Summary of Study ST000969

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 PR000664. The data can be accessed directly via it's Project DOI: 10.21228/M8V68R 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	ST000969
Study Title	Impact of thiamine metabolites and spent medium from Chlorella sorokiniana on metabolism in the green algae Auxenochlorella prototheciodes (part II)
Study Summary	The purpose of this study is to determine how thiamine metabolites impact central metabolism in Auxenochlorella protothecoides when grown in the presence of glucose. We hypothesize that thiamine metabolites alleviate bottlenecks in the TCA cycle and gluconeogensis, thus allowing for greater starch production when they are present. Cells were grown in bioreactors: 3 control cultures with no thiamine metabolites, 3 cultures received thiamine, 3 recieved HMP, and 3 were grown on residual medium from another algae species - Chlorella sorokiniana. We suspect that this residual medium also contains thiamine metabolites. Samples were taken daily from each of these 12 cultures over a 5 day time course so that we can observe build-up of metabolites over time.
Institute	University of California, Davis
Department	Genome and Biomedical Sciences Facility
Laboratory	WCMC Metabolomics Core
Last Name	Fiehn
First Name	Oliver
Address	1315 Genome and Biomedical Sciences Facility, 451 Health Sciences Drive, Davis, CA 95616
Email	ofiehn@ucdavis.edu
Phone	(530) 754-8258
Submit Date	2018-05-03
Raw Data Available	Yes
Raw Data File Type(s)	cdf
Analysis Type Detail	GC-MS
Release Date	2018-06-05
Release Version	1

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Project:

Project ID:	PR000664
Project DOI:	doi: 10.21228/M8V68R
Project Title:	Impact of thiamine metabolites and spent medium from Chlorella sorokiniana on metabolism in the green algae Auxenochlorella prototheciodes
Project Summary:	The purpose of this study is to determine how thiamine metabolites impact central metabolism in Auxenochlorella protothecoides when grown in the presence of glucose. We hypothesize that thiamine metabolites alleviate bottlenecks in the TCA cycle and gluconeogensis, thus allowing for greater starch production when they are present. Cells were grown in bioreactors: 3 control cultures with no thiamine metabolites, 3 cultures received thiamine, 3 recieved HMP, and 3 were grown on residual medium from another algae species - Chlorella sorokiniana. We suspect that this residual medium also contains thiamine metabolites. Samples were taken daily from each of these 12 cultures over a 5 day time course so that we can observe build-up of metabolites over time.
Institute:	Auburn University
Department:	College of Engineering
Laboratory:	Bioprocess Engineering
Last Name:	Higgins
First Name:	Brendan
Address:	203 Corley Building Auburn, Alabama 36849
Email:	bth0023@auburn.edu
Phone:	(334) 844-3532

Subject:

Subject ID:	SU001008
Subject Type:	Cultured cells
Subject Species:	Auxenochlorella protothecoides
Taxonomy ID:	3075

Factors:

Subject type: Cultured cells; Subject species: Auxenochlorella protothecoides (Factor headings shown in green)

mb_sample_id	local_sample_id	Treatment
SA057920	161115aZKsa47_1	1 - Control
SA057921	161115aZKsa43_1	1 - Control
SA057922	161116aZKsa08_2	1 - Control
SA057923	161116aZKsa22_2	1 - Control
SA057924	161115aZKsa10_1	1 - Control
SA057925	161115aZKsa04_1	1 - Control
SA057926	161116aZKsa06_2	1 - Control
SA057927	161116aZKsa14_2	1 - Control
SA057928	161115aZKsa07_1	1 - Control
SA057929	161115aZKsa49_1	1 - Control
SA057930	161115aZKsa39_1	1 - Control
SA057931	161115aZKsa17_1	1 - Control
SA057932	161116aZKsa17_1	1 - Control
SA057933	161115aZKsa28_1	1 - Control
SA057934	161115aZKsa08_1	1 - Control
SA057935	161116aZKsa03_2	1 - Control
SA057936	161115aZKsa13_1	1 - Control
SA057937	161115aZKsa31_1	1 - Control
SA057938	161115aZKsa25_1	2 - HMP
SA057939	161116aZKsa05_2	2 - HMP
SA057940	161115aZKsa22_1	2 - HMP
SA057941	161115aZKsa24_1	2 - HMP
SA057942	161116aZKsa16_1	2 - HMP
SA057943	161115aZKsa40_1	2 - HMP
SA057944	161116aZKsa09_2	2 - HMP
SA057945	161115aZKsa29_1	2 - HMP
SA057946	161115aZKsa12_1	2 - HMP
SA057947	161115aZKsa03_1	2 - HMP
SA057948	161116aZKsa02_2	2 - HMP
SA057949	161116aZKsa12_3	2 - HMP
SA057950	161115aZKsa05_1	2 - HMP
SA057951	161115aZKsa15_1	2 - HMP
SA057952	161116aZKsa10_2	2 - HMP
SA057953	161115aZKsa50_1	2 - HMP
SA057954	161115aZKsa27_1	2 - HMP
SA057955	161115aZKsa01_1	2 - HMP
SA057956	161116aZKsa21_1	3 - Residual
SA057957	161116aZKsa04_2	3 - Residual
SA057958	161115aZKsa45_1	3 - Residual
SA057959	161115aZKsa19_1	3 - Residual
SA057960	161115aZKsa32_1	3 - Residual
SA057961	161115aZKsa02_1	3 - Residual
SA057962	161115aZKsa23_1	3 - Residual
SA057963	161115aZKsa41_1	3 - Residual
SA057964	161116aZKsa01_2	3 - Residual
SA057965	161115aZKsa30_1	3 - Residual
SA057966	161116aZKsa07_2	3 - Residual
SA057967	161116aZKsa11_3	3 - Residual
SA057968	161116aZKsa20_1	3 - Residual
SA057969	161115aZKsa36_1	3 - Residual
SA057970	161115aZKsa37_1	3 - Residual
SA057971	161115aZKsa26_1	3 - Residual
SA057972	161115aZKsa11_1	3 - Residual
SA057973	161115aZKsa46_1	3 - Residual
SA057974	161116aZKsa18_1	4 - Thiamine
SA057975	161115aZKsa38_1	4 - Thiamine
SA057976	161115aZKsa09_1	4 - Thiamine
SA057977	161115aZKsa48_1	4 - Thiamine
SA057978	161115aZKsa20_1	4 - Thiamine
SA057979	161115aZKsa34_1	4 - Thiamine
SA057980	161115aZKsa35_1	4 - Thiamine
SA057981	161116aZKsa13_1	4 - Thiamine
SA057982	161115aZKsa33_1	4 - Thiamine
SA057983	161115aZKsa42_1	4 - Thiamine
SA057984	161115aZKsa18_1	4 - Thiamine
SA057985	161115aZKsa44_1	4 - Thiamine
SA057986	161115aZKsa14_1	4 - Thiamine
SA057987	161115aZKsa16_1	4 - Thiamine
SA057988	161115aZKsa21_1	4 - Thiamine
SA057989	161115aZKsa06_1	4 - Thiamine
SA057990	161116aZKsa15_2	4 - Thiamine
SA057991	161116aZKsa19_1	4 - Thiamine

Showing results 1 to 72 of 72

Showing results 1 to 72 of 72

Collection:

Collection ID:	CO001002
Collection Summary:	1 ml algae cell culture was collected, 1 ml 70% MeOH (30% dH2O) at -80 C was added to the algae sample. Tubes were spun at 12,000 rcf to pellet for 2 min at 0 C. Supernatant was decanted and pellets stored at -80 before freeze drying at -45 C. Freeze dried samples were stored at -20 C until submission for extraction.
Collection Protocol Filename:	StudyDesignBrendanHiggins7252016.pdf
Sample Type:	Cultured cells
Volumeoramount Collected:	0.11-3 mg
Storage Conditions:	-20℃

Treatment:

Treatment ID:	TR001022
Treatment Summary:	3 control cultures recieved no thiamine metabolites, 3 cultures received thiamine, 3 recieved HMP, and 3 were grown on residual medium from another algae species - Chlorella sorokiniana. Samples were taken daily from each of these 12 cultures over a 5 day time course so that we can observe build-up of metabolites over time.
Treatment Protocol Filename:	StudyDesignBrendanHiggins7252016.pdf

Sample Preparation:

Sampleprep ID:	SP001015
Sampleprep Summary:	1. Check the pH of methanol (pH 7) 2. Make the extraction solution by mixing methanol, chloroform, and water in proportions of 10 : 3 : 1 3. Rinse the extraction solution for 5 min with nitrogen, making sure that the nitrogen line was flushed out of air before using it for degassing the extraction solvent solution. 4. Add one metal ball to each Eppendorf tube, close, and place in liquid nitrogen. 5. Take the Eppendorf tubes from the liquid nitrogen and place into the tube-holder of the grinder being careful to compensate for weight, maintaining equilibrium. 6. Shake for 30s at a frequency of 25 s-1 and check that the leaves have been ground into a fine powder. Repeat if necessary, submerging in liquid nitrogen first. 7. After grinding add 500μL of pre-chilled extraction solution to each tube one by one to prevent even partial thawing of the sample. Store all samples on ice while finishing this step. 8. Vortex the sample for 20s. 9. Centrifuge for 3min at 14,000 rcf using the centrifuge Eppendorf 5415 D. 10. Remove the whole supernatant into a clean Eppendorf tube. 11. Add 800μL of extraction solvent back into the tube with the pellet and metal ball. 12. Vortex the sample again for 20s. 13. Centrifuge for 3min at 14,000 rcf using the centrifuge Eppendorf 5415 D. 14. Remove the whole supernatant and combine with the previous supernatant. 15. Dry in the Labconco Centrivap cold trap concentrator to complete dryness and submit for derivitization.
Sampleprep Protocol Filename:	SOP_Extraction_of_Plant_Samples--Chlamydomonas.pdf

Combined analysis:

Analysis ID	AN001583
Analysis type	MS
Chromatography type	GC
Chromatography system	Leco Pegasus III GC
Column	Restek Rtx-5Sil (30m x 0.25mm,0.25um)
MS Type	EI
MS instrument type	GC-TOF
MS instrument name	Leco Pegasus III GC TOF
Ion Mode	POSITIVE
Units	Counts

Chromatography:

Chromatography ID:	CH001112
Methods Filename:	Data_Dictionary_Fiehn_laboratory_GCTOF_MS_primary_metabolism_10-15-2013_general.pdf
Chromatography Comments:	Excel generated
Instrument Name:	Leco Pegasus III GC
Column Name:	Restek Rtx-5Sil (30m x 0.25mm,0.25um)
Column Pressure:	7.7 PSI (initial condition)
Column Temperature:	50 - 330°C
Flow Rate:	1 ml/min
Injection Temperature:	50°C ramped to 250°C by 12°C/s
Sample Injection:	0.5µl
Oven Temperature:	50°C for 1 min, then ramped at 20°C/min to 330°C, held constant for 5 min
Transferline Temperature:	230°C
Washing Buffer:	Ethyl Acetate
Sample Loop Size:	30 m length x 0.25 mm internal diameter
Chromatography Type:	GC

MS:

MS ID:	MS001461
Analysis ID:	AN001583
Instrument Name:	Leco Pegasus III GC TOF
Instrument Type:	GC-TOF
MS Type:	EI
Ion Mode:	POSITIVE
Ion Source Temperature:	250°C
Ionization Energy:	70eV
Mass Accuracy:	Nominal
Source Temperature:	250°C
Scan Range Moverz:	85-500
Scanning Cycle:	17 Hz
Scanning Range:	80-500 Da
Skimmer Voltage:	1850 V