TY - JOUR
T1 - Subdivision of the drosophila mushroom bodies by enhancer-trap expression patterns
AU - Yao Yang, Ming
AU - Armstrong, J. Douglas
AU - Vilinsky, Ilya
AU - Strausfeld, Nicholas J.
AU - Kaiser, Kim
N1 - Funding Information: This work was supported by the Wellcome Trust, the United Kingdom Science and Engineering Research Council, and the National Science Foundation (grant IBN 9316729). We are indebted to Andrea Brand and Norbert Perrrmon for making the P[GAL4] system available in advance of publrcation. We thank ChrIstran Hehn, Chris Jones, Ali Sozen, Tim Tully, and Nicola Walker for help in generating P[GAL4] Irnes; Zonsheng Wang for the chromosomal localizations; and Ron Hoy and Kevin O’Dell for reading and commenting on versions of the manuscript.
PY - 1995/7
Y1 - 1995/7
N2 - Phylogenetically conserved brain centers known as mushroom bodies are implicated in insect associative learning and in several other aspects of insect behavior. Kenyon cells, the intrinsic neurons of mushroom bodies, have been generally considered to be disposed as homogenous arrays. Such a simple picture imposes constraints on interpreting the diverse behavioral and computational properties that mushroom bodies are supposed to perform. Using a P[GAL4] enhancer-trap approach, we have revealed axonal processes corresponding to intrinsic cells of the Drosophila mushroom bodies. Rather than being homogenous, we find the Drosophila mushroom bodies to be compound neuropils in which parallel subcomponents exhibit discrete patterns of gene expression. Different patterns correspond to hitherto unobserved differences in Kenyon cell trajectory and placement. On the basis of this unexpected complexity, we propose a model for mushroom body function in which parallel channels of information flow, perhaps with different computational properties, subserve different behavioral roles.
AB - Phylogenetically conserved brain centers known as mushroom bodies are implicated in insect associative learning and in several other aspects of insect behavior. Kenyon cells, the intrinsic neurons of mushroom bodies, have been generally considered to be disposed as homogenous arrays. Such a simple picture imposes constraints on interpreting the diverse behavioral and computational properties that mushroom bodies are supposed to perform. Using a P[GAL4] enhancer-trap approach, we have revealed axonal processes corresponding to intrinsic cells of the Drosophila mushroom bodies. Rather than being homogenous, we find the Drosophila mushroom bodies to be compound neuropils in which parallel subcomponents exhibit discrete patterns of gene expression. Different patterns correspond to hitherto unobserved differences in Kenyon cell trajectory and placement. On the basis of this unexpected complexity, we propose a model for mushroom body function in which parallel channels of information flow, perhaps with different computational properties, subserve different behavioral roles.
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U2 - 10.1016/0896-6273(95)90063-2
DO - 10.1016/0896-6273(95)90063-2
M3 - Article
C2 - 7619529
SN - 0896-6273
VL - 15
SP - 45
EP - 54
JO - Neuron
JF - Neuron
IS - 1
ER -