Relationships between large neutral amino acid levels in plasma, cerebrospinal fluid, brain microdialysate and brain tissue in the rat.

Experimental limitations may preclude direct measurement of large neutral amino acid (LNAA) levels in brain tissue. Some data suggest that serum or cerebrospinal fluid (CSF) may provide an index of LNAA brain levels. We examined this in a series of experiments in rats, administering tyrosine, phenylalanine or valine IP 60min prior to harvesting of blood, CSF or brain tissue or during in vivo microdialysis of the brain. Serum indices of the administered LNAA generally showed a significant (r>0.8) correlation with brain tissue levels but the linear relationships varied significantly across brain regions, the LNAA and its dose. Increases in levels of an administered LNAA were consistently greater in CSF than in brain tissue. In contrast, changes in LNAA levels in brain tissue and in vivo microdialysate were generally comparable. We confirm that changes in serum and CSF LNAA levels can support limited, qualitative inferences about changes in brain tissue LNAA levels; quantitative inferences should not be drawn without prior validation under relevant experimental conditions.

Gamma-butyrolactone-induced dopamine accumulation in prefrontal cortex is affected by tyrosine availability.

Gamma-butyrolactone (GBL) elevates striatal and prefrontal cortex dopamine levels; only the striatal dopamine levels are elevated by increased dopamine synthesis. If increased dopamine synthesis is necessary in order for dopamine levels to be affected by tyrosine availability, then GBL-induced prefrontal cortex dopamine levels should be tyrosine insensitive. Rats received either vehicle, tyrosine (50 or 200 mg/kg i.p.) or a tyrosine-depleting mixture prior to GBL 750 mg/kg i.p.. GBL-induced dopamine levels in prefrontal cortex were lowered by tyrosine depletion. GBL-induced striatal dopamine levels were not affected. Hence, increased dopamine synthesis may not be necessary in order for tyrosine availability to affect pharmacologically elevated prefrontal cortex dopamine levels.

Tyrosine availability modulates potassium-induced striatal catecholamine efflux in vivo.

The relationship between tyrosine availability and high potassium (K+) induced dopamine (DA) and norepinephrine (NE) efflux was examined in striatum using in vivo microdialysis. High K+ (80 mM) was included in perfusate for two 30 min periods, 2.5 h apart. After the first high-K+ perfusion, a tyrosine- and phenylalanine-free mixture of large neutral amino acids (LNAA(-)) was administered (IP) to lower brain tyrosine. Tyrosine (0, 25, 50 or 100 mg/kg IP) was administered 30 min prior to the second high-K+ perfusion. The ratio of catecholamine efflux during the two perfusions (P2/P1) was compared between groups. LNAA(-) significantly lowered P2/P1 for both DA and NE. Tyrosine 25-50 mg/kg blocked the LNAA(-) effect. We conclude that catecholamine efflux during prolonged depolarization is tyrosine dependent. Analyses of LNAA levels suggest that availability of tyrosine for tyrosine hydroxylation may be modulated by competition between LNAAs within brain extracellular fluid.

Tyrosine depletion lowers dopamine synthesis and desipramine-induced prefrontal cortex catecholamine levels.

The relationship between limited tyrosine availability, DA (dopamine) synthesis and DA levels in the medial prefrontal cortex (MPFC) of the rat was examined by in vivo microdialysis. We administered a tyrosine- and phenylalanine-free mixture of large neutral amino acids (LNAA-) IP to lower brain tyrosine, and the norepinephrine transporter inhibitor desipramine (DMI) 10 mg/kg IP to raise MPFC DA levels without affecting DA synthesis. For examination of DOPA levels, NSD-1015 20 microM was included in perfusate. Neither NSD-1015 nor DMI affected tyrosine levels. LNAA- lowered tyrosine levels by 45%, and lowered DOPA levels as well; this was not additionally affected by concurrent DMI 10 mg/kg IP. In parallel studies DMI markedly increased extracellular levels of DA (420% baseline) and norepinephrine (NE) (864% baseline). LNAA- had no effect on baseline levels of DA or NE but robustly lowered DMI-induced DA (176% baseline) as well as NE (237% baseline) levels. Even when DMI (20 microM) was administered in perfusate, LNAA- still lowered DMI-induced DA and NE levels. We conclude that while baseline mesocortical DA synthesis is indeed dependent on tyrosine availability, the MPFC maintains normal extracellular DA and NA levels in the face of moderately lower DA synthesis. During other than baseline conditions, however, tyrosine depletion can lower ECF DA and NE levels in MPFC. These data offer a potential mechanism linking dysregulation of tyrosine transport and cognitive deficits in schizophrenia.

Increased striatal dopamine synthesis is associated with decreased tissue levels of tyrosine.

Tyrosine levels do not generally affect indices of dopamine (DA) synthesis or efflux under basal conditions, but can do so when DA synthesis is increased. One possibility is that a high rate of DA synthesis depletes the normally adequate pool of endogenous tyrosine. To study this, we administered drugs known to preferentially increase striatal DA synthesis and examined DOPA levels in striatal microdialysate during perfusion with NSD-1015. In additional groups, we also measured DA, tyrosine and large neutral amino acids in striatal microdialysate, as well as in tissue from striatum and medial prefrontal cortex (MPFC). gamma-butyrolactone (GBL) (750 mg/kg i.p.) increased DOPA levels in striatal microdialysate, increased tissue DA levels in the MPFC and striatum, but lowered tissue tyrosine levels only in striatum. In striatal microdialysate, GBL markedly lowered DA levels; tyrosine levels were only marginally lower. Haloperidol (HAL) (1.0 mg/kg s.c.)+/-amfonelic acid (AFA) (5 mg/kg i.p.) increased striatal DOPA accumulation, increased striatal DA efflux, lowered striatal tissue tyrosine levels, but did not affect microdialysate tyrosine levels. There were no consistent changes in levels of other large neutral amino acids. We conclude that increased tyrosine hydroxylation can significantly deplete the endogenous pool of tyrosine. Under such conditions, near normal extracellular tyrosine levels are maintained despite lower tissue levels. The data are consistent with a net transfer of tyrosine from non-DAergic cells to DA terminals in support of DA synthesis.

Clozapine-induced dopamine release in the medial prefrontal cortex is augmented by a moderate concentration of locally administered tyrosine but attenuated by high tyrosine concentrations or by tyrosine depletion.

RATIONALE: Tyrosine availability can affect indices of dopamine (DA) release in activated central DA systems. There are, however, inconsistencies between studies. One possibility is that the relationship between tyrosine availability and DA release is non-linear. OBJECTIVES: This study aimed to determine how tyrosine depletion as well as a range of administered tyrosine concentrations affect antipsychotic drug-induced extracellular DA levels in the MPFC or striatum. METHODS: A guide cannula was implanted over the medial prefrontal cortex or striatum of adult male rats. After a 24-h recovery period, a microdialysis probe was inserted. Microdialysate collection began on the following day. Some rats received vehicle or a tyrosine- and phenylalanine-free neutral amino acid solution NAA(-) (IP) prior to clozapine (CLZ 10 mg/kg IP). Others received vehicle, CLZ (10 mg/kg IP) or haloperidol (HAL) (1 mg/kg IP) while the probe was perfused with artificial cerebrospinal fluid containing tyrosine 0-200 mug/ml. RESULTS: NAA(-) reduced tyrosine levels in MPFC dialysate by 35%. This reduction did not affect basal MPFC DA levels but attenuated the peak of CLZ-induced MPFC DA levels. The NAA(-) effect could be reversed by administration of tyrosine. Infused tyrosine 12.5-200 mug/ml did not affect basal DA levels either in MPFC or striatum. Within the MPFC, tyrosine 50.0 mug/ml significantly increased CLZ-induced DA levels. Within the striatum, tyrosine 25.0 mug/ml significantly increased while 150.0 mug/ml significantly decreased HAL-induced DA levels. CONCLUSIONS: Basal extracellular levels of DA in the MPFC and striatum are not affected by wide changes in tyrosine availability. However, modestly increased brain tyrosine levels can augment CLZ-induced MPFC and HAL-induced DA levels. Very high tyrosine concentrations attenuate HAL-induced striatal DA levels. These data may explain inconsistencies in the literature and suggest that tyrosine availability could be exploited to modulate psychotropic drug-induced DA levels in the brain.