Forms Of Neuronal Plasticity Research Articles

CaM kinase II phosphorylation of slo Thr107 regulates activity and ethanol responses of BK channels

High-conductance, Ca(2+)-activated and voltage-gated (BK) channels set neuronal firing. They are almost universally activated by alcohol, leading to reduced neuronal excitability and neuropeptide release and to motor intoxication. However, several BK channels are inhibited by alcohol, and most other voltage-gated K(+) channels are refractory to drug action. BK channels are homotetramers (encoded by Slo1) that possess a unique transmembrane segment (S0), leading to a cytosolic S0-S1 loop. We identified Thr107 of bovine slo (bslo) in this loop as a critical residue that determines BK channel responses to alcohol. In addition, the activity of Ca(2+)/calmodulin-dependent protein kinase II (CaMKII) in the cell controlled channel activity and alcohol modulation. Incremental CaMKII-mediated phosphorylation of Thr107 in the BK tetramer progressively increased channel activity and gradually switched the channel alcohol responses from robust activation to inhibition. Thus, CaMKII phosphorylation of slo Thr107 works as a 'molecular dimmer switch' that could mediate tolerance to alcohol, a form of neuronal plasticity.

Behavioral Sensitization to Cocaine Is Associated with Increased AMPA Receptor Surface Expression in the Nucleus Accumbens

Regulation of AMPA receptor trafficking is important for many forms of neuronal plasticity. In this study, a protein cross-linking assay was used to evaluate the contribution of AMPA receptor trafficking to plasticity associated with behavioral sensitization, an animal model of drug addiction. Cross-linking was used to distinguish between cell surface and intracellular AMPA receptors in nucleus accumbens (NAc) tissue obtained from rats treated repeatedly with saline or cocaine. Surface/intracellular (S/I) ratios for glutamate receptor 1 (GluR1) and GluR2/3 subunits were increased 21 d after the last injection in cocaine-sensitized rats but not rats that failed to sensitize, and the magnitude of the S/I ratio for cocaine-sensitized rats was positively correlated with the magnitude of behavioral sensitization. At the 1 d withdrawal time, cocaine did not alter S/I ratios, and there was no correlation between S/I ratios and behavioral sensitization. The majority of surface-expressed GluR1 detected with this assay was associated with synapses, based on coimmunoprecipitation with postsynaptic density protein of 95 kDa. These findings suggest that behavioral sensitization to cocaine is associated with a slowly developing redistribution of AMPA receptors to the surface of NAc neurons. Motor execution of drug-seeking responses depends on activation of AMPA receptors on NAc neurons by glutamate afferents originating in cortical and limbic regions. We propose that drug-seeking responses are more effectively triggered in cocaine-sensitized rats because of increased cell surface expression of AMPA receptors.

Genomic profiling of the neuronal target genes of the plasticity‐related transcription factor – Zif268

The later phases of neuronal plasticity are invariably dependent on gene transcription. Induction of the transcription factor Zif268 (Egr-1) in neurones is closely associated with many forms of functional plasticity, yet the neuronal target genes modulated by Zif268 have not been characterized. After transfection of a neuronal cell line with Zif268 we identified genes that show altered expression using high density microarrays. Although some of the genes identified have previously been associated with forms of neuronal plasticity, the majority have not been linked with neuronal plasticity or Zif268 action. Altered expression of a representative sample of the novel target genes was confirmed in Zif268-transfected PC12 neurones, and in in vitro and in vivo models of Zif268-associated neuronal plasticity. In particular, altered expression of the protease inhibitor Cystatin C and the chemokine Cxcl10 was observed in striatal tissue after haloperidol administration. Surprisingly, the group of identified genes is enriched for components of the proteasome and the major histocompatibility complex. Our findings suggest that altered expression of these genes following Zif268 induction may be a key component of long lasting plasticity in the CNS.

SRF mediates activity-induced gene expression and synaptic plasticity but not neuronal viability

Synaptic activity-dependent gene expression is critical for certain forms of neuronal plasticity and survival in the mammalian nervous system, yet the mechanisms by which coordinated regulation of activity-induced genes supports neuronal function is unclear. Here, we show that deletion of serum response factor (SRF) in specific neuronal populations in adult mice results in profound deficits in activity-dependent immediate early gene expression, but components of upstream signaling pathways and cyclic AMP-response element binding protein (CREB)-dependent transactivation remain intact. Moreover, SRF-deficient CA1 pyramidal neurons show attenuation of long-term synaptic potentiation, a model for neuronal information storage. Furthermore, in contrast to the massive neurodegeneration seen in adult mice lacking CREB family members, SRF-deficient adult neurons show normal morphologies and basal excitatory synaptic transmission. These findings indicate that the transcriptional events underlying neuronal survival and plasticity are dissociable and that SRF plays a prominent role in use-dependent modification of synaptic strength in the adult brain.

Role for Calcium Signaling and Arachidonic Acid Metabolites in the Activity-Dependent Increase of AHP Amplitude in Leech T Sensory Neurons

Previous studies have revealed a new form of activity-dependent modulation of the afterhyperpolarization (AHP) in tactile (T) neurons of the leech Hirudo medicinalis. The firing of T cells is characterized by an AHP, which is mainly due to the activity of the Na+/K+ ATPase. Low-frequency repetitive stimulation of T neurons leads to a robust increment of the AHP amplitude, which is correlated with a synaptic depression between T neuron and follower cells. In the present study, we explored the molecular cascades underlying the AHP increase. We tested the hypothesis that this activity-dependent phenomenon was triggered by calcium influx during neural activity by applying blockers of voltage-dependent Ca2+ channels. We report that AHP increase requires calcium influx that, in turn, induces release of calcium from intracellular stores so sustaining the enhancement of AHP. An elevation of the intracellular calcium can activate the cytosolic isoforms of the phosholipase A2 (PLA2). Therefore we analyzed the role of PLA2 in the increase of the AHP, and we provide evidence that not only PLA2 but also the recruitment of arachidonic acid metabolites generated by the 5-lipoxygenase pathway are necessary for the induction of AHP increase. These data indicate that a sophisticated cascade of intracellular signals links the repetitive discharge of T neurons to the activation of molecular pathways, which finally may alter the activity of critical enzymes such as the Na+/K+ ATPase, that sustains the generation of the AHP and its increase during repetitive stimulation. These results also suggest the potential importance of the poorly studied 5-lipoxygenase pathway in forms of neuronal plasticity.

Role of Cdk5 in Drug Abuse and Plasticity

Neuronal plasticity serves as the basis for learning and memory in the adult brain. Contextual, motor, and reward-based learning are important in reinforcing survival behavior in animals. Most psychostimulant drugs of abuse target the dopaminergic reward system of the brain. Drugs of abuse cause long-standing cellular and molecular neuroadaptations in the brain. The neuronal protein kinase Cdk5 is emerging as an important player in the cellular and physiological responses to drugs of abuse. Substantial evidence indicates that Cdk5 controls dopamine neurotransmission through regulation of the protein phosphatase-1 inhibitor, DARPP-32. Furthermore, the morphological changes associated with chronic cocaine exposure are dependent on Cdk5. Thus, Cdk5 mediates cellular responses to psychostimulant drug-induced changes in dopamine signal transduction and cytoskeletal reorganization. In this regard, Cdk5, through its targeting of various substrates, integrates a number of intracellular pathways that are targeted by psychostimulant drugs. These studies and the emerging role of Cdk5 in various forms of neuronal plasticity are reviewed.

Transmitter- and Activity-Dependent Inhibition of Neuronal Firing

Neuronal excitability depends upon the activation of voltage-gated Na + channels. Various neuromodulators reduce Na + channel availability (and thus neuronal excitability) through the activation of heterotrimeric GTP-binding protein (G protein)-coupled receptor (GPCR)-mediated signaling pathways that lead to channel phosphorylation. Carr et al . used a combination of electrophysiological and pharmacological analysis to show that the reduction in Na + channel availability produced by GPCR activation closely resembled slow inactivation--a slow, voltage-dependent state that occurs in response to prolonged depolarization and during repetitive firing. The authors investigated the kinetics and voltage dependence of changes in Na + channel availability in mouse prefrontal cortex pyramidal neurons in response to treatment with the 5-HT 2a/c (5-hydroxytryptamine) receptor agonist 2,5-dimethoxy-4-iodoamphetamine hydrochloride (DOI). The effects of receptor stimulation were voltage-dependent, and DOI accelerated the development and extent of slow inactivation without affecting the time constant of recovery. Moreover, the effects of DOI, like slow inactivation, were inhibited by increases in the extracellular Na + concentration. Similarly, direct pharmacological activation of protein kinase A and protein kinase C promoted a slow inactivation-like state. The voltage dependence of phosphorylation-dependent channel inactivation occurred after phosphorylation, and mutational analysis indicated that channel phosphorylation was not required for depolarization-dependent development of slow inactivation. DOI accelerated the elevation of threshold that occurs during sustained firing (when the interspike membrane potential remains somewhat depolarized) and led to early failure of action potential generation. Thus, GPCR stimulation, by promoting a slow inactivation-like state, can selectively modulate sustained neuronal activity to produce a novel form of neuronal plasticity. D. B. Carr, M. Day, A. R. Cantrell, J. Held, T. Scheuer, W. A. Catterall, D. J. Surmeier, Transmitter modulation of slow, activity-dependent alterations in sodium channel availability endows neurons with a novel form of cellular plasticity. Neuron 39 , 793-806 (2003). [Online Journal]

Calcium-dependent regulation of cholinergic cell phenotype in the hypothalamus in vitro.

Glutamate is a major fast excitatory neurotransmitter in the CNS including the hypothalamus. Our previous experiments in hypothalamic neuronal cultures showed that a long-term decrease in glutamate excitation upregulates ACh excitatory transmission. Data suggested that in the absence of glutamate activity in the hypothalamus in vitro, ACh becomes the major excitatory neurotransmitter and supports the excitation/inhibition balance. Here, using neuronal cultures, fura-2 Ca(2+) digital imaging, and immunocytochemistry, we studied the mechanisms of regulation of cholinergic properties in hypothalamic neurons. No ACh-dependent activity and a low number (0.5%) of cholinergic neurons were detected in control hypothalamic cultures. A chronic (2 wk) inactivation of N-methyl-D-aspartate (NMDA) ionotropic glutamate receptors, L-type voltage-gated Ca(2+) channels, calmodulin, Ca(2+)/calmodulin-dependent protein kinases II/IV (CaMK II/IV), or protein kinase C (PKC) increased the number of cholinergic neurons (to 15-24%) and induced ACh activity (in 40-60% of cells). Additionally, ACh activity and an increased number of cholinergic neurons were detected in hypothalamic cultures 2 wk after a short-term (30 min) pretreatment with bis-(o-aminophenoxy)-N,N,N',N'-tetraacetic acid tetrakis(acetoxy-methyl) ester (BAPTA AM; 2.5 microM), a membrane permeable Ca(2+)-chelating agent that blocks cytoplasmic Ca(2+) fluctuations. An increase in the number of cholinergic neurons following a chronic NMDA receptor blockade was likely due to the induction of cholinergic phenotypic properties in postmitotic noncholinergic neurons, as determined using 5-bromo-2'-deoxyuridine (BrdU) labeling. In contrast, a chronic inactivation of non-NMDA glutamate receptors or cGMP-dependent protein kinase had little effect on the expression of ACh properties. The data suggest that Ca(2+), at normal intracellular concentrations, tonically suppresses the development of cholinergic properties in hypothalamic neurons. However, a decrease in Ca(2+) influx into cells (through NMDA receptors or L-type Ca(2+) channels), inactivation of intracellular Ca(2+) fluctuations, or downregulation of Ca(2+)-dependent signal transduction pathways (CaMK II/IV and PKC) remove the tonic inhibition and trigger the development of cholinergic phenotype in some hypothalamic neurons. An increase in excitatory ACh transmission may represent a novel form of neuronal plasticity that regulates the activity and excitability of neurons during a decrease in glutamate excitation. This type of plasticity has apparent region-specific character and is not expressed in the cortex in vitro; neither increase in ACh activity nor change in the number of cholinergic neurons were detected in cortical cultures under all experimental conditions.

The p42/44 Mitogen-activated Protein Kinase Pathway Couples Photic Input to Circadian Clock Entrainment

In mammals, the suprachiasmatic nuclei (SCN) of the hypothalamus function as the major biological clock. SCN-dependent rhythms of physiology and behavior are regulated by changes in the environmental light cycle. Currently, the second messenger signaling events that couple photic input to clock entrainment have yet to be well characterized. Recent work has revealed that photic stimulation during the night triggers rapid activation of the p42/44 mitogen activated protein kinase (MAPK) pathway in the SCN. The MAPK signal transduction pathway is a potent regulator of numerous classes of transcription factors and has been shown to play a role in certain forms of neuronal plasticity. These observations led us to examine the role of the MAPK pathway in clock entrainment. Here we report that pharmacological disruption of light-induced MAPK pathway activation in the SCN uncouples photic input from clock entrainment, as assessed by locomotor activity phase. In the absence of photic stimulation, transient disruption of MAPK signaling in the SCN did not alter clock-timing properties. We also report that signaling via the Ca(2+)/calmodulin kinase pathway functions upstream of the MAPK pathway, coupling light to activation of the MAPK pathway. Together these results delineate key intracellular signaling events that underlie light-induced clock entrainment.

Neural substrates of memory, affective functions, and conscious experience.

This review presents an account of the areas and circuits of the brain that are thought to be involved in such cognitive functions as memory, affect and consciousness. Considerable progress has been made in the past two decades in the identification of the cerebral areas and in our understanding of the brain mechanisms involved in these functions, thanks in large parts to a number of imaging observations (PET and fMRI), together with many clinical neurological and experimental studies. Thus, there is now convincing evidence that these high level functions are represented in a complex organization of interconnected cortical and subcortical areas that operate as spatially distributed systems, specialized for the different cognitive activities. Despite the progress that has been made, it is still not known how genetic and environmental factors interact during early development and throughout life to create the necessary conditions out of which these cognitive capacities emerge, nor is it evident to what extent they are shaped by adaptive changes in synaptic organization and other forms of neuronal plasticity.

Acetylcholine Becomes the Major Excitatory Neurotransmitter in the HypothalamusIn Vitroin the Absence of Glutamate Excitation

Glutamate and GABA are two major fast neurotransmitters (excitatory and inhibitory, respectively) in the CNS, including the hypothalamus. They play a key role in the control of excitation/inhibition balance and determine the activity and excitability of neurons in many neuronal circuits. Using neuronal cultures, whole-cell recording, Ca(2+) imaging, and Northern blots, we studied the compensatory regulation of neuronal activity during a prolonged decrease in glutamate excitation. We report here that after a chronic (6-17 d) blockade of ionotropic glutamate receptors, neurons in hypothalamic cultures revealed excitatory electrical and Ca(2+) synaptic activity, which was not elicited in the control cultures that were not subjected to glutamate blockade. This activity was suppressed with acetylcholine (ACh) receptor antagonists and was potentiated by eserine, an inhibitor of acetylcholinesterase, suggesting its cholinergic nature. The upregulation of ACh receptors and the contribution of ACh to the control of the excitation/inhibition balance in cultures after a prolonged decrease in glutamate activity were also demonstrated. Enhanced ACh transmission was also found in chronically blocked cerebellar but not cortical cultures, suggesting the region-specific character of glutamate-ACh interactions in the brain. We believe that in the absence of glutamate excitation in the hypothalamus in vitro, ACh, a neurotransmitter normally exhibiting only weak activity in the hypothalamus, becomes the major excitatory neurotransmitter and supports the excitation/inhibition balance. The increase in excitatory ACh transmission during a decrease in glutamate excitation may represent a novel form of neuronal plasticity that regulates activity and excitability of neurons during the glutamate/GABA imbalance.

Calcium signals in long-term potentiation and long-term depression

We describe postsynaptic Ca2+signals that subserve induction of two forms of neuronal plasticity, long-term potentiation (LTP) and long-term depression (LTD), in rat hippocampal neurons. The common induction protocol for LTP, a 1-s, 50-Hz tetanus, generates Ca2+increases of about 50 µM in dendritic spines of CA1 neurons. These very large increases, measured using a low affinity indicator (Mg fura 5), were found only in the spines and tertiary dendrites, and were dependent upon influx through N-methyl-D-aspartate (NMDA) gated channels. High affinity Ca2+indicators (e.g., fura 2) are unable to demonstrate these events. In acute slices, neighboring dendritic branches often showed very different responses to a tetanus, and in some instances, neighboring spines on the same dendrite responded differently. LTD in mature CA1 neurons was induced by a low frequency stimulus protocol (2 Hz, 900 pulses), in the presence of GABA- and NMDA-receptor blockers. This LTD protocol produced dendritic Ca2+increases of <1 µM. Duration of the Ca2+increase was ~30 s and was due to voltage-gated Ca2+influx. Finally, the ability of synaptically addressed Ca2+stores to release Ca2+was studied in CA3 neurons and was found to require immediate preloading and high intensity presynaptic stimulation, conditions unlike normal LTP-LTD protocols.Key words: long-term potentiation, long-term depression, Ca2+, neuronal plasticity, fluorescence imaging, N-methyl-D-aspartate (NMDA) receptor, metabotropic receptor.

Making new connections: role of ERK/MAP kinase signaling in neuronal plasticity.

One of the most intriguing questions in neurobiology is how neurons and synapses encode the long-term changes in synaptic efficacy that underlie memory consolidation. A recent set of studies suggests that the ERK/mitogen-activated protein kinase (MAPK) plays a fundamental role in vertebrate and invertebrate memory consolidation. These findings suggest that the ERK/MAPK cascade should join the cAMP response element binding protein/cAMP response element (CREB/CRE) and cAMP/protein kinase A (PKA) pathways as evolutionarily conserved regulators of memory formation. Because the MAPK cascade was previously identified as a critical regulator of cell growth, its regulatory role in synaptic function in postmitotic neurons was unexpected. Nevertheless, a wide body of work now shows that the MAPK cascade is potently activated by synaptic activity and by increases in intracellular Ca2+ and cAMP. Here, we focus on recent exciting studies that indicate that the MAPK signaling cascade is critical for both memory consolidation and long-term neuronal plasticity. We also address the mechanisms for activity- and plasticity-mediated activation of MAPK in central nervous system (CNS) neurons and discuss evidence that activation of CREB by the ERK/MAPK cascade plays a pivotal role in some forms of neuronal plasticity.

Calcium signals in long-term potentiation and long-term depression

We describe postsynaptic Ca2+ signals that subserve induction of two forms of neuronal plasticity, long-term potentiation (LTP) and long-term depression (LTD), in rat hippocampal neurons. The common induction protocol for LTP, a 1-s, 50-Hz tetanus, generates Ca2+ increases of about 50-Hz in dendritic spines of CA1 neurons. These very large increases, measured using a low affinity indicator (Mg fura 5), were found only in the spines and tertiary dendrites, and were dependent upon influx through N-methyl-D-aspartate (NMDA) gated channels. High affinity Ca2+ indicators (e.g., fura 2) are unable to demonstrate these events. In acute slices, neighboring dendritic branches often showed very different responses to a tetanus, and in some instances, neighboring spines on the same dendrite responded differently. LTD in mature CA1 neurons was induced by a low frequency stimulus protocol (2 Hz, 900 pulses), in the presence of GABA- and NMDA-receptor blockers. This LTD protocol produced dendritic Ca2+ increases of <1 microM. Duration of the Ca2+ increase was approximately 30 s and was due to voltage-gated Ca2+ influx. Finally, the ability of synaptically addressed Ca2+ stores to release Ca2+ was studied in CA3 neurons and was found to require immediate preloading and high intensity presynaptic stimulation, conditions unlike normal LTP-LTD protocols.

Lipid peroxides and neuronal plasticity.

Long-term potentiation (LTP) of synaptic transmission is a well defined form of neuronal plasticity. The induction of LTP at perforant path-dentate granule cell and Schaffer collateral-CA1 pyramidal cell synapses of the hippocampus is known to require influx of Ca2+ through postsynaptic N-methy1-D-aspartate (NMDA) receptors, while the expression of LTP has been proposed to be mediated at least in part through presynaptic1) Epileptic seizures which are associated with massive increases of intracellular cation concentration may also account for the persistent increases in efficacy of excitatory synaptic transmission in the hippocampus2) This seizure-induced synaptic potentiation (SIP) and LTP have some features in common such as the requirement of NMDA receptor activation1,3) and the consequent increase in neurotransmitter release4,5). These findings led to the concept of a retrograde messenger by which the presynaptic terminals are informed that the postsynaptic sites have been activated. Arachidonic acid (AA) has been recognized as the potential candidate for a retrograde messenger1). Here, we have addressed the involvement of lipid peroxides, especially lipoxygenase metabolites, in neuronal plasticity.

Acute Functional Tolerance to Ethanol and Fear Conditioning Are Genetically Correlated in Mice

It has been speculated that tolerance to alcohol involves some form of neuronal plasticity that is similar to or the same as that mediating learning and memory. To investigate this possibility further, we tested the hypothesis that acute functional tolerance (AFT) to alcohol is genetically correlated to a Pavlovian learning task: fear conditioning. Mice selectively bred for differences in ability to acquire AFT were tested for fear conditioning. Subjects received a mild footshock paired to a broadband clicker and were tested 24 hr later for their freezing response to the conditioning chamber (context), to an altered chamber, and to the clicker. Both the original and replicate lines selected for high AFT (HAFT) were found to freeze significantly more than those selected for low AFT (LAFT) in response to the context and to the clicker. In a second experiment, an F2 population derived from the C57BL/6 (B6) and DBA/2 (D2) mouse strains were tested first for fear conditioning, followed 3 weeks later by AFT testing. AFT was defined as the difference between blood alcohol levels determined at the time of regain balance on a dowel rod first after 1.75 g/kg of ethanol and again after a subsequent dose of 2.0 g/kg. Consistent with results from HAFT and LAFT, freezing to context was found to be significantly positively correlated to AFT (r = 0.38, p = 0.04) in the F2 mice. The results suggest that co-variation in fear conditioning and AFT may be mediated by one or more of the same or at least tightly linked genes. Further dissection of this correlation may reveal neuronal mechanisms common to both AFT and fear conditioning.

CaMKIIβ Functions As an F-Actin Targeting Module that Localizes CaMKIIα/β Heterooligomers to Dendritic Spines

Ca 2+/calmodulin-dependent protein kinase II (CaMKII) is a serine/threonine protein kinase that regulates long-term potentiation and other forms of neuronal plasticity. Functional differences between the neuronal CaMKIIα and CaMKIIβ isoforms are not yet known. Here, we use green fluorescent protein–tagged (GFP-tagged) CaMKII isoforms and show that CaMKIIβ is bound to F-actin in dendritic spines and cell cortex while CaMKIIα is largely a cytosolic enzyme. When expressed together, the two isoforms form large heterooligomers, and a small fraction of CaMKIIβ is sufficient to dock the predominant CaMKIIα to the actin cytoskeleton. Thus, CaMKIIβ functions as a targeting module that localizes a much larger number of CaMKIIα isozymes to synaptic and cytoskeletal sites of action.

Norepinephrine increases cyclic GMP levels in cerebellar cells from neuronal nitric oxide synthase knockout mice.

Cyclic GMP is an important intracellular messenger in the nervous system that may mediate cellular forms of neuronal plasticity. Previous studies show that most neurotransmitters stimulate cyclic GMP levels by the activation of nitric oxide synthase (NOS). In this study, we report that in primary cell cultures from the cerebellum of neuronal NOS knockout mice, norepinephrine stimulates an increase in cyclic GMP content. This increase is seen in both granule cell and astrocyte cultures and is not blocked by inhibitors of NOS or by inhibition of soluble guanylyl cyclase. These results suggest a novel pathway by which norepinephrine enhances cyclic GMP levels in the nervous system.

The role of excitatory amino acids in behavioral sensitization to psychomotor stimulants

Behavioral sensitization refers to the progressive augmentation of behavioral responses to psychomotor stimulants that develops during their repeated administration and persists even after long periods of withdrawal. It provides an animal model for the intensification of drug craving believed to underlie addiction in humans. Mechanistic similarities between sensitization and other forms of neuronal plasticity were first suggested on the basis of the ability of N-methyl-D-aspartate (NMDA) receptor antagonists to prevent the development of sensitization [Karler, R., Calder, L. D., Chaudhry, I. A. and Turkanis, S. A. (1989) Blockade of “reverse tolerance” to cocaine and amphetamine by MK-801. Life Sci., 45, 599–606.]. This article will review the large number of subsequent studies addressing: (1) the roles of NMDA, α-amino-3-hydroxy-5-methyl-4-isoxazole propionate (AMPA) and metabotropic glutamate receptors in the development and expression of behavioral sensitization, (2) excitatory amino acids (EAAs) and the role of conditioning in sensitization, (3) controversies regarding EAA involvement in behavioral sensitization based on studies with MK-801, (4) the effects of acute and repeated stimulant administration on EAA neurochemistry and EAA receptor expression, and (5) the neuroanatomy of EAA involvement in sensitization. To summarize, NMDA, AMPA metabotropic glutamate receptors all participate in the development of sensitization, while maintenance of the sensitized state involves alterations in neurochemical measures of EAA transmission as well as in the expression and sensitivity of AMPA and NMDA receptors. While behavioral sensitization likely involves complex neuronal circuits, with EAAs participating at several points within this circuitry, EAA projections originating in prefrontal cortex may play a particularly important role in the development of sensitization, perhaps via their regulatory effects on midbrain dopamine neurons. The review concludes by critically evaluating various hypotheses to account for EAA involvement in the development of behavioral sensitization, and considering the question of whether EAA receptors are involved in mediating the rewarding effects of psychomotor stimulants and sensitization of such rewarding effects.

In vivo observations of timecourse and distribution of morphological dynamics in Xenopus retinotectal axon arbors.

Changes in neuronal structure can contribute to the plasticity of neuronal connections in the developing and mature nervous system. However, the expectation that they would occur slowly precluded many from considering structural changes as a mechanism underlying synaptic plasticity that occurs over a period of minutes to hours. We took time-lapse confocal images of retinotectal axon arbors to determine the timecourse, magnitude, and distribution of changes in axon arbor structure within living Xenopus tadpoles. Images of axons were collected at intervals of 3 min, 30 min, and 2 h over total observation periods up to 8 h. Branch additions and retractions in arbors imaged at 3 or 30 min intervals were confined to shorter branches. Sites of additions and retractions were distributed throughout the arbor. The average lifetime of branches was about 10 min. Branches of up to 10 microns could be added to the arbor within a single 3 min observation interval. Observations of arbors at 3 min intervals showed rapid changes in the structure of branchtips, including transitions from lamellar growth cones to more streamlined tips, growth cone collaps, and re-extension. Simple branchtips were motile and appeared capable of exploratory behavior when viewed in time-lapse movies. In arbors imaged at 2-h intervals over a total of 8 h, morphological changes included longer branches, tens of microns in length. An average of 50% of the total branch length in the arbor was remodeled within 8 h. The data indicate that the elaboration of the arbor occurs by the random addition of branches throughout the arbor, followed by the selective stabilization of a small fraction of the new branches and the retraction of the majority of branches. Stabilized branches can then elongate and support the addition of more branches. These data show that structural changes in presynaptic axons can occur very rapidly even in complex arbors and can therefore play a role in forms of neuronal plasticity that operate on a timescale of minutes.