Summary of Study ST002834

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 PR001774. The data can be accessed directly via it's Project DOI: 10.21228/M8DB1F 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 ID	ST002834
Study Title	Resource competition predicts assembly of in vitro gut bacterial communities- 2021-C18
Study Summary	Microbiota dynamics arise from a plethora of interspecies interactions, including resource competition, cross-feeding, and pH modulation. The individual contributions of these mechanisms are challenging to untangle, especially in natural or complex laboratory environments where the landscape of resource competition is unclear. Here, we developed a framework to estimate the extent of multi-species niche overlaps by combining metabolomics data of individual species, growth measurements in pairwise spent media, and mathematical models. When applied to an in vitro model system of human gut commensals in complex media, our framework revealed that a simple model of resource competition described most pairwise interactions. By grouping metabolomic features depleted by the same set of species, we constructed a coarse-grained consumer-resource model that predicted assembly compositions to reasonable accuracy. Moreover, deviations from model predictions enabled us to identify and incorporate into the model additional interactions, including pH-mediated effects and cross-feeding, which improved model performance. In sum, our work provides an experimental and theoretical framework to dissect microbial interactions in complex in vitro environments.
Institute	Stanford University
Last Name	DeFelice
First Name	Brian
Address	1291 Welch Rd.
Email	bcdefelice@ucdavis.edu
Phone	5303564485
Submit Date	2023-08-28
Raw Data Available	Yes
Raw Data File Type(s)	raw(Thermo)
Analysis Type Detail	LC-MS
Release Date	2023-09-14
Release Version	1

Select appropriate tab below to view additional metadata details:

Project:

Project ID:	PR001774
Project DOI:	doi: 10.21228/M8DB1F
Project Title:	Resource competition predicts assembly of in vitro gut bacterial communities
Project Summary:	Microbiota dynamics arise from a plethora of interspecies interactions, including resource competition, cross-feeding, and pH modulation. The individual contributions of these mechanisms are challenging to untangle, especially in natural or complex laboratory environments where the landscape of resource competition is unclear. Here, we developed a framework to estimate the extent of multi-species niche overlaps by combining metabolomics data of individual species, growth measurements in pairwise spent media, and mathematical models. When applied to an in vitro model system of human gut commensals in complex media, our framework revealed that a simple model of resource competition described most pairwise interactions. By grouping metabolomic features depleted by the same set of species, we constructed a coarse-grained consumer-resource model that predicted assembly compositions to reasonable accuracy. Moreover, deviations from model predictions enabled us to identify and incorporate into the model additional interactions, including pH-mediated effects and cross-feeding, which improved model performance. In sum, our work provides an experimental and theoretical framework to dissect microbial interactions in complex in vitro environments.
Institute:	Stanford University
Last Name:	DeFelice
First Name:	Brian
Address:	1291 Welch Rd., Rm. G0821 (SIM1), Stanford CA, California, 94305, USA
Email:	bcdefelice@ucdavis.edu
Phone:	5303564485

Subject:

Subject ID:	SU002943
Subject Type:	Bacteria
Subject Species:	Bacteroides thetaiotaomicron
Taxonomy ID:	8188
Subject Comments:	Fecal derived communities and isolates, supernatant was assayed

Factors:

Subject type: Bacteria; Subject species: Bacteroides thetaiotaomicron (Factor headings shown in green)

mb_sample_id	local_sample_id	Genotype	Treatment
SA307026	Neg_BK13	Analytical Blank	Method Blank
SA307027	Neg_BK12	Analytical Blank	Method Blank
SA307028	Neg_BK11	Analytical Blank	Method Blank
SA307029	Neg_BK14	Analytical Blank	Method Blank
SA307030	Neg_BK15	Analytical Blank	Method Blank
SA307031	Neg_BK18	Analytical Blank	Method Blank
SA307032	Neg_BK17	Analytical Blank	Method Blank
SA307033	Neg_BK10	Analytical Blank	Method Blank
SA307034	Neg_BK8	Analytical Blank	Method Blank
SA307035	Neg_BK4	Analytical Blank	Method Blank
SA307036	Neg_BK3	Analytical Blank	Method Blank
SA307037	Neg_BK2	Analytical Blank	Method Blank
SA307038	Neg_BK5	Analytical Blank	Method Blank
SA307039	Neg_BK6	Analytical Blank	Method Blank
SA307040	Pos_BK18	Analytical Blank	Method Blank
SA307041	Neg_BK7	Analytical Blank	Method Blank
SA307042	Neg_BK9	Analytical Blank	Method Blank
SA307043	Neg_BK16	Analytical Blank	Method Blank
SA307044	Pos_BK17	Analytical Blank	Method Blank
SA307045	Pos_BK7	Analytical Blank	Method Blank
SA307046	Pos_BK8	Analytical Blank	Method Blank
SA307047	Pos_BK5	Analytical Blank	Method Blank
SA307048	Pos_BK4	Analytical Blank	Method Blank
SA307049	Pos_BK2	Analytical Blank	Method Blank
SA307050	Pos_BK3	Analytical Blank	Method Blank
SA307051	Pos_BK9	Analytical Blank	Method Blank
SA307052	Pos_BK6	Analytical Blank	Method Blank
SA307053	Pos_BK15	Analytical Blank	Method Blank
SA307054	Pos_BK10	Analytical Blank	Method Blank
SA307055	Pos_BK14	Analytical Blank	Method Blank
SA307056	Pos_BK16	Analytical Blank	Method Blank
SA307057	Pos_BK13	Analytical Blank	Method Blank
SA307058	Pos_BK11	Analytical Blank	Method Blank
SA307059	Pos_BK12	Analytical Blank	Method Blank
SA307094	Neg_BHICONTROL(labeled16')_r1	bacterial community	BHI fresh
SA307095	Neg_BHICONTROL(labeled16')	bacterial community	BHI fresh
SA307096	Neg_BHICONTROL(labeled16')_r2	bacterial community	BHI fresh
SA307097	Pos_BHICONTROL(labeled16')	bacterial community	BHI fresh
SA307098	Pos_BHICONTROL(labeled16')_r1	bacterial community	BHI fresh
SA307099	Pos_BHICONTROL(labeled16')_r2	bacterial community	BHI fresh
SA307100	Neg_12'_r2	bacterial community	BHI spent by Bacteroides fragilis
SA307101	Neg_12'	bacterial community	BHI spent by Bacteroides fragilis
SA307102	Neg_12'_r1	bacterial community	BHI spent by Bacteroides fragilis
SA307103	Pos_12'_r1	bacterial community	BHI spent by Bacteroides fragilis
SA307104	Pos_12'_r2	bacterial community	BHI spent by Bacteroides fragilis
SA307105	Pos_12'	bacterial community	BHI spent by Bacteroides fragilis
SA307106	Pos_4'_r2	bacterial community	BHI spent by Bacteroides thetaiotaomicron
SA307107	Neg_4'_r1	bacterial community	BHI spent by Bacteroides thetaiotaomicron
SA307108	Neg_4'	bacterial community	BHI spent by Bacteroides thetaiotaomicron
SA307109	Pos_4'_r1	bacterial community	BHI spent by Bacteroides thetaiotaomicron
SA307110	Neg_4'_r2	bacterial community	BHI spent by Bacteroides thetaiotaomicron
SA307111	Pos_4'	bacterial community	BHI spent by Bacteroides thetaiotaomicron
SA307112	Pos_14'	bacterial community	BHI spent by Bacteroides uniformis
SA307113	Pos_14'_r1	bacterial community	BHI spent by Bacteroides uniformis
SA307114	Pos_14'_r2	bacterial community	BHI spent by Bacteroides uniformis
SA307115	Neg_14'	bacterial community	BHI spent by Bacteroides uniformis
SA307116	Neg_14'_r2	bacterial community	BHI spent by Bacteroides uniformis
SA307117	Neg_14'_r1	bacterial community	BHI spent by Bacteroides uniformis
SA307118	Neg_6'	bacterial community	BHI spent by Blautia producta
SA307119	Pos_6'	bacterial community	BHI spent by Blautia producta
SA307120	Neg_6'_r2	bacterial community	BHI spent by Blautia producta
SA307121	Pos_6'_r1	bacterial community	BHI spent by Blautia producta
SA307122	Pos_6'_r2	bacterial community	BHI spent by Blautia producta
SA307123	Neg_6'_r1	bacterial community	BHI spent by Blautia producta
SA307124	Neg_5'_r2	bacterial community	BHI spent by Clostridium clostridioforme
SA307125	Neg_5'_r1	bacterial community	BHI spent by Clostridium clostridioforme
SA307126	Neg_5'	bacterial community	BHI spent by Clostridium clostridioforme
SA307127	Pos_5'_r2	bacterial community	BHI spent by Clostridium clostridioforme
SA307128	Pos_5'	bacterial community	BHI spent by Clostridium clostridioforme
SA307129	Pos_5'_r1	bacterial community	BHI spent by Clostridium clostridioforme
SA307130	Neg_11'	bacterial community	BHI spent by Clostridium hathewayi
SA307131	Pos_11'_r2	bacterial community	BHI spent by Clostridium hathewayi
SA307132	Neg_11'_r2	bacterial community	BHI spent by Clostridium hathewayi
SA307133	Neg_11'_r1	bacterial community	BHI spent by Clostridium hathewayi
SA307134	Pos_11'	bacterial community	BHI spent by Clostridium hathewayi
SA307135	Pos_11'_r1	bacterial community	BHI spent by Clostridium hathewayi
SA307136	Pos_9'	bacterial community	BHI spent by Clostridium hylemonae
SA307137	Pos_9'_r1	bacterial community	BHI spent by Clostridium hylemonae
SA307138	Neg_9'_r2	bacterial community	BHI spent by Clostridium hylemonae
SA307139	Pos_9'_r2	bacterial community	BHI spent by Clostridium hylemonae
SA307140	Neg_9'	bacterial community	BHI spent by Clostridium hylemonae
SA307141	Neg_9'_r1	bacterial community	BHI spent by Clostridium hylemonae
SA307142	Neg_7'_r2	bacterial community	BHI spent by Clostridium scindens
SA307143	Pos_7'_r1	bacterial community	BHI spent by Clostridium scindens
SA307144	Pos_7'	bacterial community	BHI spent by Clostridium scindens
SA307145	Neg_7'_r1	bacterial community	BHI spent by Clostridium scindens
SA307146	Pos_7'_r2	bacterial community	BHI spent by Clostridium scindens
SA307147	Neg_7'	bacterial community	BHI spent by Clostridium scindens
SA307148	Neg_3'_r1	bacterial community	BHI spent by Clostridium symbiosum
SA307149	Pos_3'	bacterial community	BHI spent by Clostridium symbiosum
SA307150	Pos_3'_r1	bacterial community	BHI spent by Clostridium symbiosum
SA307151	Pos_3'_r2	bacterial community	BHI spent by Clostridium symbiosum
SA307152	Neg_3'_r2	bacterial community	BHI spent by Clostridium symbiosum
SA307153	Neg_3'	bacterial community	BHI spent by Clostridium symbiosum
SA307154	Pos_10'_r1	bacterial community	BHI spent by Enterococcus faecalis
SA307155	Neg_10'	bacterial community	BHI spent by Enterococcus faecalis
SA307156	Pos_10'_r2	bacterial community	BHI spent by Enterococcus faecalis
SA307157	Pos_10'	bacterial community	BHI spent by Enterococcus faecalis
SA307158	Neg_10'_r1	bacterial community	BHI spent by Enterococcus faecalis
SA307159	Neg_10'_r2	bacterial community	BHI spent by Enterococcus faecalis

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Collection:

Collection ID:	CO002936
Collection Summary:	Isolates were obtained via plating of in vitro communities –, derived from culturing fecal samples from humanized mice –, on agar plates made with various complex media and frozen as glycerol stocks, as previously described (https://doi.org/https://doi.org/10.1016/j.chom.2021.12.008, https://www.biorxiv.org/content/10.1101/2023.01.13.523996v1). Frozen stocks were streaked onto BHI-blood agar plates (5% defibrinated horse blood in 1.5% w/v agar). Resulting colonies were inoculated into 3 mL of Brain Heart Infusion (BHI) (BD #2237500) or modified Gifu Anaerobic Medium (mGAM) (HyServe #05433) in test tubes. All culturing werewas performed at 37 °C without shaking in an anaerobic chamber (Coy). To minimize potential physiological changes from freeze-thaw cycles and changes in growth medium, cultures were diluted 1:200 every 48 h for 3 passages before growth or metabolomics measurements. After the first passage, subsequent passages were performed in 96-well polystyrene plates (Greiner Bio-One #655161) filled with 200 μL of growth medium.
Sample Type:	Bacterial cells

Treatment:

Treatment ID:	TR002952
Treatment Summary:	Many combinations of bacterial isolates were assayed. details can be found in the publicly available preprint here: https://www.biorxiv.org/content/10.1101/2022.05.30.494065v1.abstract

Sample Preparation:

Sampleprep ID:	SP002949
Sampleprep Summary:	Spent media were collected as described above and immediately stored at -80 °C. Samples were thawed only once, immediately before LC-MS/MS. Thawed samples were kept on ice, each sample was homogenized by pipetting prior to dispensing. Two 20-µL aliquots of supernatant were removed from each sample well and dispensed into two shallow 96-well polypropylene plates, maintained on ice. Additionally, 5 µL were removed from each sample and combined into a homogenous pool; this pool was dispensed in 20-µL aliquots and prepared in parallel with samples. These pooled samples were used for in-run quality control, injected at predefined intervals over the course of analysis to ensure consistent instrument performance over time. Samples were analyzed using two complementary chromatography methods: reversed phase (C18) and hydrophilic interaction chromatography (HILIC). All samples were analyzed by positive and negative mode electrospray ionization (ESI+, ESI-). Sample analysis order was randomized to minimize potential bias in data acquisition. Procedural blanks were prepared by extracting 20 µL of water in place of bacterial supernatant. Procedural blanks were inserted throughout the run as additional quality control.

Sampleprep ID:

SP002949

Sampleprep Summary:

Spent media were collected as described above and immediately stored at -80 °C. Samples were thawed only once, immediately before LC-MS/MS. Thawed samples were kept on ice, each sample was homogenized by pipetting prior to dispensing. Two 20-µL aliquots of supernatant were removed from each sample well and dispensed into two shallow 96-well polypropylene plates, maintained on ice. Additionally, 5 µL were removed from each sample and combined into a homogenous pool; this pool was dispensed in 20-µL aliquots and prepared in parallel with samples. These pooled samples were used for in-run quality control, injected at predefined intervals over the course of analysis to ensure consistent instrument performance over time. Samples were analyzed using two complementary chromatography methods: reversed phase (C18) and hydrophilic interaction chromatography (HILIC). All samples were analyzed by positive and negative mode electrospray ionization (ESI+, ESI-). Sample analysis order was randomized to minimize potential bias in data acquisition. Procedural blanks were prepared by extracting 20 µL of water in place of bacterial supernatant. Procedural blanks were inserted throughout the run as additional quality control.

Combined analysis:

Analysis ID	AN004629	AN004630
Analysis type	MS	MS
Chromatography type	Reversed phase	Reversed phase
Chromatography system	Thermo Vanquish	Thermo Vanquish
Column	Agilent Zorbax SB-C18 (100 x 3.0 mm, 1.8 um)	Agilent Zorbax SB-C18 (100 x 3.0 mm, 1.8 um)
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	counts, height	counts, height

Chromatography:

Chromatography ID:	CH003483
Chromatography Summary:	Bacterial supernatant were analyzed via reversed phase (C18) coupled to a Thermo Q-Exactive HF high resolution mass spectrometer. Prepared samples were injected onto an Agilent Zorbax SB-C18 column (100 mm length × 3 mm id; 1.8 μm particle size) with an additional Phenomenex KrudKatcher pre-column (2 μm depth x 0.004in ID) maintained at 40°C coupled to an Thermo Vanquish UPLC. The mobile phases were prepared with 0.1% formic acid in either 100% LC-MS grade water for mobile phase (A), 100% water or mobile phase (B), 100% acetonitrile. Gradient elution was performed as follows 3% (B) maintained 0–0.43 min to 97% (B) at 9 min, maintained until 11 min, returning to initial conditions at 11.5 min and equilibrating until the end of the run at 14 min. Flow rate is maintained at 0.4 mL/min. Each sample was analyzed in both positive and negative ionization modes (ESI+, ESI-) via subsequent injections. Full MS-ddMS2 data was collected, an inclusion list was used to prioritize MS2 selection of metabolites from our in-house ‘local’ library, when additional scan bandwidth was available MS2 was collected in a data-dependent manner. Mass range was 60-900 mz, resolution was 60k (MS1) and 15k (MS2), centroid data was collected, loop count was 4, isolation window was 1.5 Da. Metabolomics data was processed using MS-DIAL v4.60 (https://www.nature.com/articles/s41587-020-0531-2) and queried against a combination of our in-house MS2 library and MassBank of North America, the largest freely available spectral repository (https://doi.org/10.1002/mas.21535). Features were excluded from analysis if peak height was not at least 5-fold greater in one or more samples compared to the procedural blank average.
Instrument Name:	Thermo Vanquish
Column Name:	Agilent Zorbax SB-C18 (100 x 3.0 mm, 1.8 um)
Column Temperature:	40C
Flow Gradient:	Gradient elution was performed from 100% (B) at 0–2 min to 70% (B) at 7.7 min, 40% (B) at 9.5 min, 30% (B) at 10.25 min, 100% (B) at 12.75 min, isocratic until 16.75 min with a column flow ofGradient elution was performed as follows 3% (B) maintained 0–0.43 min to 97% (B) at 9 min, maintained until 11 min, returning to initial conditions at 11.5 min and equilibrating until the end of the run at 14 min.
Flow Rate:	0.4 mL/min.
Solvent A:	Water + 0.1% formic acid
Solvent B:	Acetonitrile + 0.1% formic acid
Chromatography Type:	Reversed phase

MS:

MS ID:	MS004375
Analysis ID:	AN004629
Instrument Name:	Thermo Q Exactive HF hybrid Orbitrap
Instrument Type:	Orbitrap
MS Type:	ESI
MS Comments:	Full MS-ddMS2 data was collected, an inclusion list was used to prioritize MS2 selection of metabolites from our in-house ‘local’ library, when additional scan bandwidth was available MS2 was collected in a data-dependent manner. Mass range was 60-900 mz, resolution was 60k (MS1) and 15k (MS2), centroid data was collected, loop count was 4, isolation window was 1.5 Da. Metabolomics data was processed using MS-DIAL v4.60. Features were excluded from analysis if peak height was not at least 5-fold greater in one or more samples compared to the procedural blank average.
Ion Mode:	POSITIVE

MS ID:	MS004376
Analysis ID:	AN004630
Instrument Name:	Thermo Q Exactive HF hybrid Orbitrap
Instrument Type:	Orbitrap
MS Type:	ESI
MS Comments:	Full MS-ddMS2 data was collected, an inclusion list was used to prioritize MS2 selection of metabolites from our in-house ‘local’ library, when additional scan bandwidth was available MS2 was collected in a data-dependent manner. Mass range was 60-900 mz, resolution was 60k (MS1) and 15k (MS2), centroid data was collected, loop count was 4, isolation window was 1.5 Da. Metabolomics data was processed using MS-DIAL v4.60. Features were excluded from analysis if peak height was not at least 5-fold greater in one or more samples compared to the procedural blank average.
Ion Mode:	NEGATIVE