Sage Journals: Discover world-class research

Abstract

The antioxidant dihydrolipoic acid has been shown to reduce hypoxic and excitotoxic neuronal damage in vitro. In the present study, we tested whether pretreatment with α-lipoic acid, which presumably allows endogenous formation of dihydrolipoic acid, can protect cultured neurons against injury caused by cyanide, glutamate, or iron ions, using the trypan blue exclusion method to determine neuronal damage. One hour of preincubation with dihydrolipoic acid (1 μM), but not with α-lipoic acid, reduced damage of neurons from chick embryo telencephalon caused by 1 mM sodium cyanide or iron ions. α-Lipoic acid (1 μM) reduced cyanide-induced neuronal damage when added 24 h before hypoxia, and pretreatment with α-lipoic acid for >24 h enhanced this neuroprotective effect. Both the R- and the S-enantiomer of α-lipoic acid exerted a similar neuroprotective effect. Pretreatment with α-lipoic acid (1 μM) from the day of plating onward prevented the degeneration of chick embryo telencephalic neurons that had been exposed to Fe²⁺/Fe³⁺. α-Lipoic acid (1 μM) added to the culture medium the day of plating also reduced neuronal injury induced by 1 mM l-glutamate in rat hippocampal cultures, whereas 30 min of preincubation with α-lipoic acid failed to attenuate glutamate-induced neuronal damage. Our results indicate that neuroprotection by prolonged pretreatment with α-lipoic acid is probably due to the radical scavenger properties of endogenously formed dihydrolipoic acid.

Keywords

Cytotoxic hypoxia Dihydrolipoic acid Glutamate Lipoic acid Neuroprotection Primary neuronal cultures

References

Ahlemeyer

Krieglstein

, (1989) Testing drug effects against hypoxic damage of cultured neurons during long-term recovery. Life Sci 45:835–842

Aust

Morehouse

Thomas

, (1985) Role of metals in oxygen radical reactions. J Free Radical Biol Med 1:3–25

Bast

Haenen

GRMM

, (1988) Interplay between lipoic acid and glutathione in protection against microsomal lipid peroxidation. Biochim Biophys Acta 963:558–561

Braughler

Hall

, (1989) Central nervous system trauma and stroke. I. Biochemical considerations for oxygen radical formation and lipid peroxidation. J Free Radical Biol Med 6:289–301

Choi

, (1990) Methods for antagonizing glutamate neurotoxicity. Cerebrovasc Brain Metab Rev 2:105–147

Dawson

London

Bredt

Snyder

, (1991) Nitric oxide mediates glutamate neurotoxicity in primary cortical cultures. Proc Natl Acad Sci USA 88:6368–6371

Ehrenthal

Prellwitz

, (1986) Biochemie und Pharmakologie der Liponsäure. In: Interdisziplinäre Bestandsaufnahme der Polyneuropathien ( Neundörfer

Sailer

, eds), Erlangen, Perimed-Fachbuchverlag, pp 154–166

Flamm

Demopoulos

Seligman

Poser

Ransohoff

, (1978) Free radicals in cerebral ischemia. Stroke 9:445–447

Halliwell

Gutteridge

JMC

, (1985) Oxygen radicals and the nervous system. Trends Neurosci 8:22–26

10.

Halliwell

Gutteridge

JMC

, (1990) Role of free radicals and catalytic metal ions in human disease. Methods Enzymol 186:1–85

11.

Kagan

Shvedova

Serbinova

Khan

Swanson

Powell

Packer

, (1992) Dihydrolipoic acid—a universal antioxidant both in the membrane and in the aqueous phase. Biochem Pharmacol 44:1637–1649

12.

Lafon-Cazal

Pietri

Culcasi

Bockaert

, (1993) NMDA-dependent superoxide production and neurotoxicity. Nature 364:535–537

13.

Lipton

Choi

Pan

Lei

Chen

HSV

Sucher

Loscalzo

Singel

Stamler

, (1993) A redox-based mechanism for the neuroprotective and neurodestructive effects of nitric oxide and related nitroso-compounds. Nature 364:626–632

14.

Majewska

Bell

, (1990) Ascorbic acid protects neurons from injury induced by glutamate and NMDA. Neuroreport 1:194–196

15.

Monyer

Hartley

Choi

, (1990) 21-Aminosteroids attenuate excitotoxic neuronal injury in cortical cell cultures. Neuron 5:121–126

16.

Murase

Hattori

Kohno

Hayashi

, (1993) Stimulation of nerve growth factor synthesis/secretion in mouse astroglial cells by coenzymes. Biochem Mol Biol Int 30:615–621

17.

Packer

, (1992) New horizons in antioxidant research: Action of the thioctic acid/dihydrolipoic acid couple in biological systems. In: 2. International Thioctic Acid Workshop: Die Rolle des Redox-Systems alpha-Liponsäure/Dihydroliponsäure in organspezifischen Modellen einer gestörten Sauerstoffversorgung ( Schmidt

Ulrich

, eds), Frankfurt, Universimed Verlag, pp 35–45

18.

Pellegrini-Giampietro

Cherici

Alesiani

Carlà

Moroni

, (1988) Excitatory amino acid release from rat hippocampal slices as a consequence of free radical formation. J Neurochem 51:1960–1963

19.

Pettmann

Louis

Sensenbrenner

, (1979) Morphological and biochemical maturation of neurones cultured in the absence of glial cells. Nature 281:378–380

20.

Prehn

JHM

Karkoutly

Nuglisch

Peruche

Krieglstein

, (1992) Dihydrolipoate reduces neuronal injury after cerebral ischemia. J Cereb Blood Flow Metab 12:78–87

21.

Pruijn

Haenen

GRMM

Bast

, (1991) Interplay between vitamin E, glutathione and dihydrolipoic acid in protection against lipid peroxidation. Fat Sci Technol 6:216–221

22.

Sato

Saito

Katsuki

, (1993) Synergism of tocopherol and ascorbate on the survival of cultured brain neurones. Neuroreport 4:1179–1182

23.

Scholich

Murphy

Sies

, (1989) Antioxidant activity of dihydrolipoate against microsomal lipid peroxidation and its dependence on α-tocopherol. Biochim Biophys Acta 1001:256–261

24.

Siesjö

Agardh

Bengtsson

, (1989) Free radicals and brain damage. Cerebrovasc Brain Metab Rev 1:165–211

25.

Suzuki

Tsuchiya

Packer

, (1991) Thioctic acid and dihydrolipoic acid are novel antioxidants which interact with reactive oxygen species. Free Radical Res Commun 15:255–263

26.

Suzuki

Tsuchiya

Packer

, (1993) Antioxidant activities of dihydrolipoic acid and its structural homologues. Free Radical Res Commun 18:115–122

27.

Tang

Aizenman

, (1993) Allosteric modulation of the NMDA receptor by dihydrolipoic and lipoic acid in rat cortical neurons in vitro. Neuron 11:857–863

Prolonged Pretreatment with α-Lipoic Acid Protects Cultured Neurons against Hypoxic,Glutamate-,or Iron-Induced Injury

Abstract

Keywords

References