Margaret E. Rice

Ascorbate regulation and its neuroprotective role in the brain.

Ascorbic acid (vitamin C) occurs physiologically as the ascorbate anion: a water-soluble antioxidant that is found throughout the body. However, despite the high, homeostatically regulated levels of brain ascorbate, its specific functions in the CNS are only beginning to be elucidated. Certainly, it acts as part of the intracellular antioxidant network, and as such is normally neuroprotective. There is also evidence that it acts as a neuromodulator. A possibly unique role it might have is as an antioxidant in the brain extracellular microenvironment, where its concentration is modulated by glutamate-ascorbate heteroexchange at glutamate uptake sites. Ongoing studies of ascorbate and glutamate transporters should lead to rapid progress in understanding ascorbate regulation and function.

Nicotine amplifies reward-related dopamine signals in striatum.

Reward-seeking behaviors depend critically on dopamine signaling—dopamine neurons encode reward-related information by switching from tonic to phasic (burst-like) activity. Using guinea pig brain slices, we show that nicotine, like cocaine and amphetamine, acts directly in striatum where it enhances dopamine release during phasic but not tonic activity. This amplification provides a mechanism for nicotine facilitation of reward-related dopamine signals, including responses to other primary reinforcers that govern nicotine dependence in smokers.

Enhanced striatal dopamine transmission and motor performance with LRRK2 overexpression in mice is eliminated by familial Parkinson's disease mutation G2019S.

PARK8/LRRK2 (leucine-rich repeat kinase 2) was recently identified as a causative gene for autosomal dominant Parkinsons disease (PD), with LRRK2 mutation G2019S linked to the most frequent familial form of PD. Emerging in vitro evidence indicates that aberrant enzymatic activity of LRRK2 protein carrying this mutation can cause neurotoxicity. However, the physiological and pathophysiological functions of LRRK2 in vivo remain elusive. Here we characterize two bacterial artificial chromosome (BAC) transgenic mouse strains overexpressing LRRK2 wild-type (Wt) or mutant G2019S. Transgenic LRRK2-Wt mice had elevated striatal dopamine (DA) release with unaltered DA uptake or tissue content. Consistent with this result, LRRK2-Wt mice were hyperactive and showed enhanced performance in motor function tests. These results suggest a role for LRRK2 in striatal DA transmission and the consequent motor function. In contrast, LRRK2-G2019S mice showed an age-dependent decrease in striatal DA content, as well as decreased striatal DA release and uptake. Despite increased brain kinase activity, LRRK2-G2019S overexpression was not associated with loss of DAergic neurons in substantia nigra or degeneration of nigrostriatal terminals at 12 months. Our results thus reveal a pivotal role for LRRK2 in regulating striatal DA transmission and consequent control of motor function. The PD-associated mutation G2019S may exert pathogenic effects by impairing these functions of LRRK2. Our LRRK2 BAC transgenic mice, therefore, could provide a useful model for understanding early PD pathological events.

Glutamatergic Signaling by Mesolimbic Dopamine Neurons in the Nucleus Accumbens

Recent evidence suggests the intriguing possibility that midbrain dopaminergic (DAergic) neurons may use fast glutamatergic transmission to communicate with their postsynaptic targets. Because of technical limitations, direct demonstration of the existence of this signaling mechanism has been limited to experiments using cell culture preparations that often alter neuronal function including neurotransmitter phenotype. Consequently, it remains uncertain whether glutamatergic signaling between DAergic neurons and their postsynaptic targets exists under physiological conditions. Here, using an optogenetic approach, we provide the first conclusive demonstration that mesolimbic DAergic neurons in mice release glutamate and elicit excitatory postsynaptic responses in projection neurons of the nucleus accumbens. In addition, we describe the properties of the postsynaptic glutamatergic responses of these neurons during experimentally evoked burst firing of DAergic axons that reproduce the reward-related phasic population activity of the mesolimbic projection. These observations indicate that, in addition to DAergic mechanisms, mesolimbic reward signaling may involve glutamatergic transmission.

Dopamine release in the basal ganglia

Dopamine (DA) is a key transmitter in the basal ganglia, yet DA transmission does not conform to several aspects of the classic synaptic doctrine. Axonal DA release occurs through vesicular exocytosis and is action potential- and Ca²⁺-dependent. However, in addition to axonal release, DA neurons in midbrain exhibit somatodendritic release by an incompletely understood, but apparently exocytotic, mechanism. Even in striatum, axonal release sites are controversial, with evidence for DA varicosities that lack postsynaptic specialization, and largely extrasynaptic DA receptors and transporters. Moreover, DA release is often assumed to reflect a global response to a population of activities in midbrain DA neurons, whether tonic or phasic, with precise timing and specificity of action governed by other basal ganglia circuits. This view has been reinforced by anatomical evidence showing dense axonal DA arbors throughout striatum, and a lattice network formed by DA axons and glutamatergic input from cortex and thalamus. Nonetheless, localized DA transients are seen in vivo using voltammetric methods with high spatial and temporal resolution. Mechanistic studies using similar methods in vitro have revealed local regulation of DA release by other transmitters and modulators, as well as by proteins known to be disrupted in Parkinsons disease and other movement disorders. Notably, the actions of most other striatal transmitters on DA release also do not conform to the synaptic doctrine, with the absence of direct synaptic contacts for glutamate, GABA, and acetylcholine (ACh) on striatal DA axons. Overall, the findings reviewed here indicate that DA signaling in the basal ganglia is sculpted by cooperation between the timing and pattern of DA input and those of local regulatory factors.

Activation of ATP-sensitive K+ (KATP) channels by H2O2 underlies glutamate-dependent inhibition of striatal dopamine release

In many cells, ATP-sensitive K+ channels (KATP channels) couple metabolic state to excitability. In pancreatic beta cells, for example, this coupling regulates insulin release. Although KATP channels are abundantly expressed in the brain, their physiological role and the factors that regulate them are poorly understood. One potential regulator is H2O2. We reported previously that dopamine (DA) release in the striatum is modulated by endogenous H2O2, generated downstream from glutamatergic α-amino-3-hydroxy-5-methyl-4-isoxazolepropionic acid (AMPA)-receptor activation. Here we investigated whether H2O2-sensitive KATP channels contribute to DA-release modulation by glutamate and γ-aminobutyric acid (GABA). This question is important because DA–glutamate interactions underlie brain functions, including motor control and cognition. Synaptic DA release was evoked by using local electrical stimulation in slices of guinea pig striatum and monitored in real time with carbon-fiber microelectrodes and fast-scan cyclic voltammetry. The KATP-channel antagonist glibenclamide abolished the H2O2-dependent increase in DA release usually seen with AMPA-receptor blockade by GYKI-52466 [1-(4-aminophenyl)-4-methyl-7,8-methylenedioxy-5H-2,3-benzodiazepine hydrochloride] and the decrease in DA release seen with GABA-type-A-receptor blockade by picrotoxin. In contrast, 5-hydroxydecanoate, a mitochondrial KATP-channel blocker, was ineffective, as were sulpiride, a D2-receptor antagonist, and tertiapin, a G protein-coupled K+-channel inhibitor. Diazoxide, a sulfonylurea receptor 1 (SUR1)selective KATP-channel opener, prevented DA modulation by H2O2, glutamate, and GABA, whereas cromakalim, a SUR2-selective opener, did not. Thus, endogenous H2O2 activates SUR1-containing KATP channels in the plasma membrane to inhibit DA release. These data not only demonstrate that KATP channels can modulate CNS transmitter release in response to fast-synaptic transmission but also introduce H2O2 as a KATP-channel regulator.

Endogenous Hydrogen Peroxide Regulates the Excitability of Midbrain Dopamine Neurons via ATP-Sensitive Potassium Channels

ATP-sensitive K+ (KATP) channels link metabolic state to cell excitability. Here, we examined regulation of KATP channels in substantia nigra dopamine neurons by hydrogen peroxide (H2O2), which is produced in all cells during aerobic metabolism. Blockade of KATP channels by glibenclamide (100 nm) or depletion of intracellular H2O2 by including catalase, a peroxidase enzyme, in the patch pipette increased the spontaneous firing rate of all dopamine neurons tested in guinea pig midbrain slices. Using fluorescence imaging with dichlorofluorescein to visualize intracellular H2O2, we found that moderate increases in H2O2 during partial inhibition of glutathione (GSH) peroxidase by mercaptosuccinate (0.1-0.3 mm) had no effect on dopamine neuron firing rate. However, with greater GSH inhibition (1 mm mercaptosuccinate) or application of exogenous H2O2, 50% of recorded cells showed KATP channel-dependent hyperpolarization. Responsive cells also hyperpolarized with diazoxide, a selective opener for KATP channels containing sulfonylurea receptor SUR1 subunits, but not with cromakalim, a selective opener for SUR2-based channels, indicating that SUR1-based KATP channels conveyed enhanced sensitivity to elevated H2O2. In contrast, when endogenous H2O2 levels were increased after inhibition of catalase, the predominant peroxidase in the substantia nigra, with 3-amino-1,2,4-triazole (1 mm), all dopamine neurons responded with glibenclamide-reversible hyperpolarization. Fluorescence imaging of H2O2 indicated that catalase inhibition rapidly amplified intracellular H2O2, whereas inhibition of GSH peroxidase, a predominantly glial enzyme, caused a slower, smaller increase, especially in nonresponsive cells. Thus, endogenous H2O2 modulates neuronal activity via KATP channel opening, thereby enhancing the reciprocal relationship between metabolism and excitability.

Ascorbate inhibits edema in brain slices

Ascorbate is an essential antioxidant in the CNS, localized predominantly in neuronal cytosol. Slices of mammalian brain rapidly lose ascorbate, however, when incubated in ascorbate‐free media; brain slices also take up water and swell. Here we investigated water gain in coronal slices of rat forebrain incubated with and without ascorbate for 1‐3 h at 34°C. Slices progressively gained water in ascorbate‐free media, with a significant 12% water increase after 3 h at 34°C, compared with the water content of slices after a 1‐h recovery period at 24°C, immediately following slice preparation. Inclusion of 400 μM ascorbate in the medium led to an increase in tissue ascorbate content and prevented water gain at 34°C. By contrast, water gain was not inhibited by isoascorbate or thiourea, which are antioxidants that are not accumulated in brain cells. The oxidant H2O2 enhanced water gain, whereas a cocktail of NMDA and non‐NMDA receptor blockers inhibited edema formation to the same extent as ascorbate. These data demonstrate that brain edema, linked to glutamate‐receptor activation, can result from intracellular oxidative stress and that this can be prevented by ascorbate.

Neuroprotective adaptations in hibernation: therapeutic implications for ischemia-reperfusion, traumatic brain injury and neurodegenerative diseases.

Brains of hibernating mammals are protected against a variety of insults that are detrimental to humans and other nonhibernating species. Such protection is associated with a number of physiological adaptations including hypothermia, increased antioxidant defense, metabolic arrest, leukocytopenia, immunosuppression, and hypocoagulation. It is intriguing that similar manipulations provide considerable protection as experimental treatments for central nervous system injury. This review focuses on neuroprotective mechanisms employed during hibernation that may offer novel approaches in the treatment of stroke, traumatic brain injury, and neurodegenerative diseases in humans.

The Migration of Substances in the Neuronal Microenvironmenta

An inescapable characteristic of the neuronal microenvironment is the diffusion of substances, whether from capillary to cell or from preto postsynaptic site. Since the reticular theory of the nervous system was laid to rest by Ramon y Cajal’ and the subsequent use of the electron microscope, it has been established that the cellular entities of the nervous system are distinct entities. Some modification of this view has taken place with the demonstration of gap junctions between specific cells, but overall, cellular isolation appears to be a necessity, presumably to ensure selective molecular information transfer. Given this fact, diffusion is, to borrow a phrase from Sherrington: the “final common path” for all substances to reach cells in the nervous system. This path is constrained by the geometry of the neuronal microenvironment. A fundamental characteristic of all physiological systems is the movement of substances. We may broadly divide this process into two categories: energetic and informational. By the former we signify the movement of metabolic substrates, products, and by-products responsible for maintenance of the living organism. Such migrations are usually characterized by the relatively large fluxes involved. In contrast, informational flows are not destined to provide fuel, but rather to change the state or behavior of the recipient, that is, to signal or communicate. Only small amounts of an “informational substance” (see Schmitt’ for the origin of this term and a review of the concept) are required, but the information content is large. In addition to the quantity of substance involved, informational substances are distinguished from energetic by the presence of specific receptors that enable signal transduction. All parts of physiological systems feature both energetic and informational flows, but the balance is usually in favor of the energetic. The brain differs radically in this respect; here information flows have achieved extraordinary prominence, and the energetic flows have become subservient to the task of providing energy for the processing of information and for maintaining the environment in a state where communication can take place.