Obesity and cage environment modulate metabolism in the Zucker rat: a multiple biological matrix approach to characterizing metabolic phenomena
Obesity and cage environment modulate metabolism in the Zucker rat: a multiple biological matrix approach to characterizing metabolic phenomena
Obesity and its comorbidities are increasing worldwide imposing a heavy socioeconomic burden. The effects of obesity on the metabolic profiles of tissues (liver, kidney, pancreas), urine, and the systemic circulation were investigated in the Zucker rat model using 1H NMR spectroscopy coupled to multivariate statistical analysis. The metabolic profiles of the obese ( fa/ fa) animals were clearly differentiated from the two phenotypically lean phenotypes, ((+/+) and ( fa/+)) within each biological compartment studied, and across all matrices combined. No significant differences were observed between the metabolic profiles of the genotypically distinct lean strains. Obese Zucker rats were characterized by higher relative concentrations of blood lipid species, cross-compartmental amino acids (particularly BCAAs), urinary and liver metabolites relating to the TCA cycle and glucose metabolism; and lower amounts of urinary gut microbial-host cometabolites, and intermatrix metabolites associated with creatine metabolism. Further to this, the obese Zucker rat metabotype was defined by significant metabolic alterations relating to disruptions in the metabolism of choline across all compartments analyzed. The cage environment was found to have a significant effect on urinary metabolites related to gut-microbial metabolism, with additional cage-microenvironment trends also observed in liver, kidney, and pancreas. This study emphasizes the value in metabotyping multiple biological matrices simultaneously to gain a better understanding of systemic perturbations in metabolism, and also underscores the need for control or evaluation of cage environment when designing and interpreting data from metabonomic studies in animal models.
2160-2174
Lees, Hannah J.
065ec499-13b2-4a01-bd6a-7e2102905c84
Swann, Jonathan R.
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Poucher, Simon
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Holmes, Elaine
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Wilson, Ian D.
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Nicholson, Jeremy K.
72991774-7e08-4592-ae57-e7dcc2ec158e
3 May 2019
Lees, Hannah J.
065ec499-13b2-4a01-bd6a-7e2102905c84
Swann, Jonathan R.
7c11a66b-f4b8-4dbf-aa17-ad8b0561b85c
Poucher, Simon
eb839294-7f30-463f-8bfb-2f7db6b85588
Holmes, Elaine
d3b92a6b-1c3f-4758-b653-ba35afd3f57d
Wilson, Ian D.
d7da811b-6cc9-4166-82d0-e780c95122d2
Nicholson, Jeremy K.
72991774-7e08-4592-ae57-e7dcc2ec158e
Lees, Hannah J., Swann, Jonathan R., Poucher, Simon, Holmes, Elaine, Wilson, Ian D. and Nicholson, Jeremy K.
(2019)
Obesity and cage environment modulate metabolism in the Zucker rat: a multiple biological matrix approach to characterizing metabolic phenomena.
Journal of Proteome Research, 18 (5), .
(doi:10.1021/acs.jproteome.9b00040).
Abstract
Obesity and its comorbidities are increasing worldwide imposing a heavy socioeconomic burden. The effects of obesity on the metabolic profiles of tissues (liver, kidney, pancreas), urine, and the systemic circulation were investigated in the Zucker rat model using 1H NMR spectroscopy coupled to multivariate statistical analysis. The metabolic profiles of the obese ( fa/ fa) animals were clearly differentiated from the two phenotypically lean phenotypes, ((+/+) and ( fa/+)) within each biological compartment studied, and across all matrices combined. No significant differences were observed between the metabolic profiles of the genotypically distinct lean strains. Obese Zucker rats were characterized by higher relative concentrations of blood lipid species, cross-compartmental amino acids (particularly BCAAs), urinary and liver metabolites relating to the TCA cycle and glucose metabolism; and lower amounts of urinary gut microbial-host cometabolites, and intermatrix metabolites associated with creatine metabolism. Further to this, the obese Zucker rat metabotype was defined by significant metabolic alterations relating to disruptions in the metabolism of choline across all compartments analyzed. The cage environment was found to have a significant effect on urinary metabolites related to gut-microbial metabolism, with additional cage-microenvironment trends also observed in liver, kidney, and pancreas. This study emphasizes the value in metabotyping multiple biological matrices simultaneously to gain a better understanding of systemic perturbations in metabolism, and also underscores the need for control or evaluation of cage environment when designing and interpreting data from metabonomic studies in animal models.
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e-pub ahead of print date: 2 April 2019
Published date: 3 May 2019
Identifiers
Local EPrints ID: 440778
URI: http://eprints.soton.ac.uk/id/eprint/440778
ISSN: 1535-3893
PURE UUID: 2155d5e5-f3f3-47b8-8e55-f98a951aefc6
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Date deposited: 18 May 2020 16:33
Last modified: 17 Mar 2024 04:00
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Author:
Hannah J. Lees
Author:
Simon Poucher
Author:
Elaine Holmes
Author:
Ian D. Wilson
Author:
Jeremy K. Nicholson
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