The effects of antidepressants on mitochondrial function in a model cell system and isolated mitochondria.

The in vitro effects of antidepressant drugs on mitochondrial function were investigated in a CHOß(2)SPAP cell line used previously to determine the effects of antidepressants on gene transcription (Abdel-Razaq et al., Biochem Pharmacol 73:1995-2003, 2007) and in rat heart isolated mitochondria. Apoptotic effects of clomipramine (CLOM), desipramine (DMI) and of norfluoxetine (NORF, the active metabolite of fluoxetine), on cellular viability were indicated by morphological changes and concentration-dependent increases in caspase-3 activity in CHO cells after 18 h exposure to CLOM, DMI and NORF. However, tianeptine (TIAN) was without effect. CLOM and NORF both reduced integrated mitochondrial function as shown by marked reductions in membrane potential (MMP) in mitochondria isolated from rat hearts. DMI also showed a similar but smaller effect, whereas, TIAN did not elicit any significant change in MMP. Moreover, micromolar concentrations of CLOM, DMI and NORF caused significant inhibitions of the activities of mitochondrial complexes (I, II/III and IV). The inhibitory effects on complex IV activity were most marked. TIAN inhibited only complex I activity at concentrations in excess of 20 µM. The observed inhibitory effects of antidepressants on the mitochondrial complexes were accompanied by a significant decrease in the mitochondrial state-3 respiration at concentrations above 10 µM. The results demonstrate that the apoptotic cell death observed in antidepressant-treated cells could be due to disruption of mitochondrial function resulting from multiple inhibition of mitochondrial enzyme complexes. The possibility that antimitochondrial actions of antidepressants could provide a potentially protective pre-conditioning effect is discussed.

The effects of antidepressants on cyclic AMP-response element-driven gene transcription in a model cell system.

The effects of the antidepressant drugs clomipramine (CLOM), desipramine (DMI), tianeptine (TIAN) and of norfluoxetine (NORF, the active metabolite of fluoxetine), were investigated in CHO cells expressing human beta2 adrenoceptors and a secreted placental alkaline phosphatase (SPAP) reporter gene to determine their actions on cyclic AMP-driven gene transcription. After 18 h of exposure, CLOM, DMI and NORF, but not TIAN, had biphasic effects on 1 microM isoprenaline-stimulated SPAP fsproduction with concentrations between 10 nM and 1 microM enhancing the maximal (E(max)) SPAP response, without changing EC50 values, but higher concentrations produced marked inhibitory effects. At nanomolar concentrations, CLOM and DMI increased expression of phospho-CREB (cyclic AMP response element binding protein). NORF was less effective but did significantly increase phospho-CREB at a concentration of 200 nM. TIAN had no effect. None of the antidepressants had any effect on CREB expression, nor on the accumulation of cyclic AMP. After prolonged exposure (7-21 days) to a low concentration (200 nM) of the antidepressants, the enhanced E(max) values for SPAP production evident after 18 h were not maintained but CLOM and DMI induced a significant leftward shift in the isoprenaline EC50 after a 7-day period of treatment and this was sustained at the 21 day time point. TIAN did not produce any significant changes. The results demonstrate that, in vitro, some but not all antidepressants can modify gene transcription via monoamine and cyclic AMP-independent mechanisms. The in vivo adaptive responses to TIAN probably involve alterations in different gene sets to those affected by other antidepressants.

The effects of desmethylimipramine on cyclic AMP-stimulated gene transcription in a model cell system.

The present study utilised an in vitro cell model of the cAMP signalling pathway to investigate the actions of desipramine (DMI) and other psychoactive agents on cAMP-driven gene transcription. The model comprised CHObeta2 SPAP cells; Chinese hamster ovary cells expressing human beta2 adrenoceptors and a secreted placental alkaline phosphatase (SPAP) reporter gene with multiple cAMP response elements (CREs) in its promoter region. SPAP assays showed DMI to inhibit isoprenaline or forskolin-enhanced gene transcription in a time and concentration-dependent manner (IC50=16.6+/-2.0 microM after 18 h). This effect of DMI was not dependent upon activity at the levels of the beta2 receptor, cAMP accumulation or phosphorylation of the transcription factor, cAMP response element binding protein (CREB). The inhibitory effects were maintained in the presence of DMI for at least 3 weeks and were mimicked by exposure to norfluoxetine (the major metabolite of fluoxetine; IC50=7.2+/-1.8 microM) and the neuroleptics, chlorpromazine and clozapine, all at a concentration of 10 microM. Amphetamine (10 microM, 18 h) enhanced SPAP gene transcription. Ca2+ imaging experiments ruled out an inhibitory effect of DMI on Ca2+ influx as concluded by previous studies. The results suggest a molecular target for DMI that lies downstream of CREB phosphorylation. Whether the inhibitory action of DMI is common to naturally expressed CRE-driven genes involved in adaptive responses to antidepressants in vivo remains to be determined.