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Influence of severe hypoglycemia on mitochondrial and plasma membrane function in rat brain

Agardh, Carl-David LU ; Chapman, A G ; Pelligrino, D and Siesjö, Bo LU (1982) In Journal of Neurochemistry 38(3). p.662-668
Abstract
Abstract: Previous experiments have shown that severe hypoglycemia disrupts cerebral energy state in spite of a maintained cerebral oxygen consumption, suggesting uncoupling of oxidative phosphorylation. Other studies have demonstrated that hypoglycemia leads to loss of cerebral cortical phospholipids and phospholipid-bound fatty acids. The objective of the present study was, therefore, to study respiratory characteristics of brain mitochondria during severe hypoglycemia and to correlate respiratory activity to mitochondrial phospholipid composition. Mitochondria were isolated after 30 or 60 min of hypoglycemia with ceased EEG activity, and after a 90-min recovery period, and their resting (state 4) and ADP-stimulated (state 3) oxygen... (More)
Abstract: Previous experiments have shown that severe hypoglycemia disrupts cerebral energy state in spite of a maintained cerebral oxygen consumption, suggesting uncoupling of oxidative phosphorylation. Other studies have demonstrated that hypoglycemia leads to loss of cerebral cortical phospholipids and phospholipid-bound fatty acids. The objective of the present study was, therefore, to study respiratory characteristics of brain mitochondria during severe hypoglycemia and to correlate respiratory activity to mitochondrial phospholipid composition. Mitochondria were isolated after 30 or 60 min of hypoglycemia with ceased EEG activity, and after a 90-min recovery period, and their resting (state 4) and ADP-stimulated (state 3) oxygen consumption rates and phospholipids and phospholipid-bound fatty acid content were measured. After 30 min of hypoglycemia, state 3 respiration decreased without any increase in state 4 respiration or change in ADP/O ratio. This decrease, which occurred with glutamate plus malate—but not with succinate—as substrates, was partly reversed by addition of bovine serum albumin and KCI. Chemical analyses of isolated mitochondria did not reveal changes in their phospholipid or fatty acid content. The results thus failed to account for the dissociation of cerebral energy state and oxygen consumption. It is emphasized, though, that uncoupling may well occur in vivo due to accumulation of free fatty acids and "futile cycling" of K+ and Ca2+. After 60 min of hypoglycemia, a moderate decrease in state 3 respiration was observed also with succinate as substrate, and there was some decrease in ADP/O ratios in KCI-containing media. However, the changes in ADP/O ratios were more conspicuous during recovery; in addition, state 4 respiration increased significantly. It is concluded that changes in mitochondrial function after 30 min of hypoglycemia are potentially reversible but that true mitochondrial failure develops in the recovery period following 60 min of hypoglycemia. This conclusion was corroborated by results demonstrating incomplete recovery of cerebral energy state. Since EEG and sensory evoked potentials return after 30 min but not after 60 min of hypoglycemia it seemed difficult to explain failure of return of electrophysiological function after 60 min of hypoglycemia solely by mitochondrial dysfunction; plasma membrane function was therefore assessed by measurements of extracellular potassium activity ([K+]e). The results showed that whereas [K+]e remained close to control in the recovery period following 30 min of hypoglycemia it rose progressively during recovery following 60 min of hypoglycemia. Possibly, inhibition of Na+ K+–activated ATPase could contribute to the permanent loss of spontaneous or evoked electrical activity. (Less)
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author
; ; and
organization
publishing date
type
Contribution to journal
publication status
published
subject
keywords
Rat, Extracellular potassium, Mitochondrial function, Hypoglycemia, Brain, Phospholipid content
in
Journal of Neurochemistry
volume
38
issue
3
pages
662 - 668
publisher
Wiley-Blackwell
external identifiers
  • pmid:7035617
  • scopus:0020071412
ISSN
1471-4159
DOI
10.1111/j.1471-4159.1982.tb08682.x
language
English
LU publication?
yes
additional info
The information about affiliations in this record was updated in December 2015. The record was previously connected to the following departments: Neurology, Lund (013027000), Unit on Vascular Diabetic Complications (013241510)
id
90d60b60-f491-40c0-b7ef-856ab6dd4a7a (old id 1102945)
date added to LUP
2016-04-01 15:52:41
date last changed
2021-01-03 11:13:36
@article{90d60b60-f491-40c0-b7ef-856ab6dd4a7a,
  abstract     = {{Abstract: Previous experiments have shown that severe hypoglycemia disrupts cerebral energy state in spite of a maintained cerebral oxygen consumption, suggesting uncoupling of oxidative phosphorylation. Other studies have demonstrated that hypoglycemia leads to loss of cerebral cortical phospholipids and phospholipid-bound fatty acids. The objective of the present study was, therefore, to study respiratory characteristics of brain mitochondria during severe hypoglycemia and to correlate respiratory activity to mitochondrial phospholipid composition. Mitochondria were isolated after 30 or 60 min of hypoglycemia with ceased EEG activity, and after a 90-min recovery period, and their resting (state 4) and ADP-stimulated (state 3) oxygen consumption rates and phospholipids and phospholipid-bound fatty acid content were measured. After 30 min of hypoglycemia, state 3 respiration decreased without any increase in state 4 respiration or change in ADP/O ratio. This decrease, which occurred with glutamate plus malate—but not with succinate—as substrates, was partly reversed by addition of bovine serum albumin and KCI. Chemical analyses of isolated mitochondria did not reveal changes in their phospholipid or fatty acid content. The results thus failed to account for the dissociation of cerebral energy state and oxygen consumption. It is emphasized, though, that uncoupling may well occur in vivo due to accumulation of free fatty acids and "futile cycling" of K+ and Ca2+. After 60 min of hypoglycemia, a moderate decrease in state 3 respiration was observed also with succinate as substrate, and there was some decrease in ADP/O ratios in KCI-containing media. However, the changes in ADP/O ratios were more conspicuous during recovery; in addition, state 4 respiration increased significantly. It is concluded that changes in mitochondrial function after 30 min of hypoglycemia are potentially reversible but that true mitochondrial failure develops in the recovery period following 60 min of hypoglycemia. This conclusion was corroborated by results demonstrating incomplete recovery of cerebral energy state. Since EEG and sensory evoked potentials return after 30 min but not after 60 min of hypoglycemia it seemed difficult to explain failure of return of electrophysiological function after 60 min of hypoglycemia solely by mitochondrial dysfunction; plasma membrane function was therefore assessed by measurements of extracellular potassium activity ([K+]e). The results showed that whereas [K+]e remained close to control in the recovery period following 30 min of hypoglycemia it rose progressively during recovery following 60 min of hypoglycemia. Possibly, inhibition of Na+ K+–activated ATPase could contribute to the permanent loss of spontaneous or evoked electrical activity.}},
  author       = {{Agardh, Carl-David and Chapman, A G and Pelligrino, D and Siesjö, Bo}},
  issn         = {{1471-4159}},
  keywords     = {{Rat; Extracellular potassium; Mitochondrial function; Hypoglycemia; Brain; Phospholipid content}},
  language     = {{eng}},
  number       = {{3}},
  pages        = {{662--668}},
  publisher    = {{Wiley-Blackwell}},
  series       = {{Journal of Neurochemistry}},
  title        = {{Influence of severe hypoglycemia on mitochondrial and plasma membrane function in rat brain}},
  url          = {{http://dx.doi.org/10.1111/j.1471-4159.1982.tb08682.x}},
  doi          = {{10.1111/j.1471-4159.1982.tb08682.x}},
  volume       = {{38}},
  year         = {{1982}},
}