Cellular and Subcellular Specification of Na,K-ATPase alpha  and beta  Isoforms in the Postnatal Development of Mouse Retina

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The Journal of Neuroscience, November 15, 1999, 19(22):9878-9889

Cellular and Subcellular Specification of Na,K-ATPase $alpha$ and $beta$ Isoforms in the Postnatal Development of Mouse Retina
Randall K. Wetzel, Elena Arystarkhova, and Kathleen J. Sweadner
Laboratory of Membrane Biology, Neuroscience Center, Massachusetts General Hospital, Charlestown, Massachusetts 02129

  ABSTRACT

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

The Na,K-ATPase is a dominant factor in retinal energy metabolism, and unique combinations of isoforms of its $alpha$ and $beta$ subunitsare expressed in different cell types and determine its functionalproperties. We used isoform-specific antibodies and fluorescenceconfocal microscopy to determine the expression of Na,K-ATPase $alpha$ and $beta$ subunits in the mouse and rat retina. In the adult retina, $alpha$ 1 was found in Müller and horizontal cells, $alpha$ 2 in some Müllerglia, and $alpha$ 3 in photoreceptors and all retinal neurons. $beta$ 1 waslargely restricted to horizontal, amacrine, and ganglion cells; $beta$ 2 was largely restricted to photoreceptors, bipolar cells, andMüller glia; and $beta$ 3 was largely restricted to photoreceptors.Photoreceptor inner segments have the highest concentration ofNa,K-ATPase in adult retinas. Isoform distribution exhibited markedchanges during postnatal development. $alpha$ 3 and $beta$ 2 were in undifferentiatedphotoreceptor somas at birth but only later were targeted to innersegments and synaptic terminals. $beta$ 3, in contrast, was expressedlate in photoreceptor differentiation and was immediately targetedto inner segments. A high level of $beta$ 1 expression in horizontalcells preceded migration, whereas increases in $beta$ 2 expression inbipolar cells occurred very late, coinciding with synaptogenesisin the inner plexiform layer. Most of the spatial specificationof Na,K-ATPase isoform expression was completed before eye openingand the onset of electroretinographic responses on postnatal day13 (P13), but quantitative increase continued until P22 in parallelwithsynaptogenesis.

Key words: Na,K-ATPase; retina; photoreceptor; development; isoforms; immunofluorescence

  INTRODUCTION

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

In the retina the Na,K-ATPase restores Na⁺ and K⁺ gradients used by the photoreceptor dark current, synaptic activity, actionpotentials, and transmitter uptake. It consumes 50% of the metabolicenergy (41% of oxygen uptake and 58% of glycolysis) (Ames et al.,1992). The Na,K-ATPase is a heterodimer of two subunits, $alpha$ (112kDa) and $beta$ (32 kDa) (for review, see Blanco and Mercer, 1998). $alpha$ is the catalytic unit, but both subunits affect cation affinity.There are three well characterized isoforms of $alpha$ ( $alpha$ 1, $alpha$ 2, and $alpha$ 3) and another found so far only in testis ( $alpha$ 4), and three isoformsof $beta$ ( $beta$ 1, $beta$ 2, and $beta$ 3). In kidney there is also a $gamma$ subunit (7.3kDa), but we have not detected it in Western blots of retinalmembranes (our unpublished observations). Immunocytochemistrydetects abundant Na,K-ATPase in the photoreceptor inner segmentsand the outer and inner plexiform (synaptic) layers (Stahl andBaskin, 1984).

The $alpha$ 1, $alpha$ 2, and $alpha$ 3 isoforms have been localized in adult rat retina (McGrail and Sweadner, 1989) and $beta$ 1 and $beta$ 2 in adult mouseretina (Weber et al., 1998), but here the distributions of allthe subunits were examined with double- and triple-label immunofluorescenceto assess the extent of colocalization. In artificial expressionsystems, $alpha$ and $beta$ isoforms can be interchanged; in the retina thethree $alpha$ and three $beta$ isoforms produced six of nine possible $alpha$ $beta$ combinations in different celltypes.

Ascertaining the changes in the Na,K-ATPase isoforms during development and differentiation is important as a basis for understandinghow the expression of genetically different subunit isoforms contributesto the fine control of ion transport. Four classes of developmentalchanges occurred that presumably require very different controlmechanisms: cell-specific commitment to particular isoform combinations,downregulation of precursor cell isoforms, subcellular targeting,and upregulation to accommodate the increased demand for ion transportin the active retina. These events occurred on different timeschedules in different celltypes.

Photoreceptors were examined closely because of their propensity for apoptosis in mice with genetically modified Na,K-ATPase $beta$ subunits (Magyar et al., 1994; Molthagen et al., 1996; Weberet al., 1998). Oddly, photoreceptors survive and differentiatefor many days in the absence of their principal $beta$ subunit ( $beta$ 2),and we expected to find robust early expression of another $beta$ subunitthat could support cell survival. This was not the case, however.Expression of $beta$ 1 was not detected, and $beta$ 3 expression occurredafter a delay and rose slowly in postnatal development. The specialrole of the Na,K-ATPase in photoreceptor activity and survivalisdiscussed.

  MATERIALS AND METHODS

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Antibodies. Both monoclonal and polyclonal antibodies specific for Na,K-ATPase $alpha$ and $beta$ subunit isoforms were used (Table 1).Most of the antibodies are either directed against known sitesor have mapped epitopes. Monoclonal antibodies 6F (for $alpha$ 1), McB2(for $alpha$ 2), and XVI-F9G10 (for $alpha$ 3) all bind within the first 60residues of the respective $alpha$ subunits, on the cytoplasmic surface(Arystarkhova and Sweadner, 1996). Monoclonal antibodies BSP-3(for $beta$ 1) and 426 (for $beta$ 2) both bind somewhere in the extracellulardomain of $beta$ (Gloor et al., 1992), as does IEC 1/48, used for $beta$ 1in the rat (Marxer et al., 1989). The epitope for GP-50 antibodyagainst rat $beta$ 2 is not known. Rabbit polyclonal antibody RNT $beta$ 3is directed against the cytoplasmic N terminus of $beta$ 3 (Arystarkhovaand Sweadner, 1997). For some experiments a polyclonal antibodydirected against a large intracellular portion of $alpha$ 3 and preadsorbedto increase its isoform specificity was also used (Shyjan andLevenson, 1989).


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Table 1. Antibodies used for Na,K-ATPase isoform detection in the mouse and rat

Immunocytochemistry. Mice (BALB/c) or rats (CD) were anesthetized to the point of cessation of respiration with ether andthen decapitated. The eyes were immediately removed, bisected,and fixed by immersion in 2% paraformaldehyde in a periodate-lysinebuffer (McLean and Nakane, 1974) for 2 hr at room temperaturewith constant gentle agitation. The eyecups were rinsed for 10min in PBS (0.1 M sodium phosphate, 0.15 M NaCl, pH 7.2), andthe lenses and any remaining vitreous were removed. The eye cupswere placed in 30% sucrose in PBS for 3 hr at 4°C, embedded inTBS Tissue Freezing Medium (Triangle Biomedical Sciences, Durham,NC) in aluminum boats, frozen on liquid nitrogen, and stored at $-$ 20°C. Cryostat sections (15 µm) were cut at $-$ 20°C and storedat $-$ 20°C untiluse.

Slides were brought to room temperature and a PAP pen (Kiyota International, Elk Grove, IL) was used to draw a hydrophobicring around the sections. The slides were rinsed in PBS for 10min and then laid flat in a dark moist box for all subsequentincubations. The sections were covered with 5% normal goat serum(to block nonspecific binding) in PBS with 0.3% Triton X-100 (PBS-Triton)and incubated for 1 hr at room temperature. The blocking solutionwas removed with an aspirator, primary antisera diluted in PBS-Triton(mouse: 6F, 1:4; McB2, 1:4; XVI-F9G10, 1:500; BSP-3, 1:4; 426,1:4; polyclonal $alpha$ 3, 1:250; and RNT $beta$ 3, 1:2500) (rat: IEC 1/48,1:3; GP-50, 1:3; and RNT $beta$ 3, 1:2500) were applied to the sections,and the slides were incubated overnight at 4°C. They were rinsed(three times for 10 min each time) in PBS and then incubated inthe appropriate fluorescent secondary antibody diluted in PBS-Triton,rhodamine-conjugated goat anti-mouse IgG (1:500; Accurate, Westbury,NY) or Cy5-conjugated goat anti-mouse (1:200; Jackson Laboratories,Bar Harbor, ME), FITC-conjugated goat anti-rabbit IgG (1:1000;Accurate), or TRITC-conjugated goat anti-rat IgG + IgM (1:500;Sigma, St. Louis, MO). The slides were rinsed in PBS as beforeand coverslipped with Vectashield fluorescence mounting medium(Vector Laboratories, Burlingame, CA). The sections were observed,and electronic images were collected using a Leica DMRB fluorescencemicroscope equipped with a Bio-Rad MRC 1024 Laser Sharp scanninglaser confocal system (version 2.1A).

  RESULTS

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Immunocytochemistry with isoform-specific antibodies

Figure 1 summarizes the staining patterns for all six Na,K-ATPase subunit isoforms in the adult mouse retina. The use of mouse-,rat-, and rabbit-derived antibodies made it possible to performtriple-antibody staining on the same sections. The pigment epithelium(seen at the top of each section; asterisks) stained for $alpha$ 1 and $beta$ 1 and no other subunit isoform. Photoreceptor rod inner segments(IS), the brightest structures in the retina, stained for $alpha$ 3, $beta$ 2, and $beta$ 3. In contrast, outer segments (OS) were completely unstainedwith all antibodies. A band near the base of the photoreceptorinner segments stained for $alpha$ 1, but by double-labeling it was clearthat this was distinct from the inner segments and representedthe outer limiting membrane (OLM) formed by Müller cells linkedby tight junctions, plus Müller cell processes extending partwayup between the inner segments (Olney, 1968). Stain for $beta$ 3 alsoshowed a concentration of stain near the base of the inner segment,in addition to staining the full length of the inner segment.In double-labeled sections, however, $beta$ 3 stain was clearly differentfrom $alpha$ 1 stain (Fig. 2A,B). Figure 2A-D shows the different distributionsof inner segment stain at higher magnification; where $beta$ 3 appearedto be concentrated at the base of the inner segments, $beta$ 2 appearedto be slightly concentrated at their tips, whereas $alpha$ 3 distributionwas uniform. Photoreceptor cell somas in the outer nuclear layer(ONL) and their presumptive terminals in the outer plexiform layer(OPL) stained with the $alpha$ 3, $beta$ 2, and $beta$ 3 antibodies, although notas intensely as in the inner segments (Fig. 1). The OPL stainedmost brightly for $alpha$ 1 and $beta$ 1 contributed by horizontal cells locatedat the extreme outer edge of the inner nuclear layer (INL), althoughall subunit isoforms were present. The INL showed clear divisioninto zones: the outer zone contained bipolar cells and stainedfor $alpha$ 3 and $beta$ 2, whereas the inner zone contained amacrine cellsand stained for $alpha$ 3 and $beta$ 1. The inner plexiform layer (IPL) stainedfor $alpha$ 1, $alpha$ 3, $beta$ 1, and $beta$ 2, with visible banding of $alpha$ 1, $beta$ 1, and $beta$ 2reflecting the stratification of processes of the stained cells.Ganglion cell somas stained most brightly for $beta$ 1, whereas bundlesof axons stained for $alpha$ 3 and $beta$ 1.

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Figure 1. Confocal fluorescent micrographs of adult mouse retina sections triple-labeled with $alpha$ 1, $beta$ 1, and $beta$ 3 (top row) or $alpha$ 2, $beta$ 2, and $alpha$ 3 (bottom row) isoform-specific primary antibodies and Cy5-conjugated (blue, anti-mouse), TRITC-conjugated (red, anti-rat), or FITC-conjugated (green, anti-rabbit) secondary antibodies. The images on the right side include all three color channels. Arrowheads and asterisks indicate Müller cell endfeet in the region of the OLM and label in the retinal pigment epithelium, respectively. Scale bar, 50 µm.

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Figure 2. High-magnification images of adult mouse retinas showing detail of label in the photoreceptor inner segments (A-D) and in the region of the OPL (E-G) for various subunit isoforms. A + B, C + D, and E + F are double-labeled. Arrowheads in F indicate $beta$ 3 label in photoreceptor terminals. Scale bar, 10 µm.

Stain for $alpha$ 2 was extremely light in the retina, and background staining of blood vessels by the anti-mouse secondary antibodywas very apparent (Fig. 1). This nonspecific staining of bloodvessels was equally evident in sections stained with the anti-mousesecondary antibody alone (data not shown) and was probably causedby interaction with circulating mouse immunoglobins in blood vessels.It is likely that blood vessels were similarly labeled in the $alpha$ 1- and $alpha$ 3-stained retinas, where mouse immunoglobins were used,but the $alpha$ 1- and $alpha$ 3-specific stain was much more intense than thenonspecific stain and thus masked the staining of blood vessels.Retinal $alpha$ 2 stain was irregular and characterized by a largelyvertical pattern with some lateral processes typical of Müllerglia. The amount of $alpha$ 2 label increased from central to peripheralregions of the adult retina (Fig. 3A-C). In the central retina(Fig. 3A), there were occasional labeled Müller cell processesin the region of the OLM (arrow). In the more lateral regions(Fig. 3B), the number of stained Müller cells increased, whereasdistance between labeled cells decreased. In the extreme periphery(Fig. 3C), the labeled cells formed a completely labeled OLM withoutany breaks (arrow). Interestingly, the nonpigmented ciliary epitheliumwas intensely labeled for $alpha$ 2 as reported for other species (Ghoshet al., 1990), much more so than the retina. None of the otherNa,K-ATPase subunit isoforms showed an obvious central-to-peripheralgradient of expression in adult retinas.

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Figure 3. Collage of confocal micrographs of $alpha$ 2 label in an adult mouse retina section. Labeled Müller cell endfeet in the region of the OLM (arrows) increase in number and stain intensity from central (A) to more lateral (B) retinal regions, to a maximum in peripheral retina (C). The ciliary epithelium (far right in C) was intensely labeled. Scale bar, 50 µm.

Many of these observations confirm previous studies of the distribution of the $alpha$ isoforms in adult rat retina (McGrail andSweadner, 1986, 1989) or the distribution of $beta$ 1 and $beta$ 2 in adultmouse retina (Weber et al., 1998). The colocalization of pairsof $alpha$ and $beta$ isoforms is shown here for the first time, except forthe presence of $alpha$ 3 and $beta$ 2 in photoreceptors (Schneider and Kraig,1990; Schneider et al., 1991). The distribution of $beta$ 3 in the retinahas not been reported before. $beta$ 3 expression elsewhere in the CNSis relatively low (Arystarkhova and Sweadner, 1997; Peng et al.,1997), but there was good reason to expect it to be present becauseit was cloned from mouse retina (Besirli et al., 1997); however,its presence in photoreceptors was both unexpected and interesting,for reasons to be discussed below. What was most notable aboutthe staining patterns for $beta$ 1 and $beta$ 3 was that they had complementarydistributions: $beta$ 1 in the inner retina and $beta$ 3 in the outer retina.When stained simultaneously, the distributions of $beta$ 3 and $beta$ 1 staineven in the OPL had very little overlap. Figure 2E-G shows thespatial separation of stain for $beta$ 1 and $beta$ 3 at higher magnification.The appearance is consistent with the presence of $beta$ 3 in photoreceptorterminals and $beta$ 1 in horizontal cellprocesses.

The survey of isoform expression in the adult retina indicates that there was no simple correlation of $alpha$ subunit isoform with $beta$ subunit isoform. At least six isoform combinations can be inferredto be present as a major heterodimer in at least one kind of cell: $alpha$ 1 $beta$ 1, $alpha$ 1 $beta$ 2, $alpha$ 2 $beta$ 2, $alpha$ 3 $beta$ 1, $alpha$ 3 $beta$ 2, and $alpha$ 3 $beta$ 3 (Table 2). We also observedthat adult rat retina had the same distribution of $alpha$ and $beta$ subunitsas the mouse retina, using different monoclonal antibodies for $beta$ 1 and $beta$ 2 (Fig. 4). The only notable differences were a relativelygreater intensity of $beta$ 2 stain in photoreceptor inner segmentsin the rat and a more prominent $alpha$ 2 stain of a subpopulation ofamacrine cells.


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Table 2. Summary of Na,K-ATPase subunit isoform expression in mouse retinal cell types

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Figure 4. Adult rat retina sections labeled with isoform-specific antibodies. All of the antibodies were mouse monoclonals with the exception of the rabbit antibody against $beta$ 3 (Table 1). Scale bar, 50 µm.

Developmental changes in Na,K-ATPase isoform expression

Although cell birth (the cessation of division) and commitment (the irreversible choice of cell fate) occur prenatally formany cells in the rodent retina, most of the phenotypic differentiationoccurs postnatally during the 2 week delay before eye opening.Embryonic retinas begin as a pseudostratified columnar epitheliumof ventricular cells, and as cells become postmitotic, they migrateinward to their final position (for review, see Olney, 1968; Weidmanand Kuwabara, 1968; Raedler and Sievers, 1975). Well before birth,ganglion cells migrate to the inner margin of the retina and sendaxons to the brain. At about the same time, amacrine cells migrateinward, and processes of ganglion and amacrine cells arborizehorizontally, forming the inner plexiform (synaptic) layer. Atthe time of birth, the mouse retina consists of ganglion celllayer (GCL), IPL, amacrine cells in what will become the innerhalf of the INL, and a thick neuroblastic layer (NBL), the outerthird of which contains opsin-containing but poorly differentiatedrods and cones. Horizontal cells migrate into the central neuroblasticlayer and extend processes that form the OPL by the end of thefirst postnatal week. Photoreceptor outer segments appear on postnatalday 5 (P5) and become noticeable as a layer by P10. At the timethe eyes open on P13 or P14, cell multiplication, developmentallyscheduled apoptosis, and differentiation are complete, and theretina has all of the cellular and synaptic layers of the adult.Synaptogenesis then continues for 1-2weeks.

Retinas were taken from mice ranging in age from 2 to 22 d and examined for the distribution of each Na,K-ATPase subunit isoform.Figures 5-10 present the data one isoform at a time so that progressivechanges either in isoform level or in cell position or morphologycan be followed. In all of the Figures, photoreceptors are atthe top and ganglion cells at the bottom. In many pictures thepigment epithelium is visible at the top, but frequently it separatedfrom the retina. $alpha$ 1 stain was found everywhere at the earliestage but greatly intensified with development, and the patternbecame dominated by Müller and horizontal cells. The stain ofblood vessels was artifactual. The developing retina had littleor no $alpha$ 2 stain, but eventually a subpopulation of Müller gliaexpressed it. $alpha$ 3 stain was present throughout development, butthe pattern became dominated by subcellular targeting to innersegments and to neuronal processes. The $beta$ 1 isoform had a moredistinctive distribution at the earliest age than any of the otherisoforms, with well defined stain in horizontal cells, amacrinecells, and ganglion cells and no detectable stain in the neuroblastcells. In contrast, $beta$ 2 stain was unusually prominent at birthin the cells that will become photoreceptors, but its expressionin the inner retina increased late in development. $beta$ 3 stain wasexpressed relatively late and was confined to photoreceptors.

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Figure 5. $alpha$ 1 expression during mouse postnatal retinal development. In the P2 retina, the IPL and the outer and inner margins of the retina were labeled with moderate strength, and the entire retina was lightly labeled. In the outer retina, the label appeared to be on radially oriented fibers of the neuroblasts, but lightly ring-stained cells were seen near the IPL and in the GCL. The pattern of stain did not change noticeably until P8, when the lightly stained OPL became evident. On P10-P12, numerous labeled fibers were seen to span the retina, from the OLM to the ILM, and ring-stained cells were seen in the central and outer portions of the INL (presumably Müller cells and horizontal cells, respectively) and in the GCL. Artifactually stained blood vessels also appeared in this period. Although the IPL was lightly labeled, a pair of brighter-staining bands was seen in its center at P8-P12, resembling the ramifications of the starburst amacrine cells, but at P16 and beyond only a single, more diffuse band was seen. From P12 to P22 there was an increase in the intensity stain at each locus: labeled fibers crossing the retina, bands in the IPL, and the OLM. In the adult retina, $alpha$ 1 stain was seen in nearly all retinal layers. At the OLM, delicate Müller cell processes extended from the outer surface of the brightly labeled OLM, and Müller cell fibers passing through the GCL formed bands of stain at the ILM. Ring-stained horizontal cells were seen in the outer portion of the INL, and their labeled processes extended horizontally in the OPL. Ring-stained ganglion cells and labeled axons were seen in the GCL. The OPL was brightly labeled, whereas the IPL had a more punctate appearance, with a layer of bright stain in the central portion of the IPL. Scale bar, 50 µm.

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Figure 6. $alpha$ 2 expression during mouse postnatal retinal development. No $alpha$ 2-specific stain was seen until P22, when lightly stained Müller cell processes were seen in the ONL, terminating at the OLM. Because the labeled processes in the OLM did not appear to be in contact with each other, $alpha$ 2 stain was confined to a subpopulation of Müller cells, as reported earlier for the rat (McGrail and Sweadner, 1986). The number of labeled Müller cells was higher in the peripheral retina than in more central regions, as shown above for the adult. The staining pattern was unchanged in the adult retina, although the intensity of $alpha$ 2 stain was greater. Scale bar, 50 µm.

More detail on the changes in isoform-specific expression patterns can be found in the Figure legends. Here we describe Na,K-ATPaseisoform expression one cell type at a time to integrate the contributionsof multiple isoforms in eachcell.

Photoreceptors
At birth in the rat eye, expression of opsin can already be detected in committed photoreceptor cell bodies in the outer thirdof the neuroblastic layer (Hicks and Barnstable, 1987). Like opsin,we found that the Na,K-ATPase $beta$ 2 subunit was present in thesecells in the mouse, and in fact photoreceptors were the only cellsin the retina to express $beta$ 2 at a level detectable by immunofluorescencefrom P2 to P6 (see Fig. 9). The cells appeared ring-stained, similarto the distribution of opsin. No $beta$ 1 or $beta$ 3 was detected (see Figs.8, 10). Both $alpha$ 1 and $alpha$ 3 were expressed uniformly in the neuroblasticlayer with a pattern that suggested stain of processes that extendacross the layer and thus including the neuroblasts and futurebipolar cells (Fig. 5, 7). We infer that the nascent photoreceptorsexpressed $alpha$ 1, $alpha$ 3, and $beta$ 2 at birth, whereas the undifferentiatedneuroblasts expressed $alpha$ 1, $alpha$ 3, and no $beta$ subunit that we could detectabove background. It remains possible that there is an undiscovered $beta$ subunit isoform.

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Figure 7. $alpha$ 3 expression during mouse postnatal retinal development. In the P2 retina, the brightest $alpha$ 3 stain was seen in the IPL and on the outer margin of the retina, although the entire retina was lightly labeled. As seen in $alpha$ 1-stained retinas, the $alpha$ 3 label appeared to be on radially oriented fibers in the outer retina, but there were numerous ring-stained amacrine cells and ganglion cells in the inner retina. The general appearance of the stain did not change until P8, when the OPL could just be detected, in contrast to its clear stain by other antibodies. At this time, the brightest stain was in the IPL and at photoreceptor cell bodies. During the second and third postnatal weeks, the $alpha$ 3 stain became less intense in the plexiform layers and more intense in photoreceptor inner segments. Additionally, lightly ring-stained amacrine and bipolar cells became apparent in the third postnatal week in the inner and outer zones of the INL, respectively. In the adult retina, $alpha$ 3 stain was seen in the photoreceptor cell inner segments. Labeled fibers from ring-stained presumptive bipolar cells in the outer zone of the INL extended to the OPL and IPL. Occasionally, ring-stained amacrine cells were seen in the inner INL with labeled processes in the IPL. The plexiform layers were also lightly labeled. Lightly ring-stained ganglion cells and their labeled axons were seen in the GCL. Scale bar, 50 µm.

Even before birth, there is an apical enlargement of neuroblastic cells at the outer margin of the retina that extends beyondthe outer limiting membrane and contains accumulations of mitochondria,seen with electron microscopy (Weidman and Kuwabara, 1968; Raedlerand Sievers, 1975). This resembles the future inner segment enoughso that it has occasionally been described as a primitive innersegment (Olney, 1968), but in fact ventricular epithelial cellselsewhere in the developing nervous system display the same structure,and its relationship to inner segment is probably evolutionaryrather than functional. The same surface expansions are rich inlectin-binding components at P2-P4 (Blanks and Johnson, 1983).When stained for Na,K-ATPase subunits, only $alpha$ 1 and $beta$ 1 showed anyconcentration at the outer surface (Figs. 5, 8). Because the retinalpigment epithelium expressed $alpha$ 1 and $beta$ 1 and sometimes left bitsof tissue adhering to the surface of the retina when it was pulledaway, and because $beta$ 2 in photoreceptors was pointedly not concentratedin the apical stain (Fig. 9), it is likely that the $alpha$ 1 and $beta$ 1stain originated in pigment epithelium rather than the photoreceptors.Thus although there are accumulations of mitochondria in the apicalexpansions that could provide the ATP for the Na,K-ATPase, itappears that enrichment in the enzyme occurs at a later stageof photoreceptor differentiation.

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Figure 8. $beta$ 1 expression during mouse postnatal retinal development. On P2, $beta$ 1 stain was located in the GCL, in the IPL, and in migrating horizontal cells in the outer portion of the NBL. Delicate brightly labeled horizontal cell processes extended from ring-stained somas inward to the central portion of the NBL, outward to the outer margin of the retina, and horizontally. Additionally, labeled processes extended inward from ring-stained amacrine cells in the inner NBL and outward from ring-stained ganglion cells in the GCL into the IPL. On days P4-P6, the number of brightly labeled horizontal cells in the outer third of the NBL increased, as well as the intensity of stain. These cells migrated inward, and their vertically oriented processes became shorter until, on P8, they formed a brightly labeled OPL in the central portion of the former NBL. Their cell bodies were located in the outer portion of the INL adjacent to the newly formed OPL. The intensity of $beta$ 1 stain in amacrine and ganglion cells, as well as in the INL, increased during the third postnatal week. In the adult retina, the most intense $beta$ 1 stain was in the plexiform layers. Horizontal and amacrine cells in the outer and inner margins of the INL, respectively, and ganglion cells in the GCL were also clearly ring-stained. However, the OLM, photoreceptor inner and outer segments, ONL, and the inner portion of the INL were all devoid of stain. $beta$ 1 stain was not seen in photoreceptors at any age; it was unambiguously absent from the ONL from P8 on when the horizontal cells had moved out. Scale bar, 50 µm.

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Figure 9. $beta$ 2 expression during mouse postnatal retinal development. On P2, the brightest $beta$ 2 stain was seen in ring-stained future photoreceptor cells with inward-oriented processes in the outer third of the retina. The IPL and GCL were also lightly labeled. Although the general pattern of staining did not change over the following week, the amount of stain and number of labeled cells increased. On P8, the OPL became evident along the inner margin of the bright ring-stained cells in the outer retina. Lightly ring-stained cells were also seen for the first time on P8 throughout the INL. On P12, several layers of bright staining were seen in the widening IPL. On P16-P22, the intensity of $beta$ 2 stain in the ONL decreased, although the intensity of stain in the photoreceptor inner segments increased. In addition, there was an increase in the intensity of $beta$ 2 label in the IPL, in ring-stained bipolar cells in the outer zone of the INL, and in ganglion cell axons in the NFL. In the adult retina, the brightest stain was seen in the photoreceptor inner segments. Photoreceptor cell bodies in the ONL were lightly ring-stained. $beta$ 2 stain was also seen in ring-stained bipolar cells in the central INL and in their labeled processes extending inward and outward to the brightly labeled plexiform layers. The bright bands of $beta$ 2 stain seen in the IPL on P12-P22 were not evident in the adult retina. Ganglion cell axon bundles in the NFL were brightly stained (not visible in the picture shown), although their somas in the GCL were not labeled. This is consistent with the presence of $beta$ 2 mRNA in astrocytes in the optic nerve (Magyar et al., 1994). Scale bar, 50 µm.

Photoreceptor outer segments first appear in electron microscope images of mouse and rat retina at P5 (Olney, 1968; Weidmanand Kuwabara, 1968), and rhodopsin (opsin with chromophore) isfirst detected at the same time (Bonting et al., 1961). By P6a few inner segments look well developed by electron microscopy,and by P10 they demonstrate their mature size and shape (Weidmanand Kuwabara, 1968; He et al., 1998). By P4-P6 we observed thefirst faint stain of inner segments for $beta$ 3, which was visiblebecause the antibody stained no other structure (Fig. 10). Stainfor $beta$ 2 became visible above the background of photoreceptor somastain only on P8 (Fig. 9). Interestingly, $alpha$ 3 stain was not clearlyconcentrated in inner segments until after P8 (P12 was the nextday examined) (Fig. 7). Whether this indicates that targetingof unassembled Na,K-ATPase $beta$ subunits precedes targeting of the $alpha$ subunit in this structure merits further investigation.

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Figure 10. $beta$ 3 expression during mouse postnatal retinal development. Although the P2 retina was unstained by the $beta$ 3 antiserum, very lightly stained cells were seen on the outer margin of P4 retinas. The intensity of stain and number of labeled cells increased on the outer margin and on P6, and very light label was seen in the outer third of the NBL. On P8, although it was only very lightly labeled, the IPL was evident as a boundary between the unlabeled INL and the light label in the ONL. The brightest label on the outer margin of the retina, corresponding to photoreceptor inner segments, increased at P10-P15, whereas the label in the ONL remained light and somewhat punctate. $beta$ 3 stain in the adult retina was limited to the outer retina, from the outer margin of the OPL to the tips of the photoreceptor inner segments. In contrast to the $beta$ 1 stain described above, the inner portion of the retina, from the OPL to the ILM, was completely devoid of $beta$ 3 stain. With the $beta$ 3 antiserum, cytoplasmically labeled cells were seen transiently in the inner retina in the GCL. This stain peaked on P10, and then decreased by P16. Because it did not resemble the plasma membrane-associated stain expected of the Na,K-ATPase, it may represent incidental cross-reactivity with another protein. Scale bar, 50 µm.

Cone photoreceptors begin making synapses with horizontal cells very early (P3), and rod photoreceptor synapses with horizontalcells and bipolar cells are well established by P10 (Olney, 1968;Rich et al., 1996). The expression of $alpha$ 3 in photoreceptor terminalsin the OPL could not be distinguished from expression of $alpha$ 3 inhorizontal cells by light microscopy, but expression of $beta$ 2 and $beta$ 3 there was clearly temporally distinct. $beta$ 2 stain of the OPLwas obvious at P8, whereas $beta$ 3 stain was barely detectable at P12and not really strong until P22 (Figs. 9, 10). This is interestingin view of the mechanisms for subcellular targeting of these closelyrelated proteins. From P8 to P12, $beta$ 2 shows a distribution balancedbetween inner segments and photoreceptor terminals, whereas $beta$ 3was preponderantly routed to inner segments. This may have a cellularbasis, in that photoreceptor soma staining for $beta$ 2 was uniformacross the thickness of the outer nuclear layer, whereas $beta$ 3-stainingsomas were concentrated in the outer half until later in development.We cannot be sure that $beta$ 2 and $beta$ 3 were expressed in the same cells,but for both isoforms the number of stained cells was too highto represent cones, which are only 3% of total photoreceptors(Rich et al., 1996).
At P2, $alpha$ 1 was present in cells in the outer third of the neuroblastic layer, but it diminished with time. By P12 the remaining $alpha$ 1 stain appeared to be in Müller glia, implying that it is downregulatedduring photoreceptor differentiation (Fig. 5). For $alpha$ 3, $beta$ 2, and $beta$ 3, the proportion of stain that appeared in somas relative toinner segments declined between P12 and P17 (Figs. 7, 9, 10). Thiscould be attributable to reduced targeting to cell bodies or toenhanced stability of the fraction in the innersegment.

Müller glia
Trans-epithelial ventricular cells phenotypically differentiate to Müller cells between P7 and P10. Müller cells can beidentified by electron microscopy first at P7 (Raedler and Sievers,1975), and their lateral processes expand by P10 (Weidman andKuwabara, 1968). A monoclonal antibody (RT10F7) that appears tostain the entire Müller cell stains all ventricular cells atP1 but shows more selective stain at P4 and a nearly adult-likeMüller cell by P8 (Yamaskai et al., 1998). P8 is also the agewhen Müller cell amino acid metabolic pathways are expressed:a reduction of glutamate immunoreactivity and the appearance ofglutamine immunoreactivity and GABA uptake (Fletcher and Kalloniatis,1997). None of the Na,K-ATPase subunit antibodies were observedto stain P8 Müller cells with the same pattern as the RT10F7antibody, but stain for $alpha$ 1 was apparent by P12 and for $alpha$ 2 by P22.Because $beta$ 2 was the only known $beta$ subunit isoform that spanned theretina, it was the only candidate for expression in Müller glia,although such stain was not obvious above the background of bright $beta$ 2 stain of neural cells. Because Na,K-ATPase stain was not prominentwhen Müller cells first display differentiated characteristics,it was apparently upregulated later when there is increased demandfor ion transport secondary to the dark current and synapticactivity.

Horizontal cells
Horizontal cells have a unique behavior in the retina in that they show significant differentiated phenotype before migration.These large-diameter cell bodies have already extended processesvertically and laterally when they begin migration between P1and P8 (Olney, 1968; Weidman and Kuwabara, 1968; Raedler and Sievers,1975). They are similarly distinctive in that they display brightstain for the Na,K-ATPase $beta$ 1 subunit as early as P2 and are theonly cell type identifiable with this isoform in the outer retina(Fig. 8). Stain for $alpha$ 3 was also visible in early migrating horizontalcells, brighter than the background stain of neuroblastic cellsand photoreceptors (Fig. 7). Stain for $alpha$ 1 was not detectable abovethe background of other cells during early postnatal developmentbut could be seen in the adult, and dissociated horizontal cellsfrom adult rat retina were seen to stain for both $alpha$ 1 and $alpha$ 3 (McGrailand Sweadner, 1986). The upregulation of $alpha$ 1 may be delayed untilquite late in synaptogenesis (P17). Horizontal cells receive synapsesfrom photoreceptor cells early in retinal development but makesynapses on bipolar cells considerably later (Olney, 1968), andit is conceivable that the kinetic requirements for ion transportchange with this change in cellfunction.

Bipolar cells
Bipolar cells are the last neuron to differentiate in the retina and the most crucial for creating the through-pathway forvisual signals. Although their birthdates peak at P3 (Young, 1985),by electron microscopy their cell bodies still resemble undifferentiatedneuroblastic cells at P10 (Raedler and Sievers, 1975). They arethe last cells, up to P9, to be stained for MASH-1, a helix-loop-helixDNA-binding transcription factor that marks neural progenitorcells (Jasoni and Reh, 1996). Stain of these cells for Na,K-ATPase $alpha$ 1, $alpha$ 3, and $beta$ 2 appeared first at P12, and the staining graduallyintensified until adulthood (Figs. 5, 7, 9). The specificationof Na,K-ATPase subunits at P12 coincides with the appearance oftwo other bipolar cell markers, a monoclonal antibody epitopeRet-B2 (Barnstable et al., 1983) and neuron-specific enolase (Richet al., 1996). Bipolar cell terminal differentiation in the IPLoccurs from P11 to P18, although they received synapses from rodsin the OPL from P6 to P10 (Olney, 1968). It is this later periodof synaptogenesis that correlates with the largest increase inNa,K-ATPaseexpression.

Amacrine cells and ganglion cells
Amacrine and ganglion cells are among the first cells to be specified in the retina, and already at birth they expressed $alpha$ 3and $beta$ 1, and to a lesser extent $alpha$ 1 and $beta$ 2, and showed stain forall of these subunits in the primitive inner plexiform layer (Figs.5, 7-9). By adulthood, $alpha$ 1 and $beta$ 2 stain were reduced, but $alpha$ 1 persistedas a minor component, which can be shown to be axonally transportedwith $alpha$ 3 when retinas are labeled with radioactive tracer (Spechtand Sweadner, 1984). A major upregulation occurred in the innerplexiform layer late in retinal development, corresponding withthe maturation of synaptic structure. A caveat is that amacrinecells as a class are quite heterogeneous in phenotype, and althoughno subset of them stood out as different, a closer look couldreveal more cellulardetail.

Pigment epithelium
Although the pigment epithelium was frequently inadvertently removed from the neural retina during tissue preparation, itwas almost always visible somewhere in the section. $alpha$ 1 and $beta$ 1were the predominant isoforms expressed at all ages. The literatureis not entirely consistent. It has been reported that $alpha$ 1 and $beta$ 1mRNAs were detected (Gundersen et al., 1991; Ruiz et al., 1995)and that $alpha$ 2 and $alpha$ 3 mRNAs were not detected in pigment epithelium(Gundersen et al., 1991; Ruiz et al., 1996); this was confirmedhere at the protein level with isoform-specific antibodies. Wedid not detect the $beta$ 2 subunit, however, which has been reportedin human pigment epithelium-derived cell preparations both ascDNA isolated by RT-PCR and in immunoblots of microsomes (Ruizet al., 1996). Unless $beta$ 2 is localized in human pigment epitheliumin situ, it is possible that its apparent presence in isolatedcells was caused by contaminating photoreceptor material, whichhas abundant $beta$ 2 mRNA andprotein.

  DISCUSSION

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Predifferentiation and postdifferentiation patterns of Na,K-ATPase isoform expression

It is notable that in some cell types, elevated levels of particular Na,K-ATPase subunit isoforms ( $alpha$ 3 with $beta$ 2 in photoreceptorsor $alpha$ 3 with $beta$ 1 in horizontal cells) preceded significant otherphenotypic differentiation. In most other cases, however, detectableexpression coincided with the adoption of differentiated characteristics,and upregulation corresponded with increases in retinal function.The electroretinogram, as a measure of evocable light response,is first detected at P13 in the rat (Weidman and Kuwabara, 1968)and increases in magnitude approximately 20-fold over the next2 weeks (Bonting et al., 1961). Over the same time period therates of glycolysis and oxygen consumption go up 2.5-fold (Graymore,1959, 1960). This roughly coincides in time with the largest increasein the total amount of each Na,K-ATPase isoform. It remains tobe determined by experiment whether the increase in sodium pumpexpression is a consequence of the development of the dark currentor whether it is determined by a genetic program that orchestratesall of the late events of retinal maturation. When investigatingthe genetic control of Na,K-ATPase expression, it is to be expectedthat there will be cell-type specificity in whether any givensubunit is among the earliest genes to be turned on during cellspecification. Some genes may be controlled instead by factorsthat relate to the demand for iontransport.

Subcellular targeting

The extent to which different Na,K-ATPase isoforms were targeted subcellularly varied greatly from cell to cell. $alpha$ 3 was obviousin cell somas in photoreceptors and ganglion cells early in development,but distribution in somas later diminished and routing to innersegments and photoreceptor terminals, or to ganglion cell axons,predominated. $beta$ 2 expression in somas of photoreceptors similarlyoccurred very early but was diminished with targeting to innersegments. On the other hand, somal expression of $beta$ 1 in horizontalcells, amacrine cells, and ganglion cells and $beta$ 2 expression inbipolar cells persisted from its first appearance until adulthood. $beta$ 3 expression in photoreceptor somas was uniquely minimal fromthe onset of its appearance. Differences in intracellular routingmay fine-tune the shape and speed of ion gradientfluctuations.

The photoreceptor and its sensitivity to Na,K-ATPase loss

$beta$ 2 was initially thought to be an adhesion protein important for CNS development (Gloor et al., 1990). Magyar et al. (1994)generated $beta$ 2 knockout mice that initially developed normally,but in the third postnatal week the mice exhibited motor incoordination.They died on P17 or P18 with grossly vacuolated astrocytes (whichnormally express $beta$ 2) in the brainstem, suggesting that the primarycause of pathology was a defect in Na,K-ATPase activity. Examinationof the retinas revealed that photoreceptors developed normallyduring the first postnatal week, but the rate of apoptotic photoreceptorcell death increased above levels seen in wild-type mice duringthe second and third postnatal weeks (Molthagen et al., 1996).Because retinal photoreceptors were thought to express $beta$ 2 andnot $beta$ 1 (Schneider et al., 1991; Magyar et al., 1994), it was unclearwhy photoreceptors developed normally in the first postnatal weekin $beta$ 2-deficient mice, apparently without a $beta$ subunit and thuswithout a functional Na,K-ATPase. In a subsequent study, Weberet al. (1998) generated mice with $beta$ 1 cDNA placed into the $beta$ 2 geneunder the control of the $beta$ 2 regulatory elements, and these animalssurvived into adulthood. Their photoreceptors expressed the $beta$ 1subunit. However, apoptosis in photoreceptors continued slowlywith age in these $beta$ 1 "knock-in" mice, resulting eventually ina severe visualdeficit.

Weber et al. (1998) hypothesized the early expression and subsequent downregulation of $beta$ 1 in photoreceptors during the first2 postnatal weeks to explain how the photoreceptors survived aslong as they did. We examined isoform-specific antibody stainin the developing retina but found that $beta$ 1 stain in the outerportion of the NBL was in migrating horizontal cells. It is likelythat $beta$ 1 in situ hybridization signal in the outer NBL during thefirst postnatal week that was thought to be in photoreceptors(Weber et al., 1998) was actually in horizontal cells, obscuredbecause of the low resolution of the method. At the time of theformation of the OPL on P8, all $beta$ 1 antibody stain was confinedto the inner retina. Furthermore, we showed that photoreceptorsin normal mice coexpressed $beta$ 2 and $beta$ 3 from P4 to adulthood. Althoughthe level is evidently not sufficient to replace $beta$ 2, it may havea protective effect over what would happen without it. The factthat the $beta$ 2 null photoreceptor cells manage to survive and formouter and inner segments between the end of the cell commitmentphase, when $beta$ 2 predominates, and the beginning of the third postnatalweek, suggests that they retain enough Na,K-ATPase derived fromthe progenitor cell, and/or express enough $beta$ 3, to survive anddifferentiate until the dark current and light-evoked responsesbegin and put great metabolic demand on the cells (Graymore, 1959;Graymore, 1960).

Because $beta$ 2 was first cloned as an adhesion protein and there is some evidence for its mediation of cell-cell interactions(for review, see Magyar et al., 1994), the question arises whetherit could play a role in cell adhesion and histogenesis. Its onlyearly expression in the mouse retina, however, was in photoreceptorsthat have already taken up position scleral to the still-proliferatingprogenitor cells (Hicks and Barnstable, 1987; Jasoni and Reh,1996). Notably, it had relatively low expression in the neuroblasticcells that play the role of scaffold for cell migration in earlyneuronal development. If it was expressed in Müller glia, thatexpression arose too late to have a role in cell migration. Itsexpression in bipolar cells occurred long after histogenesis andappeared to reflect the increased need for ion transport consequentto synaptogenesis. It is unlikely that $beta$ 2 has a role in the self-associationof photoreceptor cell bodies in the most scleral part of the neuroblasticlayer, because the cellular organization of the retina in the $beta$ 2 null mouse is normal up until P13 (Molthagen et al., 1996).Investigation of the retina thus supports a role for $beta$ 2 only inNa,K-ATPaseactivity.

Ion affinities of the Na,K-ATPase isoforms

Numerous studies have now confirmed that Na,K-ATPase subunit isoform composition has effects on the affinities of the enzymefor Na⁺, K⁺, and ouabain (for review, see Sweadner, 1989; Blanco and Mercer,1998). The interpretation is not simple, however, because it hasalso been shown that a given combination of $alpha$ and $beta$ subunits canhave different properties in different cellular environments (Therienet al., 1996, 1997). $alpha$ 3, for example, has shown very low affinityfor Na⁺ in transfected cells (Jewell and Lingrel, 1991; Munzer et al.,1994) but higher affinity in axolemma (mainly $alpha$ 3 $beta$ 1) or pineal(mainly $alpha$ 3 $beta$ 2) (Sweadner, 1985; Shyjan et al., 1990). Substitutionof $beta$ 2 or $beta$ 3 for $beta$ 1 (as occurs in photoreceptors) increases affinityfor Na⁺ in Sf-9 cells (Yu et al., 1997; Blanco and Mercer, 1998) butmay have different effects in other cells and with other isoforms(Schmalzing et al., 1992; Jaisser et al., 1994). A further complicationis that the isoforms may be regulated differently, such as bykinases (Beguin et al., 1996). What is most unusual about theretina is the large flux of Na⁺ in photoreceptors, and the fact that they must be depolarized(by Na⁺ influx) in the steady state in the dark to be sensitive to photicstimuli. They are hyperpolarized largely by turning off the Na⁺ leak and allowing the Na,K-ATPase to pump the Na⁺ back out. It is possible, then, that a given combination of isoformsis found in one cell type where a relatively high cytoplasmicNa⁺ concentration is needed or at least tolerated, and another combinationis found in a cell type that requires a steep Na⁺ gradient for Na⁺-dependent uptake of transmitter, for example. Still another combinationmay be needed in glia for their special role in K⁺ homeostasis. In this way, Na,K-ATPase isoforms could adapt eachcell for itsrole.

  FOOTNOTES

Received May 18, 1999; revised Aug. 23, 1999; accepted Aug. 27, 1999.

This work was supported by National Institutes of Health Grant NS27653. We thank Drs. Del Ames and Richard H. Masland foruseful comments on this manuscript, and Dr. Bradley T. Hyman formaking available the confocal microscope. We are grateful to otherinvestigators for the gift of useful antibodies: R. Levenson (PennsylvaniaState University College of Medicine, Philadelphia, PA), ChristoGoridis (Institut National de la Santé et de la Recherche Médicale-CentreNational de la Recherche Scientifique, Marseille Luminy, France),Andrea Quaroni (Cornell University, Ithaca, NY), M. Schachner(ETH Zurich, Zurich, Switzerland), and Phillip Beesley (RoyalHolloway and Bedford New College, Egham, UK). Antibody 6F, originallya gift of D. M. Fambrough (Johns Hopkins University, Baltimore,MD), is available from the Developmental Studies Hybridoma Bank(Iowa City, IA). Antibody XVIF9G10 ("16-F9-G10"), originally agift of K. P. Campbell (University of Iowa, Iowa City, IA), isavailable from Affinity BioReagents (Golden,CO).
Correspondence should be addressed to Kathleen J. Sweadner, 149-6118 Massachusetts General Hospital, 149 13^th Street, Charlestown, MA 02129. E-mail: sweadner{at}helix.mgh.harvard.edu.

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