Regulation of non-AU-rich element containing c-fms proto-oncogene expression by HuR in breast cancer.

The role of RNA-binding proteins in cancer biology is recognized increasingly. The nucleocytoplasmic shuttling and AU-rich RNA-binding protein HuR stabilizes several cancer-related target mRNAs. The proto-oncogene c-fms, whose 3'untranslated region (3'UTR) is not AU-rich, is associated with poor prognosis in breast cancer. Using a large breast-cancer tissue array (N=670), we found nuclear HuR expression to be associated with nodal metastasis and independently with poor survival (P=0.03, RR 1.45), as well as to be co-expressed with c-fms in the breast tumors (P=0.0007). We described c-fms mRNA as a direct target of HuR in vivo, and that HuR bound specifically to a 69-nt region containing 'CUU' motifs in 3'UTR c-fms RNA. Overexpressing or silencing HuR significantly up- or down-regulated c-fms RNA expression, respectively. We also found that known glucocorticoid stimulation of c-fms RNA and protein is largely dependent on the presence of HuR. HuR, by binding to the 69-nt wild type, but not mutant, c-fms sequence can regulate reporter gene expression post-transcriptionally. We are the first to describe that HuR can regulate gene expression by binding non-AU-rich sequences in 3'UTR c-fms RNA. Collectively, our findings suggest that HuR plays a supportive role for c-fms in breast cancer progression by binding a 69-nt element in its 3'UTR, thus regulating its expression.

Independent regulation of invasion and anchorage-independent growth by different autophosphorylation sites of the macrophage colony-stimulating factor 1 receptor.

Invasion of tissue by macrophages and implantation into the uterine wall by placental trophoblasts are known to be regulated by the macrophage colony-stimulating factor (CSF-1) and its receptor (CSF-1R, the product of the c-fms proto-oncogene). Recently, the clinical importance of CSF-1 and CSF-1R in invasive breast carcinoma has been recognized, but the significance of coexpression of CSF-1 and CSF-1R in mammary epithelial cell invasion has not been explored. In the present study, we investigated the invasive potential of a noninvasive, CSF-1R-negative, mouse mammary epithelial cell line (HC11) expressing a high level of CSF-1, which was stably transfected with the mouse wild-type CSF-1R. Compared with parental cells, transfected cells expressing a wild-type CSF-1R invaded 100-fold more efficiently through a barrier of reconstituted basement membrane (Matrigel) and formed colonies in soft agar, whereas the cellular growth rate was only slightly increased. Analysis of cell-conditioned medium by zymography and quantitative enzyme activity assays showed that clones transfected with a wild-type CSF-1R expressed significantly higher levels of urokinase-type plasminogen activator than did untransfected clones. Furthermore, after injection into the tail veins of BALB/c mice, CSF-1R-expressing clones also produced a 10-fold higher incidence of lung tumors than the parental cell line. We also analyzed HC11 clones transfected with CSF-1R mutated at two major autophosphorylation sites (Tyr-->Phe807 and Tyr-->Phe721). Mutation at Tyr807 eradicated the stimulatory effect of Fms expression on the invasive ability of HC11 cells and substantially reduced the metastatic potential of the transfected clones but did not alter the Fms-induced anchorage-independent growth in soft agar. In contrast, mutation at Tyr721 of Fms had no effect on invasion as measured in the in vitro assay but markedly abolished Fms-induced colony formation in soft agar and eradicated the metastatic potential of the transfected clones. Our results suggest that expression of CSF-1R can facilitate cellular invasion and anchorage-independent growth in mammary epithelial cells, and these two processes are independently regulated by separate phosphotyrosine sites of CSF-1R.

Na, K-ATPase isoform gene expression in normal and hypertrophied dog heart.

OBJECTIVES: The catalytic alpha subunit of the sodium-potassium ATPase, the target of digitalis glycosides, has three isoforms; the expression of these isoforms is tissue-specific and developmentally regulated. While the effect of pressure overload on Na, K-ATPase isoform expression has been studied in rodent heart, there are no systematic data on this question in hearts of larger animals, which differ from those of rodents both in isoform composition and in glycoside sensitivity. Thus, we investigated the expression of Na, K-ATPase isoforms in normal dog heart; we also examined the effect of experimental left ventricular hypertrophy on isoform expression. METHODS: hypertrophy was produced by aortic banding. Expression was assessed by quantitative Northern and Western blotting, immunofluorescence, and 3H-ouabain binding. RESULTS: RNA blotting indicated that the alpha 3 isoform represented 11% of Na, K-ATPase mRNA in normal dog LV. Normal dog LV expressed alpha 1 and alpha 3 protein, but no detectable alpha 2; immunoreactive alpha 1 and alpha 3 protein were also present in Purkinje fibers. There was a statistically significant decrease in total expression of all alpha isoform mRNA's in hypertrophied dog LV, resulting in a greater proportion of alpha 1. The expression level of the alpha 3 isoform mRNA and protein was lower in hypertrophied hearts. CONCLUSIONS: These results indicate a greater proportion of alpha 1 isoform pumps in experimental canine hypertrophy. Thus, shifts in NA, K-ATPase isoforms occur in pressure-overloaded heart in large animals as well as rodents.

Developmental regulation of Na, K-ATPase in rat lung.

Late in gestation lung epithelium changes from net chloride and fluid secretion to sodium and fluid absorption. Fluid resorption is required for postnatal gas exchange and occurs by combined action of epithelial sodium channels and Na, K-ATPase. We hypothesized that alveolar epithelial Na, K-ATPase increases perinatally. Immunofluorescence (IF) and immunoelectron microscopy (IEM) with a monoclonal anti-alpha subunit antibody demonstrated that Na, K-ATPase was present on the basolateral surfaces of columnar epithelial cells at fetal day (FD) 17 and on type II cells throughout development. However, type I epithelial cells did not have detectable Na,K-ATPase. The steady-state levels of both the alpha 1 isoform and the beta-subunit mRNAs were maximal at FD20-neonatal day (ND) 1, with consistent increases from FD17 level. Na, K-ATPase alpha-subunit protein also increased from FD17 to FD20-22 and then decreased in the early postnatal period. The ouabain-inhibitable sodium pump activity per milligram membrane protein increased 2.6-fold from FD17 to FD22-ND1 (P < 0.05). The quantities of sodium pump mRNA, antigenic protein, and enzyme activity increase in late gestation in accord with a proposed role for Na, K-ATPase in resorption of alveolar sodium and fluid in preparation for birth.

Transcriptional regulation of the c-fms (CSF-1R) proto-oncogene in human breast carcinoma cells by glucocorticoids.

Expression of the macrophage colony stimulating factor CSF-1 and its receptor, the c-fms proto-oncogene, has been observed in macrophages, trophoblast and in a variety of neoplasms of epithelial origin including those of the breast. We have reported earlier (Oncogene, 1991, 6: 941-952) that c-fms transcript and protein expression were dramatically increased in several breast carcinoma cell lines by glucocorticoids which are essential humoral regulators of normal mammary epithelial cell differentiation. In this communication, we demonstrate that levels of c-fms transcript and protein increased significantly within the first few hours of glucocorticoid treatment, and that these increases were completely abolished by pretreatment of cells with mifepristone (RU486). We also demonstrate that such early increases in c-fms transcript levels could not be attributed to prolongation of transcript half-life. Both promoters of the c-fms gene were found to exhibit some basal activity in breast carcinoma cell lines and both were stimulated 2-3-fold by glucocorticoids. However the first promoter was shown to be responsible for more than 95% of the observed c-fms transcription. Sequence upstream of both promoters was found to contain potential 'glucocorticoid response elements' (GREs), and in each case, elimination of the GRE closest to the promoter abolished glucocorticoid stimulation. Our observations suggest that one mechanism by which glucocorticoids regulate the proliferation and differentiation of neoplastic mammary epithelial cells is through their regulation of transcription of the gene for the receptor of a ubiquitous cytokine, CSF-1.

Post-transcriptional regulation of c-fms proto-oncogene expression by dexamethasone and of CSF-1 in human breast carcinomas in vitro.

The c-fms proto-oncogene encodes the receptor for a hematopoietic growth factor, CSF-1. Recently, the importance of c-fms and its ligand CSF-1 in malignancies of non-hematopoietic origin, such as breast, ovarian, endometrial, pulmonary, and trophoblastic cancers has been recognized. We have previously shown that glucocorticoids induce a large increase in c-fms mRNA and protein levels in breast carcinoma cell lines. In this report, we investigate the mechanism underlying such c-fms overexpression by dexamethasone. We show that dexamethasone treatment of two breast carcinoma cell lines (BT20-c-fms expressor, and SKBR3-co-expressor of both c-fms and CSF-1) does not increase the rate of c-fms gene transcription, suggesting a post-transcriptional mechanism of regulation of c-fms expression by dexamethasone. The effect of protein synthesis inhibition was studied to help determine whether there was a role for intermediary regulatory proteins in the regulation of c-fms expression. We find that several protein synthesis inhibitors interfere with dexamethasone induction of c-fms transcripts, suggesting the existence of regulatory proteins. These regulatory proteins do not appear to be constitutively expressed, as we show no effect of protein synthesis inhibition on c-fms transcript expression in resting BT20 cells. These findings suggest that the putative regulatory proteins are induced by dexamethasone. Furthermore, the addition of a protein synthesis inhibitor, pactamycin, to dexamethasone-treated BT20 cells results in a decrease in c-fms mRNA stability.(ABSTRACT TRUNCATED AT 250 WORDS)

Posttranscriptional regulation of colony-stimulating factor-1 (CSF-1) and CSF-1 receptor gene expression during inhibition of phorbol-ester-induced monocytic differentiation by dexamethasone and cyclosporin A: potential involvement of a destabilizing protein.

Colony stimulating factor-1 (CSF-1) and its receptor (encoded by the c-fms proto-oncogene) have long been recognized as playing an important role in monocytic differentiation. However, the regulation of expression of the CSF-1 and c-fms genes during inhibition of monocytic differentiation has not been fully characterized. The present studies demonstrate that dexamethasone (dex) and cyclosporin A (CsA) resulted in inhibition of 12-O-tetradecanoylphorbol-13-acetate (TPA)-induced monocytic differentiation of HL60 cells, as well as TPA induction of c-fms and CSF-1 transcripts. These agents also blocked TPA-induced adherence, alpha-naphthyl acetate esterase staining, and the development of a more differentiated morphology. Nuclear run-off analyses revealed no effect of either of these agents on transcription of either c-fms or CSF-1 genes in TPA-treated HL60 cells. Measurements of c-fms transcript half-life confirmed post-transcriptional regulation of c-fms transcript levels after the addition of dex or CsA to TPA, both of which resulted in a decrease in c-fms mRNA half-life. Others have suggested that TPA results in the stabilization of c-fms mRNA in HL60 cells through induction of a labile mRNA stabilizing protein. We observed, however, that the inhibition of protein synthesis by cycloheximide (CH) in this setting of early monocytic differentiation increased both c-fms and CSF-1 steady-state transcript levels. While CH had no effect on the transcription of c-fms and CSF-1 genes in TPA/dex- or TPA/CsA-treated HL60 cells, c-fms mRNA was stabilized after the addition of CH to TPA/dex-treated cells. Taken together, our results suggest the existence of a labile mRNA regulatory protein or proteins, whose actions include destabilization of both c-fms and CSF-1 transcripts after inhibition of TPA-induced monocytic differentiation by dex or CsA.

Expression of alpha isoforms of the Na,K-ATPase in human heart.

We studied expression of isoforms of Na,K-ATPase in normal and diseased human hearts. Na,K-ATPase alpha-isoform mRNA in samples from normal human left ventricle (LV) was composed of 62.5%, alpha 1, 15% alpha 2 and 22.5% alpha 3 on average. There was an increase in expression of the alpha 3 isoform in samples from failing hearts, but expression of all three isoforms decreased in pressure-overloaded right ventricle (RV).

Differential translation of the Na,K-ATPase subunit mRNAs.

Expression of the Na,K-ATPase alpha and beta subunit genes is influenced by a complex series of regulatory pathways. For example, unequal amounts of subunit mRNAs are detected in several tissues, both at rest and upon mRNA induction, even though equal quantities of subunit proteins exist. We therefore studied mRNA stability and translational efficiency of wild type, deletion mutant, and chimeric subunit mRNAs in a cell-free translation system, to examine the possible role of post-transcriptional events in regulating subunit expression. alpha 1 mRNA translated less efficiently than beta 1 mRNA and competed less efficiently for rate-limiting translation factors. Deletion of the 5'-untranslated region of alpha 1 mRNA significantly increased its translation efficiency. Conversely, the alpha 1 5'-untranslated region impaired translation of beta 1 mRNA when attached upstream of the beta 1 coding sequence. This region is G/C-rich, and has a complex mRNA secondary structure. We propose that differential translational efficiency may contribute to the equal biosynthesis of subunit proteins in those tissues in which subunit mRNAs either exist in unequal amounts or are differentially induced.

Changes in Na,K-ATPase gene expression during granulocytic differentiation of HL60 cells.

During granulocytic differentiation of HL60 cells, immediate reduction of ouabain-sensitive potassium flux is observed within the first 12 hours of addition of dimethyl sulfoxide (DMSO). We show that gene expression of the alpha 3 isoform of Na+,K(+)-ATPase, which encodes an ouabain-inhibitable Na+,K(+)-ATPase activity, significantly declines during the first 24 hours of granulocytic differentiation by DMSO of HL60 cells. The more common alpha 1 isoform decreases, but more gradually over 72 hours of DMSO induction. Loss of alpha 3 and alpha 1 messenger RNA (mRNA) are due to changes in mRNA decay; their transcription is not altered. alpha 3 mRNA half-life is 3 hours in HL60 cells; upon induction by 16 hours of DMSO, it decreases to approximately 2 hours. alpha 1 transcripts are less sensitive to DMSO induction, with their half-life being 3.5 hours in HL60 cells; upon induction, their half-life decreases to 3 hours. Experiments measuring protein stability confirm that alpha 3 protein is more labile than alpha 1. In uninduced HL60 cells, alpha 3 membrane protein comprises 30% of the total alpha isoforms, and is less stable than alpha 1, with a protein half-life of only 9 hours. Upon DMSO induction, steady-state alpha 3 protein decreases markedly within 10 hours, whereas alpha 1 protein remains stable. These results show that posttranscriptional changes during induction play a major role in the differential regulation of alpha 1 and alpha 3 isoforms of Na+,K(+)-ATPase; regulation of the latter may be important for early granulocytic differentiation, or for one of the differentiated functions of mature granulocytes.

The A2 isoform of rat Na+,K(+)-adenosine triphosphatase is active and exhibits high ouabain affinity when expressed in transfected fibroblasts.

The alpha isoforms of the Na+,K(+)-ATPase (Na+ pump) are expressed with developmental and tissue heterogeneity in rodents and possess different sensitivity to inhibition by ouabain. We directly characterized the ouabain sensitivity of the rat A2 (alpha 2) isoform by transfecting NIH 3T3 cells with rat A2. The treated cells exhibit high affinity (40 nM) ouabain binding with a density of 2 pmol/mg protein. 86Rb+ flux studies confirm that A2 is functional in this system and that A2 is inhibited by submicromolar concentrations of ouabain. These findings are consistent with measurements of ouabain affinity in tissues which express the A2 isoform.

Distinct molecular signals for nuclear import of the nucleolar snRNA, U3.

Export to the cytoplasm of U3 RNA transcribed from a rat U3 gene injected into the nucleus of Xenopus oocytes indicates that the biogenesis of U3 RNA, like that of the previously studied Sm-precipitable nucleoplasmic snRNAs (U1, U2, U4, and U5), includes a cytoplasmic phase. The regulation of import of the U3 snRNA into the nucleus has been analyzed by injection of synthetic human U3 transcripts into the cytoplasm of Xenopus oocytes. Binding of the major autoantigenic protein of the U3 snRNP, fibrillarin, and cap trimethylation can occur in the cytoplasm, but neither are required for import. The 3'-terminal 13 nucleotides are required for optimal import and cap trimethylation and participate in a phylogenetically conserved U3 structural element, a short 3'-terminal stem. An artificial construct containing the 3'-terminal 13 nucleotides, including the 3'-terminal stem, but only 56 nucleotides of the 217 nucleotides in U3, appears to be sufficient for import. The presence of the 3'-terminal stem in all snRNAs known to be imported suggests that it might be a universal element required for nuclear import.

The cardiac conduction system in the rat expresses the alpha 2 and alpha 3 isoforms of the Na+,K(+)-ATPase.

The sodium pump is crucial for the function of the heart and of the cardiac conduction system, which initiates the heartbeat. The alpha (catalytic) subunit of this pump has three isoforms; the alpha 1 isoform is ubiquitous, but the alpha 2 and alpha 3 isoforms are localized to excitable tissue. Because rodent alpha 2 and alpha 3 isoforms are relatively sensitive to ouabain, which also slows cardiac conduction, we studied heart-cell-specific expression of pump isoform genes. Multiple conduction-system structures, including sinoatrial node, bundle branches, and Purkinje strands, had prominent, specific hybridization signal for alpha 2 and alpha 3 isoforms compared with adjacent working myocytes. This gene-expression approach may be useful for labeling conduction tissue and also for localizing specific membrane channels and receptors in this system.

Upregulation of rat lung Na-K-ATPase during hyperoxic injury.

A major function of the alveolar epithelium is to keep the airspace free of fluid and preserve gas exchange. Since Na-K-ATPase is believed to be important in this process, we hypothesized that Na-K-ATPase in the rat lung would increase in response to acute lung injury with pulmonary edema. Na-K-ATPase localization, mRNA expression, and protein levels were determined in hyperoxic lung injury. Adult male rats were exposed to greater than 97% oxygen for 60 h followed by recovery in room air. At 60 h of hyperoxia, the wet-to-dry lung weights increased, consistent with edema. Within the alveolar capillary region, the sodium pump remained localized to the type II cell basolateral membrane by immunocytochemistry. By Northern blot analysis, the level of total lung mRNA expression of the alpha 1- and beta-subunits of Na-K-ATPase increased three- to fourfold during hyperoxia compared with unexposed rats. Total lung Na-K-ATPase membrane protein, visualized with a Western blot technique, appeared to increase by 24 h of hyperoxic insult when compared with levels in unexposed animals. The increase in sodium pump gene expression that occurs during hyperoxic insult, followed by an increase in sodium pump membrane protein, suggests that type II cells increase their Na-K-ATPase synthesis as an early response to pulmonary edema and/or hyperoxia.

Detection of the Na(+)-K(+)-ATPase alpha 3-isoform in multinucleated macrophages.

We previously reported that multinucleated macrophages express a high concentration of Na(+)-K(+)-ATPases that are concentrated on the nonadherent domain of their plasma membrane (A. Vignery, T. Niven-Fairchild, D. H. Ingbar, and M. Caplan. J. Histochem. Cytochem. 37: 1265-1271, 1989). We also showed that an increase in newly synthesized alpha-subunit occurred during cell culture and multinucleation. We now present evidence that macrophage multinucleation in vitro is accompanied by an increased accumulation of Na(+)-K(+)-ATPase alpha-subunit mRNA. Most interesting is the detection of significant amount of both alpha 1- and alpha 3-isoform mRNA and peptide in these cells by in situ hybridization, Northern and Western blot analyses. These qualitative and quantitative variations in Na(+)-K(+)-ATPase expression suggest that macrophage multinucleation is accompanied by a coordinated regulation of gene expression and that multinucleation confers a specific function to macrophages. Multinucleated macrophages offer a novel model system to investigate not only the specific function(s) of the alpha 3-isoform but also the role of the Na(+)-K(+)-ATPase in giant cells and osteoclasts.

Cytoarchitectural relationships between [3H]ouabain binding and mRNA for isoforms of the sodium pump catalytic subunit in rat brain.

We examined the cell type-specific expression of the alpha 1, alpha 2, and alpha 3 subunits of the sodium pump in rat brain using in situ hybridization and [3H]ouabain autoradiography. These techniques allowed us to colocalize mRNA and functional alpha 2/alpha 3 pumps on adjacent sections. The perikarya of many neurons possessed high levels of alpha 1 and/or alpha 3 transcripts, while alpha 2 mRNA appeared to be present in only a few neuronal types. [3H]Ouabain binding in general paralleled the distribution of alpha 3 mRNA-positive neurons. The regional variation of alpha 1 and alpha 3 transcripts was complex and varied. Large neurons of the olfactory bulb and piriform cortex expressed high levels of alpha 3 transcripts, but low levels of alpha 1 mRNA. In frontal cortex, neurons of layers II-III were enriched in alpha 1 mRNA, while those in layer V exhibited high levels of alpha 3 transcripts. In the hippocampus, principal neurons expressed all three alpha subunit mRNAs. CA subfield pyramidal neurons exhibited a high alpha 3/alpha 1 ratio, while dentate granule cells and hilar pyramidal neurons expressed approximately equal levels of alpha 1 and alpha 3. In the cerebellum, Purkinje and Golgi cells were rich in alpha 3 mRNA, while the granule cells appeared to express only alpha 1 transcripts. The distribution of functional sodium pump protein, as localized by [3H]ouabain binding, was highest in the neuropil of the hippocampus and cerebral cortex, and lowest over perikarya and white matter. [3H]ouabain did not bind to alpha 1 pump units, as confirmed by the complete absence of labeling over the choroid plexus, a tissue expressing only alpha 1 mRNA. In the cerebellum, regions of dense [3H]ouabain binding were localized to the granule cell layer, the inner third of the molecular layer in the basket region, and the deep cerebellar nuclei. Surprisingly, the dense neuropil in the outer 2/3 of the molecular layer lacked high [3H]ouabain binding. Thus, functional alpha 3 sodium pump units appear distributed to the axon terminals and not to apical dendrites of Purkinje, Golgi and basket cells. A similar pattern of increased [3H]ouabain binding in axonal but not dendritic fields of alpha 3-enriched neurons was present in the cerebral cortex and the hippocampus. Considering that many alpha 3-enriched neurons are of the Golgi I type with long axons, the alpha 3 isoform may be preferentially directed into axons to function in presynaptic membranes.

Expression of multiple Na+,K+-adenosine triphosphatase isoform genes in human hematopoietic cells. Behavior of the novel A3 isoform during induced maturation of HL60 cells.

Multiple isoenzymes of the Na+,K+-ATPase (alpha, alpha+, and alpha 3) have been identified by molecular cloning (Shull, G. E., J. Greeb, and J. B. Lingrel. 1986. Biochemistry. 25:8125-8132; and Schneider, J. W., R. W. Mercer, and E. J. Benz, Jr. 1987. Clin. Res. 35:585A. [Abstr.]). At least one of these, the alpha 3 chain, represents a novel form for which protein products and enzymatic activities are just beginning to be defined in rodents. We have recently demonstrated that expression of alpha 3 is largely confined to neuromuscular tissues of fetal and adult rats (Schneider, J. W., R. W. Mercer, M. Gilmore-Hebert, M. F. Utset, C. Lai, A. Greene, and E. J. Benz, Jr. 1988. Proc. Natl. Acad. Sci. USA. 85:284-288). We now report that certain human leukemia cell lines including HL60, HEL, and Molt 4 express mRNA for both alpha and alpha 3 isoforms of Na+,K+-ATPase; mRNA was not detected in several other cell lines, including K562 and U937; no cell lines expressed alpha+ mRNA. In uninduced HL60 cells, alpha 3 mRNA comprised 20-30% of total Na+,K+-ATPase mRNA. Furthermore, in HL60 and HEL cells, both alpha and alpha 3 mRNA declined after induction of maturation by DMSO, retinoic acid, or hemin. However, the reduction in alpha 3 mRNA was far more dramatic. alpha 3 mRNA virtually disappeared, but alpha mRNA declined by only approximately 50%. In contrast, when maturation of HL60 cells along the monocyte/macrophage lineage was induced by exposure to phorbol esters, alpha 3 mRNA remained abundant. Moreover, mRNA for the beta subunit of the Na+,K+-ATPase increased dramatically. Our results demonstrate that the alpha 3 isoform, formerly thought to be confined to neuromuscular tissues, is expressed in restricted lineages of hematopoietic origin. These leukemia cell lines should provide a useful model for analyzing regulation of the alpha 3 isoform gene and characterization of alpha 3 isoform activities.

Tissue specificity, localization in brain, and cell-free translation of mRNA encoding the A3 isoform of Na+,K+-ATPase.

The isolation of multiple Na+,K+-ATPase cDNAs from rat brain has led to the discovery of a family of alpha-isoform genes. Using A1 (alpha), A2 (alpha+), and A3 (alpha III) Na+,K+-ATPase gene probes, we have analyzed the distribution of Na+,K+-ATPase mRNAs in adult and fetal rat tissues by RNA blot and hybridization histochemistry. A1 Na+,K+-ATPase mRNA was found ubiquitously among various tissues, with highest levels in transport epithelial and neural tissues. A2 mRNA was found in adult neural and muscle tissues, and A3 mRNA was found only in neural tissues and fetal heart muscle. Both A1 and A2 mRNAs were less abundant in fetal brain than in adult brain; in contrast, A3 mRNA was abundant at both stages. In situ mapping of brain areas that contain A3 mRNA suggests that this Na+,K+-ATPase isoenzyme is expressed predominantly by neural cells. Analysis of Na+,K+-ATPase proteins generated by cell-free translation of synthetic mRNAs suggests that the A3 protein has properties similar to A2 (alpha+).