Of the three organizers of this NATO Advanced Research Workshop on "Neocortex: Onto geny and Phylogeny," one derived most of his knowledge about neocortex from studies on birds, another had never studied any animal but the cat and could probably recognize not more than ten animal species, and the third had very limited experience with mountaineering. They had in common the belief that evolutionary thinking permeates what biologists do, but that evolution of species and structures cannot be directly experimentally addressed. Although the fossil record can provide some major insights, the inroad to the evolution of the brain is indirect, via comparative anatomy and developmental biology. By identifying similarities and differences between brain structures in the species at hand, comparative anatomy generates hypotheses of evolutionary transformations. By understanding the rules of morphological transformation, developmental biology can, in principle, estimate the likelihood that a given transformation may have actually occurred. The meeting was a way to check if this notion is viable, by gathering together scientists from these two fields. Standing, left to right: F. Ebner, V. Caviness, M. Weisskopf, B. Fritszch, N. Swindale, J. Walter, H. Karten, J. Pettigrew, E. Welker, M. Cynader, D. Frost, L. Lopez-Mascaraque, P. Katz, H. Jerison, E. Soriano, Mayor of Alagna, Dr. G. Guglielmina, and associate, H. Van der Loos, B. Finlay, H. Scheich, C. Ruela. Seated: S. Pallas, T. Lohmann, J. De Carlos, F. Valverde, G. Innocenti, M. Diamond v "Gathering" does not accurately describe what really happened."

Of the three organizers of this NATO Advanced Research Workshop on "Neocortex: Onto geny and Phylogeny," one derived most of his knowledge about neocortex from studies on birds, another had never studied any animal but the cat and could probably recognize not more than ten animal species, and the third had very limited experience with mountaineering. They had in common the belief that evolutionary thinking permeates what biologists do, but that evolution of species and structures cannot be directly experimentally addressed. Although the fossil record can provide some major insights, the inroad to the evolution of the brain is indirect, via comparative anatomy and developmental biology. By identifying similarities and differences between brain structures in the species at hand, comparative anatomy generates hypotheses of evolutionary transformations. By understanding the rules of morphological transformation, developmental biology can, in principle, estimate the likelihood that a given transformation may have actually occurred. The meeting was a way to check if this notion is viable, by gathering together scientists from these two fields. Standing, left to right: F. Ebner, V. Caviness, M. Weisskopf, B. Fritszch, N. Swindale, J. Walter, H. Karten, J. Pettigrew, E. Welker, M. Cynader, D. Frost, L. Lopez-Mascaraque, P. Katz, H. Jerison, E. Soriano, Mayor of Alagna, Dr. G. Guglielmina, and associate, H. Van der Loos, B. Finlay, H. Scheich, C. Ruela. Seated: S. Pallas, T. Lohmann, J. De Carlos, F. Valverde, G. Innocenti, M. Diamond v "Gathering" does not accurately describe what really happened."

Development of Vision and the Pre-Visual System; S.S. Easter, Jr., et al. Cellular and Molecular Aspects of Photoreceptor Differentiation; R. Adler. Embryonic Patterning of Cone Subtypes in the Mammalian Retina; K.C. Wikler, D.L. Stull. Development of Cone Distribution Patterns in Mammals; A. Szel, et al. Genesis of Topographic and Cellular Diversity in the Primate Retina; P. Rakic. Development of ON and OFF Retinal Ganglion Cell Mosaics; L.M. Chalupa, et al. Getting to Grips with Neuronal Diversity: What is a Neuronal Type? J.E. Cook. Glio-Neuronal Interactions in Retinal Development; A. Reichenbach. Comparative Anatomy and Function of Mammalian Horizontal Cells; L. Peichl, et al. Parallel Pathways of Primate Vision: Sampling of Information in the Fourier Space by M and P Cells; L. Peichl, et al. Parallel Pathways of Primate Vision: Sampling of Information in the Fourier Space by M and P Cells; L.C.L. Silveira, H.D. De Mello, Jr. Transient and Persistent Na+, Ca2+, and Mixed-Cation Currents in Retinal Ganglion Cells; A.T. Ishida. Synaptic Transmission Between Retinal Neurons; M. Wilson. Scaling the Retina, Micro and Macro; B.L. Finlay, R.L. Snow. Retinal Ganglion Cell Axonal Transport: Moving Down the Road to Functional Connections; K.L. Moya. 5 Additional Articles. Index.

The vertebrate retina has a form that is closely and clearly linked to its func tion. Though its fundamental cellular architecture is conserved across verte brates, the retinas of individual species show variations that are also of clear and direct functional utility. Its accessibility, readily identifiable neuronal types, and specialized neuronal connectivity and morphology have made it a model system for researchers interested in the general questions of the genet ic, molecular, and developmental control of cell type and shape. Thus, the questions asked of the retina span virtually every domain of neuroscientific inquiry-molecular, genetic, developmental, behavioral, and evolutionary. Nowhere have the interactions of these levels of analysis been more apparent and borne more fruit than in the last several years of study of the develop ment of the vertebrate retina. Fields of investigation have a natural evolution, rdoving through periods of initial excitement, of framing of questions and controversy, to periods of synthesis and restatement of questions. The study of the development of the vertebrate retina appeared to us to have reached such a point of synthesis. Descriptive questions of how neurons are generated and deployed, and ques tions of mechanism about the factors that control the retinal neuron's type and distribution and the conformation of its processes have been posed, and in good part answered. Moreover, the integration of cellular accounts of development with genetic, molecular, and whole-eye and behavioral accounts has begun."