Summary of Study ST002063

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 PR001306. The data can be accessed directly via it's Project DOI: 10.21228/M8WT4R This work is supported by NIH grant, U2C- DK119886.

See: https://www.metabolomicsworkbench.org/about/howtocite.php

Study ID	ST002063
Study Title	Intravenous lipopolysaccharide infusion and the bovine metabolome
Study Type	MS plasma lipidomics and metabolomics
Study Summary	The effects of lipopolysaccharides (i.e., endotoxin; LPS) on metabolism are poorly defined in lactating dairy cattle experiencing hyperlipidemia. Our objective was to explore the effects of acute intravenous LPS administration on metabolism in late-lactation Holstein cows experiencing hyperlipidemia. Ten non-pregnant lactating Holstein cows (273 ± 35 d in milk) were administered a single bolus of saline (3 mL of saline; n = 5) or LPS (0.375 μg of LPS/kg of body weight; n = 5). Simultaneously, cows were intravenously infused a triglyceride emulsion and fasted for 16 h to induce hyperlipidemia in an attempt to model the periparturient period. Blood was sampled at routine intervals. Changes in circulating total fatty acid concentrations and inflammatory parameters were measured. Plasma samples were analyzed using untargeted lipidomics and metabolomics. Endotoxin increased circulating serum amyloid A, LPS-binding protein, and cortisol concentrations. Endotoxin administration decreased plasma lysophosphatidylcholine (LPC) concentrations and increased select plasma ceramide concentrations. These outcomes suggest modulation of the immune response and insulin action. Lipopolysaccharide decreased the ratio of phosphatidylcholine to phosphatidylethanomanine, which potentially indicate a decrease in the hepatic activation of phosphatidylethanolamine N-methyltransferase and triglyceride export. Endotoxin administration also increased plasma concentrations of pyruvic and lactic acids, and decreased plasma citric acid concentrations, which implicate the upregulation of glycolysis and downregulation of the citric acid cycle (i.e., the Warburg effect), potentially in leukocytes. Acute intravenous LPS administration decreased circulating LPC concentrations, modified ceramide and glycerophospholipid concentrations, and influenced intermediary metabolism in dairy cows experiencing hyperlipidemia.
Institute	Cornell University
Department	Animal Science
Laboratory	McFadden lab
Last Name	Javaid
First Name	Awais
Address	400 Warren Rd, Ithaca, New York, 14850, USA
Email	aj366@cornell.edu
Phone	6072287246
Submit Date	2022-01-09
Raw Data Available	Yes
Raw Data File Type(s)	mzXML
Analysis Type Detail	LC-MS
Release Date	2022-06-30
Release Version	1

Select appropriate tab below to view additional metadata details:

Project:

Project ID:	PR001306
Project DOI:	doi: 10.21228/M8WT4R
Project Title:	Intravenous lipopolysaccharide infusion and the bovine metabolome
Project Type:	MS lipidomics and metabolomics
Project Summary:	The effects of lipopolysaccharides (i.e., endotoxin; LPS) on metabolism are poorly defined in lactating dairy cattle experiencing hyperlipidemia. Our objective was to explore the effects of acute intravenous LPS administration on metabolism in late-lactation Holstein cows experiencing hyperlipidemia. Ten non-pregnant lactating Holstein cows (273 ± 35 d in milk) were administered a single bolus of saline (3 mL of saline; n = 5) or LPS (0.375 μg of LPS/kg of body weight; n = 5). Simultaneously, cows were intravenously infused a triglyceride emulsion and fasted for 16 h to induce hyperlipidemia in an attempt to model the periparturient period. Blood was sampled at routine intervals. Changes in circulating total fatty acid concentrations and inflammatory parameters were measured. Plasma samples were analyzed using untargeted lipidomics and metabolomics. Endotoxin increased circulating serum amyloid A, LPS-binding protein, and cortisol concentrations. Endotoxin administration decreased plasma lysophosphatidylcholine (LPC) concentrations and increased select plasma ceramide concentrations. These outcomes suggest modulation of the immune response and insulin action. Lipopolysaccharide decreased the ratio of phosphatidylcholine to phosphatidylethanomanine, which potentially indicate a decrease in the hepatic activation of phosphatidylethanolamine N-methyltransferase and triglyceride export. Endotoxin administration also increased plasma concentrations of pyruvic and lactic acids, and decreased plasma citric acid concentrations, which implicate the upregulation of glycolysis and downregulation of the citric acid cycle (i.e., the Warburg effect), potentially in leukocytes. Acute intravenous LPS administration decreased circulating LPC concentrations, modified ceramide and glycerophospholipid concentrations, and influenced intermediary metabolism in dairy cows experiencing hyperlipidemia.
Institute:	Animal Science
Department:	Animal Science
Laboratory:	McFadden lab
Last Name:	Javaid
First Name:	Awais
Address:	400 Warren Rd, Ithaca, New York, 14850, USA
Email:	aj366@cornell.edu
Phone:	6072287246
Funding Source:	Agriculture and Food Research Initiative grant no. 2018-67015-27548

Subject:

Subject ID:	SU002145
Subject Type:	Mammal
Subject Species:	Bos taurus
Taxonomy ID:	9913
Genotype Strain:	Holstein dairy cows
Age Or Age Range:	4- 5 years
Weight Or Weight Range:	733-797
Gender:	Female
Animal Housing:	Tie stall
Animal Feed:	TMR Ad lib
Animal Water:	Ad libitum
Animal Inclusion Criteria:	lactation stage, Days in milk

Factors:

Subject type: Mammal; Subject species: Bos taurus (Factor headings shown in green)

mb_sample_id	local_sample_id	Time	Treatment	Category
SA194101	233-10336_CON-IL_12.raw	12	CON	Lipidomics
SA194102	234-9855_CON-IL_12.raw	12	CON	Lipidomics
SA194103	231-9852_CON-IL_12.raw	12	CON	Lipidomics
SA194104	230-9609_CON-IL_12.raw	12	CON	Lipidomics
SA194105	232-9610_CON-IL_12.raw	12	CON	Lipidomics
SA194106	238-9785_LPS-IL_12.raw	12	LPS	Lipidomics
SA194107	237-10008_LPS-IL_12.raw	12	LPS	Lipidomics
SA194108	235-10218_LPS-IL_12.raw	12	LPS	Lipidomics
SA194109	239-10103_LPS-IL_12.raw	12	LPS	Lipidomics
SA194110	236-8473_LPS-IL_12.raw	12	LPS	Lipidomics
SA194111	241-9852_CON-IL_16.raw	16	CON	Lipidomics
SA194112	240-9609_CON-IL_16.raw	16	CON	Lipidomics
SA194113	244-9855_CON-IL_16.raw	16	CON	Lipidomics
SA194114	242-9610_CON-IL_16.raw	16	CON	Lipidomics
SA194115	243-10336_CON-IL_16.raw	16	CON	Lipidomics
SA194116	9609CON-IL-16_NEG.raw	16	CON	Metabolomics
SA194117	9852CON-IL-16_NEG.raw	16	CON	Metabolomics
SA194118	9855CON-IL-16_NEG.raw	16	CON	Metabolomics
SA194119	10336CON-IL-16_NEG.raw	16	CON	Metabolomics
SA194120	9610CON-IL-16_NEG.raw	16	CON	Metabolomics
SA194121	249-10103_LPS-IL_16.raw	16	LPS	Lipidomics
SA194122	245-10218_LPS-IL_16.raw	16	LPS	Lipidomics
SA194123	246-8473_LPS-IL_16.raw	16	LPS	Lipidomics
SA194124	248-9785_LPS-IL_16.raw	16	LPS	Lipidomics
SA194125	247-10008_LPS-IL_16.raw	16	LPS	Lipidomics
SA194126	10218LPS-IL-16_NEG.raw	16	LPS	Metabolomics
SA194127	10103LPS-IL-16_NEG.raw	16	LPS	Metabolomics
SA194128	8473LPS-IL-16_NEG.raw	16	LPS	Metabolomics
SA194129	9785LPS-IL-16_NEG.raw	16	LPS	Metabolomics
SA194130	10008LPS-IL-16_NEG.raw	16	LPS	Metabolomics
SA194131	251-9852_CON-IL_24.raw	24	CON	Lipidomics
SA194132	254-9855_CON-IL_24.raw	24	CON	Lipidomics
SA194133	250-9609_CON-IL_24.raw	24	CON	Lipidomics
SA194134	253-10336_CON-IL_24.raw	24	CON	Lipidomics
SA194135	252-9610_CON-IL_24.raw	24	CON	Lipidomics
SA194136	257-10008_LPS-IL_24.raw	24	LPS	Lipidomics
SA194137	259-10103_LPS-IL_24.raw	24	LPS	Lipidomics
SA194138	255-10218_LPS-IL_24.raw	24	LPS	Lipidomics
SA194139	258-9785_LPS-IL_24.raw	24	LPS	Lipidomics
SA194140	256-8473_LPS-IL_24.raw	24	LPS	Lipidomics
SA194141	264-9855_CON-IL_48.raw	48	CON	Lipidomics
SA194142	260-9609_CON-IL_48.raw	48	CON	Lipidomics
SA194143	262-9610_CON-IL_48.raw	48	CON	Lipidomics
SA194144	261-9852_CON-IL_48.raw	48	CON	Lipidomics
SA194145	263-10336_CON-IL_48.raw	48	CON	Lipidomics
SA194146	265-10218_LPS-IL_48.raw	48	LPS	Lipidomics
SA194147	266-8473_LPS-IL_48.raw	48	LPS	Lipidomics
SA194148	267-10008_LPS-IL_48.raw	48	LPS	Lipidomics
SA194149	269-10103_LPS-IL_48.raw	48	LPS	Lipidomics
SA194150	268-9785_LPS-IL_48.raw	48	LPS	Lipidomics
SA194151	211-9852_CON-IL_4.raw	4	CON	Lipidomics
SA194152	210-9609_CON-IL_4.raw	4	CON	Lipidomics
SA194153	214-9855_CON-IL_4.raw	4	CON	Lipidomics
SA194154	213-10336_CON-IL_4.raw	4	CON	Lipidomics
SA194155	212-9610_CON-IL_4.raw	4	CON	Lipidomics
SA194156	216-8473_LPS-IL_4.raw	4	LPS	Lipidomics
SA194157	218-9785_LPS-IL_4.raw	4	LPS	Lipidomics
SA194158	217-10008_LPS-IL_4.raw	4	LPS	Lipidomics
SA194159	215-10218_LPS-IL_4.raw	4	LPS	Lipidomics
SA194160	219-10103_LPS-IL_4.raw	4	LPS	Lipidomics
SA194161	222-9610_CON-IL_8.raw	8	CON	Lipidomics
SA194162	220-9609_CON-IL_8.raw	8	CON	Lipidomics
SA194163	224-9855_CON-IL_8.raw	8	CON	Lipidomics
SA194164	223-10336_CON-IL_8.raw	8	CON	Lipidomics
SA194165	221-9852_CON-IL_8.raw	8	CON	Lipidomics
SA194166	9855CON-IL-8_NEG.raw	8	CON	Metabolomics
SA194167	10336CON-IL-8_NEG.raw	8	CON	Metabolomics
SA194168	9852CON-IL-8_NEG.raw	8	CON	Metabolomics
SA194169	9609CON-IL-8_NEG.raw	8	CON	Metabolomics
SA194170	9610CON-IL-8_NEG.raw	8	CON	Metabolomics
SA194171	227-10008_LPS-IL_8.raw	8	LPS	Lipidomics
SA194172	229-10103_LPS-IL_8.raw	8	LPS	Lipidomics
SA194173	228-9785_LPS-IL_8.raw	8	LPS	Lipidomics
SA194174	226-8473_LPS-IL_8.raw	8	LPS	Lipidomics
SA194175	225-10218_LPS-IL_8.raw	8	LPS	Lipidomics
SA194176	8473LPS-IL-8_NEG.raw	8	LPS	Metabolomics
SA194177	9785LPS-IL-8_NEG.raw	8	LPS	Metabolomics
SA194178	10103LPS-IL-8_NEG.raw	8	LPS	Metabolomics
SA194179	10008LPS-IL-8_NEG.raw	8	LPS	Metabolomics
SA194180	10218LPS-IL-8_NEG.raw	8	LPS	Metabolomics
SA194098	QC_3_NEG.raw	.	.	Metabolomics
SA194099	QC_1_NEG.raw	.	.	Metabolomics
SA194100	QC_2_NEG.raw	.	.	Metabolomics
SA194078	202-9610_CON-IL_0.raw	-	CON	Lipidomics
SA194079	204-9855_CON-IL_0.raw	-	CON	Lipidomics
SA194080	200-9609_CON-IL_0.raw	-	CON	Lipidomics
SA194081	201-9852_CON-IL_0.raw	-	CON	Lipidomics
SA194082	203-10336_CON-IL_0.raw	-	CON	Lipidomics
SA194083	10336CON-IL-0_NEG.raw	-	CON	Metabolomics
SA194084	9610CON-IL-0_NEG.raw	-	CON	Metabolomics
SA194085	9852CON-IL-0_NEG.raw	-	CON	Metabolomics
SA194086	9855CON-IL-0_NEG.raw	-	CON	Metabolomics
SA194087	9609CON-IL-0_NEG.raw	-	CON	Metabolomics
SA194088	206-8473_LPS-IL_0.raw	-	LPS	Lipidomics
SA194089	209-10103_LPS-IL_0.raw	-	LPS	Lipidomics
SA194090	208-9785_LPS-IL_0.raw	-	LPS	Lipidomics
SA194091	205-10218_LPS-IL_0.raw	-	LPS	Lipidomics
SA194092	207-10008_LPS-IL_0.raw	-	LPS	Lipidomics
SA194093	10008LPS-IL-0_NEG.raw	-	LPS	Metabolomics
SA194094	8473LPS-IL-0_NEG.raw	-	LPS	Metabolomics

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Collection:

Collection ID:	CO002138
Collection Summary:	Blood was collected via coccygeal venipuncture after the morning milking during the baseline period and at -0.5, 0, 4, 8, 16, 24, and 48 h, relative to saline or LPS administration. Plasma samples were incubated on ice for 30 min before centrifugation.
Collection Protocol ID:	N/A
Collection Protocol Filename:	Collection_Protocol.docx
Collection Protocol Comments:	N/A
Sample Type:	Blood (plasma)
Collection Method:	Blood collection using venipuncture needle
Collection Location:	Coccygeal venipuncture
Collection Frequency:	At interval of -0.5, 0, 4, 8, 16, 24, and 48 h respectively
Collection Duration:	1 min
Volumeoramount Collected:	10ml
Storage Conditions:	-20℃
Collection Vials:	10 ml blood vial
Storage Vials:	Eppendorf tubes 2ml
Collection Tube Temp:	4°C

Treatment:

Treatment ID:	TR002157
Treatment Summary:	Sterile saline (CON; n = 5) or 2) LPS (0.375 μg of LPS/kg of BW in sterile saline; Escherichia coli O55:B5; Sigma Aldrich, St. Louis, MO; n = 5)
Treatment Protocol ID:	N/A
Treatment Protocol Filename:	N A

Sample Preparation:

Sampleprep ID:	SP002151
Sampleprep Summary:	Untargeted lipidomics samples were prepared by dissolving in dicholormethane/ methanol ( MeOH; 2:1). Untargeted metabolomics was done by centrifugation, samples were re-suspended with 60% ACN prior to analysis. FOR details please refer to publication Wang et al 2022.

Combined analysis:

Analysis ID	AN003362
Analysis type	MS
Chromatography type	Reversed phase
Chromatography system	Vanquish UHPLC system
Column	Accucore C30 (150 x 2.1mm,2.6um)
MS Type	ESI
MS instrument type	Single quadrupole
MS instrument name	Thermo Q Exactive HF hybrid Orbitrap
Ion Mode	UNSPECIFIED
Units	Normalized ion intensity

Chromatography:

Chromatography ID:	CH002488
Chromatography Summary:	Chromatographic separation was performed on a Vanquish UHPLC system with an Accucore C30, 2.6 μm column (2.1 mm id × 150mm) coupled to a Q Exactive™ Hybrid Quadrupole-Orbitrap High Resolution Mass Spectrometer (Thermo Fisher Scientific, San Jose, CA) and generated data was processed using LipidSearch™ software version 4.1 (Thermo Scientific),
Methods Filename:	Genenral_method_for_Untargeted_Metabolomics_Mar2020.docx
Instrument Name:	Vanquish UHPLC system
Column Name:	Accucore C30 (150 x 2.1mm,2.6um)
Chromatography Type:	Reversed phase

MS:

MS ID:	MS003131
Analysis ID:	AN003362
Instrument Name:	Thermo Q Exactive HF hybrid Orbitrap
Instrument Type:	Single quadrupole
MS Type:	ESI
MS Comments:	Please refer to publication Wang et al 2022.
Ion Mode:	UNSPECIFIED