Abstract
The survival and function of brain cells requires uninterrupted ATP synthesis. Different brain structures subserve distinct neurological functions, and therefore have different energy production/consumption requirements. Typically, mitochondrial function is assessed following their isolation from relatively large amounts of starting tissue, making it difficult to ascertain energy production/failure in small anatomical locations. In order to overcome this limitation, we have developed and optimized a method to measure mitochondrial function in brain tissue biopsy punches excised from anatomically defined brain structures, including white matter tracts. We describe the procedures for maintaining tissue viability prior to performing the biopsy punches, as well as provide guidance for optimizing punch size and the drug doses needed to assess various aspects of mitochondrial respiration. We demonstrate that our method can be used to measure mitochondrial respiration in anatomically defined subfields within the rat hippocampus. Using this method, we present experimental results which show that a mild traumatic brain injury (mTBI, often referred to as concussion) causes differential mitochondrial responses within these hippocampal subfields and the corpus callosum, novel findings that would have been difficult to obtain using traditional mitochondrial isolation methods. Our method is easy to implement and will be of interest to researchers working in the field of brain bioenergetics and brain diseases.
Highlights
Respiration in a cellular context, in vitro cultures do not recapitulate the complex three dimensional brain anatomy and heterogeneous cellular environment that exists within the brain, especially in experimental models of brain diseases
In the Seahorse metabolic analyzer, mitochondrial function can be assessed by real-time monitoring of the oxygen consumption rate (OCR; primarily consumed by glucose metabolism through the citric acid cycle)
The residual OCR observed after addition of these two compounds is carried out by non-mitochondrial oxygen-consuming enzymes that may be present in the sample
Summary
Respiration in a cellular context, in vitro cultures do not recapitulate the complex three dimensional brain anatomy and heterogeneous cellular environment that exists within the brain, especially in experimental models of brain diseases. Seahorse XF analyzers (marketed by Agilent) are being used to assess mitochondrial function by measuring their oxygen consumption rate (OCR) in response to modulators of key components of the electron transport chain While these instruments have been used to assess mitochondrial function in intact tissues[29,30,31,32,33], it has proven to be challenging to measure brain tissue respiration in anatomically defined regions in a highthroughput manner. We employed our method to show that mild traumatic brain injury (mTBI) results in distinct mitochondrial responses within different hippocampal subfields, a finding which has not been described previously This method is adaptable to meet specific experimental requirements, and can be used to map changes in mitochondrial function in different brain regions/ subregions that may arise from many different pathological conditions or disease states
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