Mild spherocytosis and altered red cell ion transport in protein 4.2–null mice

Protein 4.2 is a major component of the red blood cell (RBC) membrane skeleton. We used targeted mutagenesis in embryonic stem (ES) cells to elucidate protein 4.2 functions in vivo. Protein 4.2–null (4.2^–/–) mice have mild hereditary spherocytosis (HS). Scanning electron microscopy and ektacytometry confirm loss of membrane surface in 4.2^–/– RBCs. The membrane skeleton architecture is intact, and the spectrin and ankyrin content of 4.2^–/– RBCs are normal. Band 3 and band 3–mediated anion transport are decreased. Protein 4.2^–/– RBCs show altered cation content (increased K⁺/decreased Na⁺)resulting in dehydration. The passive Na⁺ permeability and the activities of the Na-K-2Cl and K-Cl cotransporters, the Na/H exchanger, and the Gardos channel in 4.2^–/– RBCs are significantly increased. Protein 4.2^–/– RBCs demonstrate an abnormal regulation of cation transport by cell volume. Cell shrinkage induces a greater activation of Na/H exchange and Na-K-2Cl cotransport in 4.2^–/– RBCs compared with controls. The increased passive Na⁺ permeability of 4.2^–/– RBCs is also dependent on cell shrinkage. We conclude that protein 4.2 is important in the maintenance of normal surface area in RBCs and for normal RBC cation transport.

Protein 4.2 is a 72-kDa component of the red blood cell (RBC) membrane skeleton (200,000 copies per RBC) (1). An intact membrane skeleton attached to the lipid bilayer by vertical interactions between spectrin, ankyrin, protein 4.2, and band 3 (anion exchanger 1 [AE1]) is required for normal RBC membrane integrity. Defects in all of these components have been identified in hereditary spherocytosis (HS) (2). In humans, protein 4.2 defects are most common in people of Japanese descent and give rise to pleiotropic RBC morphological changes and hemolytic anemias of varying severity (3).

In RBCs, protein 4.2 binds to the cytoplasmic domain of band 3 (4). In solution, protein 4.2 binds directly to spectrin, ankyrin, and protein 4.1, and promotes binding of spectrin to ankyrin-depleted inside-out vesicles (4, 5). The significance of these interactions in vivo is unknown. However, mice totally deficient in band 3 are also completely protein 4.2 deficient, suggesting that band 3 is critical for stable incorporation of protein 4.2 into the membrane skeleton (6).

Hereditary spherocytes are characterized by increased Na⁺ and decreased K⁺ content compared with normal RBCs (2). Studies in mice and humans suggest that the cation alterations are the result of increased passive RBC membrane permeability and that the increased passive flux reflects the overall loss of membrane skeleton integrity, not the specific protein defect (7, 8). Protein 4.2 has been proposed to negatively regulate band 3–mediated RBC anion transport (9), but its role in regulating RBC cation transport and intracellular cation content is unknown.

We targeted the erythrocyte protein 4.2 gene (Epb4.2) in embryonic stem (ES) cells to create a null mutation (4.2^–/–) in mice. Deficiency of protein 4.2 in mice results in mild HS. Normal amounts of spectrin and ankyrin are assembled onto the membrane, and the membrane skeleton architecture is intact. The band 3 content of the membrane is decreased. Contrary to previous reports, band 3–mediated anion transport in not increased in 4.2^–/– RBCs, but is decreased. Protein 4.2–deficient RBCs show significant changes in RBC cation transporter activities. These changes are in marked contrast to those obtained in spectrin- and ankyrin-deficient mouse and human red cells (7, 8), suggesting that specific membrane skeleton defects differentially influence cation transporter activities. Our results show that protein 4.2 is important in the maintenance of normal surface area in RBCs and is required for normal RBC cation transport.

Gene targeting. The mouse erythrocyte protein 4.2 gene, Epb4.2, is ∼22 kb in length and consists of 13 exons (1). We replaced a fragment extending from intron 3 to exon 8 with a neomycin-resistant cassette, removing exons 4 through 7 and part of exon 8 (Figure 1a). Homozygous null mutants are not distinguishable from normal littermates by phenotype at any age. Genotyping reveals the expected Mendelian frequency of homozygous null (4.2^–/–; 23%), heterozygous (4.2^+/–; 51%), and wild-type (4.2^+/+; 26%) offspring from heterozygous mating pairs.

Protein 4.2 is not detected in 4.2^–/– RBC ghosts on Coomassie blue–stained SDS-PAGE gels (Figure 1b) or by Western blotting of RBC ghosts or whole-RBC lysates (Figure 1c). No protein 4.2 mRNA is detected by Northern blot analysis of 4.2^–/– newborn reticulocyte RNA (Figure 1d). Protein 4.2 is detected in wild-type, but not 4.2^–/–, platelet lysates (Figure 1e).

We examined expression of Epb4.2 in nonerythroid tissues by RNase protection using a 295-bp fragment as probe (1). In kidney, the expected 295-bp protected fragment is detected in 4.2^+/+, but not 4.2^–/–, mRNA (Figure 1f). Intermediate levels are seen in 4.2^+/– kidney. Unexpectedly, a 250-bp protected fragment is detected at equal intensities in kidney mRNA in all 3 groups of animals. The origin of the 250-bp fragment is unknown. However, increasing the RNase concentration during hybridization significantly lowers the intensity of the 250-bp product, but not that of the 295-bp product (Figure 1f, third panel), suggesting that the 250-bp product derives from a related but distinct gene. RNase protection assays of brain, heart, liver, and spleen gave the same results (not shown).

Scanning densitometry of Coomassie blue–stained gels reveals a decreased protein 4.2/spectrin ratio in 4.2^+/– RBC ghost membranes (ratio X ± SEM; 4.2^+/+, 0.14 ± 0.01 [n = 3]; 4.2^+/–, 0.10 ± 0.01 [n = 3]; P < 0.05). We conclude that the gene-targeting event produces a null mutation in the Epb4.2 gene when homozygous and partial protein 4.2 deficiency when heterozygous .

4.2^–/– mice have mild HS. RBC counts and hematocrits (HCT) are significantly reduced in 4.2^–/– mice (Table 1). Hemoglobin (HGB) levels do not differ significantly but are slightly lower in 4.2^–/– mice. Reticulocyte percentages and spleen weights are increased approximately 2-fold, indicating a compensatory acceleration of erythropoiesis. White blood cell counts do not differ (not shown). The mean corpuscular volume (MCV) is reduced and the MCHC is elevated (Table 1 and Figure 2a), indicating the presence of a population of small, dehydrated RBCs in 4.2^–/– mice. All hematological parameters in 4.2^+/– mice are normal (Table 1).

Figure 2

Protein 4.2^–/– mice are mildly anemic. (a) RBC volume and hemoglobin concentration histograms obtained by automated analysis of normal (4.2^+/+) and mutant (4.2^–/–) whole blood. A population of small (left-shifted volume distribution in 4.2^–/–; bottom left) and dehydrated (right-shifted distribution in 4.2–/–; bottom right) RBCs are present in 4.2^–/– whole blood compared with controls. (b–d) Scanning electron microscopy. Representative photomicrographs of normal (b), heterozygous (c), and 4.2^–/– (d) RBCs. Note the spherocytic shape of the 4.2^–/– cells. Both normal biconcave and partially spherocytic RBCs are seen in 4.2^+/– mice. Scale bar: 1 μm. (e and f) Wright-stained peripheral blood smears from normal (e) and 4.2^–/– (f) mice. Note the presence of spherocytes in 4.2-deficient mice and the lack of fragmented cells. Scale bar: 10 μM. (g and h) Accumulation of iron in 4.2^–/– spleen (h) is increased compared with wild-type (g). Scale bar: 10 μm. (i) Osmotic gradient ektacytometry. Representative osmotic deformability profiles of RBCs from wild-type (+/+), heterozygous (+/–), and homozygous (–/–) protein 4.2–deficient mice.

Peripheral blood smears and scanning electron microscopy (Figure 2, b–f) confirm the presence of spherocytes in 4.2^–/– mice. Both normal biconcave RBCs and intermediate, cup-shaped cells are seen in heterozygotes. Iron staining shows increased iron deposition in the 4.2^–/– spleen, indicative of increased RBC destruction (Figure 2, g and h). No iron deposition is seen in 4.2^–/– kidney, indicating that intravascular hemolysis is negligible (not shown). Osmotic deformability profiles confirm loss of membrane surface in 4.2^–/– RBCs (Figure 2i). The maximum value of the deformability index (DI_max), a direct measure of the mean RBC membrane surface area (25), is lower than normal in 4.2^+/– RBCs and is further decreased in 4.2^–/– RBCs. The osmolality at which the DI reaches a minimum in the hypotonic region of the gradient (O_min), a measure of the average surface area/volume ratio of the RBCs, is higher than normal in 4.2^–/– RBCs. We conclude that 4.2 deficiency results in RBC membrane loss and mild HS.

4.2^–/– RBCs are band 3 deficient. The band 3 content of 4.2^–/– RBC membranes appears to be decreased on SDS-PAGE gels (Figure 1b) and Western blots (Figure 3a). The band 3/spectrin ratio, estimated by scanning densitometry of Coomassie blue–stained gels, is decreased in 4.2^–/– RBCs (ratio X ± SEM; 4.2^+/+, 1.19 ± 0.07 [n = 3]; 4.2^–/–, 1.00 ± 0.03 [n = 5]; P < 0.01]. The DIDS concentration required to maximally inhibit sulfate influx is decreased to ∼70% of normal in 4.2^–/– RBCs (Figure 3b). The maximal inhibitory DIDS concentration directly correlates to the number of band 3 molecules, confirming band 3 deficiency in the absence of protein 4.2. Net DIDS-sensitive sulfate influx is decreased to ∼60% of wild-type (Figure 3c) in 4.2^–/– RBCs. In both normal and 4.2^–/– RBCs, <10% of band 3 molecules were laterally mobile (n = 6 and 14 cells, respectively). The diffusion coefficient of the mobile band 3 molecules could not be estimated reliably for this degree of lateral immobilization. The prebleach fluorescence values of eosin-labeled 4.2^–/– RBCs were 69% of those of normal RBCs, in agreement with the results above indicating that band 3 is 30% decreased in 4.2^–/– RBCs.

Figure 3

Partial band 3 deficiency in 4.2^–/– RBCs. (a) Western blots demonstrating immunoreactive α- and β-spectrin (Sp; top 2 arrows, respectively), band 3 (Bd 3), ankyrin (Ank), protein 4.1 (4.1), p55, and glycophorin C (GPC) in normal (+/+) and 4.2-null (–/–) RBC membrane ghosts. p55 and GPC were detected using chemiluminescence; Sp, Bd 3, Ank, and protein 4.1 were detected using alkaline phosphatase–labeled secondary antibody. Each lane contains either equivalent amounts of ghost proteins (5 μg: bd 3 and 4.1; 20 μg: p55 and GPC) or cells (5 × 10⁷ total cells: Sp and Ank). Note the decrement in band 3 in null (–/–) vs. normal (+/+) RBC membrane ghosts. (b) The maximal inhibitory DIDS concentration in 4.2^–/– RBCs is decreased to ∼70% of 4.2^+/+, confirming reduction of band 3. (c) Red blood cell anion transport. DIDS-sensitive sulfate transport (X ± SEM) in 4.2^–/– and 4.2^+/– RBCs is decreased to ∼ 60% and ∼80%, respectively, of 4.2^+/+ RBCs. *P < 0.05 vs. 4.2^+/+. **P < 0.01 vs. 4.2^+/+.

In 4.2^+/– RBCs, the band 3/spectrin ratio is also decreased compared with 4.2^+/+ (1.12 ± 0.04 [n = 3], P > 0.05), and the net DIDS-sensitive sulfate influx is ∼80% of normal (Figure 3c).

4.2^–/– RBC membrane skeleton architecture and spectrin content are normal. Despite the absence of protein 4.2 and partial band 3 deficiency, a normal membrane skeleton is assembled in 4.2^–/– RBCs. Electron microscopy shows a qualitatively normal, intact skeleton architecture (Figure 4, a and b). By SDS-PAGE and Western blotting of RBC ghost membranes, normal amounts of spectrin, ankyrin, protein 4.1, p55, and GPC are seen in 4.2^–/– RBCs (Figures 1b and 3a). In low-ionic-strength Triton X-100–extracted RBC membranes, the equivalent of pure, isolated membrane skeletons (so-called Triton “shells”), normal amounts of α- and β-spectrin and ankyrin are present in 4.2^–/– skeletons (Figure 4c). However, increased levels of protein 4.1 are seen reproducibly in 4.2^–/– Triton shells prepared in both 0 (Figure 4c) and 150 mM (not shown) salt concentrations.

Figure 4

Ultrastructure of RBC membrane skeletons. (a and b) Negatively stained, spread membrane skeletons from normal (a) and protein 4.2^–/– (b) RBCs. Sp, spectrin filament. JC, junctional complexes. Ank, ankyrin. Scale bar: 100 nm. (c) Triton X-100–extracted RBC membranes. Ten micrograms of normal (+/+), heterozygous (+/–), and 4.2-null (–/–) RBC ghost membranes was extracted in 0.1, 0.5, or 1.0% Triton X-100. The pellet and supernatant (sup) fractions were resolved on a 3.5–17% Fairbanks gradient gel and stained with Coomassie blue. Sp, spectrin. Ank, ankyrin. bd 3, band 3. 4.1, protein 4.1. 4.2, protein 4.2. (d–f) IMPs in normal (d), band 3–null (e), and 4.2-null (f) RBCs. Note the presence of enlarged particle-free areas in band 3– and 4.2-null RBCs. Scale bar: 100 nm.

Previous studies revealed a near-normal membrane skeleton, qualitatively and quantitatively, in mouse band 3–null RBCs (6). Band 3–null RBC membranes are, however, ∼50% deficient in IMPs, and the IMPs that remain are clustered (Figure 4, d and e). Similar loss and clustering of IMPs, albeit less extreme, are seen in 4.2^–/– RBCs (Figure 4f). These observations support the hypothesis that membrane loss in 4.2^–/– RBCs, as in band 3–null RBCs, results from destabilization of the membrane due to a lack of horizontal lipid-protein interactions in those areas that are relatively devoid of integral membrane proteins (as visualized by the IMP distribution) within the bilayer.

Cation content and transporter activities in 4.2^–/– RBCs. The Na⁺ content is increased and K⁺ content decreased in 4.2^–/– RBCs (Figure 5, a and b). The absolute K⁺ loss exceeds the Na⁺ gain, resulting in dehydration. No significant differences were seen in 4.2^+/– RBCs compared with wild-type. To elucidate possible mechanisms involved in producing the observed cation alterations, we measured cation transporter activities and determined the passive Na⁺ and K⁺ permeabilities in 4.2^–/– and 4.2^+/– RBCs compared with wild-type RBCs.

Figure 5

Cation content and transporter activities of 4.2-deficient RBCs. Na⁺ (a) and K⁺ (b) content of RBCs. The Na⁺ content is significantly increased and the K⁺ content is significantly decreased in 4.2-null (–/–) RBCs compared with normal (+/+) RBCs. (c) Maximal activity of the RBC Na-K pump. (d) Chloride-dependent K-Cl cotransporter activity. Hatched bars show K efflux in the presence of 260 mOsm NaCl. Filled bars show Cl-dependent K⁺ efflux (difference between efflux in NaCl and Na sulfamate media, 260 mOsm). (e) Bumetanide-sensitive Na-K-2Cl cotransporter activity. (f) Gardos channel activity. (g) Amiloride-sensitive Na/H exchanger activity. (h) Passive permeability for Na⁺ and K⁺ in the presence of 1 mM ouabain, 10 μM bumetanide, and 10 μM amiloride. Filled bars, Na⁺ efflux. Hatched bars, K⁺ efflux. The observed changes in Na-K-2Cl cotransporter and Na/H exchanger rates account for the majority of the cation concentration differences seen in 4.2^–/– cells. All values X ± SD. *P < 0.05 vs. 4.2^+/+. **P < 0.01 vs. 4.2^+/+. ***P < 0.001 vs. 4.2^+/+.

The maximal rates of the Na-K pump are identical among the 3 genotypes (Figure 5c). There is a small but significant (P < 0.05) increase in the activity of the K-Cl cotransporter, defined as the Cl-dependent efflux (efflux in the presence of hypotonic NaCl minus that in Na sulfamate), in 4.2^–/– RBCs compared with normal RBCs (Figure 5d). Significant increases in the activities of the bumetanide-sensitive Na-K-2Cl cotransporter and the calcium-stimulated K⁺ efflux (Gardos) channel are seen in 4.2^–/– RBCs, with intermediate values seen in 4.2^+/– RBCs (Figure 5, e and f). An even more dramatic increase is seen in the activity of the Na/H exchanger in 4.2^–/– RBCs (Figure 5g). A small increase in the passive Na⁺ permeability is present in 4.2^–/– RBCs; no differences are seen in the passive K⁺ permeability (Figure 5h).

To determine if the increased Na/H exchange and Na-K-2Cl cotransport are due to altered regulation of these transporters, we studied the effect of volume changes by changing the osmolarity of the flux medium. As shown in Figure 6, the increased transport activities and passive Na permeability observed in 4.2^–/– RBCs are due to increased sensitivity to cell shrinkage.

Figure 6

Effect of cell shrinkage on cation transport in 4.2-deficient RBCs. Influence of cell volume on the activities of Na-K-2Cl cotransport (a), Na/H exchange (b), and Na⁺ passive permeability (c).

Mechanism of increased cation transport: a potential role for phosphorylation. Increased Na-K-2Cl cotransporter and Na/H exchanger activities correlate with a net increase in phosphorylation in a variety of cell types (33–36). To assess the phosphorylation status of 4.2-deficient RBCs, we measured the activities of the major RBC kinases. Cytosolic PKC is significantly decreased in 4.2-deficient RBCs (Table 2). Western blot analyses show decreased PKC-α and PKC-βI isoforms but normal PKC-βII (Figure 7a) in 4.2^–/– RBCs. Cytosolic protein kinase A (PKA) activity is increased in 4.2^–/– RBCs (Table 2). Consistent with the observed PKC and PKA changes, basal phosphorylation is increased and PMA-stimulated phosphorylation is reduced in 4.2^–/– RBC membranes compared with normal (Figure 7b). In addition, cytosolic casein kinase I (CKI) activity is normal in 4.2-deficient RBCs, whereas cytosolic CKII activity is decreased (Table 2). The functional significance of the latter activity, if any, is unknown.

Figure 7

PKC isozyme levels and phosphorylation of membrane skeleton proteins in 4.2^–/– RBCs. (a) Western blots of PKC isozymes in RBCs. Each lane contains equivalent amounts of cytosolic protein from 4.2-null (–/–) and normal (+/+) RBCs. Left, PKC-α; middle, PKC-βI; right, PKC-βII. (b) Basal and PMA-stimulated phosphorylation of RBC membrane skeleton proteins in normal and protein 4.2–deficient RBCs. Sp/Ank, spectrin and ankyrin. Add, adducin. 4.1, protein 4.1. 4.9, protein 4.9.

Table 2

Erythrocyte kinase activities

The activity of the major RBC membrane–bound kinase, CKI, was measured by incubating ghost membranes in the presence of [γ-³²P]ATP and excising and counting phosphorylated proteins identified by autoradiography. In 2 separate experiments, the counts obtained from 4.2^–/– membranes were significantly greater than wild-type membranes and slightly greater in heterozygous membranes. The counts obtained in one experiment are given in Table 2.

Nonerythroid pathology. Immunologically related protein 4.2 has been localized previously to platelet vesicles with the characteristics of early lysosomes, but it is absent from other intracellular organelles, including dense bodies, alpha granules, mitochondria, and Golgi (37). We show that protein 4.2 is present in normal platelets and absent from 4.2^–/– platelets (Figure 1e). This observation indicates that protein 4.2 in platelets is a product of the same gene (Epb4.2) as is erythrocyte protein 4.2. However, no abnormality of platelet number is seen in 4.2-deficient mice (platelet counts × 10³/μL; X ± SEM; n = 6: 4.2^+/+, 1,177 ± 108; 4.2^+/–, 1,150 ± 70; 4.2^–/–, 1,112 ± 130), and bleeding times do not significantly differ among the 3 groups of mice (not shown).

Histological examination of brain, spinal cord, heart, lung, liver, kidney, intestine, and muscle reveals no overt pathological changes in protein 4.2–deficient mice at 2 or 9 months of age (not shown).

Mechanism of membrane loss in HS. Two hypotheses regarding the mechanism of membrane loss in HS have been proposed (2). In the first, the lipid bilayer is stabilized by interactions with the underlying spectrin skeleton. Unsupported, spectrin-deficient areas vesiculate, leading to spherocytosis. In the second, the “lipid-anchoring” hypothesis, the bilayer is stabilized by horizontal interactions between lipids and neighboring integral membrane proteins in the bilayer. Band 3 would be expected to contribute greatly to these lipid-protein interactions, as there are ∼1.2 × 10⁶ band 3 molecules per cell, each containing 12 transmembrane loops (38). Indeed, the primary evidence for the lipid-anchoring hypothesis arose from the observation that band 3 deficiency in humans causes HS, yet the membrane skeleton spectrin content and structure are normal (2). Further evidence was provided by targeted deletion of band 3 in mice. Band 3–null mice are severely anemic and their RBCs shed membrane copiously, yet the membrane spectrin content is normal and the skeleton architecture is intact (6).

This study provides further evidence for lipid anchoring as a significant determinant of membrane stability. Protein 4.2^–/– RBCs shed membrane and become spherocytic in the presence of a normal membrane skeleton with normal spectrin content. IMP-free areas are clearly visible, suggesting that portions of the RBC membrane are relatively protein free. Presumably, the loss of IMPs in 4.2^–/– RBCs occurs secondary to partial band 3 deficiency (although we cannot strictly rule out other integral protein contributions); as a result of band 3 loss, lipid anchoring is compromised and unsupported lipids lost, resulting in spherocytosis. Spectrin- and ankyrin-deficient red cells (17) could also become spherocytic by this mechanism. Since spectrin filaments limit the lateral movement of band 3 molecules (39), a decrease in spectrin would allow band 3 molecules to cluster, leading to vesiculation. Hence, loss of lipid anchoring conceivably represents the final common pathway leading to HS in a variety of membrane skeletal protein defects.

Protein 4.2 interactions within the membrane skeleton. The studies reported here provide insights into the interactions of protein 4.2 within the membrane. The maximal DIDS inhibitory concentration is decreased to 70% of normal, confirming the decrement in the number of band 3 molecules in 4.2^–/– RBCs. Previous studies suggested that protein 4.2 negatively regulates band 3 anion transport activity. In band 3 reconstituted liposomes, anion transport activity increased with decreasing levels of bound protein 4.2 (9). In human 4.2 deficiency, normal DIDS maximal inhibitory concentration was seen, yet band 3–mediated anion transport activity was dramatically increased (7). These observations lead to the hypothesis that protein 4.2 exerts an allosteric effect upon binding to the cytoplasmic domain of band 3, which inhibits its anion transport function. Our data do not support an inverse correlation between membrane protein 4.2 content and anion transport activity in mouse RBCs, as the number of band 3 molecules in the membrane is decreased by 30%, and the overall anion transport activity by 40%, in the absence of protein 4.2.

As reported previously (26), the lateral mobility of band 3 in normal mouse RBCs is markedly restricted. In normal RBCS, ∼40% of band 3 molecules are thought to be laterally immobilized by high-affinity (i.e., long-lived) interactions between ankyrin and band 3 tetramers, whereas ∼50% of band 3 molecules are believed to be immobilized by steric hindrance between the cytoplasmic domain of band 3 and the spectrin-based membrane skeleton (26). The concordance between the band 3 lateral mobility values in normal and 4.2^–/– RBCs suggests that these interactions between band 3 and the membrane skeleton are preserved in 4.2-null RBCs. These data do not exclude the possibility, however, that weakened interactions between a fraction of band 3 molecules and the membrane skeleton are responsible for the partial loss of band 3 as protein 4.2–deficient RBCs develop in the bone marrow.

Rotational mobility data could address the extent of band 3 mobility restriction more sensitively than could the lateral mobility data presented here (26). Unfortunately, signal-to-noise considerations have prevented us from obtaining meaningful data from polarized fluorescence depletion experiments on 4.2^–/– RBCs. In future studies, we plan to use a combination of biochemical and biophysical techniques to investigate quantitatively the degree of interaction between the membrane skeleton and the various oligomerization states of band 3 in 4.2^–/– RBCs.

By SDS-PAGE analysis, the protein 4.1 content of 4.2^–/– Triton shells is significantly increased compared with normal Triton shells. In RBC ghost membranes, however, increased protein 4.1 is much less (if at all) apparent (Figures 1b and 3a). RBC ghosts include Triton-soluble GPC, a major protein 4.1 ligand. The protein 4.1 and protein 4.2 binding sites have been localized to nearby sites on the cytoplasmic domain of band 3 (40). Possibly, in the absence of protein 4.2, additional binding sites for protein 4.1 on band 3 are exposed, and protein 4.1 bound previously to GPC prior to extraction with Triton X-100 becomes bound to these additional sites.

Both protein 4.1 and GPC deficiency in humans alter red cell shape and mechanical properties (41, 42). Mechanical instability of GPC-deficient RBCs, however, is due to secondary deficiency of protein 4.1 and can be restored by reconstituting the membrane with protein 4.1 or with the protein 4.1 spectrin-actin binding domain (43). Neither GPC nor protein 4.1 is diminished in 4.2^–/– RBC membranes. Conceivably, however, a change in location of protein 4.1 could contribute to the 4.2^–/– phenotype. We feel this is unlikely based upon the following observations. Dissociation of protein 4.1 from band 3 decreases membrane deformability in studies using inside-out vesicles, presumably by increasing band 3-ankyrin interactions that, in turn, reduce the flexibility of spectrin filaments (44). Based on these data, increased protein 4.1-band 3 linkages would not be expected to decrease membrane deformability. Marked fragmentation, decreased GPC (16% of normal), and absent p55 are observed in protein 4.1–null mouse RBCs (45). Protein 4.2^–/– RBCs, however, show normal levels of p55 and GPC and are not fragmented, suggesting that the protein 4.1-GPC-p55 ternary complex is intact. It seems unlikely, therefore, that altered location of protein 4.1 contributes to the 4.2-null phenotype. However, as the relative distribution of protein 4.1 bound to band 3 and GPC in the intact 4.2^–/– RBC is unknown, additional analyses (e.g., pulse-chase analyses, binding studies) of the interactions of the major membrane skeleton components of 4.2^–/– RBCs will be required to definitively determine the role of protein 4.1, if any, in the 4.2^–/– phenotype.

Protein 4.2 in nonerythroid cells. Proteins cross-reactive with protein 4.2 antisera have been detected in platelets, melanocytes, kidney, liver, heart, and brain (19, 46, 47). Protein 4.2 mRNA has been detected upon prolonged exposure of Northern blot analyses of kidney, liver, heart, and brain (19, 47). In this study, RNase protection assays detected an unexpected protected fragment in 4.2^–/– tissues. However, we detected no pathology in the major organs of 4.2^–/– mice, suggesting that their phenotype is limited to erythroid cells. Together, these observations suggest that a protein 4.2 homologue encoded by a distinct gene is present in nonerythroid tissues.

We provide evidence that the erythrocyte protein 4.2 gene (Epb4.2) is also present in platelets, but no platelet dysfunction is seen. Additional, more quantitative analyses will be required to elicit the role of protein 4.2 in platelets.

Protein 4.2 and cation transport. RBC dehydration due to altered cation concentration is characteristic of membrane skeleton defects in humans and mice. A markedly accelerated Na-K pump rate and increased passive permeability were demonstrated in 2 different mouse mutations, spectrin-deficient sph mice and ankyrin-deficient nb mice (8). In both mutants, however, the activities of the bumetanide Na-K-2Cl and K-Cl cotransporters were normal, indicating that K⁺ loss and Na⁺ gain were not mediated by these transporters. Hence, it was concluded that the membrane skeleton plays a role in maintaining the RBC permeability barrier, and loss of membrane skeleton integrity results in increased passive permeability. As reported here, protein 4.2–deficient RBCs show normal Na-K pump activity, markedly increased Na-K-2Cl cotransporter, Na/H exchanger and Gardos channel activities, and a moderate increase in K-Cl cotransport activity. The changes in cation transport activities in 4.2^–/– RBCs cannot be attributed to the presence of younger cells. Na-K pump activity is increased in reticulocytes but shows no changes in 4.2^–/– RBCs, which may indicate that 4.2 deficiency blunts its upregulation in reticulocytes and earlier erythroid precursor cells. Moreover, sph and nb homozygous mice are characterized by much greater numbers (>50%) of circulating reticulocytes than are 4.2^–/– mice, yet K-Cl and Na-K-2Cl cotransporter activities are normal in these mutants (8). Hence, markedly different cation transport alterations occur in 4.2 deficiency compared with both spectrin and ankyrin deficiency in the mouse, suggesting that specific membrane skeleton components regulate, directly or indirectly, the activity of specific cation transporters or a subset of cation transporters.

The reduced K⁺ and increased Na⁺ contents of 4.2^–/– RBCs can be attributed to increased Na⁺ permeability and K-Cl cotransport. Increased Na-K-2Cl cotransport, which induces net loss of Na⁺ and K⁺, and Na/H exchange, which induces a net gain of Na⁺, may also contribute to the altered cation composition of 4.2^–/– RBCs. Protein 4.2^–/– RBCs also demonstrate an abnormal regulation of cation transport by cell volume. Cell shrinkage induces a more prominent activation of Na/H exchange and Na-K-2Cl cotransport in 4.2^–/– RBCs compared with controls. The increased passive Na⁺ permeability of 4.2^–/– RBCs is dependent on cell shrinkage as well (Figure 6).

The maximal rate of the Na-K pump corresponds to the number of pump sites per cell (48, 49) and is unchanged in 4.2^–/– RBCs, indicating that there is no compensatory increase in the number of pumps per cell. However, the 4.2^–/– red cell is in a different steady state compared with normal control cells. In normal cells, the activity of a fixed number of pumps depends on the internal Na⁺ level (50); increased Na⁺ permeability (inward leak) increases the activity of the Na-K pump, balancing the increased Na⁺ leak. In 4.2^–/– RBCs, the Na⁺ concentration remains elevated, despite a normal number of pumps per cell; i.e., 4.2^–/– red cell pump activity does not respond to the same level of internal Na⁺ as do normal cells.

In a recent study of human HS patients, similar cation transport alterations were reported regardless of the underlying membrane skeleton defect (7). Increased Na-K pump activity and passive cation permeabilities, decreased K-Cl cotransporter activity, and normal Na-K-2Cl cotransporter and Na/H exchanger activities were reported in patients with combined spectrin and ankyrin deficiency, band 3 deficiency, and 4.2 deficiency. These findings are markedly different than those reported in this study. One explanation may be that cation transport regulatory mechanisms differ in human and mouse RBCs. A potential molecular basis for transporter regulation differences between species has been identified in the case of the K-Cl cotransporter. Human and mouse K-Cl cotransporters share 96% amino acid conservation, but important consensus binding sites for PKC and CKII phosphorylation that are present in human cDNA are missing in the mouse (51).

The contribution of partial band 3 deficiency to 4.2^–/– mouse RBC cation transport is unknown. In band 3–null mice, protein 4.2 is also totally deficient, making it impossible to distinguish the relative band 3-protein 4.2 contributions to transporter activities using the band 3–null mouse model (6). However, in a recently described dominant band 3 mutation in humans, band 3 campinas (52), RBC Na/H exchange is increased 3- to 6-fold, while in other, unrelated cases of band 3 deficiency, Na/H exchanger activity is unchanged. Notably, the band 3 campinas mutation results in skipping of exon 8, leading to a frameshift mutation and a premature stop codon at amino acid 203 in the cytoplasmic domain. Hence, it can be predicted that bound protein 4.2 is decreased in these patients, leading to speculation that changes in the Na/H exchanger activity (and perhaps other transporters) in band 3 deficiency depends on the specific mutation and may be related to changes in membrane protein 4.2 content. To test this hypothesis in the mouse, band 3 knock-in experiments, or a similar strategy in which substitutions in the binding site for protein 4.2 are made, are required.

The mechanism by which protein 4.2 influences cation transporter activities in RBCs remains a mystery. Na-K-2Cl cotransporter activity correlates with increasing phosphorylation in shark rectal gland, vascular endothelial cells, intestinal epithelial cells, and duck and ferret RBCs (33–36). In the latter, increased Na/H exchanger activity correlates with increased phosphorylation as well. The pattern of cation transporter activities in protein 4.2–deficient mouse RBCs is consistent with an overall increase in RBC phosphorylation, and the basal phosphorylation state of membrane skeleton components in 4.2-deficient RBCs is increased. It will be of interest in future studies to determine if artificially accelerating cation transport pathways (e.g., loading cells with Na⁺ or Ca²⁺ to accelerate cotransport or the Gardos channel activity, respectively) alters RBC membrane skeleton protein phosphorylation patterns in normal cells. To determine whether any of the changes in kinase activities detected in 4.2-deficient RBCs are causally related to the changes in cation transporter rates in 4.2-null RBCs will also require further study.

We thank Alicia Rivera, Totam Nguyen, Michelle Rotter, and Laura Derick for excellent technical assistance; Roderick Bronson for tissue pathology studies; Jennifer L. Smith for computer graphics; and Nancy Wandersee and Connie Birkenmeier for critical review of the manuscript. Supported by National Institutes of Health grants DK-26263 (to N. Mohandas), HL-55321 (to L.L. Peters), DK-34083 (to S.E. Lux), HL-32262 (to S.E. Lux), HL-15157 (to C. Brugnara), HL-32854 (to D.E. Golan), HL-15157 (to D.E. Golan), and DK-50422 (to C. Brugnara); a grant from the March of Dimes (to L.L. Peters); and cancer core grant CA-34196 (to The Jackson Laboratory).

1. Korsgren, C, Cohen, CM. cDNA sequence, gene structure, and properties of murine pallidin (band 4.2), the protein implicated in the murine pallid mutation. Genomics 1994. 21:478-485.
   View this article via: PubMed CrossRef Google Scholar
2. Lux, S.E., and Palek, J. 1995. Disorders of the red cell membrane. In Blood: principles and practice of hematology. R.I. Handin, S.E. Lux, and T.P. Stossel, editors. J.B. Lippincott. Philadelphia, PA. 1701–1818.
   View this article via: PubMed Google Scholar
3. Yawata, Y. Red cell membrane protein band 4.2: phenotypic, genetic and electron microscopic aspects. Biochim Biophys Acta 1994. 1204:131-148.
   View this article via: PubMed Google Scholar
4. Korsgren, C, Cohen, CM. Associations of human erythrocyte protein 4.2. Binding to ankyrin and to the cytoplasmic domain of band 3. J Biol Chem 1988. 263:10212-10218.
   View this article via: PubMed Google Scholar
5. Golan, DE, et al. Control of band 3 lateral and rotational mobility by band 4.2 in intact erythrocytes: release of band 3 oligomers from low-affinity binding sites. Biophys J 1996. 70:1534-1542.
   View this article via: PubMed Google Scholar
6. Peters, LL, et al. Anion exchanger 1 (band 3) is required to prevent erythrocyte membrane surface loss but not to form the membrane skeleton. Cell 1996. 86:917-927.
   View this article via: PubMed CrossRef Google Scholar
7. De Franceschi, L, et al. Membrane cation and anion transport activities in erythrocytes of hereditary spherocytosis: effects of different membrane protein defects. Am J Hematol 1997. 55:121-128.
   View this article via: PubMed CrossRef Google Scholar
8. Joiner, C, et al. Increased cation permeability in mutant red blood cells with defective membrane skeletons. Blood 1995. 86:4307-4314.
   View this article via: PubMed Google Scholar
9. Malik, S, Sami, M, Watts, A. A role for band 4.2 in human erythrocyte band 3 mediated anion transport. Biochemistry 1993. 32:10078-10084.
   View this article via: PubMed CrossRef Google Scholar
10. Tybulewicz, VLJ, Crawford, CE, Jackson, PK, Bronson, RT, Mulligan, RC. Neonatal lethality and lymphopenia in mice with a homozygous disruption of the c-abl proto-oncogene. Cell 1991. 65:1153-1163.
    View this article via: PubMed CrossRef Google Scholar
11. Hooper, M, Hardy, K, Handyside, A, Hunter, S, Monk, M. HPRT-deficient (Lesch-Nyhan) mouse embryos derived from germline colonization by cultured cells. Nature 1987. 326:292-295.
    View this article via: PubMed CrossRef Google Scholar
12. Robertson, E.J. 1987. Teratocarcinomas and embryonic stem cells: a practical approach. IRL Press. Oxford, United Kingdom. 254 pp.
    View this article via: PubMed Google Scholar
13. Chomczynski, P, Sacchi, N. Single-step method of RNA isolation by acid guanidinium thiocyanate-phenol-chloroform extraction. Anal Biochem 1987. 162:156-159.
    View this article via: PubMed Google Scholar
14. Steck, TL. The organization of proteins in the human red cell membrane. J Cell Biol 1974. 62:1-19.
    View this article via: PubMed CrossRef Google Scholar
15. Laemmli, UK. Cleavage of structural proteins during the assembly of the head of bacteriophage T4. Nature 1970. 227:680-685.
    View this article via: PubMed CrossRef Google Scholar
16. Lehnert, ME, Lodish, HF. Unequal synthesis and differential degradation of α- and β-spectrin during murine erythroid differentiation. J Cell Biol 1988. 107:413-426.
    View this article via: PubMed CrossRef Google Scholar
17. Savvides, P, Shalev, O, John, KM, Lux, SE. Combined spectrin and ankyrin deficiency is common in dominant hereditary spherocytosis. Blood 1993. 82:2953-2960.
    View this article via: PubMed Google Scholar
18. Jöns, T, Drenckhahn, D. Identification of the binding interface involved in linkage of the cytoskeletal protein 4.1 to the erythrocyte anion exchanger. EMBO J 1992. 11:2863-2867.
    View this article via: PubMed Google Scholar
19. Gwynn, B, Korsgren, C, Ciciotte, S, Cohen, CM, Peters, LL. The gene encoding protein 4.2 is distinct from the mouse platelet storage pool deficiency mutation pallid. Genomics 1997. 42:532-535.
    View this article via: PubMed CrossRef Google Scholar
20. Thomas, HA, Machen, TE, Smolka, A, Baron, R, Kopito, RR. Identification of a 185-kDa band 3-related polypeptide in oxyntic cells. Am J Physiol 1989. 257:C537-C544.
    View this article via: PubMed Google Scholar
21. Hassoun, H, et al. Complete deficiency of glycophorin A in red blood cells from mice with targeted inactivation of the band 3 (AE1) gene. Blood 1998. 91:2146-2151.
    View this article via: PubMed Google Scholar
22. Peters, LL, Barker, JE. Novel inheritance of the murine severe combined anemia and thrombocytopenia (scat) phenotype. Cell 1993. 74:135-142.
    View this article via: PubMed CrossRef Google Scholar
23. Swank, RT, Reddington, M, Howlett, O, Novak, EK. Platelet storage pool deficiency associated with inherited abnormalities of the inner ear in the mouse pigment mutants muted and mocha. Blood 1991. 78:2036-2044.
    View this article via: PubMed Google Scholar
24. Liu, SC, et al. Molecular basis of altered red blood cell membrane properties in Southeast Asian ovalocytosis: role of the mutant band 3 protein in band 3 oligomerization and retention by the membrane skeleton. Blood 1995. 86:349-358.
    View this article via: PubMed Google Scholar
25. Clark, MR, Mohandas, N, Shohet, SB. Osmotic gradient ektacytometry: comprehensive characterization of red cell volume and surface maintenance. Blood 1983. 61:899-910.
    View this article via: PubMed Google Scholar
26. Yi, SJ, et al. Red cell membranes of ankyrin-deficient nb/nb mice lack band 3 tetramers but contain normal membrane skeletons. Biochemistry 1997. 36:9596-9604.
    View this article via: PubMed CrossRef Google Scholar
27. Schofield, AE, Reardon, DM, Tanner, MJA. Defective anion transport activity of the abnormal band 3 in hereditary ovalocytic red blood cells. Nature 1992. 335:836-838.
28. Wolff, D, Cecchi, X, Spalvins, A, Canessa, M. Charybdotoxin blocks with high affinity the Ca-activated K⁺ channel of Hb A and Hb S red cells: individual differences in the number of channels. J Membr Biol 1988. 196:243-252.
29. Ai, Z, Cohen, CM. Phorbol 12-myristate 13-acetate-stimulated phosphorylation of erythrocyte membrane skeletal proteins is blocked by calpain inhibitors: possible role of protein kinase. Biochem J 1993. 296:675-683.
    View this article via: PubMed Google Scholar
30. Danilov, YN, Fennell, R, Ling, E, Cohen, CM. Selective modulation of band 4.1 binding to erythrocyte membranes by protein kinase C. J Biol Chem 1990. 265:2556-2562.
    View this article via: PubMed Google Scholar
31. Jindal, HK, Ai, Z, Gascard, P, Horton, C, Cohen, CM. Specific loss of protein kinase activities in senescent erythrocytes. Blood 1996. 88:1479-1487.
    View this article via: PubMed Google Scholar
32. Manno, S, Takakuwa, Y, Nagao, K, Mohandas, N. Modulation of erythrocyte membrane mechanical function by β-spectrin phosphorylation and dephosphorylation. J Biol Chem 1995. 270:5659-5665.
    View this article via: PubMed CrossRef Google Scholar
33. O’Donnell, ME, Martinez, A, Sun, D. Endothelial Na-K-Cl cotransport regulation by tonicity and hormones: phosphorylation of cotransport protein. Am J Physiol 1995. 269:C1513-C1523.
    View this article via: PubMed Google Scholar
34. Klein, JD, Perry, PB, O’Neill, WC. Regulation by cell volume of Na(+)-K(+)-2Cl cotransport in vascular endothelial cells: role of protein phosphorylation. J Membr Biol 1993. 132:243-252.
    View this article via: PubMed Google Scholar
35. Mairbaurl, H, Herth, C. Na(+)–K(+)-2Cl- cotransport, Na+/H+ exchange, and cell volume in ferret erythrocytes. Am J Physiol 1996. 271:C1603-C1611.
    View this article via: PubMed Google Scholar
36. Lytle, C. A volume-sensitive protein kinase regulates the Na-K-2Cl cotransporter in duck red blood cells. Am J Physiol 1998. 43:C1002-C1010.
37. Hamilton, CM, Cohen, CM. Non-erythroid forms of human erythrocyte membrane protein 4.2 are found on a unique population of vesicles in platelets and cultured cell lines. Mol Biol Cell 1996. 7:434a. (Abstr.)
38. Tanner, MJA. The structure and function of band 3 (AE1): recent developments. Mol Membr Biol 1997. 14:155-165.
    View this article via: PubMed Google Scholar
39. Sheetz, MP, Schindler, M, Koppel, DE. Lateral mobility of integral membrane proteins is increased in spherocytic erythrocytes. Nature 1980. 285:510-511.
    View this article via: PubMed CrossRef Google Scholar
40. Lombardo, CR, Willardson, BM, Low, PS. Localization of the protein 4.1-binding site on the cytoplasmic domain of erythrocyte membrane band 3. J Biol Chem 1992. 267:9540-9546.
    View this article via: PubMed Google Scholar
41. Conboy, JG. Structure, function, and molecular genetics of erythroid membrane skeletal protein 4.1 in normal and abnormal red blood cells. Semin Hematol 1993. 30:58-73.
    View this article via: PubMed Google Scholar
42. Chasis, JA, Mohandas, N. Red blood cell glycophorins. Blood 1992. 80:1869-1879.
    View this article via: PubMed Google Scholar
43. Discher, DE, et al. Mechanochemistry of protein 4.1’s spectrin-actin-binding domain: ternary complex interactions, membrane binding, network integration, structural strengthening. J Cell Biol 1995. 130:897-907.
    View this article via: PubMed CrossRef Google Scholar
44. An, XL, Takakuwa, Y, Nunomura, W, Manno, S, Mohandas, N. Modulation of band 3-ankyrin interaction by protein 4.1. Functional implications in regulation of erythrocyte membrane mechanical properties. J Biol Chem 1996. 271:33187-33191.
    View this article via: PubMed CrossRef Google Scholar
45. Shi, Z-T, et al. Protein 4.1R-deficient mice are viable but have erythroid membrane skeleton abnormalities. J Clin Invest 1999. 103:331-340.
    View this article via: JCI PubMed Google Scholar
46. Risinger, MA, Derick, LH, Cohen, CM. Melanocytes cultured from pallid mice are less melanized than C57 melanocytes and demonstrate differences in pallidin (band 4.2) localization. Mol Biol Cell 1994. 5:366a. (Abstr.)
47. White, RA, et al. The murine pallid mutation is a platelet storage pool disease associated with the protein 4.2 (pallidin) gene. Nat Genet 1992. 2:80-83.
    View this article via: PubMed CrossRef Google Scholar
48. Erdmann, E, Hasse, W. Quantitative aspects of ouabain binding to human erythrocyte and cardiac membranes. J Physiol (Lond) 1975. 251:671-682.
    View this article via: PubMed Google Scholar
49. Joiner, CH, Lauf, PK. Ouabain binding and potassium transport in young and old populations of human red cells. Membr Biochem 1978. 1:187-202.
    View this article via: PubMed Google Scholar
50. Tosteson, DC, Hoffman, JF. Regulation of cell volume by active cation transport in high and low potassium sheep red cells. J Gen Physiol 1960. 44:169-194.
    View this article via: PubMed CrossRef Google Scholar
51. Pellegrino, CM, Rybicki, AC, Musto, S, Nagel, RL, Schwartz, RS. Molecular identification and expression of erythroid K:Cl cotransporter in human and mouse erythroleukemic cells. Blood Cells Mol Dis 1998. 24:31-40.
    View this article via: PubMed CrossRef Google Scholar
52. Lima, PR, Gontijo, JA, Lopes de Faria, JB, Costa, FF, Saad, ST. Band 3 campinas: a novel splicing mutation in the band 3 gene (AE1) associated with hereditary spherocytosis, hyperactivity of Na+/Li+ countertransport and an abnormal renal bicarbonate handling. Blood 1997. 90:2810-2818.
    View this article via: PubMed Google Scholar