Long-term potentiation : a debate of current issues

The twenty-five contributions in this pivotal volume cover the most recent discoveries and debates, providing a comprehensive update on LTP for those who work in the field of learning and memory and a solid introduction to the properties, mechanisms, and functions of LTP for investigators in other areas of brain research.Controversy is a hallmark of an evolving field. Since its discovery by neuroscientists in 1972, long-term potentiation (LTP) of synaptic transmission has been a prime candidate for a cellular explanation of memory and an exciting source of controversies that run from the molecular to the behavioral level. The twenty-five contributions in this pivotal volume cover the most recent discoveries and debates, providing a comprehensive update on LTP for those who work in the field of learning and memory and a solid introduction to the properties, mechanisms, and functions of LTP for investigators in other areas of brain research.ContributorsI. Pre- versus the Post-Synaptic Changes in LTP. T.V.P. Bliss, M.P. Clements, M.L. Errington, M.A. Lynch, and J.H. Williams. L. Aniksztejn, M.P. Roisin, A. Represa, and Y. Ben-Ari. Z.I. Bashir, S.T. Alford, J.F. Blake, B.G. Frenguelli, S.N. Davies, K. G. Reymann and G.L. Collingridge. W.E.J.M. Ghijsen, and F.H. Lopes Da Silva. F. Crepel. J.M. Bekkers and C.F. Stevens. B.L. McNaughton. R. Malinow and R. Tsien. J. Larson, J. Ambros-Ingerson, and G. Lynch. * II. The Role of Different CalciumDependent Enzymes in LTP. D.J. Perkel and R.A. Nicoll. A. Routtenberg. M. Baudry. P.N.E. De Graan and W.H. Gispen. * III. The Biophysical/Structural Changes in LTP. C. Wallace, N. Hawrylak and W. Greenough. H.J. Matthies. IV. The Relationship between LTP and Learning and Memory. C.A. Barnes, B.L. McNaughton, and C.A. Erickson. C. Mondadori and L. Weiskrantz. R.G.M. Morris, S. Davis, and S.P. Butcher. S. LaRoche, V. Doyere, and C. Redini Del Negro. B. Soumireut-Mourat. V. LTP Rules in Neural Networks. T.W. Berger and M.F. Yeckel. T. Brown, A.M. Zador, and Z.F. Mainen. R. Granger, A. Cobas, and G. Lynch. J.C. Taylor. Y. Fregnac.

• Pre-versus the post-synaptic changes in LTP
• the role of different calcium-dependent enzymes in LTP
• the biophysical / structural changes in LTP
• the relationship between LTP and learning and memory
• LTP rules in neural networks.

Following the successful format of the first volume on long-term potentiation-a leading candidate for the neuronal basis of learning and memory-Volume 2 brings together the most recent data and hypotheses by top neuroscientists regarding the mechanisms of this phenomenon and of long-term depression (LTD).Following the successful format of the first volume on long- term potentiation-a leading candidate for the neuronal basis of learning and memory-Volume 2 brings together the most recent data and hypotheses by top neuroscientists regarding the mechanisms of this phenomenon and of long-term depression (LTD). The book is divided into several sections covering different aspects of the field ranging from molecular mechanisms of plasticity to computational neurobiology. It revisits some of the major points covered in Volume 1, updating them in this fast-moving field. It also introduces several new issues that have arisen since then. Of the many possible new topics that could have been added, the editors have focused on retrograde messengers and the mechanisms and functions of LTP and LTD because they are the subject of much interest, research, and controversy. The section on retrograde messengers deals primarily with nitric oxide.

• Part 1 The role of nitric oxide in long-term potentiation: nitric oxide as a physiological messenger in long-term potentiation and memory formation - electrophysiological and behavioural evidence, Christelle Bon et al
• involvement of nitric oxide in long-term potentiation, Daniel V. Madison and Erin M. Schuman
• nitric oxide synthase inhibition in vivo - lack of effect on hippocampal synaptic enhancement or spatial memory, Carol A. Barnes et al
• NO or NOT - fact or artifact?, Michel Baudry. Part 2 Expression and maintenance mechanisms: the role of calcium in the induction of long-term potentiation in the CA1 region of the hippocampus, Toshiya Manabe et al
• mechanisms of expression of long-term potentiation - time-dependent reversal and role of protein kinases, Dominique Muller et al
• two different forms of quantal changes during long-term potentiation and their impact on neuronal output, Roberto Malinow et al
• multiple forms of NMDA receptor-dependent synaptic plasticity in the hippocampus, Robert C. Malenka. Part 3 Relationships between long-term potentiation and long-term depression: mechanisms of synaptic plasticity in the cerebellum, Francis Crepel et al
• long-term enhancement of inhibitory synaptic transmission in the central nervous system, Stephane Charpier et al
• long-term depression of synaptic transmission - cellular mechanisms and regulation by previous synaptic history, Patric K. Stanton et al
• postsynaptic induction of long-term depression of synaptic transmission in the hippocampal slice, Lynn J. Bindman et al
• homosynaptic long-term depression and its relationship to long-term potentiation in the rat neocortex in vitro, Alain Artola
• does postsynaptic membrane potential regulate functional plasticity in kitten visual cortex?, Yves Fregnac et al. Part 4 Relationships between long-term potentiation and learning and memory: long-term potentiation in piriform cortex - characterization and functional speculations, Lewis B. Haberly et al
• long-term potentiation and long-term depression in piriform cortex in vivo, Francois S. Roman et al
• the hippocampus, long-term potentiation and memory - enhancing the connection, Tim Otto and Howard Eichenbaum. Part 5 Synaptic plasticity and computational neurobiology: a hierarchical model derived from an n-level field theory to study the effects of long-term potentiation on system properties of the hippocampus, Gilbert A. Chauvet and Theodore W. Berger
• intrinsic and emergent corticohippocampal computation, Richard Granger et al
• from neurobiology to neurocomputation, John M. Sarvey.

This is the third volume in a series of books devoted to the mechanisms and functional significance of two forms of synaptic plasticity, Long-Term Potentiation (LTP) and Long-Term Depression (LTD), which are widely assumed to play critical roles in information processing and storage in the brain. Long-Term Potentiation offers the most recent hypotheses concerning the molecular and cellular mechanisms underlying LTP and LTD, discusses the functional significance of LTP and LTD in neuronal networks, and reviews several examples of network simulations incorporating LTP- and LTD-like rules of synaptic modification. The book is organized into several sections covering different aspects of the field ranging from molecular and cellular processes to network models. The often deliberately controversial contributions are from the leading laboratories in the field and reflect contemporary multidisciplinary approaches.

• Part 1 Molecular and cellular processes in synaptic plasticity: mGluR1 and mGluR5 glutamate receptors - molecular biology, pharmacology and roles on hippocampal synaptic transmission, Joel Bockaert et al
• AMPA-glutamate receptor regulation and synaptic plasticity, Steve Standley et al
• the expression of LTP of glutamate receptor-mediated synaptic transmission as determined by the redox state of NMDA receptors and the extent of NMDA receptor activation during a tetanus, June C. Hirsch et al
• analysis of synaptic plasticity and memory in the mammalian brain with the gene-knockout technology, Chong Chen and Susumu Tonegawa. Part 2 LTP and LTD mechanisms: involvement of AMPA receptors in LTP mechanisms and memory, John Larson and Peter W. Vanderklish
• mechanisms of homosynaptic LTD in the hippocampus, Robert C. Malenka
• homosynaptic LTD and depotentiation in the hippocampus in vivo, Serge Laroche et al
• LTP and LTD in the visual cortex, Alfredo Kirkwood and Mark F. Bear
• electroresponsive properties of cerebellar purkinje cells in mGlur1 gene-lacking mice, Francis Crepel et al
• LTD and LTP at the corticostriatal synapse, Antonio Pisani et al. Part 3 Synaptic plasticity in network processes: generation of temporal correlations in firing of pyramidal cells by networks of inhibitory neurons, Roger D. Traub et al
• LTP and LTD and the encoding of memory in small ensembles of hippocampal neurons, Robert E. Hampson and Sam A. Deadwyler
• the constraint of synaptic potentiation and memory formation by entorhinal-hippocampal network dynamics, James J. Chrobak and Gyorgy Buzsaki
• network determinants of hippocampal synaptic plasticity, Theodore W. Berger et al. Part 4 Synaptic plasticity in network models: what LTP, LTD and cortical receptive fields tell us about synaptic modification, Harel Shouval and Leon M. Cooper
• linking LTP to network function - a simulation of episodic memory in the hippocampal formation, Michael E. Hasselmo and Chantal E. Stern
• adaptive stimulus representations in a computational model of cortical-hippocampal function, Mark A. Gluck and Catherine E. Myers
• adapting recurrent cortical excitation, Christof Koch et al.