Peripheral afferent input regulates the expression of dopaminergic properties in a population of local circuit intrinsic neurons of the rodent olfactory bulb. Lesions of the olfactory receptor neurons produced in the mouse by intranasal irrigation with either ZnSO4 or Triton X-100 and in the rat by surgical deafferentation or axotomy are associated with a decrease in the levels of dopamine (DA), the DA metabolite 3,4-dihydroxyphenylacetic acid (DOPAC), the activity of the enzyme tyrosine hydroxylase (TH), bulb weight and an increase in norepinephrine (NE) levels in the olfactory bulb. The anatomical correlates of the biochemical sequelae of deafferentation of olfactory bulb DA neurons were studied using immunohistochemical techniques to localize TH. Within 3 to 4 weeks all lesions produced a dramatic and uniform reduction in TH staining of the juxtaglomerular DA neurons and their processes which was paralleled by a reduction in DA and DOPAC levels and bulb weight. Seven weeks following reversible chemical lesions produced by Triton X-100, DA and DOPAC levels and tissue weight as well as TH staining in the juxtaglomerular neurons returned to control levels. These observations suggested that DA neurons remained present even when not demonstrable with TH antibodies. Additional evidence for the continued presence of the DA neurons was the ability of the olfactory bulbs from both lesioned mouse and rat to synthesize DA from exogenously administered L-3,4-dihydroxyphenylalanine (l-DOPA). These data suggested that the decrease in DA levels and TH staining in the olfactory bulb following lesions of the olfactory receptor neurons were produced by transneuronal mechanisms since there was no direct injury of the bulb. Furthermore, the demonstration that following reinnervation, catecholamine synthetic capacity is restored suggests that the juxtaglomerular dopamine neurons remain in the bulb and that afferent receptor input is required for expression of TH enzyme.