Biogenic amines, such as serotonin and dopamine, can be important in reinforcing associative learning. This function is evident as changes in memory performance with manipulation of either of these signals. In the insects, evidence begins to argue for a common role of dopamine in negatively reinforced memory. In contrast, the role of the serotonergic system in reinforcing insect associative learning is either unclear or controversial. We investigated the role of both of these signals in operant place learning in Drosophila. By genetically altering serotonin and dopamine levels, manipulating the neurons that make serotonin and dopamine, and pharmacological treatments we provide clear evidence that serotonin, but not dopamine, is necessary for place memory. Thus, serotonin can be critical for memory formation in an insect, and dopamine is not a universal negatively reinforcing signal.biogenic amines ͉ dopamine ͉ learning ͉ white-ABC transporter ͉ reinforcement T he neural systems containing biogenic amines, such as dopamine and serotonin, may mediate reinforcement information to influence memory performance. In the monkey for example, activity in the dopaminergic system is modulated based on expected reward (1), and the phasic output of these neurons may regulate memory performance (1, 2). In some invertebrates the biogenic amines have also been shown to be critical for conditioning (3)(4)(5). Within the insects, however, dopamine is the only biogenic amine clearly implicated in negatively reinforced associative memory (6-8). Indeed, and interestingly, dopaminergic system activation can be a sufficient reinforcing signal for olfactory conditioning in Drosophila larvae (9). Thus, support grows for a general function of the dopaminergic system in negatively reinforced memory. Whether serotonin has a role in insect learning is less clear (10), and in Drosophila it is controversial (11-13). Here, we investigated the influence of serotonin and dopamine on reinforcement of place learning in Drosophila.The ''heat box'' can be used to rapidly condition place memories in Drosophila (14,15). In this paradigm, single flies are allowed to wander in a chamber that is lined top and bottom with Peltier heating elements ( Fig. 1) (16, 17). A series of light sensors on one side of the chamber tracks the behavior of a fly, and when the animal moves to a predetermined half, the whole chamber heats to a nonpreferred (aversive) temperature. With experience, normal flies avoid the chamber-half associated with rising temperatures (15,16,18). A test performed after conditioning, when the danger of rising temperature is removed, is used to measure place memory. Importantly, one can dissociate acquisition from reinforcement processing defects by the performance of mutant flies after short and long training sessions (19). Flies that are mutant for a type-1 adenylyl cyclase (i.e., rutabaga) show poor memory performance after short periods of conditioning but normal memory after longer training, emphasizing the memory acquisition function for...
