Activity-dependent regulation of Na+, K(+)-ATPase alpha isoform mRNA expression in vivo

Region- and neuronal-subtype-specific expression of Na,K-ATPase alpha and beta subunit isoforms in the mouse brain

Na,K‐ATPase is a ubiquitous molecule contributing to the asymmetrical distribution of Na⁺ and K⁺ ions across the plasma membrane and maintenance of the membrane potential, a prerequisite of neuronal activity. Na,K‐ATPase comprises three subunits (α, β, and FXYD). The α subunit has four isoforms in mice, with three of them (α1, α2, and α3) expressed in the brain. However, the functional and biological significances of the different brain isoforms remain to be fully elucidated. Recent studies have revealed the association of Atp1a3, a gene encoding α3 subunit, with neurological disorders. To map the cellular distributions of the α subunit isoforms and their coexpression patterns, we evaluated the mRNA expression of Atp1a1, Atp1a2, and Atp1a3 by in situ hybridization in the mouse brain. Atp1a1 and Atp1a3 were expressed in neurons, whereas Atp1a2 was almost exclusively expressed in glial cells. Most neurons coexpressed Atp1a1 and Atp1a3, with highly heterogeneous expression levels across the brain regions and neuronal subtypes. We identified parvalbumin (PV)‐expressing GABAergic neurons in the hippocampus, somatosensory cortex, and retrosplenial cortex as an example of a neuronal subtype expressing low Atp1a1 and high Atp1a3. The expression of Atp1b isoforms was also heterogeneous across brain regions and cellular subtypes. The PV‐expressing neurons expressed a high level of Atp1b1 and a low level of Atp1b2 and Atp1b3. These findings provide basic information on the region‐ and neuronal‐subtype‐dependent expression of Na,K‐ATPase α and β subunit isoforms, as well as a rationale for the selective involvement of neurons expressing high levels of Atp1a3 in neurological disorders.

Possible role of brain salt-inducible kinase 1 in responses to central sodium in Dahl rats

In Dahl salt-sensitive (S) rats, Na+ entry into the cerebrospinal fluid (CSF) and sympathoexcitatory and pressor responses to CSF Na+ are enhanced. Salt-inducible kinase 1 (SIK1) increases Na+/K+-ATPase activity in kidney cells. We tested the possible role of SIK1 in regulation of CSF [Na+] and responses to Na+ in the brain. SIK1 protein and activity were lower in hypothalamic tissue of Dahl S (SS/Mcw) compared with salt-resistant SS.BN13 rats. Intracerebroventricular infusion of the protein kinase inhibitor staurosporine at 25 ng/day, to inhibit SIK1 further increased mean arterial pressure (MAP) and HR but did not affect the increase in CSF [Na+] or hypothalamic aldosterone in Dahl S on a high-salt diet. Intracerebroventricular infusion of Na+-rich artificial CSF caused significantly larger increases in renal sympathetic nerve activity, MAP, and HR in Dahl S vs. SS.BN13 or Wistar rats on a normal-salt diet. Intracerebroventricular injection of 5 ng staurosporine enhanced these responses, but the enhancement in Dahl S rats was only one-third that in SS.BN13 and Wistar rats. Staurosporine had no effect on MAP and HR responses to intracerebroventricular ANG II or carbachol, whereas the specific protein kinase C inhibitor GF109203X inhibited pressor responses to intracerebroventricular Na+-rich artificial CSF or ANG II. These results suggest that the SIK1-Na+/K+-ATPase network in neurons acts to attenuate sympathoexcitatory and pressor responses to increases in brain [Na+]. The lower hypothalamic SIK1 activity and smaller effect of staurosporine in Dahl S rats suggest that impaired activation of neuronal SIK1 by Na+ may contribute to their enhanced central responses to sodium.

Brain Na+, K+-ATPase isoforms: Different hypothalamus and mesencephalon response to acute desipramine treatment

We studied Na(+), K(+)-ATPase activity alpha isoforms by performing ouabain inhibition curves in rat hypothalamus and mesencephalon after acute administration of desipramine to rats. In hypothalamus, Ki values for high, intermediate and low affinity populations were 0.075x10(-9) M, 0.58x10(-6) M and 0.97x10(-3) M, with isoform distribution of 55%, 28% and 17%, respectively. In mesencephalon, Ki values for high, intermediate and low affinity populations were 1.80x10(-9) M, 0.56x10(-6) M and 0.21x10(-3) M, with isoform distribution of 28%, 46% and 21%, respectively. Three hours after acute administration of 10 mg/kg desipramine to rats, Na(+), K(+)-ATPase activity in hypothalamus increased significantly 54%, 39% and 51% as assayed respectively in the absence of ouabain or in the presence of 1x10(-9) M, or 5x10(-6) M ouabain, whereas only a trend was recorded in the presence of 1x10(-3) M ouabain. In such conditions, enzyme activity in mesencephalon increased significantly 73%, 54%, 30% and 271%, respectively. Present results showed that desipramine treatment enhances the activity of Na(+), K(+)-ATPase alpha isoforms in rat hypothalamus and mesencephalon, but the extent of this increase differs according to the isoform and the anatomical area studied, suggesting a differential enzyme regulation in response to noradrenergic stimulation.

Transcriptome analysis in a rat model of L-DOPA-induced dyskinesia

We have examined the pattern of striatal messenger RNA expression of over 8000 genes in a rat model of levodopa (L-DOPA)-induced dyskinesia and Parkinson disease (PD). 6-Hydroxydopamine (6-OHDA)-lesioned rats were treated with L-DOPA or physiological saline for 22 days and repeatedly tested for antiakinetic response to L-DOPA and the development of abnormal involuntary movements (AIMs). In a comparison of rats that developed a dyskinetic motor response to rats that did not, we found striking differences in gene expression patterns. In rats that developed dyskinesia, GABA neurons had an increased transcriptional activity, and genes involved in Ca2+ homeostasis, in Ca2+ -dependent signaling, and in structural and synaptic plasticity were upregulated. The gene expression patterns implied that the dyskinetic striatum had increased transcriptional, as well as synaptic activity, and decreased capacity for energy production. Some basic maintenance chores such as ribosome protein biosynthesis were downregulated, possibly a response to expended ATP levels.

Expression of Na+-dependent citrate transport in a strongly metastatic human prostate cancer PC-3M cell line: regulation by voltage-gated Na+ channel activity

Prostate is a unique organ which synthesizes and releases large amounts of citrate. It has been shown that in metastatic prostate cancer, the amount of citrate in prostatic fluid is significantly reduced, approaching the level normally found in blood. In our previous study, we characterized electrophysiologically the mechanism of citrate transport in a normal prostatic epithelial (PNT2-C2) cell line. It was concluded that the cells expressed a novel transporter carrying 1 citrate3- together with 4 K+, primarily out of cells. In the present study, we aimed similarly to characterize the mechanism(s) of citrate transport in a strongly metastatic human prostate cancer (PC-3M) cell line and to compare this with the previous data. Citrate transport in PC-3M cells was found to be both Na+ and K+ dependent. Intracellular application of citrate produced an outward current that was primarily K+ dependent whilst extracellular citrate elicited an inward current that was mainly Na+ dependent. The electrophysiological and pharmacological characteristics of the citrate outward current were similar to the K+-dependent citrate transporter found in the PNT2-C2 cells. On the other hand, the inward citrate current had a markedly different reversal potential, ionic characteristics, inhibitor profile and pH sensitivity. Preincubation of the PC-3M cells (24 or 48 h) with the voltage-gated Na+ channel (VGSC) blocker tetrodotoxin (TTX) significantly reduced the Na+ sensitivity of the citrate current, up-regulated VGSC mRNA expression but did not change the partial permeability of the membrane to Na+. It was concluded (a) that PC-3M cells express a K+-dependent transporter (carrying citrate outward), similar to that found in normal prostate epithelial cells, as well as (b) a Na+-dependent transporter (carrying citrate inward). The molecular nature of the latter was investigated by RT-PCR; the three known Na+-dependent citrate/dicarboxylate transporters could not be detected. VGSC activity, which itself has been associated with metastatic prostate cancer, had a differential effect on the two citrate transporters, down-regulating the expression of the Na+-dependent component whilst enhancing the K+-dependent citrate transporter.

Neuronal interaction determines the expression of the alpha-2 isoform of Na, K-ATPase in oligodendrocytes

Na,K-ATPase is an integral membrane enzyme responsible for maintenance of the transmembrane Na+/K+ gradient which generates membrane excitability. Previous studies showed that oligodendrocytes within the CNS robustly expressed the alpha2 isoform of the Na,K-ATPase while oligodendrocytes in isolated cultures did not. We tested whether the levels of this isoform might be modulated by interactions with neurons. Western blots showed alpha2 protein expression was very low in rat optic nerve immediately after birth, but that expression was greatly increased by days 5 and 14. In adult optic nerves, levels were barely detectable. Since the first myelinated axons are observed in rat optic nerve at day 5, and the next 2 weeks are considered the period of peak myelination, this timing suggested a relationship between oligodendrocyte-neuron contact, myelination onset and the upregulation of the alpha2 isoform. In further experiments we plated oligodendrocytes in isolation or in co-culture with neurons dissociated from cerebral cortex at the day of birth. After 6 days in vitro, 45% of oligodendrocytes co-cultured with neurons expressed abundant alpha2 protein which was detected by immunohistochemistry, a six-fold increase over cells expressing alpha2 protein in isolated cultures. Conditioned medium from neuronal cultures did not affect alpha2 levels in oligodendrocytes. These results suggest that neurons may play a role in upregulating glial expression of the alpha2 isoform during peak periods of myelination, and that the effect is likely to be dependent on contact.

Luminal localization of blood-brain barrier sodium, potassium adenosine triphosphatase is dependent on fixation

Cytochemical data in the literature reporting localization of sodium, potassium adenosine triphosphatase (Na(+), K(+)-ATPase) in the blood-brain barrier (BBB) have been contradictory. Whereas some studies showed the enzyme to be located exclusively on the abluminal endothelial plasma membrane, others demonstrated it on both the luminal and abluminal membranes. The influence of fixation on localization of the enzyme was not considered a critical factor, but our preliminary studies showed data to the contrary. We therefore quantitatively investigated the effect of commonly used fixatives on the localization pattern of the enzyme in adult rat cerebral microvessels. Fixation with 1%, 2%, and 4% formaldehyde allowed deposition of reaction product on both the luminal and abluminal plasma membranes. The luminal reaction was reduced with increasing concentration of formaldehyde. Glutaraldehyde at 0.1%, 0.25%, 0.5%, in combination with 2% formaldehyde, drastically inhibited the luminal reaction. The abluminal reaction was not significantly altered in all groups. These results show that luminal localization of BBB Na(+), K(+)-ATPase is strongly dependent on fixation. The lack of luminal localization, as reported in the literature, may have been the result of fixation. The currently accepted abluminal polarity of the enzyme should be viewed with caution.

Na,K-ATPase mRNA levels and plaque load in Alzheimer's disease

The expression of Na,K-ATPase alpha 1- and alpha 3-mRNAs was analyzed by in situ hybridization in the superior frontal cortex and cerebellum of brains from five Alzheimer's disease (AD), five nondemented age-matched, and three young control subjects. Brains with well-preserved RNA, tested by Northern hybridization of immobilized RNA with [32P]-labeled human beta-actin riboprobe, were chosen for analysis. In situ hybridization was performed on formalin-fixed, 5 microns-thick Paraplast sections with [35S]-labeled riboprobes prepared by in vitro transcription of the respective linearized clones: a 537-bp EcoRI-PstI fragment of alpha 1-cDNA and a 342-bp PstI-EcoRI fragment of alpha 3-cDNA. In cortex, grains related to mRNA were measured by density per unit area in five cortical columns separated by 1.0-1.2 cm in each of two adjacent sections. Each cortical column of 180-micron width was divided into four depths orthogonal to the pial surface between the pia and the white matter. Amyloid plaques were counted in the same regions of adjacent sections. In addition, alpha 3-mRNA grain clusters over individual pyramidal neurons within depth 4 were analyzed. We found the following significant changes (p < 0.05): 1. Increases in total alpha 1-mRNA by 13-19% in AD compared to young and by 7-12% in AD compared to age-matched controls. 2. Decrease in total alpha 3-mRNA by 31-38% in AD compared to young and age-matched controls. 3. Decrease in alpha 3-mRNA content over individual pyramidal perikarya by 14% in normal aged brains without plaques compared to young controls, and by 44% in AD relative to young controls and by 35% compared to age-matched controls. No significant difference (p < 0.2) was found with respect to alpha 1- or alpha 3-mRNA in cerebellar cortex or individual Purkinje cells among any of the groups. In addition, there was a trend toward an inverse correlation between the levels of alpha 3-mRNA and of diffuse plaques, but not of neuritic plaques, in AD cases.

IN CONCLUSION

1. The increases in alpha 1-mRNA in AD may be related to an increased reactive gliosis. 2. The declines in alpha 3-mRNA per individual neuron found in normal aging occur prior to the formation of diffuse plaques and are greatly accelerated in AD. 3. The declines in alpha 3-mRNA per neuron found in normal aging may predispose to or potentiate AD pathogenesis.

Desipramine modulates 3H-ouabain binding in rat hypothalamus

We have previously shown that Na+, K(+)-ATPase activity in hypothalamus is increased after administration of an acute dose of desipramine, a noradrenaline uptake inhibitor (Viola et al., Cell Molec Neurobiol 9:263-271, 1989). In this report the same treatment (10 mg per kg) was applied to evaluate 3H-ouabain binding in rat brain sections by quantitative autoradiography. Results disclosed an increase in the number of ouabain binding sites in hypothalamus but not in cerebral cortex. Concomitantly, such acute DMI treatment enhanced K(+)-stimulated-p-nitrophenylphosphatase activity in hypothalamus membranes whereas it failed to modify cerebral cortex membranes. A direct interaction of DMI with the enzyme was ruled out since in vitro DMI is known to inhibit the enzyme. It may be speculated that DMI indirectly stimulates Na+, K(+)-ATPase through the increase in noradrenaline which acts in turn on the external phosphorylated site of the enzyme.

Characterization of dual leucine zipper-bearing kinase, a mixed lineage kinase present in synaptic terminals whose phosphorylation state is regulated by membrane depolarization via calcineurin

The biochemistry and regulation of dual leucine zipper bearing kinase (DLK), a member of the mixed lineage kinase or MLK subfamily of protein kinases, was examined in the nervous system. DLK transcript expression in the nervous system was predominantly neuronal. DLK protein was present in synaptic terminals where it was associated with both plasma membrane and cytosol fractions. Within these two fractions, DLK had differing characteristics. Cytosolic DLK existed in both a phosphorylated and dephosphorylated state; DLK associated with plasma membrane existed in the dephosphorylated state only. On nonreducing SDS-polyacrylamide gel electrophoresis, cytosolic DLK migrated at 130 kDa, while membrane associated DLK migrated with an apparent Mr >/= 260,000. Similarly, DLK transiently expressed in COS 7 cells autophosphorylated in vivo and migrated at approximately 260 kDa when separated by nonreducing SDS-polyacrylamide gel electrophoresis. In cotransfection experiments, FLAG-tagged DLK or a FLAG-tagged truncated DLK mutant (F-Delta520) was coimmunoprecipitated with Myc-tagged DLK and formed complexes under nonreducing conditions consistent with the conclusion that DLK formed covalently associated homodimers in overexpressing COS 7 cells. In aggregating neuronal-glial cultures, depolarization of plasma membrane lead to dephosphorylation of DLK. Treatment of aggregates with 5 nM or 200 nM okadaic acid lead to a shift in electrophoretic mobility consistent with phosphorylation of DLK. Treatment with cyclosporin A, a specific inhibitor of the calcium/calmodulin-dependent protein phosphatase 2B (calcineurin), had no effect on DLK phosphorylation under basal conditions. However, cyclosporin A completely inhibited DLK dephosphorylation upon membrane depolarization.

Regional distributions of hippocampal Na+,K(+)-ATPase, cytochrome oxidase, and total protein in temporal lobe epilepsy

Na+,K(+)-ATPase (the sodium pump) is a ubiquitous enzyme that consumes ATP to maintain an adequate neuronal transmembrane electrical potential necessary for brain function and to dissipate ionic transients. Reductions in sodium pump function augment the sensitivity of neurons to glutamate, increasing excitability and neuronal damage in vitro. Temporal lobe epilepsy (TLE) is one disease characterized by hyperexcitability and marked hippocampal neuronal losses that could depend in part, on impaired sodium pump capacity secondary to changes in sodium pump levels and/or insufficient ATP supply. To assess whether abnormalities in the sodium pump occur in this disease, we used [3H]ouabain to determine the density of Na+,K(+)-ATPase for each anatomic region of hippocampus by in vitro autoradiography. Tissues were surgically obtained from epileptic patients with hippocampal sclerosis and compared with specimens from patients with seizures originating from temporal lobe tumors and autopsy controls. Changes in cellular population arising from neuronal losses or gliosis were assessed by protein densities derived from quantitative computerized densitometry of Coomassie-stained tissue sections. We estimated regional differences in capacity for ATP generation by determining cytochrome c oxidase (CO) activity. Principal neurons of hippocampus exhibit high levels of sodium pump enzyme. Both epilepsy groups exhibited slight but significant increases in sodium pump density/unit mass of protein in the dentate molecular layer, CA2, and subiculum as compared with autopsy controls. Greater hilar sodium pump density was also observed in sclerotic hippocampi. In contrast, CO activity was reduced in both epilepsy types throughout hippocampus. Results suggest that although sodium pump protein in surviving neurons appears to be upregulated in epilepsy, sodium pump capacity may be limited by the reduced levels of CO activity. Functional reduction in sodium pump capacity may be an important factor in hyperexcitability and neuronal death.

Glutamate up-regulates alpha 1 and alpha 2 subunits of the sodium pump in astrocytes of mixed telencephalic cultures but not in pure astrocyte cultures

Prior work employing an in vitro model of the cerebral cortex has shown that sodium pump activity is a critical determinant for neuronal survival of glutamate stimulation. We have hypothesized that up-regulation of total brain sodium pump activity will protect against potential excitotoxins. Increased sodium pump activity could theoretically occur by changes in the reaction rate (short-term) and/or by increased levels of sodium pump protein (long-term) and is potentially complex since the three catalytic (a) subunit isoforms of the sodium pump are distributed in a highly variable, cell-specific pattern in the brain. Short-term regulation (seconds to minutes) has been well studied: brain sodium pump exhibits a large dynamic range. In contrast, the possibility of long-term modulation of sodium pump activity has not been extensively explored. We used isoform specific antibodies and [3H]ouabain binding to determine whether prolonged stimulation of sodium pump activity in rodent telencephalic cultures increased total sodium pump enzyme. Exposure of mixed neuronal-glial cultures to high levels of glutamate (10 mM) for 18 h, which is highly toxic to neurons, was associated with an approximately 80% increase in alpha 1 and alpha 2 subunit expression by glia. Induction of alpha 2 subunit immunoreactivity was also associated with comparable changes in [3H]ouabain binding, suggesting that the up-regulation corresponded to functional alpha 2 protein. Shorter (30 min) glutamate treatments, which also killed neurons, did not produce similar changes in sodium pump expression. In contrast to mixed cultures, pure astrocyte cultures had undetectable alpha 2 and alpha 3 and moderate levels of alpha 1 protein, as confirmed by low levels of [3H]ouabain binding. Glutamate treatment using this protocol was associated with a decrease in alpha 1 sodium pump expression. We conclude that long-term regulation of the sodium pump can be demonstrated in glia which have developed in the presence of neurons. Both alpha 1 and alpha 2 isoforms of the sodium pump are involved in this response to glutamate.

Differential axonal transport of individual Na,K-ATPase catalytic (alpha) subunit isoforms in rat sciatic nerve

Three isoforms of the Na,K-ATPase catalytic (alpha) subunit are present in neurons, demonstrated by in situ hybridization of neurons and Western blot of nerve. We used Western blot with antibodies specific for alpha 1, alpha 2 and alpha 3 peptides to measure the accumulation of individual peptides at a ligature on the sciatic nerve. alpha 1 peptide accumulated with kinetics suggesting rapid axonal transport of that isoform within nerve. alpha 2 and alpha 3 peptides did not accumulate at the ligature. These studies provide insight into the dynamics of axonal Na,K-ATPase isoforms.

Rapid increases in cerebellar Purkinje cell glutamic acid decarboxylase (GAD67) mRNA after lesion-induced increases in cell firing

Loss of the inferior olive-climbing fiber input to the cerebellar cortex doubles the simple spike activity of the cerebellar Purkinje cell. There is a 3- to 4-fold increase in Purkinje cell messenger RNA for the 67 kDa form of glutamic acid decarboxylase (a synthetic enzyme for the neurotransmitter GABA) within 4-5 h of the increase in electrical activity, suggesting a rapid response of mechanisms influencing neurotransmitter synthesis or stability to altered electrophysiological activity.