A previous study using the in situ hybridization technique showed that serotonin neurons contain substantially more GTP cyclohydrolase I mRNA than do either dopamine or norepinephrine neurons. The objective of the current study was to determine whether these differences in mRNA abundance are predictive of the amount of GTP cyclohydrolase I protein available for tetrahydrobiopterin biosynthesis. The double-label immunofluorescence technique was used to localize GTP cyclohydrolase I protein to the tyrosine hydroxylase-positive A9 dopamine neurons of the substantia nigra and the A6 norepinephrine neurons of the locus ceruleus or the tryptophan hydroxylase-positive B6/B7 serotonin neurons of the dorsal raphe nucleus. Although GTP cyclohydrolase I immunofluorescence within serotonin and norepinephrine neurons was relatively intense, the fluorescence signal within dopamine neurons was faint to nondetectable. An immunoautoradiographic technique was developed to quantify these apparent differences in GTP cyclohydrolase I protein expression at the cellular level. Significant differences between all three neurochemical subdivisions were found and comparisons showed that on average serotonin neurons contain between 2.3- and 7.3-fold more GTP cyclohydrolase I protein than do either norepinephrine or dopamine neurons, respectively. Nigrostriatal dopamine neurons thus appear to synthesize and maintain tetrahydrobiopterin at low levels. Because dopamine and norepinephrine neurons express essentially equal amounts of GTP cyclohydrolase I mRNA, posttranscriptional events may serve to maintain low levels of GTP cyclohydrolase I protein within dopamine neurons. Phenotypic differences in GTP cyclohydrolase I protein expression across populations of monoamine neurons may be an important control point in neurotransmitter biosynthesis.