Development of dopamine-immunoreactive neurons associated with the antennal lobes of the honey bee, Apis mellifera.

This report examines the development of the dopaminergic system in the primary antennosensory centres (antennal lobes) of the brain of the honey bee, Apis mellifera, and the effects of dopamine on neurite outgrowth of antennal-lobe neurons in vitro. Antibodies raised against dopamine were used to follow the development of a small population of dopamine-immunoreactive neurons that invade the antennal lobes during metamorphic adult development. Immunopositive somata associated with the antennal lobes were first detected at stage 2 of the nine stages of metamorphic adult development, but processes of these neurons within the antennal-lobe neuropil did not exhibit immunostaining until pupal stage 3. Severe depletion of primary sensory input to the right antennal lobe early in metamorphic adult development or removal of the right antenna from newly emerged bees did not alter the expression of dopamine immunoreactivity in the antennal-lobe neuropil. The presence of dopamine in developing antennal lobes was confirmed by using high performance liquid chromatography with electrochemical detection. Levels of dopamine were significantly higher at pupal stage 4 than at all other stages examined. This surge in dopamine levels coincided with rapid growth and compartmentalisation of the antennal-lobe neuropil. Exogenously applied dopamine (50 microM) enhanced the growth of antennal-lobe neurons in vitro, but only in cells derived from pupae at stage 5 of metamorphic adult development. The early appearance of dopamine-immunoreactive neurons and the effects of dopamine on stage 5 antennal-lobe neurons in vitro support the view that dopamine plays a role in the developing brain of the honey bee.

Distribution of dopamine receptors and dopamine receptor homologs in the brain of the honey bee, Apis mellifera L.

In the brain of the honey bee, Apis mellifera, the radioligands [3H]-SCH23390 and [3H]-spiperone recognise D1- and D2-like receptors, respectively. In addition to being pharmacologically distinct and exhibiting significantly different expression profiles during the lifetime of the bee, [3H]-SCH23390- and [3H]-spiperone-binding sites differ markedly in their distribution within the brain. Estimates of [3H]-SCH23390-binding site density are highest in the somatal rind, whereas [3H]-spiperone-binding sites are most concentrated in the beta lobe neuropil of the mushroom bodies. Molecular cloning techniques have been used to identify two honey bee genes encoding dopamine receptor homologs. The first is the honey bee counterpart of a Drosophila D1-like dopamine receptor and is expressed in the mushroom bodies of both workers and drones. The second is related to D2-like dopamine receptors from vertebrates and is expressed in the brain of the bee, but the precise distribution of expression is not yet known.

Voltage-activated currents from adult honeybee (Apis mellifera) antennal motor neurons recorded in vitro and in situ.

Voltage-activated currents from adult honey bee antennal motor neurons were characterized with in vitro studies in parallel with recordings taken from cells in situ. Two methods were used to ensure unequivocal identification of cells as antennal motor neurons: 1) selective backfilling of the neurons with fluorescent markers before dissociation for cell culture or before recording from cells in intact brains, semiintact brains, or in brain slices or 2) staining with a fluorescent marker via the patch pipette during recordings and identifying antennal motor neurons in situ on the basis of their characteristic morphology. Four voltage-activated currents were isolated in these antennal motor neurons with pharmacological, voltage, and ion substitution protocols. The neurons expressed at least two distinct K+ currents, a transient current (IA) that was blocked by 4-aminopyridine (4-5 x 10(-3) M), and a sustained current (IK(V)) that was partially blocked by tetraethylammonium (2-3 x 10(-2) M) and quinidine (5 x 10(-5) M). IA activated above -40 to -30 mV and the half-maximal voltages for steady-state activation and inactivation were -8.8 and -43.2 mV, respectively. IK(V) activated above -50 to -40 mV and the midpoint of the steady-state activation curve was +11.2 mV. IK(V) did not show steady-state inactivation. Additionally, two inward currents were isolated: a tetrodotoxin (10(-7) M)-sensitive, transient Na+ current (INa) that activated above -35 mV, with a maximum around -5 mV and a half-maximal voltage for inactivation of -72.6 mV, and a CdCl2 (5 x 10(-5) M)-sensitive Ca2+ current that activated above -45 to -40 mV, with a maximum around -15 mV. This study represents the first step in our effort to analyze the cellular and ionic mechanisms underlying the intrinsic properties and plasticity of antennal motor neurons.

Antennal lobe neurons of the honey bee, Apis mellifera, express a D2-like dopamine receptor in vitro.

We have used the D2-specific dopamine receptor ligand spiperone [N-(p-aminophenethyl) spiperone; NAPS] coupled to the fluorophore 7-nitrobenz-2-oxa-1,3-diazole-4-yl (NBD) to visualize dopamine receptors expressed in vitro by neurons of the primary antennosensory centers (antennal lobes) of the brain of the honey bee, Apis mellifera. Changes in the percentage of antennal lobe neurons exhibiting spiperone binding sites over time in culture and at different stages of metamorphic adult development have been investigated. Neurons obtained from animals at all stages of development exhibited spiperone binding sites, but only after 2 days or more in vitro. The percentage of antennal lobe neurons in vitro expressing spiperone binding sites increased significantly with the development of the antennal lobe neuropil. Fluorescently labelled spiperone (120 nM) could be displaced effectively by 1 mM dopamine but not by the same concentration of tyramine, octopamine, or serotonin. In addition, the D2 antagonist spiperone and the D2/D1 antagonist fluphenazine were more effective at displacing the fluorescent ligand than the D1-specific antagonist SCH23390. Our results indicate that Apis antennal lobe neurons in culture express a dopamine receptor and that this receptor is more likely to be D2-like than D1-like in nature. The receptor is expressed early in the metamorphic adult development of the antennal lobe neuropil of the brain.

Enhancement by serotonin of the growth in vitro of antennal lobe neurons of the sphinx moth Manduca sexta.

Cell culture experiments have been used to examine the effects of serotonin [5-hydroxytryptamine (5-HT)] on the morphological development of antennal lobe (AL) neurons in the brain of the sphinx moth, Manduca sexta. The majority of cells used in this study were from animals at stage 5 of the 18 stages of metamorphic adult development. 5-HT did not affect the survival of M. sexta AL neurons in culture, but did increase the numbers of cells displaying features characteristic of certain cell types. Three morphologically distinct cell types were examined in detail. The principal effect of 5-HT on these neurons was enhancement of cell growth. The magnitude of responses to this amine was cell-type specific. Site-specific responses to 5-HT were apparent also in one cell type. Our results suggest that the effects of 5-HT can change during the course of metamorphic development. These changes coincide temporally with the development of fast, sodium-based action potentials.