Kathy L. Parsons

Neurotoxic effects of feline immunodeficiency virus, FIV - PPR

FIV is a lentivirus of domestic cats that causes neurologic disorders which are remarkably similar to those found in HIV-1 infected people. Using feline neuron cultures, we investigated the potential of both FIV virus and FIV-Env protein to cause neuronal damage through the excitotoxicity mechanism. The neuron swelling and lactate dehydrogenase (LDH) release assays were used as measures of cellular damage. The effects of FIV Env protein on glutamate receptor mediated increases in intracellular calcium were also examined. We found that FIV virus and FIV-Env protein significantly increased LDH release from the neuron cultures. Additionally, an increase in neuron size was detected in the cultures exposed to the virus, while swelling did not occur with exposure to either saline, denatured virus, or FIV-Env by itself. However, when both 20 microM glutamate and the FIV-PPR Env protein were added to the culture, a significant increase in neuron cell size was observed. The NMDA calcium signals were similar in general form between the control and FIV-PPR Env exposed cultures. However, the FIV - PPR Env protein treated cultures resulted in significant enhancement of the NMDA induced calcium signal. Our results indicate that FIV Env protein (either within the virion or baculovirus expressed) induced neurotoxicity as measured by neuron swelling and LDH release assays and that exposure of feline neurons to FIV Env protein alters the handling of intracellular calcium. These findings help to validate the FIV/cat system as a potential animal model for evaluating therapeutic approaches that target the excitotoxicity mechanisms of lentivirus induced CNS disease.

Chronic alcohol reduces calcium signaling elicited by glutamate receptor stimulation in developing cerebellar neurons.

The effect of chronic alcohol (33 mM ethanol) on Ca2+ signals elicited by glutamate receptor agonists (quisqualate and NMDA) was examined in developing cerebellar Purkinje and granule neurons in culture. The neurons were exposed to alcohol during the second week in culture, the main period of morphological and physiological development. The Ca2+ signals were measured with fura-2 based microscopic video imaging. Chronic exposure to alcohol during development significantly reduced the peak amplitude of the Ca2+ signals to quisqualate (1 microM; Quis) in both the somatic and dendritic regions of the Purkinje neurons. The dendritic region was affected to a greater extent than the somatic region. Granule neurons also showed a reduced somatic Ca2+ signal to Quis (dendrites not measured) in the alcohol-treated cultures, indicating that the effect was not limited to Purkinje neurons. In addition to the effects on in the response to Quis, the peak amplitude of the Ca2+ signals to NMDA (100 microM) was reduced by chronic alcohol exposure during development in both the cultured Purkinje and granule neurons. Resting Ca2+ levels were not consistently affected by alcohol treatment in either neuronal type. These results indicate that Ca2+ signaling linked to glutamate receptor activation is an important target of alcohol in the developing nervous system and could be a contributing factor in the altered CNS function and development observed in animal models of fetal alcohol syndrome.

Chronic exposure to alcohol during development alters the calcium currents of cultured cerebellar Purkinje neurons

The effect of chronic exposure to alcohol during development on the calcium currents of rat cerebellar Purkinje neurons was studied in a culture model system using voltage clamp techniques. The neurons were exposed to 30 mM alcohol (ethanol) during the main period of morphological and physiological development. The calcium currents were measured at the end of the treatment period, which lasted for 8-10 days. The currents were evoked by a series of depolarizing test commands from holding potentials of -62 mV and -90 mV. The evoked currents were qualitatively similar in control and alcohol-treated neurons and were comprised of a high threshold slowly inactivating calcium current and a low threshold rapidly inactivating calcium current. The low threshold current could be observed in isolation at test potentials ranging from -50 to -30 mV. The mean peak amplitude of this current was significantly smaller in the alcohol-treated neurons compared to controls. At more depolarized test potentials, the high threshold current dominated the current response, which was characterized by an initial peak that slowly declined to a smaller relatively sustained level. The mean amplitude of the high threshold current at both peak and sustained levels was significantly larger in the alcohol-treated neurons compared to controls. Measurement of cell size indicated that alcohol-treated neurons were approximately 25% smaller than control neurons, a difference that could contribute to the smaller low threshold current observed in these neurons. These data show that chronic exposure to alcohol during the development can significantly influence the amplitude of calcium currents of the cultured Purkinje neurons.(ABSTRACT TRUNCATED AT 250 WORDS)

Neonatal alcohol exposure reduces NMDA induced Ca2+ signaling in developing cerebellar granule neurons

Glutamatergic neurotransmission through NMDA receptors is critical for both neurogenesis and mature function of the central nervous system (CNS), and is thought to be one target for developmentally-induced damage by alcohol to brain function. In the current study we examined Ca2+ signaling linked to NMDA receptor activation as a potential site for alcohols detrimental effects on the developing nervous system. We compared Ca2+ signals to NMDA in granule neurons cultured from cerebella of rat neonates exposed to alcohol (ethanol) during development with responses to NMDA recorded in separated control groups. Alcohol exposure was by the vapor chamber method on postnatal days 4-7. An intermittent exposure paradigm was used where the pups were exposed to alcohol vapor for 2. 5 h/day to produce peak BALs of approximately 320 mg%. Control pups were placed in an alcohol-free chamber for a similar time period or remained with their mother. After culture under alcohol-free conditions for up to 9 days, Ca2+ signaling in response to NMDA was measured using fura-2 Ca2+ imaging. Results show that the peak amplitude of the Ca2+ signal to NMDA was significantly smaller in cultured granule neurons obtained from alcohol-treated pups compared to granule neurons from control pups. In contrast, the Ca2+ signal to K+ depolarization was not depressed by the alcohol treatment. Resting Ca2+ levels were also altered by the alcohol treatment. These results show that intermittent alcohol exposure during development in vivo can induce long-term changes in CNS neurons that affect the Ca2+ signaling pathway linked to NMDA receptors and resting Ca2+ levels. Such changes could play an important role in the CNS dysfunction associated with alcohol exposure during CNS development.

Chronic ethanol treatment alters AMPA-induced calcium signals in developing Purkinje neurons

Cerebellar Purkinje neurons developing in culture were treated chronically with 30 mM (140 mg%; 3-11 days in vitro) ethanol to study the actions of prolonged ethanol exposure on responses to exogenous application of AMPA, a selective agonist at the AMPA subtype of ionotropic glutamate receptors. There was no consistent difference between control and chronic ethanol-treated neurons in resting membrane potential, input resistance, or the amplitude or duration of the membrane responses to AMPA (1 or 5 microM applied by brief microperfusion) as measured using the nystatin patch method of whole cell recording. In additional studies, the Ca2+ signal to AMPA was examined using the Ca2+ sensitive dye fura-2. The mean peak Ca2+ signal elicited by 5 microM AMPA was enhanced in the dendritic region (but not the somatic region) of chronic ethanol-treated Purkinje neurons compared to control neurons. In contrast, there was no difference between control and chronic ethanol-treated neurons in the peak amplitude of the Ca2+ signal to 1 microM AMPA, whereas the recovery of the Ca2+ signals was more rapid in both somatic and dendritic regions of ethanol-treated neurons. Resting Ca2+ levels in the somatic and dendritic regions were similar between control and ethanol-treated neurons. These data show that the membrane and Ca2+ responses to AMPA in Purkinje neurons are differentially affected by prolonged ethanol exposure during development. Moreover, chronic ethanol exposure produces a selective enhancement of AMPA-evoked dendritic Ca2+ signals under conditions reflecting intense activation (i.e., 5 microM AMPA), whereas both somatic and dendritic Ca2+ signals are attenuated with smaller levels of activation (i.e., 1 microM AMPA). Because Ca2+ is an important regulator of numerous intracellular functions, chronic ethanol exposure during development could produce widespread changes in the development and function of the cerebellum.

Cannabinoids and Interleukin-6 Enhance the Response to Nmda in Developing CNS Neurons

Maternal cannabinoid use during pregnancy is harmful to the central nervous system (CNS) of the developing infant12. Cannabinoids pass easily from the mother to the fetus, where they can access neuronal receptors in the developing CNS. Cannabinoid receptors are known to be expressed by CNS neurons, although their role in normal brain functions has yet to be defined. It is likely that these receptors mediate some form of intercellular signaling, since biochemicals endogenous to the CNS (e.g., anandamide)5 have been shown to act at CNS cannabinoid receptors.4 Cannabinoid receptors are expressed during the main period of morphological and physiological development of the CNS,11 a correlation that may reflect a role in the developmental process. Hyperactivation of these receptors by maternal cannabinoid use could lead to a disruption of the normal signaling pattern and, consequently, altered development and permanent changes in CNS function.