Amy E. Moseley

Deficiency in Na,K-ATPase α Isoform Genes Alters Spatial Learning, Motor Activity, and Anxiety in Mice

Several disorders have been associated with mutations in Na,K-ATPase α isoforms (rapid-onset dystonia parkinsonism, familial hemiplegic migraine type-2), as well as reduction in Na,K-ATPase content (depression and Alzheimers disease), thereby raising the issue of whether haploinsufficiency or altered enzymatic function contribute to disease etiology. Three isoforms are expressed in the brain: the α1 isoform is found in many cell types, the α2 isoform is predominantly expressed in astrocytes, and the α3 isoform is exclusively expressed in neurons. Here we show that mice heterozygous for the α2 isoform display increased anxiety-related behavior, reduced locomotor activity, and impaired spatial learning in the Morris water maze. Mice heterozygous for the α3 isoform displayed spatial learning and memory deficits unrelated to differences in cued learning in the Morris maze, increased locomotor activity, an increased locomotor response to methamphetamine, and a 40% reduction in hippocampal NMDA receptor expression. In contrast, heterozygous α1 isoform mice showed increased locomotor response to methamphetamine and increased basal and stimulated corticosterone in plasma. The learning and memory deficits observed in the α2 and α3 heterozygous mice reveal the Na,K-ATPase to be an important factor in the functioning of pathways associated with spatial learning. The neurobehavioral changes seen in heterozygous mice suggest that these mouse models may be useful in future investigations of the associated human CNS disorders.

The Na,K-ATPase α2 Isoform Is Expressed in Neurons, and Its Absence Disrupts Neuronal Activity in Newborn Mice

Na,K-ATPase is an ion transporter that impacts neural and glial physiology by direct electrogenic activity and the modulation of ion gradients. Its three isoforms in brain have cell-type and development-specific expression patterns. Interestingly, our studies demonstrate that in late gestation, the α2 isoform is widely expressed in neurons, unlike in the adult brain, in which α2 has been shown to be expressed primarily in astrocytes. This unexpected distribution of α2 isoform expression in neurons is interesting in light of our examination of mice lacking the α2 isoform which fail to survive after birth. These animals showed no movement; however, defects in gross brain development, muscle contractility, neuromuscular transmission, and lung development were ruled out. Akinesia suggests a primary neuronal defect and electrophysiological recordings in the pre-Bötzinger complex, the brainstem breathing center, showed reduction of respiratory rhythm activity, with less regular and smaller population bursts. These data demonstrate that the Na,K-ATPase α2 isoform could be important in the modulation of neuronal activity in the neonate.

Enhanced pressor response to increased CSF sodium concentration and to central ANG I in heterozygous α2 Na+-K+-ATPase knockout mice

Intracerebroventricular (ICV) infusion of NaCl mimics the effects of a high-salt diet in salt-sensitive hypertension, raising the sodium concentration in the cerebrospinal fluid (CSF [Na]) and subsequently increasing the concentration of an endogenous ouabain-like substance (OLS) in the brain. The OLS, in turn, inhibits the brain Na(+)-K(+)-ATPase, causing increases in the activity of the brain renin-angiotensin system (RAS) and blood pressure. The Na(+)-K(+)-ATPase alpha (catalytic)-isoform(s) that mediates the pressor response to increased CSF [Na] is unknown, but it is likely that one or more isoforms that bind ouabain with high affinity are involved (e.g., the Na(+)-K(+)-ATPase alpha(2)- and/or alpha(3)-subunits). We hypothesize that OLS-induced inhibition of the alpha(2)-subunit mediates this response. Therefore, a chronic reduction in alpha(2) expression via a heterozygous gene knockout (alpha(2) +/-) should enhance the pressor response to increased CSF [Na]. Intracerebroventricular (ICV) infusion of artificial CSF containing 0.225 M NaCl increased mean arterial pressure (MAP) in both wild-type (+/+) and alpha(2) +/- mice, but to a greater extent in alpha(2) +/-. Likewise, the pressor response to ICV ouabain was enhanced in alpha(2) +/- mice, demonstrating enhanced sensitivity to brain Na(+)-K(+)-ATPase inhibition per se. The pressor response to ICV ANG I but not ANG II was also enhanced in alpha(2) +/- vs. alpha(2)+/+ mice, suggesting an enhanced brain RAS activity that may be mediated by increased brain angiotensin converting enzyme (ACE). The latter hypothesis is supported by enhanced ACE ligand binding in the organum vasculosum laminae terminalis. These studies demonstrate that chronic downregulation of Na(+)-K(+)-ATPase alpha(2)-isoform expression by heterozygous knockout increases the pressor response to increased CSF [Na] and activates the brain RAS. Since these changes mimic those produced by the endogenous brain OLS, the brain alpha(2)-isoform may be a target for the brain OLS during increases in CSF [Na], such as in salt-dependent hypertension.

Targeted mutations in the Na,K‐ATPase alpha 2 isoform confer ouabain resistance and result in abnormal behavior in mice

Sodium and potassium‐activated adenosine triphosphatases (Na,K‐ATPase) are ubiquitous, participate in osmotic balance and membrane potential, and are composed of α, β, and γ subunits. The α subunit is required for the catalytic and transport properties of the enzyme and contains binding sites for cations, ATP, and digitalis‐like compounds including ouabain. There are four known α isoforms; three that are expressed in the CNS in a regional and cell‐specific manner. The α2 isoform is most commonly found in astrocytes, pyramidal cells of the hippocampus in adults, and developmentally in several other neuronal types. Ouabain‐like compounds are thought to be produced endogenously in mammals, bind the Na,K‐ATPase, and function as a stress‐related hormone, however, the impact of the Na,K‐ATPase ouabain binding site on neurobehavioral function is largely unknown. To determine if the ouabain binding site of the α2 isoform plays a physiological role in CNS function, we examined knock‐in mice in which the normally ouabain‐sensitive α2 isoform was made resistant (α2R/R) while still retaining basal Na,K‐ATPase enzymatic function. Egocentric learning (Cincinnati water maze) was impaired in adult α2R/R mice compared to wild type (WT) mice. They also exhibited decreased locomotor activity in a novel environment and increased responsiveness to a challenge with an indirect sympathomimetic agonist (methamphetamine) relative to WT mice. The α2R/R mice also demonstrated a blunted acoustic startle reflex and a failure to habituate to repeated acoustic stimuli. The α2R/R mice showed no evidence of altered anxiety (elevated zero maze) nor were they impaired in spatial learning or memory in the Morris water maze and neither group could learn in a large Morris maze. These results suggest that the ouabain binding site is involved in specific types of learning and the modulation of dopamine‐mediated locomotor behavior. Synapse, 2011.

Developmental induction of DHPR α1s and RYR1 gene expression does not require neural or mechanical signals

This study compares dihydropyridine receptor (DHPR) and ryanodine receptor (RyR1) gene expression in the diaphragm and hindlimb skeletal muscles of neonatal mice, and examines the contribution of neural and mechanical signals to their developmental induction in vivo. DHPR α1s subunit and RyR1 protein are expressed concurrently, while their respective mRNAs are induced sequentially, with DHPR mRNA ahead of RyR1 mRNA. Both DHPR and RyR1 are more abundant in the diaphragm at birth, and become more abundant in the hindlimb at maturity. These patterns are consistent across different muscles and species. A critical period for DHPR α1s and RyR1 gene expression in the hindlimb occurs between days 5 and 19 postnatal. Their mRNA expression during this period is unchanged by denervation or tenotomy, but DHPR protein decreases after tenotomy. These results demonstrate that both transcriptional and post-transcriptional mechanisms contribute to the muscle-specific and coordinated assembly of the functional DHPR-RyR1 complex, and that the developmental induction of DHPR and RyR1 gene transcription does not require neural or mechanical signals.

Comparative Genomics of Tissue Specific Gene Expression

Specification and specialization of cell and tissue structure and function is the result of the informational content and transcriptional programming of the entire genome. Because of this, whole genome/whole organism expression profiling has the potential to reveal tremendous amounts of information about the genome, specific cell types and tissues, and the evolution biological systems. Systems evolution can be studied by identifying and correlating conserved and diverged gene expression patterns of homologous and non-homologous cells and tissues, the functions of these implicated genes, and the corresponding genomic sequences and gene structural features that are conserved or diverged between multiple species’ genomes. The combination of these approaches represents comparative transcriptomics or “orthologenomics”, which has as its general hypothesis that improved understanding of any particular biological system can be derived through multispecies comparative analyses of genomes, transcriptionally active genes, and corresponding gene features. In this chapter we have sought to illustrate a test of this hypothesis using genes over-expressed in the central nervous system (CNS) tissues of humans and mice. The exercise lends strong support to the conjecture that these types of approaches will provide powerful new insights into specific systems that determine the health and disease of complex organisms.