Reactive oxygen species, including superoxide, generally are considered neurotoxic molecules whose effects can be alleviated by antioxidants. Different from this view, we show that scavenging of superoxide with an antioxidant enzyme is associated with deficits in hippocampal long-term potentiation (LTP), a putative neural substrate of memory, and hippocampal-mediated memory function. Using transgenic mice that overexpress extracellular superoxide dismutase (EC-SOD), a superoxide scavenger, we found that LTP was impaired in hippocampal area CA1 despite normal LTP in area CA3. The LTP impairment in area CA1 could be reversed by inhibition of EC-SOD. In addition, we found that EC-SOD transgenic mice exhibited impaired long-term memory of fear conditioning to contextual cues despite exhibiting normal short-term memory of the conditioning experience. These findings strongly suggest that superoxide, rather than being considered exclusively a neurotoxic molecule, should also be considered a signaling molecule necessary for normal neuronal function.
Superoxide has been shown to be critically involved in several pathological manifestations of aging animals. In contrast, superoxide can act as a signaling molecule to modulate signal transduction cascades required for hippocampal synaptic plasticity. Mitochondrial superoxide dismutase (SOD-2 or Mn-SOD) is a key antioxidant enzyme that scavenges superoxide. Thus, SOD-2 may not only prevent aging-related oxidative stress, but may also regulate redox signaling in young animals. We used transgenic mice overexpressing SOD-2 to study the role of mitochondrial superoxide in aging, synaptic plasticity and memory-associated behavior. We found that overexpression of SOD-2 had no obvious effect on synaptic plasticity and memory formation in young mice, and could not rescue the age-related impairments in either synaptic plasticity or memory in old mice. However, SOD-2 overexpression did decrease mitochondrial superoxide in hippocampal neurons, and extended the lifespan of the mice. These findings increase our knowledge of the role of mitochondrial superoxide in physiological and pathological processes in the brain.
In this study, litters of rat pups and their mothers were continuously video-monitored from Day 14 to Day 35 postpartum in order to describe the behavioral changes that occur during that period. Prior to the onset of solid food intake (Day 18), pups spent most of their active time suckling. During Days 18 to 26, feeding, drinking, grooming, and play-fighting rapidly became frequent daily activities, while suckling gradually began to decline. By Day 28, pups' food and water intake relative to body weight and time allocated to the new behaviors reached asymptote. Pups nevertheless continued to suckle until Day 34. These results suggest that (1) the transition from milk to solid food is embedded in a multitude of behavioral changes; (2) these behavioral changes have distinct temporal characteristics; and (3) the developmental period between Days 14 and 34 can be divided into three phases.
1. As part of an effort to evaluate the biological plausibility of theoretically derived principles of synaptic modification, we studied activity-dependent long-term depression (LTD) of glutamatergic transmission in the hippocampus of anesthetized adult rats. Field potentials of CA1 pyramidal cells evoked by single-pulse stimulation (0.1 Hz) of the commissural afferents were recorded before and after paired-pulse stimulation (0.5 Hz) of the same pathway. A train of 150 or 200 paired pulses produced robust LTD of the commissural input to the CA1 pyramidal neurons when the interstimulus interval (ISI) of the pairs was short (25 ms) but not when the ISI was long (1,000 ms). 2. Paired-pulse stimulation with the short but not with the long ISI also was associated with pronounced inhibition of pyramidal cell firing upon the second pulse of a pair, despite the fact that the excitatory input was facilitated with the short-ISI paradigm. The inhibition of pyramidal cell activity was mediated by input to the pyramidal cells from local gamma-aminobutyric acid (GABA)-releasing interneurons activated by commissural fibers and/or CA1 recurrent collaterals, because the inhibition was eliminated by local administration of the selective GABAA receptor antagonist, bicuculline (50 microM), near the recording site. 3. Postsynaptic input from GABAergic interneurons was necessary for the induction of LTD, because short-ISI paired-pulse stimulation failed to produce LTD in the presence of bicuculline. 4. N-methyl-D-aspartate (NMDA) receptor-mediated excitation also was necessary for the induction of LTD, because administration of the selective NMDA receptor antagonist, D-2-amino-5-phosphonvaleric acid (100 microM), near the recording site prevented the development of LTD.(ABSTRACT TRUNCATED AT 250 WORDS)
Acute amphetamine (AMPH) exposure elevates extracellular dopamine through a variety of mechanisms that include inhibition of dopamine reuptake, depletion of vesicular stores, and facilitation of dopamine efflux across the plasma membrane. Recent work has shown that the DAT substrate AMPH, unlike cocaine and other nontransported blockers, can also stimulate endocytosis of the plasma membrane dopamine transporter (DAT). Here, we show that when AMPH enters the cytoplasm it rapidly stimulates DAT internalization through a dynamin-dependent, clathrin-independent process. This effect, which can be observed in transfected cells, cultured dopamine neurons, and midbrain slices, is mediated by activation of the small GTPase RhoA. Inhibition of RhoA activity with C3 exotoxin or a dominant-negative RhoA blocks AMPHinduced DAT internalization. These actions depend on AMPH entry into the cell and are blocked by the DAT inhibitor cocaine. AMPH also stimulates cAMP accumulation and PKA-dependent inactivation of RhoA, thus providing a mechanism whereby PKA-and RhoA-dependent signaling pathways can interact to regulate the timing and robustness of AMPH's effects on DAT internalization. Consistent with this model, the activation of D1/D5 receptors that couple to PKA in dopamine neurons antagonizes RhoA activation, DAT internalization, and hyperlocomotion observed in mice after AMPH treatment. These observations support the existence of an unanticipated intracellular target that mediates the effects of AMPH on RhoA and cAMP signaling and suggest new pathways to target to disrupt AMPH action.oth cocaine and amphetamine (AMPH) are psychostimulants that induce euphoria and hyperactivity by increasing extracellular dopamine. Despite the apparent commonalities in the effects and mechanism of action of the two drugs, amphetamine exposure has behavioral, neuroadaptive, and neurotoxic consequences not associated with cocaine use (1-5). These dissimilarities likely stem from several differences in the mechanism of action of the two drugs. Amphetamines, unlike cocaine and other nontransported inhibitors of the dopamine transporter (DAT), are transporter substrates that compete with dopamine for transport, enter dopamine neurons, enhance efflux of dopamine, and also stimulate internalization of the DAT from the cell surface (6, 7). To better understand how amphetamines mediate their effects within the cell, we undertook a series of studies to establish the cellular pathways and signaling mechanisms that underlie the endocytosis of the DAT triggered by amphetamines.AMPH-mediated DAT internalization has been shown to be dynamin-dependent (6). Dynamin-dependence is a key feature of clathrin-mediated endocytosis, and, indeed, previous reports of clathrin-dependent constitutive cycling (8) and PKC-mediated internalization (9) of DAT make it reasonable to consider that the same machinery would be involved in AMPH-mediated internalization. A secondary pathway of dynamin-mediated internalization of membrane-localized proteins involves small GTPases o...
We are studying the role of the evolutionarily conserved tlx gene in forebrain development in mice. Tlx is expressed in the ventricular zone that gives rise to neurons and glia of the forebrain. We have shown by mutating the tlx gene in mice, that in the absence of this transcription factor, mutant animals survive, but suffer specific anatomical defects in the limbic system. Because of these developmentally induced structural changes, mice with a mutation in the tlx gene can function, but exhibit extreme behavioral pathology. Mice show heightened aggressiveness, excitability, and poor cognition. In this article, we present a summary of our findings on the cellular and behavioral changes in the forebrain of mutant animals. We show that absence of the tlx gene leads to abnormal proliferation and differentiation of progenitor cells (PCs) in the forebrain from embryonic day 9 (E9). These abnormalities lead to hypoplasia of superficial cortical layers and subsets of GABAergic interneurons in the neocortex. We examined the behavior of mutant animals in three tests for anxiety/fear: the open field, the elevated plus maze, and fear conditioning. Mutant animals are less anxious and less fearful when assessed in the elevated plus and open-field paradigm. In addition, mutant animals do not condition to either the tone or the context in the fear-conditioning paradigm. These animals, therefore, provide a genetic tool to delineate structure/function relationships in defined regions of the brain and decipher how their disruption leads to behavioral abnormalities.
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