Summary of Study ST003036

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 PR001879. The data can be accessed directly via it's Project DOI: 10.21228/M8TX45 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	ST003036
Study Title	Identifying and mathematically modeling the time-course of extracellular metabolic markers associated with resistance to ceftolozane/tazobactam in Pseudomonas aeruginosa - Part 2
Study Type	Biomedical research
Study Summary	Extracellular bacterial metabolites have potential as markers of bacterial growth and resistance emergence, but have not been evaluated in dynamic in vitro studies. We investigated the dynamic metabolomic footprint of a multidrug-resistant hypermutable Pseudomonas aeruginosa isolate exposed to ceftolozane/tazobactam as continuous infusion (4.5g/day, 9g/day) in a hollow-fiber infection model over 7-9 days in biological replicates (n=5). Bacterial samples were collected at 0, 7, 23, 47, 71, 95, 143, 167, 191 and 215h, the supernatant quenched and extracellular metabolites extracted. Metabolites were analyzed via untargeted metabolomics, including hierarchical clustering and correlation with quantified total and resistant bacterial populations. The time-courses of five metabolites were mathematically modeled. These five (of 1921 detected) metabolites were from enriched pathways (arginine and central carbon metabolism). Absorbed L-arginine and secreted L-ornithine were highly correlated with the total bacterial population (r -0.79 and 0.82 respectively, p<0.0001). Ribose-5-phosphate, sedoheptulose-7-phosphate and trehalose-6-phosphate correlated with the resistant subpopulation (0.64, 0.64 and 0.67, respectively, p<0.0001), and were likely secreted due to resistant growth overcoming oxidative and osmotic stress induced by ceftolozane/tazobactam. Using PK/PD-based transduction models, these metabolites were successfully modeled based on the total or resistant bacterial populations. The models well described the abundance of each metabolite across the differing time-course profiles of biological replicates, based on bacterial killing and, importantly, resistant regrowth. These proof-of-concept studies suggest further exploration is warranted to determine the generalizability of these findings. The metabolites modeled in this work are not exclusive to bacterial cells. Future studies may use this approach to identify bacteria-specific metabolites correlating with resistance, which would ultimately be extremely useful for clinical translation.
Institute	Monash Institute of Pharmaceutical Sciences
Department	Drug Delivery, Disposition and Dynamics
Laboratory	Cornelia Landersdorfer
Last Name	Landersdorfer
First Name	Cornelia
Address	399 Royal Pd
Email	cornelia.landersdorfer@monash.edu
Phone	+61 3 9903 9061
Submit Date	2023-12-17
Num Groups	6 groups with time points
Total Subjects	NA
Num Males	NA
Num Females	NA
Publications	Identifying and mathematically modeling the time-course of extracellular metabolic markers associated with resistance to ceftolozane/tazobactam in Pseudomonas aeruginosa
Raw Data Available	Yes
Raw Data File Type(s)	raw(Thermo)
Analysis Type Detail	LC-MS
Release Date	2024-01-11
Release Version	1

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Project:

Project ID:	PR001879
Project DOI:	doi: 10.21228/M8TX45
Project Title:	Identifying and mathematically modeling the time-course of extracellular metabolic markers associated with resistance to ceftolozane/tazobactam in Pseudomonas aeruginosa
Project Type:	Biomedical research
Project Summary:	Extracellular bacterial metabolites have potential as markers of bacterial growth and resistance emergence, but have not been evaluated in dynamic in vitro studies. We investigated the dynamic metabolomic footprint of a multidrug-resistant hypermutable Pseudomonas aeruginosa isolate exposed to ceftolozane/tazobactam as continuous infusion (4.5g/day, 9g/day) in a hollow-fiber infection model over 7-9 days in biological replicates (n=5). Bacterial samples were collected at 0, 7, 23, 47, 71, 95, 143, 167, 191 and 215h, the supernatant quenched and extracellular metabolites extracted. Metabolites were analyzed via untargeted metabolomics, including hierarchical clustering and correlation with quantified total and resistant bacterial populations. The time-courses of five metabolites were mathematically modeled. These five (of 1921 detected) metabolites were from enriched pathways (arginine and central carbon metabolism). Absorbed L-arginine and secreted L-ornithine were highly correlated with the total bacterial population (r -0.79 and 0.82 respectively, p<0.0001). Ribose-5-phosphate, sedoheptulose-7-phosphate and trehalose-6-phosphate correlated with the resistant subpopulation (0.64, 0.64 and 0.67, respectively, p<0.0001), and were likely secreted due to resistant growth overcoming oxidative and osmotic stress induced by ceftolozane/tazobactam. Using PK/PD-based transduction models, these metabolites were successfully modeled based on the total or resistant bacterial populations. The models well described the abundance of each metabolite across the differing time-course profiles of biological replicates, based on bacterial killing and, importantly, resistant regrowth. These proof-of-concept studies suggest further exploration is warranted to determine the generalizability of these findings. The metabolites modeled in this work are not exclusive to bacterial cells. Future studies may use this approach to identify bacteria-specific metabolites correlating with resistance, which would ultimately be extremely useful for clinical translation.
Institute:	Monash Institute of Pharmaceutical Sciences
Department:	Monash Institute of Pharmaceutical Sciences
Laboratory:	Cornelia Landersdorfer
Last Name:	Landersdorfer
First Name:	Cornelia
Address:	399 Royal Pd
Email:	dovile.anderson@monash.edu
Phone:	0448671141
Publications:	Identifying and mathematically modeling the time-course of extracellular metabolic markers associated with resistance to ceftolozane/tazobactam in Pseudomonas aeruginosa
Contributors:	Jessica R. Tait, Dovile Anderson, Roger L. Nation, Darren J. Creek, Cornelia B. Landersdorfer

Subject:

Subject ID:	SU003150
Subject Type:	Bacteria
Subject Species:	Pseudomonas aeruginosa
Taxonomy ID:	287
Genotype Strain:	CW41
Age Or Age Range:	NA
Weight Or Weight Range:	NA
Gender:	Not applicable

Factors:

Subject type: Bacteria; Subject species: Pseudomonas aeruginosa (Factor headings shown in green)

mb_sample_id	local_sample_id	treatment
SA328785	BR_Blank_broth_B0_B0	BR_Blank_broth_B0
SA328786	BR_Blank_broth_B1_E	BR_Blank_broth_B1
SA328787	BR_Blank_broth_B2_J	BR_Blank_broth_B2
SA328788	BR_Blank_broth_B2_F	BR_Blank_broth_B2
SA328789	BR_Blank_broth_B2_E	BR_Blank_broth_B2
SA328790	BR_Blank_broth_B3_i	BR_Blank_broth_B3
SA328791	BR_Blank_broth_B3_i_20200426061728	BR_Blank_broth_B3
SA328792	BR_Blank_broth_B3_J	BR_Blank_broth_B3
SA328793	BR_Blank_broth_B3_F_20200425222826	BR_Blank_broth_B3
SA328794	BR_Blank_broth_B3_F	BR_Blank_broth_B3
SA328795	BR_Blank_broth_B3_E	BR_Blank_broth_B3
SA328796	BR_Blank_broth_B4_A	BR_Blank_broth_B4
SA328797	BR_Blank_broth_B4_B	BR_Blank_broth_B4
SA328798	BR_Blank_broth_B4_i	BR_Blank_broth_B4
SA328799	BR_Blank_broth_B4_J	BR_Blank_broth_B4
SA328800	Blank_4	Extraction blank
SA328801	Blank_5	Extraction blank
SA328802	Blank_6	Extraction blank
SA328803	Blank_2	Extraction blank
SA328804	Blank_3	Extraction blank
SA328805	Blank_1	Extraction blank
SA328806	M_Cefto_3g_143h_E	M_Cefto_3g_143h
SA328807	M_Cefto_3g_143h_F	M_Cefto_3g_143h
SA328808	M_Cefto_3g_167h_E	M_Cefto_3g_167h
SA328809	M_Cefto_3g_167h_F	M_Cefto_3g_167h
SA328810	M_Cefto_3g_23h_E	M_Cefto_3g_23h
SA328811	M_Cefto_3g_23h_F	M_Cefto_3g_23h
SA328812	M_Cefto_3g_47h_F	M_Cefto_3g_47h
SA328813	M_Cefto_3g_47h_E	M_Cefto_3g_47h
SA328814	M_Cefto_3g_71h_F	M_Cefto_3g_71h
SA328815	M_Cefto_3g_71h_E	M_Cefto_3g_71h
SA328816	M_Cefto_3g_7h_E	M_Cefto_3g_7h
SA328817	M_Cefto_3g_7h_F	M_Cefto_3g_7h
SA328818	M_Cefto_3g_95h_E	M_Cefto_3g_95h
SA328819	M_Cefto_3g_95h_F	M_Cefto_3g_95h
SA328820	M_Cefto_6g_143h_i	M_Cefto_6g_143h
SA328821	M_Cefto_6g_143h_J	M_Cefto_6g_143h
SA328822	M_Cefto_6g_167h_J	M_Cefto_6g_167h
SA328823	M_Cefto_6g_167h_i	M_Cefto_6g_167h
SA328824	M_Cefto_6g_23h_i	M_Cefto_6g_23h
SA328825	M_Cefto_6g_23h_J	M_Cefto_6g_23h
SA328826	M_Cefto_6g_47h_i	M_Cefto_6g_47h
SA328827	M_Cefto_6g_47h_J	M_Cefto_6g_47h
SA328828	M_Cefto_6g_71h_i	M_Cefto_6g_71h
SA328829	M_Cefto_6g_71h_J	M_Cefto_6g_71h
SA328830	M_Cefto_6g_7h_J	M_Cefto_6g_7h
SA328831	M_Cefto_6g_7h_i	M_Cefto_6g_7h
SA328832	M_Cefto_6g_95h_i	M_Cefto_6g_95h
SA328833	M_Cefto_6g_95h_J	M_Cefto_6g_95h
SA328834	M_Control_143h_A	M_Control_143h
SA328835	M_Control_143h_B	M_Control_143h
SA328836	M_Control_167h_B	M_Control_167h
SA328837	M_Control_167h_A	M_Control_167h
SA328838	M_Control_23h_B	M_Control_23h
SA328839	M_Control_23h_A	M_Control_23h
SA328840	M_Control_47h_A	M_Control_47h
SA328841	M_Control_47h_B	M_Control_47h
SA328842	M_Control_71h_B	M_Control_71h
SA328843	M_Control_71h_A	M_Control_71h
SA328844	M_Control_7h_B	M_Control_7h
SA328845	M_Control_7h_A	M_Control_7h
SA328846	M_Control_95h_A	M_Control_95h
SA328847	M_Control_95h_B	M_Control_95h
SA328848	QC_6	Pooled QC
SA328849	QC_5	Pooled QC
SA328850	QC_1	Pooled QC
SA328851	QC_2	Pooled QC
SA328852	QC_3	Pooled QC
SA328853	QC_4	Pooled QC

Showing results 1 to 69 of 69

Showing results 1 to 69 of 69

Collection:

Collection ID:	CO003143
Collection Summary:	A hypermutable P. aeruginosa clinical isolate, CW41, was challenged with ceftolozane-tazobactam (Zerbaxa®, MSD, Australia) in the HFIM (C3008-1 cartridges; FiberCell Systems Inc., Frederick, MD, USA), in five biological replicates performed across two studies. The first study, with replicates 1 and 2, was conducted over 167 h and the second study, with replicates 3, 4 and 5, over 215 h. Briefly, the studied isolate was characterized as susceptible to ceftolozane-tazobactam (MIC 4 mg/L), and MDR (i.e. resistant to at least 1 antibiotic from each of ≥3 antibiotic classes) (17-20). The HFIM studies used cation-adjusted Mueller Hinton broth (CAMHB) and agar (CAMHA) [Becton Dickinson & Co., Sparks, MD, USA, with 25.0 mg/L Ca2+ and 12.5 mg/L Mg2+]. Ceftolozane-tazobactam was administered to simulate steady-state concentrations of ceftolozane predicted to occur in the epithelial lining fluid of the lung in patients with CF, following daily doses of 3 g/1.5 g and 6 g/3 g via continuous infusion (10.6 and 21.3 mg/L, respectively) (21-23). Total bacterial populations were quantified on antibiotic-free CAMHA, and resistant subpopulations on CAMHA containing ceftolozane-tazobactam (12 and 20 mg/L).
Sample Type:	Bacterial cells

Treatment:

Treatment ID:	TR003159
Treatment Summary:	Ceftolozane-tazobactam was administered to simulate steady-state concentrations of ceftolozane predicted to occur in the epithelial lining fluid of the lung in patients with CF, following daily doses of 3 g/1.5 g and 6 g/3 g via continuous infusion (10.6 and 21.3 mg/L, respectively) (21-23). Total bacterial populations were quantified on antibiotic-free CAMHA, and resistant subpopulations on CAMHA containing ceftolozane-tazobactam (12 and 20 mg/L).
Treatment Compound:	Ceftolozane-tazobactam
Treatment Dose:	3 g and 6 g
Treatment Dosevolume:	10.6 and 21.3 mg/L

Sample Preparation:

Sampleprep ID:	SP003156
Sampleprep Summary:	Each sample (25 µL) was added to 100 µL of pre-chilled methanol containing the internal standards (CHAPS, CAPS, TRIS and PIPES) at 1 µM. This mixture was vortexed, and subsequently centrifuged at 14800 x g and 4°C for 10 min .The final supernatant samples containing the extracted extracellular metabolites were stored at -80°C until LC-MS analysis was performed (Figure S2B).
Processing Method:	IDEOM
Processing Storage Conditions:	-80℃
Extract Storage:	-80℃

Combined analysis:

Analysis ID	AN004977	AN004978
Analysis type	MS	MS
Chromatography type	HILIC	HILIC
Chromatography system	Thermo Dionex Ultimate 3000	Thermo Dionex Ultimate 3000
Column	Merck SeQuant ZIC-pHILIC (150 x 4.6mm,5um)	Merck SeQuant ZIC-pHILIC (150 x 4.6mm,5um)
MS Type	ESI	ESI
MS instrument type	Orbitrap	Orbitrap
MS instrument name	Thermo Q Exactive Orbitrap	Thermo Q Exactive Orbitrap
Ion Mode	POSITIVE	NEGATIVE
Units	peak height	peak height

Chromatography:

Chromatography ID:	CH003758
Chromatography Summary:	ZIC-pHILIC chromatography at pH 9 using pos neg switching
Methods Filename:	Metabolomics_pHILIC_Parkville_v1.pdf
Instrument Name:	Thermo Dionex Ultimate 3000
Column Name:	Merck SeQuant ZIC-pHILIC (150 x 4.6mm,5um)
Column Temperature:	25 C
Flow Gradient:	0 min - 80%B, 15 min - 50%B, 18 min - 5%B, 21 min - 5%B, 24 min - 80%B, 32 min - 80%B
Flow Rate:	0.3 ml/min
Solvent A:	20 mM ammonium carbonate
Solvent B:	acetonitrile
Washing Buffer:	syringe wash 50% IPA
Chromatography Type:	HILIC

Chromatography ID:	CH003759
Chromatography Summary:	ZIC-pHILIC chromatography at pH 9 using pos neg switching
Methods Filename:	Metabolomics_pHILIC_Parkville_v1.pdf
Instrument Name:	Thermo Dionex Ultimate 3000
Column Name:	Merck SeQuant ZIC-pHILIC (150 x 4.6mm,5um)
Column Temperature:	25 C
Flow Gradient:	0 min - 80%B, 15 min - 50%B, 18 min - 5%B, 21 min - 5%B, 24 min - 80%B, 32 min - 80%B
Flow Rate:	0.3 ml/min
Solvent A:	20 mM ammonium carbonate
Solvent B:	acetonitrile
Washing Buffer:	syringe wash 50% IPA
Chromatography Type:	HILIC

MS:

MS ID:	MS004717
Analysis ID:	AN004977
Instrument Name:	Thermo Q Exactive Orbitrap
Instrument Type:	Orbitrap
MS Type:	ESI
MS Comments:	polarity switching used, resolution 35 k, full scan
Ion Mode:	POSITIVE
Capillary Temperature:	300 C
Capillary Voltage:	3.5 kV
Collision Energy:	NA
Dry Gas Flow:	50
Dry Gas Temp:	120
Ion Source Temperature:	120 C
Mass Accuracy:	3 ppm
Precursor Type:	[M+H]+
Acquisition Parameters File:	Metabolomics_pHILIC_Parkville_v1.pdf
Analysis Protocol File:	PQMS3-MPMF-WIN-0501_LCMS_data_acquisition_for_untargeted_metabolomics_analysis.pdf

MS ID:	MS004718
Analysis ID:	AN004978
Instrument Name:	Thermo Q Exactive Orbitrap
Instrument Type:	Orbitrap
MS Type:	ESI
MS Comments:	polarity switching used, resolution 35 k, full scan
Ion Mode:	NEGATIVE
Capillary Temperature:	300 C
Capillary Voltage:	4 kV
Collision Energy:	NA
Dry Gas Flow:	50
Dry Gas Temp:	120
Ion Source Temperature:	120 C
Mass Accuracy:	3 ppm
Precursor Type:	[M-H]-
Acquisition Parameters File:	Metabolomics_pHILIC_Parkville_v1.pdf
Analysis Protocol File:	PQMS3-MPMF-WIN-0501_LCMS_data_acquisition_for_untargeted_metabolomics_analysis.pdf