 Replicate=B; Volume_mL=270; RAW_FILE_NAME(HILIC_SampID)=200929_Smp_B_6HV_T36; RAW_FILE_NAME(RP_SampID)=201006_Smp_B_6HV_T36; RAW_FILE_NAME(Vitamin_SampID)=230511_Smp_B_6HV_T36 SUBJECT_SAMPLE_FACTORS - B_HV_48 Sample source:Marine Microbe Culture | Treatment:HV | Timepoint_h:48 Replicate=B; Volume_mL=100; RAW_FILE_NAME(HILIC_SampID)=200929_Smp_B_6HV_T48; RAW_FILE_NAME(RP_SampID)=201006_Smp_B_6HV_T48; RAW_FILE_NAME(Vitamin_SampID)=230511_Smp_B_6HV_T48 SUBJECT_SAMPLE_FACTORS - C_C_0 Sample source:Marine Microbe Culture | Treatment:C | Timepoint_h:0 Replicate=C; Volume_mL=50; RAW_FILE_NAME(HILIC_SampID)=200929_Smp_C_1C_T0; RAW_FILE_NAME(RP_SampID)=201006_Smp_C_1C_T0; RAW_FILE_NAME(Vitamin_SampID)=230511_Smp_C_1C_T0 SUBJECT_SAMPLE_FACTORS - C_C_12 Sample source:Marine Microbe Culture | Treatment:C | Timepoint_h:12 Replicate=C; Volume_mL=50; RAW_FILE_NAME(HILIC_SampID)=200929_Smp_C_1C_T12; RAW_FILE_NAME(RP_SampID)=201006_Smp_C_1C_T12; RAW_FILE_NAME(Vitamin_SampID)=230511_Smp_C_1C_T12 SUBJECT_SAMPLE_FACTORS - C_C_18 Sample source:Marine Microbe Culture | Treatment:C | Timepoint_h:18 Replicate=C; Volume_mL=50; RAW_FILE_NAME(HILIC_SampID)=200929_Smp_C_1C_T18; RAW_FILE_NAME(RP_SampID)=201006_Smp_C_1C_T18; RAW_FILE_NAME(Vitamin_SampID)=230511_Smp_C_1C_T18 SUBJECT_SAMPLE_FACTORS - C_C_24 Sample source:Marine Microbe Culture | Treatment:C | Timepoint_h:24 Replicate=C; Volume_mL=100; RAW_FILE_NAME(HILIC_SampID)=200929_Smp_C_1C_T24; RAW_FILE_NAME(RP_SampID)=201006_Smp_C_1C_T24; RAW_FILE_NAME(Vitamin_SampID)=230511_Smp_C_1C_T24 SUBJECT_SAMPLE_FACTORS - C_C_30 Sample source:Marine Microbe Culture | Treatment:C | Timepoint_h:30 Replicate=C; Volume_mL=50; RAW_FILE_NAME(HILIC_SampID)=200929_Smp_C_1C_T30; RAW_FILE_NAME(RP_SampID)=201006_Smp_C_1C_T30; RAW_FILE_NAME(Vitamin_SampID)=230511_Smp_C_1C_T30 SUBJECT_SAMPLE_FACTORS - C_C_36 Sample source:Marine Microbe Culture | Treatment:C | Timepoint_h:36 Replicate=C; Volume_mL=100; RAW_FILE_NAME(HILIC_SampID)=200929_Smp_C_1C_T36; RAW_FILE_NAME(RP_SampID)=201006_Smp_C_1C_T36; RAW_FILE_NAME(Vitamin_SampID)=230511_Smp_C_1C_T36 SUBJECT_SAMPLE_FACTORS - C_C_42 Sample source:Marine Microbe Culture | Treatment:C | Timepoint_h:42 Replicate=C; Volume_mL=50; RAW_FILE_NAME(HILIC_SampID)=200929_Smp_C_1C_T42; RAW_FILE_NAME(RP_SampID)=201006_Smp_C_1C_T42; RAW_FILE_NAME(Vitamin_SampID)=230511_Smp_C_1C_T42 SUBJECT_SAMPLE_FACTORS - C_C_48 Sample source:Marine Microbe Culture | Treatment:C | Timepoint_h:48 Replicate=C; Volume_mL=100; RAW_FILE_NAME(HILIC_SampID)=200929_Smp_C_1C_T48; RAW_FILE_NAME(RP_SampID)=201006_Smp_C_1C_T48; RAW_FILE_NAME(Vitamin_SampID)=230511_Smp_C_1C_T48 SUBJECT_SAMPLE_FACTORS - C_C_6 Sample source:Marine Microbe Culture | Treatment:C | Timepoint_h:6 Replicate=C; Volume_mL=50; RAW_FILE_NAME(HILIC_SampID)=200929_Smp_C_1C_T6; RAW_FILE_NAME(RP_SampID)=201006_Smp_C_1C_T6; RAW_FILE_NAME(Vitamin_SampID)=230511_Smp_C_1C_T6 SUBJECT_SAMPLE_FACTORS - C_LV_0 Sample source:Marine Microbe Culture | Treatment:LV | Timepoint_h:0 Replicate=C; Volume_mL=50; RAW_FILE_NAME(HILIC_SampID)=200929_Smp_C_3LV_T0; RAW_FILE_NAME(RP_SampID)=201006_Smp_C_3LV_T0; RAW_FILE_NAME(Vitamin_SampID)=230511_Smp_C_3LV_T0 SUBJECT_SAMPLE_FACTORS - C_LV_12 Sample source:Marine Microbe Culture | Treatment:LV | Timepoint_h:12 Replicate=C; Volume_mL=50; RAW_FILE_NAME(HILIC_SampID)=200929_Smp_C_3LV_T12; RAW_FILE_NAME(RP_SampID)=201006_Smp_C_3LV_T12; RAW_FILE_NAME(Vitamin_SampID)=230511_Smp_C_3LV_T12 SUBJECT_SAMPLE_FACTORS - C_LV_24 Sample source:Marine Microbe Culture | Treatment:LV | Timepoint_h:24 Replicate=C; Volume_mL=100; RAW_FILE_NAME(HILIC_SampID)=200929_Smp_C_3LV_T24; RAW_FILE_NAME(RP_SampID)=201006_Smp_C_3LV_T24; RAW_FILE_NAME(Vitamin_SampID)=230511_Smp_C_3LV_T24 SUBJECT_SAMPLE_FACTORS - C_LV_36 Sample source:Marine Microbe Culture | Treatment:LV | Timepoint_h:36 Replicate=C; Volume_mL=100; RAW_FILE_NAME(HILIC_SampID)=200929_Smp_C_3LV_T36; RAW_FILE_NAME(RP_SampID)=201006_Smp_C_3LV_T36; RAW_FILE_NAME(Vitamin_SampID)=230511_Smp_C_3LV_T36 SUBJECT_SAMPLE_FACTORS - C_LV_48 Sample source:Marine Microbe Culture | Treatment:LV | Timepoint_h:48 Replicate=C; Volume_mL=100; RAW_FILE_NAME(HILIC_SampID)=200929_Smp_C_3LV_T48; RAW_FILE_NAME(RP_SampID)=201006_Smp_C_3LV_T48; RAW_FILE_NAME(Vitamin_SampID)=230511_Smp_C_3LV_T48 SUBJECT_SAMPLE_FACTORS - C_HV_0 Sample source:Marine Microbe Culture | Treatment:HV | Timepoint_h:0 Replicate=C; Volume_mL=50; RAW_FILE_NAME(HILIC_SampID)=200929_Smp_C_6HV_T0; RAW_FILE_NAME(RP_SampID)=201006_Smp_C_6HV_T0; RAW_FILE_NAME(Vitamin_SampID)=230511_Smp_C_6HV_T0 SUBJECT_SAMPLE_FACTORS - C_HV_12 Sample source:Marine Microbe Culture | Treatment:HV | Timepoint_h:12 Replicate=C; Volume_mL=50; RAW_FILE_NAME(HILIC_SampID)=200929_Smp_C_6HV_T12; RAW_FILE_NAME(RP_SampID)=201006_Smp_C_6HV_T12; RAW_FILE_NAME(Vitamin_SampID)=230511_Smp_C_6HV_T12 SUBJECT_SAMPLE_FACTORS - C_HV_24 Sample source:Marine Microbe Culture | Treatment:HV | Timepoint_h:24 Replicate=C; Volume_mL=100; RAW_FILE_NAME(HILIC_SampID)=200929_Smp_C_6HV_T24; RAW_FILE_NAME(RP_SampID)=201006_Smp_C_6HV_T24; RAW_FILE_NAME(Vitamin_SampID)=230511_Smp_C_6HV_T24 SUBJECT_SAMPLE_FACTORS - C_HV_36 Sample source:Marine Microbe Culture | Treatment:HV | Timepoint_h:36 Replicate=C; Volume_mL=100; RAW_FILE_NAME(HILIC_SampID)=200929_Smp_C_6HV_T36; RAW_FILE_NAME(RP_SampID)=201006_Smp_C_6HV_T36; RAW_FILE_NAME(Vitamin_SampID)=230511_Smp_C_6HV_T36 SUBJECT_SAMPLE_FACTORS - C_HV_48 Sample source:Marine Microbe Culture | Treatment:HV | Timepoint_h:48 Replicate=C; Volume_mL=100; RAW_FILE_NAME(HILIC_SampID)=200929_Smp_C_6HV_T48; RAW_FILE_NAME(RP_SampID)=201006_Smp_C_6HV_T48; RAW_FILE_NAME(Vitamin_SampID)=230511_Smp_C_6HV_T48 #COLLECTION CO:COLLECTION_SUMMARY Particulate metabolites were sampled using gentle vacuum filtration onto 47 mm CO:COLLECTION_SUMMARY 0.2-mm polytetrafluoroethylene (PTFE) omnipore filters (Omnipore Membrane CO:COLLECTION_SUMMARY Filters, Merck Millipore Ltd). Glass and polysulfone filtration rigs were used. CO:COLLECTION_SUMMARY Glass rigs were combusted at 450 ˚C for 4 hours before and between experiments. CO:COLLECTION_SUMMARY The polysulfone filtration setups were soaked in 10% HCl for 24 hours and triple CO:COLLECTION_SUMMARY rinsed with MiliQ water before and between experiments. In between sampling CO:COLLECTION_SUMMARY different treatments, timepoints, and biological replicates, the filtration CO:COLLECTION_SUMMARY setups were triple rinsed with MiliQ water, rinsed with 10% HCl, and then triple CO:COLLECTION_SUMMARY rinsed again with MiliQ water. After filtration, samples were wrapped in CO:COLLECTION_SUMMARY combusted foil and flash frozen in liquid nitrogen before storage at -80˚C CO:COLLECTION_SUMMARY until analysis. Sample volumes ranged from 50–300 mL to account for variations CO:COLLECTION_SUMMARY in biomass throughout the experiment and filtration times ranged from 5–15 CO:COLLECTION_SUMMARY minutes. CO:SAMPLE_TYPE Bacterial cells CO:STORAGE_CONDITIONS -80℃ #TREATMENT TR:TREATMENT_SUMMARY Three biological replicates (Replicates A, B, and C) of Prochlorococcus MED4 and TR:TREATMENT_SUMMARY associated heterotrophic bacteria were inoculated with 3 different levels of the TR:TREATMENT_SUMMARY virus P-SSP7 at the beginning of the experiment. The treatments were as follows: TR:TREATMENT_SUMMARY Control (C), no virus added; Low Virus (LV), viruses added in a 1:0.001 TR:TREATMENT_SUMMARY host:virus ratio; and High Virus (HV), viruses add in a 1:0.7 host:virus ratio. TR:TREATMENT_SUMMARY The experiment was run for 48 hours with samples collected at timepoints TR:TREATMENT_SUMMARY (timepoint_h) of 0, 12, 24, 36, and 48 hours for the LV and HV treatments and 0, TR:TREATMENT_SUMMARY 6, 12, 18, 24, 30, 36, 42, 48 hours for the C treatment. #SAMPLEPREP SP:SAMPLEPREP_SUMMARY Each sample was extracted using a modified Bligh-Dyer extraction. Briefly, SP:SAMPLEPREP_SUMMARY filters were cut up and put into 15 mL teflon centrifuge tubes containing a SP:SAMPLEPREP_SUMMARY mixture of 100 µm and 400 µm silica beads. Heavy isotope-labeled internal SP:SAMPLEPREP_SUMMARY standards were added along with ~2 mL of cold aqueous solvent (50:50 SP:SAMPLEPREP_SUMMARY methanol:water) and ~3 mL of cold organic solvent (dichloromethane). The samples SP:SAMPLEPREP_SUMMARY were shaken on a FastPrep-24 Homogenizer for 30 seconds and chilled in a -20 °C SP:SAMPLEPREP_SUMMARY freezer repeatedly for three cycles of bead-beating and a total of 30 minutes of SP:SAMPLEPREP_SUMMARY chilling. The organic and aqueous layers were separated by spinning samples in a SP:SAMPLEPREP_SUMMARY centrifuge at 4,300 rpm for 2 minutes at 4 °C. The aqueous layer was removed to SP:SAMPLEPREP_SUMMARY a new glass centrifuge tube. The remaining organic fraction was rinsed three SP:SAMPLEPREP_SUMMARY more times with additions of 1 to 2 mL of 50:50 methanol:water. All aqueous SP:SAMPLEPREP_SUMMARY rinses were combined for each sample and dried down under N2 gas. The remaining SP:SAMPLEPREP_SUMMARY organic layer was transferred into a clean glass centrifuge tube and the SP:SAMPLEPREP_SUMMARY remaining bead beating tube was rinsed two more times with cold organic solvent. SP:SAMPLEPREP_SUMMARY The combined organic rinses were centrifuged, transferred to a new tube, and SP:SAMPLEPREP_SUMMARY dried under N2 gas. Dried aqueous fractions were re-dissolved in 380 µL of SP:SAMPLEPREP_SUMMARY water. Dried organic fractions were re-dissolved in 380 µL of 1:1 SP:SAMPLEPREP_SUMMARY water:acetonitrile. 20 µL of isotope-labeled injection standards in water were SP:SAMPLEPREP_SUMMARY added to both fractions. Blank filters were extracted alongside samples as SP:SAMPLEPREP_SUMMARY methodological blanks. SP:PROCESSING_STORAGE_CONDITIONS On ice SP:EXTRACT_STORAGE -80℃ #CHROMATOGRAPHY CH:CHROMATOGRAPHY_TYPE Reversed phase CH:INSTRUMENT_NAME Waters Acquity CH:COLUMN_NAME Waters ACQUITY UPLC HSS CN (100 x 2.1mm,1.8um) CH:SOLVENT_A 100% water; 0.1% formic acid; 20mM ammonium formate CH:SOLVENT_B 100% acetonitrile CH:FLOW_GRADIENT The column was held at 2% B for 0.5 minutes, ramped to 25% B for 7.8 minutes, CH:FLOW_GRADIENT ramped to 95% B, held at 95% B for 1 minute, and equilibrated back to 2% B for CH:FLOW_GRADIENT 1.7 minutes (total run time is 11 minutes) CH:FLOW_RATE 0.6 mL/min CH:COLUMN_TEMPERATURE 35C #ANALYSIS AN:ANALYSIS_TYPE MS #MS MS:INSTRUMENT_NAME Waters Xevo-TQ-S MS:INSTRUMENT_TYPE Triple quadrupole MS:MS_TYPE ESI MS:ION_MODE POSITIVE MS:MS_COMMENTS MS acquisition Comments: The selected reaction monitoring (SRM) transitions were MS:MS_COMMENTS monitored over a 5 to 10 minute window around the retention time. For most MS:MS_COMMENTS metabolites, two SRM transitions were monitored, one for quantification and an MS:MS_COMMENTS additional for compound confirmation. Scheduling was set up to ensure at least MS:MS_COMMENTS 12 data points per peak were collected. Data processing Comments: Data was MS:MS_COMMENTS processed as in Heal et al. 2014 (DOI: 10.1021/acs.analchem.7b04400). MS:MS_COMMENTS Software/procedures used for feature assignments: Peaks were integrated using MS:MS_COMMENTS Skyline. Data was processed using quality control, and best-matched internal MS:MS_COMMENTS standard normalization. MS parameters were as follows: capillary voltage of 0.5 MS:MS_COMMENTS kV, source temperature of 130C, cone gas flow at 150 L/h and desolvation gas MS:MS_COMMENTS flow at 1000 L/h, Desolvation temperature was 500C #MS_METABOLITE_DATA MS_METABOLITE_DATA:UNITS nmol/L MS_METABOLITE_DATA_START Samples A_C_0 A_C_12 A_C_18 A_C_24 A_C_30 A_C_36 A_C_42 A_C_48 A_C_6 A_LV_0 A_LV_12 A_LV_24 A_LV_36 A_LV_48 A_HV_0 A_HV_12 A_HV_24 A_HV_36 A_HV_48 B_C_0 B_C_12 B_C_18 B_C_24 B_C_30 B_C_36 B_C_42 B_C_48 B_C_6 B_LV_0 B_LV_12 B_LV_24 B_LV_36 B_LV_48 B_HV_0 B_HV_12 B_HV_24 B_HV_36 B_HV_48 C_C_0 C_C_12 C_C_18 C_C_24 C_C_30 C_C_36 C_C_42 C_C_48 C_C_6 C_LV_0 C_LV_12 C_LV_24 C_LV_36 C_LV_48 C_HV_0 C_HV_12 C_HV_24 C_HV_36 C_HV_48 Factors Sample source:Marine Microbe Culture | Treatment:C | Timepoint_h:0 Sample source:Marine Microbe Culture | Treatment:C | Timepoint_h:12 Sample source:Marine Microbe Culture | Treatment:C | Timepoint_h:18 Sample source:Marine Microbe Culture | Treatment:C | Timepoint_h:24 Sample source:Marine Microbe Culture | Treatment:C | Timepoint_h:30 Sample source:Marine Microbe Culture | Treatment:C | Timepoint_h:36 Sample source:Marine Microbe Culture | Treatment:C | Timepoint_h:42 Sample source:Marine Microbe Culture | Treatment:C | Timepoint_h:48 Sample source:Marine Microbe Culture | Treatment:C | Timepoint_h:6 Sample source:Marine Microbe Culture | Treatment:LV | Timepoint_h:0 Sample source:Marine Microbe Culture | Treatment:LV | Timepoint_h:12 Sample source:Marine Microbe Culture | Treatment:LV | Timepoint_h:24 Sample source:Marine Microbe Culture | Treatment:LV | Timepoint_h:36 Sample source:Marine Microbe Culture | Treatment:LV | Timepoint_h:48 Sample source:Marine Microbe Culture | Treatment:HV | Timepoint_h:0 Sample source:Marine Microbe Culture | Treatment:HV | Timepoint_h:12 Sample source:Marine Microbe Culture | Treatment:HV | Timepoint_h:24 Sample source:Marine Microbe Culture | Treatment:HV | Timepoint_h:36 Sample source:Marine Microbe Culture | Treatment:HV | Timepoint_h:48 Sample source:Marine Microbe Culture | Treatment:C | Timepoint_h:0 Sample source:Marine Microbe Culture | Treatment:C | Timepoint_h:12 Sample source:Marine Microbe Culture | Treatment:C | Timepoint_h:18 Sample source:Marine Microbe Culture | Treatment:C | Timepoint_h:24 Sample source:Marine Microbe Culture | Treatment:C | Timepoint_h:30 Sample source:Marine Microbe Culture | Treatment:C | Timepoint_h:36 Sample source:Marine Microbe Culture | Treatment:C | Timepoint_h:42 Sample source:Marine Microbe Culture | Treatment:C | Timepoint_h:48 Sample source:Marine Microbe Culture | Treatment:C | Timepoint_h:6 Sample source:Marine Microbe Culture | Treatment:LV | Timepoint_h:0 Sample source:Marine Microbe Culture | Treatment:LV | Timepoint_h:12 Sample source:Marine Microbe Culture | Treatment:LV | Timepoint_h:24 Sample source:Marine Microbe Culture | Treatment:LV | Timepoint_h:36 Sample source:Marine Microbe Culture | Treatment:LV | Timepoint_h:48 Sample source:Marine Microbe Culture | Treatment:HV | Timepoint_h:0 Sample source:Marine Microbe Culture | Treatment:HV | Timepoint_h:12 Sample source:Marine Microbe Culture | Treatment:HV | Timepoint_h:24 Sample source:Marine Microbe Culture | Treatment:HV | Timepoint_h:36 Sample source:Marine Microbe Culture | Treatment:HV | Timepoint_h:48 Sample source:Marine Microbe Culture | Treatment:C | Timepoint_h:0 Sample source:Marine Microbe Culture | Treatment:C | Timepoint_h:12 Sample source:Marine Microbe Culture | Treatment:C | Timepoint_h:18 Sample source:Marine Microbe Culture | Treatment:C | Timepoint_h:24 Sample source:Marine Microbe Culture | Treatment:C | Timepoint_h:30 Sample source:Marine Microbe Culture | Treatment:C | Timepoint_h:36 Sample source:Marine Microbe Culture | Treatment:C | Timepoint_h:42 Sample source:Marine Microbe Culture | Treatment:C | Timepoint_h:48 Sample source:Marine Microbe Culture | Treatment:C | Timepoint_h:6 Sample source:Marine Microbe Culture | Treatment:LV | Timepoint_h:0 Sample source:Marine Microbe Culture | Treatment:LV | Timepoint_h:12 Sample source:Marine Microbe Culture | Treatment:LV | Timepoint_h:24 Sample source:Marine Microbe Culture | Treatment:LV | Timepoint_h:36 Sample source:Marine Microbe Culture | Treatment:LV | Timepoint_h:48 Sample source:Marine Microbe Culture | Treatment:HV | Timepoint_h:0 Sample source:Marine Microbe Culture | Treatment:HV | Timepoint_h:12 Sample source:Marine Microbe Culture | Treatment:HV | Timepoint_h:24 Sample source:Marine Microbe Culture | Treatment:HV | Timepoint_h:36 Sample source:Marine Microbe Culture | Treatment:HV | Timepoint_h:48 Hydroxocobalamin 5.566733888544325e-4 6.665866535717929e-4 6.347753385119344e-4 0.00116737903697303 3.652145058610861e-4 4.075304624328113e-4 0.00144440115163059 7.86745684822366e-4 3.26875752924827e-4 5.842227378023057e-4 4.90046546177556e-4 0.00116162064720395 0.00146292460345686 0.00166241681901951 6.20739263449796e-4 7.655173051703574e-4 0.00186068537675623 3.6274761673523034e-4 0.00339090737222493 4.6250098564400464e-4 0.00105772149022239 3.304861117734688e-4 0.00113934287678481 0.00109605266633 0.0013496604862719 0.00132144816481772 0.00135486955596433 8.56939319583184e-5 5.353294625656099e-4 0.0014445413229605 9.905207027757694e-4 0.00125736966217462 0.00108743402374799 6.047218476973748e-4 0.00119388846618958 0.00143735091257779 1.0740645692948448e-4 0.00568576397232701 4.417480519893773e-4 8.968502644629755e-4 8.46649986285271e-4 9.299894187426124e-4 0.0011082021110599 5.572586988671451e-4 3.49000092563933e-4 0.00122728144422877 5.155615166346415e-4 4.211883274651601e-4 8.656413072802775e-4 0.00103245087248906 4.748436395043141e-4 0.00288117433102432 4.0662187439797473e-4 6.708448312694565e-4 4.980401003964797e-4 4.4349261678455e-4 0.0020875356263435 Cyanopseudocobalamin 9.936365136590146e-4 0.00158879759391795 0.0012402957243148 0.0027942380220235 4.453374645978501e-4 7.804531020010258e-4 0.00388915006799851 0.00221378902406221 6.753098682440512e-4 0.00105607153559935 7.507121639719986e-4 0.00108168420049189 0.00183920358712335 9.998800158530484e-5 8.969593053811843e-4 5.618743234715965e-4 1.4520485462720303e-4 1.358489682925263e-4 2.809575987315234e-4 0.0013491993652852 0.00160462604710708 5.655478734531926e-4 0.00146142401806094 0.00228643998924066 7.760915064966828e-4 4.064254247371611e-4 0.00319062888185961 3.896057772553613e-4 0.00142538848534857 4.204452038046153e-4 0.00175055641508252 0.00154107295119228 4.098665038923836e-4 2.6110816663346985e-4 7.407082545645368e-4 3.177927289016438e-4 6.707686921013457e-5 1.0251197055736108e-4 0.00113846839311423 0.00131756289590266 0.00192294247402418 0.00246450242374497 0.00216530991557768 0.00128330793644284 8.66538837244296e-4 0.00222076059422895 6.795965280974019e-4 0.00155862747897869 0.00139623511094664 0.00237084733621 0.00135392031129771 4.597838659510666e-4 0.00100141279053243 0.00122147325125193 3.18559116241337e-4 2.174317521443549e-4 2.0180766891247644e-4 Hyrodoxopseudocobalamin 0.00156053385614 9.9973564177203e-4 0.00119359353813463 0.00136676797089023 0.00142766346360525 9.69012390875502e-4 0.00170348739752319 0.00141386496947626 0.00105920020304253 0.00161317055827838 7.702979999133503e-4 0.00159777297446418 9.98605068442998e-4 9.156533486213694e-4 0.00201430728229023 8.277827358593021e-4 4.333342679118121e-4 8.869130958463899e-5 1.2772411580970513e-4 8.251175863839407e-4 0.00143030957629864 9.985363245081174e-4 0.00212620548669148 0.0018440232675966 0.00228013373287858 0.00226215349231088 0.00280985122788865 0.00102007961610062 0.00151721248597739 0.00265103687433005 0.00159584074109455 5.981272286070014e-4 2.1045479744071817e-4 0.00246540921337112 0.00118160671108949 3.135802181522356e-4 2.101331698342779e-5 1.5619996883514488e-4 0.00153669980511748 0.00164218895958988 0.00149601820205428 0.00175291957469716 0.00248100033780199 0.00147189542650526 0.00105378106577596 0.00242760850997891 0.00108852953845949 0.00104765122198263 0.00221022115110526 0.0012103903254234 5.27594893820758e-4 1.298403714050219e-4 6.397500947785597e-4 0.00101828381300174 2.2828591654968435e-4 5.956926357132388e-5 9.544407918788629e-5 MS_METABOLITE_DATA_END #METABOLITES METABOLITES_START metabolite_name mz RT_minute PubChem_Code KEGG_Code Hydroxocobalamin 664.7861 4.35 70678542 cpd:C08230 Cyanopseudocobalamin 673.2805 4.3 NA NA Hyrodoxopseudocobalamin 659.775 3.5 NA NA METABOLITES_END #END