Scott A. Mackler

Stimulus-induced coordinate changes in mRNA abundance in single postsynaptic hippocampal CA1 neurons

The molecular effects of use-dependent changes in synaptic transmission were studied in individual CA1 pyramidal neurons from rat hippocampal slices. Potentiation of excitatory postsynaptic currents was associated with coordinate changes in the relative abundance of several mRNAs 30 min to 3 hr after stimulation. There was a 300% increase in calcium/calmodulin-dependent protein kinase II mRNA levels concordant with a 50% decrease in protein kinase C beta 1 isoform mRNA. A 2-fold increase in zif-268 mRNA was seen, while increases in c-fos and c-jun mRNA levels were inconsistent, gamma-Aminobutyric acid A receptor beta 1 subunit mRNA levels increased 3-fold. Potentiation-induced changes were prevented by N-methyl-D-aspartate receptor blockade. Changes in mRNA abundance in individual cells, with synaptic and glial interactions intact, combine to produce a molecular fingerprint of a potentiated CA1 neuron.

Effect of acamprosate and naltrexone, alone or in combination, on ethanol consumption

Both acamprosate and naltrexone have demonstrated clinical utility in reducing relapse to alcohol use in recovering alcoholics. The present experiments examined the effects of acamprosate and naltrexone, either alone or in combination, on basal ethanol consumption in a limited-access model with the use of outbred Wistar rats. Naltrexone, 0.1 mg/kg, significantly reduced ethanol consumption as previously reported. Acamprosate, 50 mg/kg, did not significantly reduce ethanol consumption when administered alone and provided no evidence of additive or synergistic effects when combined with naltrexone. Acamprosate, 200 mg/kg, produced a modest reduction in ethanol consumption when administered alone but no evidence of additive or synergistic effects when combined with naltrexone. From these findings, it is suggested that a combination approach of these drugs may not be any more effective than monotherapy.

Expression and localization of epithelial sodium channel in mammalian urinary bladder

The mammalian urinary bladder exhibits transepithelial Na+ absorption that contributes to Na+ gradients established by the kidney. Electrophysiological studies have demonstrated that electrogenic Na+ absorption across the urinary bladder is mediated in part by amiloride-sensitive Na+ channels situated within the apical membrane of the bladder epithelium. We have used a combination of in situ hybridization, Northern blot analysis, and immunocytochemistry to examine whether the recently cloned epithelial Na+ channel (ENaC) is expressed in the rat urinary bladder. In situ hybridization and Northern blot analyses indicate that alpha-, beta-, and gamma-rat ENaC (rENaC) are expressed in rat urinary bladder epithelial cells. Quantitation of the levels of alpha-, beta-, and gamma-rENaC mRNA expression in rat urinary bladder, relative to beta-actin mRNA expression, indicates that, although comparable levels of alpha- and beta-rENaC subunits are expressed in the urinary bladder of rats maintained on standard chow, the level of gamma-rENaC mRNA expression is 5- to 10-fold lower than alpha- or beta-rENaC mRNA. Immunocytochemistry, using an antibody directed against alpha-rENaC, revealed that ENaCs are predominantly localized to the luminal membrane of the bladder epithelium. Together, these data demonstrate that ENaC is expressed in the mammalian urinary bladder and suggest that amiloride-sensitive Na+ transport across the apical membrane of the mammalian urinary bladder epithelium is mediated primarily by ENaC.The mammalian urinary bladder exhibits transepithelial Na+ absorption that contributes to Na+ gradients established by the kidney. Electrophysiological studies have demonstrated that electrogenic Na+ absorption across the urinary bladder is mediated in part by amiloride-sensitive Na+ channels situated within the apical membrane of the bladder epithelium. We have used a combination of in situ hybridization, Northern blot analysis, and immunocytochemistry to examine whether the recently cloned epithelial Na+ channel (ENaC) is expressed in the rat urinary bladder. In situ hybridization and Northern blot analyses indicate that α-, β-, and γ-rat ENaC (rENaC) are expressed in rat urinary bladder epithelial cells. Quantitation of the levels of α-, β-, and γ-rENaC mRNA expression in rat urinary bladder, relative to β-actin mRNA expression, indicates that, although comparable levels of α- and β-rENaC subunits are expressed in the urinary bladder of rats maintained on standard chow, the level of γ-rENaC mRNA expression is 5- to 10-fold lower than α- or β-rENaC mRNA. Immunocytochemistry, using an antibody directed against α-rENaC, revealed that ENaCs are predominantly localized to the luminal membrane of the bladder epithelium. Together, these data demonstrate that ENaC is expressed in the mammalian urinary bladder and suggest that amiloride-sensitive Na+ transport across the apical membrane of the mammalian urinary bladder epithelium is mediated primarily by ENaC.

Sour Ageusia in Two Individuals Implicates Ion Channels of the ASIC and PKD Families in Human Sour Taste Perception at the Anterior Tongue

Background The perception of sour taste in humans is incompletely understood at the receptor cell level. We report here on two patients with an acquired sour ageusia. Each patient was unresponsive to sour stimuli, but both showed normal responses to bitter, sweet, and salty stimuli. Methods and Findings Lingual fungiform papillae, containing taste cells, were obtained by biopsy from the two patients, and from three sour-normal individuals, and analyzed by RT-PCR. The following transcripts were undetectable in the patients, even after 50 cycles of amplification, but readily detectable in the sour-normal subjects: acid sensing ion channels (ASICs) 1a, 1β, 2a, 2b, and 3; and polycystic kidney disease (PKD) channels PKD1L3 and PKD2L1. Patients and sour-normals expressed the taste-related phospholipase C-β2, the δ-subunit of epithelial sodium channel (ENaC) and the bitter receptor T2R14, as well as β-actin. Genomic analysis of one patient, using buccal tissue, did not show absence of the genes for ASIC1a and PKD2L1. Immunohistochemistry of fungiform papillae from sour-normal subjects revealed labeling of taste bud cells by antibodies to ASICs 1a and 1β, PKD2L1, phospholipase C-β2, and δ-ENaC. An antibody to PKD1L3 labeled tissue outside taste bud cells. Conclusions These data suggest a role for ASICs and PKDs in human sour perception. This is the first report of sour ageusia in humans, and the very existence of such individuals (“natural knockouts”) suggests a cell lineage for sour that is independent of the other taste modalities.

Behavioral recovery following spinal transection: functional regeneration in the lamprey CNS

Abstract The large larval sea lamprey (4–5 years old) recovers behaviorally from spinal transection. This is accompanied by regeneration of axons across the lesion site. The regenerated portions of these axons form functional synapses and appear to do so selectively with their normal target neurons. By studying ventral root (motor) discharges in the isolated spinal cord, it has been shown that the regenerated connections mediate intersegmental coordination of locomotor circuitry across the healed lesion. The lamprey spinal cord has now met all the criteria for functional regeneration of neurites, and has helped to define the potential of the vertebrate CNS for recovery from traumatic injury. It may also yield insights into the mechanisms of neural development.

The effect of gamma-vinyl-GABA on the consumption of concurrently available oral cocaine and ethanol in the rat.

It has frequently been reported that a high percentage of individuals, identified as either alcohol- or cocaine-dependent, concurrently abuse both drugs. The experiments reported here represent a continuing effort to develop an animal model to predict the effects of a potential pharmacotherapeutic agent on concurrently available oral ethanol and cocaine. These experiments utilized drinkometer circuitry to assess the effects of gamma-vinyl-GABA (GVG), a gamma-aminobutyric acid (GABA) transaminase inhibitor, on the consumption and temporal pattern of responses for orally self-administered ethanol and cocaine. The results of these experiments showed that GVG, at doses of 100, 200 and 300 mg/kg, reduced both ethanol and cocaine consumption in a dose-related manner. When compared to vehicle, GVG at all doses significantly reduced ethanol consumption while consumption of cocaine was significantly reduced only at 300 mg/kg. This is consistent with data showing that GVG reduces consumption of these drugs when administered alone and data showing that GVG is more potent in reducing ethanol-induced compared to cocaine-induced extracellular dopamine in the nucleus accumbens. Analysis of the temporal pattern of drinking across the session suggests that GVGs effects are due to a disruption of the reinforcing properties of ethanol and cocaine rather than a more general reduction in motor behavior. These data suggest that GVG has potential for clinical use in populations that abuse either alcohol or cocaine alone or in combination.

NAC1 regulates the recruitment of the proteasome complex into dendritic spines.

Coordinated proteolysis of synaptic proteins is required for synaptic plasticity, but a mechanism for recruiting the ubiquitin-proteasome system (UPS) into dendritic spines is not known. NAC1 is a cocaine-regulated transcriptional protein that was found to complex with proteins in the UPS, including cullins and Mov34. NAC1 and the proteasome were cotranslocated from the nucleus into dendritic spines in cortical neurons in response to proteasome inhibition or disinhibiting synaptic activity with bicuculline. Bicuculline also produced a progressive accumulation of the proteasome and NAC1 in the postsynaptic density. Recruitment of the proteasome into dendrites and postsynaptic density by bicuculline was prevented in neurons from mice harboring an NAC1 gene deletion or in neurons transfected with mutated NAC1 lacking the proteasome binding domain. These experiments show that NAC1 modulates the translocation of the UPS from the nucleus into dendritic spines, thereby suggesting a potential missing link in the recruitment of necessary proteolysis machinery for synaptic remodeling.

A comparison of the effects of 6-β naltrexol and naltrexone on the consumption of ethanol or sucrose using a limited-access procedure in rats

We recently reported that 6-beta naltrexol, the major metabolite of naltrexone in humans, reduced ethanol consumption in rats. Two new experiments were designed to compare 6-beta naltrexol and naltrexone across three dose levels on an ethanol or sucrose baseline using a limited-access procedure in Wistar rats. The results of Experiment 1 showed that both 6-beta naltrexol and naltrexone reduced ethanol consumption across a range of doses. An in vivo assay showed that naltrexone was approximately 25 times more potent than 6-beta naltrexol at comparable ED50 doses. In addition, there was no indication of systematic development of tolerance to the effect of either drug across the 4 days of drug administration. In Experiment 2, both 6-beta naltrexol and naltrexone reduced the consumption of a sucrose solution using a limited-access procedure. The implications of these data for the development of pharmacotherapeutic agents capable of reducing drinking in recovering alcoholics are discussed.

Complementary DNA synthesis in situ : methods and applications

In situ transcription is the synthesis of cDNA within cells. This chapter has illustrated some of the application of IST to the study of gene expression in complex cell environments. While the importance of transcription in modulating cellular activity has been long appreciated, the role of translational control mechanisms in regulating central nervous system functioning is just beginning to be recognized. Previous limitations in the availability of tissue have made it difficult to construct cDNA libraries from defined cell populations, to examine translational control, and to quantitate differences in the amount of mRNA for many distinct mRNAs in the same sample. In situ transcription facilitates all of these procedures, making it possible to characterize aspects of gene regulation that were previously difficult. Indeed, taken to its furthest extreme it is now possible to characterize gene expression in single live cells. This level of analysis allows basic questions, such as How different morphologically identical cells are at the level of gene expression, and How synaptic connectivity and glial interactions influence gene expression in single cells, to be experimentally approached. The ability to characterize gene expression in small amounts of tissue and single cells is critical to gaining an understanding of the contribution of specific cell types to the physiology of the central nervous system.

The POZ/BTB protein NAC1 interacts with two different histone deacetylases in neuronal-like cultures

NAC1 is a cocaine‐regulated POZ/BTB (Pox virus and Zinc finger/Bric‐a‐brac Tramtrack Broad complex) protein. NAC1 is increased by cocaine selectively in the nucleus accumbens, a CNS region important for drug addiction. NAC1s role in the cell, however, is not known. Each of the two NAC1 isoforms, sNAC1 (short NAC1) and lNAC1 (long NAC1), may serve as corepressors for other POZ/BTB proteins. This study investigated whether sNAC1 and lNAC1 demonstrated protein–protein interactions with other corepressors. Histone deacetylase (HDAC) inhibition reversed sNAC1 and lNAC1 repression of Gal4 luciferase, but only in neuronal‐like cultures. Because these inhibitors do not distinguish among histone deacetylases, two histone deacetylases were selected for further study. HDAC 3 and 4 both demonstrated protein–protein interactions with sNAC1 and lNAC1. This was shown using coimmunoprecipitations, glutathione‐S‐transferase (GST) pulldowns and mammalian two‐hybrids. Importantly, either the POZ domain or NAC1 without the POZ domain can bind these two HDACs. Other corepressors, specifically NCoR (nuclear receptor corepressor), SMRT (silencing mediator for retinoid and thyroid hormone receptor) and mSin3a, do not exhibit protein–protein interactions with sNAC1 and lNAC1. None showed protein–protein interactions in GST pulldowns or mammalian two‐hybrids. Taken together, the results of these experiments indicate sNAC1 and lNAC1 recruit histone deacetylases for transcriptional repression, further enhancing POZ/BTB protein mediated repression.