The role of octopamine and tyramine in Drosophila larval locomotion.

The characteristic crawling behavior of Drosophila larvae consists of a series of rhythmic waves of peristalsis and episodes of head swinging and turning. The two biogenic amines octopamine and tyramine have recently been shown to modulate various parameters of locomotion, such as muscle contraction, the time spent in pausing or forward locomotion, and the initiation and maintenance of rhythmic motor patterns. By using mutants having altered octopamine and tyramine levels and by genetic interference with both systems we confirm that signaling of these two amines is necessary for larval locomotion. We show that a small set of about 40 octopaminergic/tyraminergic neurons within the ventral nerve cord is sufficient to trigger proper larval locomotion. Using single-cell clones, we describe the morphology of these neurons individually. Given various potential roles of octopamine and tyramine in the larval brain, such as locomotion, learning and memory, stress-induced behaviors or the regulation of the energy state, functions that are often not easy to discriminate, we dissect here for the first time a subset of this complex circuit that modulates specifically larval locomotion. Thus, these data will help to understand-for a given neuronal modulator-how specific behavioral functions are executed within distinct subcircuits of a complex neuronal network.

Selcho M ，Pauls D ，El Jundi B ，Stocker RF ，Thum AS ... -  《-》

Tyramine and octopamine have opposite effects on the locomotion of Drosophila larvae.

Biogenic amines are believed to play important roles in producing behaviors. Although some biogenic amines have been extensively studied in both vertebrates and invertebrates, little is known about the effects of trace amines like tyramine and octopamine. We investigated how trace amines affect behaviors using quantitative morphometric methods on Drosophila Tbetah(nM18) and iav(N) mutants that have altered levels of tyramine and octopamine. Locomotion of wild-type and mutant third instar larvae was analyzed using Dynamic Image Analysis System (DIAS) software. We found that Tbetah(nM18) mutants, with elevated tyramine levels and reduced octopamine levels, had a severe locomotion phenotype. Mutant larvae spent much more time in pausing episodes than wild-type larvae and displayed a reduction in speed and linear translocation. The locomotion phenotype was partially rescued by feeding Tbetah(nM18) larvae octopamine, an effect that could be nullified with simultaneous feeding of tyramine. Feeding Tbetah(nM18) larvae yohimbine, an agent that inhibits the activity of Drosophila tyramine receptors, also improved some locomotion parameters. Feeding both octopamine and yohimbine further improved rescue efficiency. Simultaneously reducing the octopamine and tyramine levels as in iav(N) larvae, in contrast, led to a less severe behavioral phenotype than that of Tbetah(nM18) mutants. Feeding iav(N) larvae either tyramine or octopamine exerted only a minor improvement in locomotion. These results suggest that tyramine and octopamine have opposite effects on Drosophila larval locomotion regulation and that a balance between the two is important in producing normal behavior.

Saraswati S ，Fox LE ，Soll DR ，Wu CF ... -  《journal of neurobiology》

Characterization of the octopaminergic and tyraminergic neurons in the central brain of Drosophila larvae.

Drosophila larvae are able to evaluate sensory information based on prior experience, similarly to adult flies, other insect species, and vertebrates. Larvae and adult flies can be taught to associate odor stimuli with sugar reward, and prior work has implicated both the octopaminergic and the dopaminergic modulatory systems in reinforcement signaling. Here we use genetics to analyze the anatomy, up to the single-cell level, of the octopaminergic/tyraminergic system in the larval brain and subesophageal ganglion. Genetic ablation of subsets of these neurons allowed us to determine their necessity for appetitive olfactory learning. These experiments reveal that a small subset of about 39 largely morphologically distinguishable octopaminergic/tyraminergic neurons is involved in signaling reward in the Drosophila larval brain. In addition to prior work on larval locomotion, these data functionally separate the octopaminergic/tyraminergic system into two sets of about 40 neurons. Those situated in the thoracic/abdominal ganglion are involved in larval locomotion, whereas the others in the subesophageal ganglion and brain hemispheres mediate reward signaling.

Selcho M ，Pauls D ，Huser A ，Stocker RF ，Thum AS ... -  《-》

Tyramine as an independent transmitter and a precursor of octopamine in the locust central nervous system: an immunocytochemical study.

Octopamine and its precursor tyramine are biogenic amines that are found ubiquitously in insects, playing independent but opposite neuromodulatory roles in a wide spectrum of behaviors, ranging from locomotion and aggression to learning and memory. We used recently available antibodies to octopamine and tyramine to label the distribution of immunoreactive profiles in the brain and ventral nerve cord of the locust. In the brain and all ventral cord ganglia all known octopaminergic neurons were labeled with both the tyramine and octopamine antisera. In the brain the subesophageal ganglion and all fused abdominal ganglia we found somata that were only labeled by the tyramine antibody. Some prominent architectural features of the brain, like the protocerebral bridge, the central body, and associated neuropils, also contain intensely labeled tyramine-immunoreactive fibers. In addition, tyraminergic fibers occur in all ganglia of the ventral cord. For known octopaminergic neurons of the thoracic ganglia, octopamine-immunoreactivity was confined to the cell body and to the varicosities or boutons, whereas fiber processes always expressed tyramine-immunoreactivity. The distribution of the tyramine and octopamine content within these neurons turned out to be dependent on how the animal was handled before fixation for immunocytochemistry. We conclude that tyramine is an independent transmitter in locusts, and that in octopaminergic neurons the ratio between octopamine and its precursor tyramine is highly dynamic.

Kononenko NL ，Wolfenberg H ，Pflüger HJ 《-》

A comprehensive anatomical map of the peripheral octopaminergic/tyraminergic system of Drosophila melanogaster.

Pauls D ，Blechschmidt C ，Frantzmann F ，El Jundi B ，Selcho M ... -  《-》