Spatially Resolved Isotope Tracing Reveals Tissue Metabolic Activity

Overview

Journal Nat Methods

Specialties Biomedical Engineering
Pathology

Date 2022 Feb 8

PMID 35132243

Authors

Lin Wang

Xi Xing

Xianfeng Zeng

S RaElle Jackson

Tara TeSlaa

Osama Al-Dalahmah

Laith Z Samarah

Katharine Goodwin

Lifeng Yang

Melanie R McReynolds

Xiaoxuan Li

Jeremy J Wolff

Joshua D Rabinowitz

Shawn M Davidson

Affiliations

Soon will be listed here.

Abstract

Isotope tracing has helped to determine the metabolic activities of organs. Methods to probe metabolic heterogeneity within organs are less developed. We couple stable-isotope-labeled nutrient infusion to matrix-assisted laser desorption ionization imaging mass spectrometry (iso-imaging) to quantitate metabolic activity in mammalian tissues in a spatially resolved manner. In the kidney, we visualize gluconeogenic flux and glycolytic flux in the cortex and medulla, respectively. Tricarboxylic acid cycle substrate usage differs across kidney regions; glutamine and citrate are used preferentially in the cortex and fatty acids are used in the medulla. In the brain, we observe spatial gradations in carbon inputs to the tricarboxylic acid cycle and glutamate under a ketogenic diet. In a carbohydrate-rich diet, glucose predominates throughout but in a ketogenic diet, 3-hydroxybutyrate contributes most strongly in the hippocampus and least in the midbrain. Brain nitrogen sources also vary spatially; branched-chain amino acids contribute most in the midbrain, whereas ammonia contributes in the thalamus. Thus, iso-imaging can reveal the spatial organization of metabolic activity.

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