Spectrin-actin Binding Domain Research Articles

The Human Kell Blood Group Binds the Erythroid 4.1R Protein: New Insights into the 4.1R-Dependent Red Cell Membrane Complex

Introduction: Protein 4.1R is a cytoskeletal adaptor protein that is responsible for the control of the mechanical stability of erythrocyte membranes, and for the proper anchoring of transmembrane proteins to the membrane skeletal network. Analysis of 4.1R-deficient human and murine erythrocytes revealed the complex array of membrane proteins that bind 4.1R and link these proteins to the spectrin-based skeletal network. 4.1R is composed of four functional domains: the N-terminal 30 kDa domain referred to as the FERM domain, the 16 kDa domain, the 10 kDa spectrin-actin binding domain, and the C-terminal 24 kDa domain. The Kell glycoprotein (93 kDa) is a type II single-span membrane protein which carry the Kell blood group system including the K1 (Kell) and K2 (cellano) antigens. Kell protein has endothelin-3 converting enzyme activity of type II membrane glycoproteins.In this study we have analyzed the expression of Kell blood group protein in erythrocytes from a patient with hereditary elliptocytosis associated with complete 4.1R deficiency (4.1(-) HE) and performed detailed characterization of the interaction between 4.1R and Kell glycoprotein. Furthermore we also investigated the expression of membrane proteins exhibiting blood group antigens and the functional activities of AQP1, Band 3 and RhAG in the 4.1(-) HE erythrocyte membrane.Results: Flow cytometry and western blot analyses revealed a severe reduction of Kell in the absence of 4.1R. In vitro pull down and co-immunoprecipitation experiments from erythrocyte membranes showed a direct interaction between Kell and 4.1R. Using different recombinant domains of 4.1R and the cytoplasmic domain of Kell, we demonstrated that the R46 R motif in the juxta-membrane region of Kell binds to lobe B of the 4.1R FERM domain. We also observed that 4.1R deficiency is associated with a reduction of XK and DARC proteins, the absence of the glycosylated form of the urea transporter B and a slight decrease of band 3. The functional alteration of the 4.1(-) HE erythrocyte membranes was also determined by measuring various transport activities. We documented a slower rate of HCO3-/Cl- exchange (band 3-dependent), but a normal water (AQP1-dependent) and ammonia (RhAG-dependent) transport in the absence of 4.1R.Discussion: In this study, we provide evidence for a direct interaction between Kell and 4.1R and we propose an updated model for the 4.1R- multiprotein complex in human erythrocyte (Fig 1). The lobe A in the 4.1R FERM domain binds to protein transporters such as band 3, NHE1 and UT-B. Functional and structural experiments are required to confirm the presence of UT-B in this complex. The transmembrane proteins GPC, XK, Duffy and Kell bind to the lobe B and the binding site of p55 is located in lobe C.The deficiency of blood group antigens carrying proteins in HS and HE erythrocytes can be explained by various molecular mechanisms including perturbed traffickingto the erythroblast membrane, aberrant protein sorting duringerythroblast enucleation, and selective loss during reticulocytemembrane remodelling. Establishing when and where these proteins associate during erythroid differentiation should provide mechanistic insights into membrane multi-protein complex formation in both normal and abnormal erythropoiesis.Conclusion: The findings from the present study using 4.1(-) HE human erythrocytes have enabled us to obtain novel insights into the 4.1R complex organization.Table 1Antigen and protein expression of human erythrocytes.Specific antibody binding capacity, as determined by indirect immunofluorescence using QIFIKIT calibrated beads. *Mean of fluorescence intensity given in arbitrary units.ProteinsNormal4.1(-) HEGPC54075 (± 1075)4000 (± 500)Band 3415000(±7000)317000(±6000)Kell4150 (±66)1220 (±35)CD4721300 (±1556)21000 (± 2350)Rh135200 (±283)121000 (±113)RhAG90450 (±2192)71950 (±13150)GPA357500 (±7072)310500(±12500)DARC2500 (±283)1850 (±250)CD444150 (±71)4100 (±200)UT-B*13125 (± 1968)2702 (±142)Lu/BCAM1300 (±141)1624 (±153)AQP1*256 (±15)202 (± 22)GLUT-110961 (± 239)11542 (± 806) [Display omitted] DisclosuresNo relevant conflicts of interest to declare.

Alteration Young’s moduli by protein 4.1 phosphorylation play a potential role in the deformability development of vertebrate erythrocytes

The mechanical properties of vertebrate erythrocytes depend on their cytoskeletal protein networks. Membrane skeleton proteins spectrin and protein 4.1 (4.1R) cross-link with actin to maintain membrane stability under mechanical stress. Phosphorylation of 4.1R alters the affinity of 4.1R for spectrin–actin binding and this modulates the mechanical properties of human erythrocytes. In this study, phorbol 12-myristate-13-acetate (PMA)-induced phosphorylation of 4.1R was tested, erythrocyte deformability was determined and the erythrocyte elastic modulus was detected in human, chick, frog and fish. Furthermore, amino acid sequences of the functionally important domains of 4.1R were analyzed. Results showed that PMA-induced phosphorylation of 4.1R decreased erythrocyte deformability and this property was stable after 1h. The values of Young’s modulus alteration gradually decreased from human to fish (0.388±0.035kPa, 0.219±0.022kPa, 0.191±0.036kPa and 0.141±0.007kPa). Ser-312 and Ser-331 are located within the consensus sequence recognized by protein kinase C (PKC); however, Ser-331 in zebrafish was replaced by Ala-331. The sequence of the 8 aa motif from vertebrate 4.1R showed only one amino acid mutation in frog and numerous substitutions in fish. Analyses of Young’s modulus suggested that the interaction between 4.1R with the spectrin–actin binding domain may have a special relationship with the development of erythrocyte deformability. In addition, amino acid mutations in 4.1R further supported this relationship. Thus, we hypothesize that alteration of membrane skeleton protein binding affinity may play a potential role in the development of erythrocyte deformability, and alteration of Young’s modulus values may provide a method for determining the deformability development of vertebrate erythrocytes.

Functional characterization of protein 4.1 homolog in amphioxus: Defining a cryptic spectrin-actin-binding site

Vertebrate 4.1 proteins have a spectrin-actin-binding (SAB) domain, which is lacking in all the invertebrate 4.1 proteins indentified so far, and it was therefore proposed that the SAB domain emerged with the advent of vertebrates during evolution. Here we demonstrated for the first time that amphioxus (an invertebrate chordate) protein 4.1, though lacking a recognizable SAB, was able to bind both spectrin and actin, with a binding capacity comparable to that of human protein 4.1. Detailed structure-activity analyses revealed that the unique domain U2/3 was a newly identified SAB-like domain capable of interacting with spectrin and actin, suggesting the presence of a “cryptic” SAB domain in amphioxus 4.1 protein. We also showed that amphioxus 4.1 protein gene was the common ancestor of vertebrate 4.1 protein genes, from which 4.1R, 4.1N, 4.1G, and 4.1B genes originated. This work will encourage further study on the structure-activity of invertebrate 4.1 protein and its interacting proteins.

Two different unique cardiac isoforms of protein 4.1R in zebrafish, Danio rerio, and insights into their cardiac functions as related to their unique structures

Protein 4.1R (4.1R) has been identified as the major component of the human erythrocyte membrane skeleton. The members of the protein 4.1 gene family are expressed in a tissue-specific alternative splicing manner that increases their functions in each tissue; however, the exact roles of cardiac 4.1R in the developing myocardium are poorly understood. In zebrafish (ZF), we identified two heart-specific 4.1R isoforms, ZF4.1RH2 and ZF4.1RH3, encoding N-terminal 30 kDa (FERM) domain and spectrin-actin binding domain (SABD) and C-terminal domain (CTD), separately. Applying immunohistochemistry using specific antibodies for 30 kDa domain and CTD separately, the gene product of ZF4.1RH2 and ZF4.1RH3 appeared only in the ventricle and in the atrium, respectively, in mature hearts. During embryogenesis, both gene expressions are expressed starting 24 h post-fertilization (hpf). Following whole-mount in situ hybridization, ZF4.1RH3 gene expression was detected in the atrium of 37 hpf embryos. These results indicate that the gene product of ZF4.1RH3 is essential for normal morphological shape of the developing heart and to support the repetitive cycles of its muscle contraction and relaxation.

Characterization of protein 4.1R in erythrocytes of zebrafish ( Danio rerio): Unique binding properties with transmembrane proteins and calmodulin

Cytoskeletal protein 4.1R is instrumental in regulating erythrocyte plasticity. 4.1R is comprised of four domains identified after chymotryptic digestion: an N-terminal 30 kDa domain responsible for interaction with membrane proteins, a unique domain, a spectrin-actin binding (SAB) domain, and a C-terminal domain (CTD). 4.1R 30 kDa domain interactions with transmembrane proteins are regulated by the Ca 2+/calmodulin (CaM) complex. Unlike mature mammalian erythrocytes, fish erythrocytes remain nucleated. Comparing their cytoskeleton architecture and functional properties is therefore of great interest. Here we characterized the recently cloned zebrafish ( Danio rerio, ZF) 4.1R and compared its properties with human 4.1R. We identified three ZF4.1R mRNA transcripts in erythrocytes, all characterized by exclusion of the central domains. The major transcript, referred to as BL31, included a full length 30 kDa domain (ZFR30) and parts of the unique region Ua and of CTD. Two minor transcripts, referred to as BL42 and BL56, expressed parts of ZFR30 and of the unique region Ub and full length SAB and CTD domains. Antibodies to ZFR30, ZF4.1R CTD and ZF glycophorin C (GPC) labeled the ZF erythrocyte plasma membrane. ZFR30 bound to CaM in presence or absence of Ca 2+. Resonant mirror detection binding assays revealed that ZFR30 bound to human Band3 with low K (D) (∼ 10nM), and to GPC with higher K (D) (∼ 1nM). The Ca 2+/CaM complex did not affect ZFR30 binding to Band3 and GPC. Finally, we confirmed ZFR30 binding to erythrocyte plasma membrane proteins by pulling down ZFR30 with human erythrocyte inside–out vesicles (IOV). This study defines unique structural and functional properties for ZF4.1R.

Two Protein 4.1 Domains Essential for Mitotic Spindle and Aster Microtubule Dynamics and Organization in Vitro

Multifunctional structural proteins belonging to the 4.1 family are components of nuclei, spindles, and centrosomes in vertebrate cells. Here we report that 4.1 is critical for spindle assembly and the formation of centrosome-nucleated and motor-dependent self-organized microtubule asters in metaphase-arrested Xenopus egg extracts. Immunodepletion of 4.1 disrupted microtubule arrays and mislocalized the spindle pole protein NuMA. Remarkably, assembly was completely rescued by supplementation with a recombinant 4.1R isoform. We identified two 4.1 domains critical for its function in microtubule polymerization and organization utilizing dominant negative peptides. The 4.1 spectrin-actin binding domain or NuMA binding C-terminal domain peptides caused morphologically disorganized structures. Control peptides with low homology or variant spectrin-actin binding domain peptides that were incapable of binding actin had no deleterious effects. Unexpectedly, the addition of C-terminal domain peptides with reduced NuMA binding caused severe microtubule destabilization in extracts, dramatically inhibiting aster and spindle assembly and also depolymerizing preformed structures. However, the mutant C-terminal peptides did not directly inhibit or destabilize microtubule polymerization from pure tubulin in a microtubule pelleting assay. Our data showing that 4.1 is a crucial factor for assembly and maintenance of mitotic spindles and self-organized and centrosome-nucleated microtubule asters indicates that 4.1 is involved in regulating both microtubule dynamics and organization. These investigations underscore an important functional context for protein 4.1 in microtubule morphogenesis and highlight a previously unappreciated role for 4.1 in cell division.

Plasmodium falciparum cysteine protease falcipain-2 cleaves erythrocyte membrane skeletal proteins at late stages of parasite development: Presented in part in abstract form at the 43rd Annual Meeting of the American Society of Hematology, Orlando, FL, 2001.

AbstractPlasmodium falciparum–derived cysteine protease falcipain-2 cleaves host erythrocyte hemoglobin at acidic pH and specific components of the membrane skeleton at neutral pH. Analysis of stage-specific expression of these 2 proteolytic activities of falcipain-2 shows that hemoglobin-hydrolyzing activity is maximum in early trophozoites and declines rapidly at late stages, whereas the membrane skeletal protein hydrolyzing activity is markedly increased at the late trophozoite and schizont stages. Among the erythrocyte membrane skeletal proteins, ankyrin and protein 4.1 are cleaved by native and recombinant falcipain-2 near their C-termini. To identify the precise peptide sequence at the hydrolysis site of protein 4.1, we used a recombinant construct of protein 4.1 as substrate followed by MALDI-MS analysis of the cleaved product. We show that falcipain-2–mediated cleavage of protein 4.1 occurs immediately after lysine 437, which lies within a region of the spectrin–actin-binding domain critical for erythrocyte membrane stability. A 16-mer peptide containing the cleavage site completely inhibited the enzyme activity and blocked falcipain-2–induced fragmentation of erythrocyte ghosts. Based on these results, we propose that falcipain-2 cleaves hemoglobin in the acidic food vacuole at the early trophozoite stage, whereas it cleaves specific components of the red cell skeleton at the late trophozoite and schizont stages. It is the proteolysis of skeletal proteins that causes membrane instability, which, in turn, facilitates parasite release in vivo.

Functional characterization of spectrin-actin-binding domains in 4.1 family of proteins.

Protein 4.1R is the prototypical member of a protein family that includes 4.1G, 4.1B, and 4.1N. 4.1R plays a crucial role in maintaining membrane mechanical integrity by binding cooperatively to spectrin and actin through its spectrin-actin-binding (SAB) domain. While the binary interaction between 4.1R and spectrin has been well characterized, the actin binding site in 4.1R remains unidentified. Moreover, little is known about the interaction of 4.1R homologues with spectrin and actin. In the present study, we showed that the 8 aa motif (LKKNFMES) within the 10 kDa spectrin-actin-binding domain of 4.1R plays a critical role in binding of 4.1R to actin. Recombinant 4.1R SAB domain peptides with mutations in this motif showed a marked decrease in their ability to form ternary complexes with spectrin and actin. Binary protein-protein interaction studies revealed that this decrease resulted from the inability of mutant SAB peptides to bind to actin filaments while affinity for spectrin was unchanged. We also documented that the 14 C-terminal residues of the 21 amino acid cassette encoded by exon 16 in conjunction with residues 27-43 encoded by exon 17 constituted a fully functional minimal spectrin-binding motif. Finally, we showed that 4.1N SAB domain was unable to form a ternary complex with spectrin and actin, while 4.1G and 4.1B SAB domains were able to form such a complex but less efficiently than 4.1R SAB. This was due to a decrease in the ability of 4.1G and 4.1B SAB domain to interact with actin but not with spectrin. These data enabled us to propose a model for the 4.1R-spectrin-actin ternary complex which may serve as a general paradigm for regulation of spectrin-based cytoskeleton interaction in various cell types.

Molecular and Functional Characterization of Protein 4.1B, a Novel Member of the Protein 4.1 Family with High Level, Focal Expression in Brain

Brain-enriched isoforms of skeletal proteins in the spectrin and ankyrin gene families have been described. Here we characterize protein 4.1B, a novel homolog of erythrocyte protein 4.1R that is encoded by a distinct gene. In situ hybridization revealed high level, focal expression of 4.1B mRNA in select neuronal populations within the mouse brain, including Purkinje cells of the cerebellum, pyramidal cells in hippocampal regions CA1-3, thalamic nuclei, and olfactory bulb. Expression was also detected in adrenal gland, kidney, testis, and heart. 4.1B protein exhibits high homology to the membrane binding, spectrin-actin binding, and C-terminal domains of 4.1R, including motifs for interaction with NuMA and FKBP13. cDNA characterization and Western blot analysis revealed multiple spliceoforms of protein 4.1B, with functionally relevant heterogeneity in the spectrin-actin and NuMA binding domains. Regulated alternative splicing events led to expression of unique 4. 1B isoforms in brain and muscle; only the latter possessed a functional spectrin-actin binding domain. By immunofluorescence, 4. 1B was localized specifically at the plasma membrane in regions of cell-cell contact. Together these results indicate that 4.1B transcription is selectively regulated among neuronal populations and that alternative splicing regulates expression of 4.1B isoforms possessing critical functional domains typical of other protein 4.1 family members.

Alternative splicing of protein 4.1R exon 16: ordered excision of flanking introns ensures proper splice site choice

Alternative splicing plays a major role in regulating tissue-specific expression of cytoskeletal protein 4.1R isoforms. In particular, expression of the protein's functionally critical spectrin-actin binding domain, essential for maintenance of red cell membrane mechanical properties, is governed by a developmentally regulated splicing switch involving alternative exon 16. Using a model 3-exon 4.1R pre-messenger RNA (pre-mRNA), we explored the sequence requirements for excision of the introns flanking exon 16. These studies revealed that splicing of this alternative exon occurs preferentially in an ordered fashion. The first step is excision of the downstream intron to join exons 16 and 17, followed by excision of the upstream intron. Constructs designed to test the converse pathway were spliced less efficiently and with less fidelity, in part due to activation of a cryptic 5' splice site in exon 16. This downstream-first model for ordered splicing is consistent with the hypothesis that regulated alternative splicing requires cooperation between multiple exonic and/or intronic regulatory elements whose spatial organization is critical for recruitment of appropriate splicing factors. Our results predict that exon 16 splicing is regulated at the first step-excision of the downstream intron-and that cells unable to catalyze this step will exhibit exon 16 skipping. In cells that include exon 16, adherence to an ordered pathway is important for efficient and accurate production of mature 4.1R mRNA encoding an intact spectrin-actin binding domain. (Blood. 2000;95:692-699)

Cloning and Characterization of 4.1G (EPB41L2), a New Member of the Skeletal Protein 4.1 (EPB41) Gene Family

The prototypical erythrocyte membrane skeletal protein 4.1 (HGMW-approved symbol EPB41), here designated 4.1R, is encoded by a large, complexly spliced gene located on human chromosome 1p32–p33. In this paper we report evidence for a second 4.1 gene, 4.1G (HGMW-approved symbol EPB41L2), which maps to human chromosome 6q23 and is widely expressed among human tissues. The complete nucleotide sequence of 4.1G cDNA predicts a 113-kDa protein that exhibits three regions of high homology to 4.1R, including the membrane binding domain, the spectrin–actin binding domain, and the C-terminal domain. Interspersed among the shared domains are unique sequences that may define functional differences between 4.1R and 4.1G. Specific isoforms of 4.1R and 4.1G exhibit differential subcellular localizations. These results expand the 4.1 gene superfamily and demonstrate that the diverse cellular complement of 4.1 isoforms results from both alternative splicing and expression of distinct genes.

Cell Shape-dependent Regulation of Protein 4.1 Alternative Pre-mRNA Splicing in Mammary Epithelial Cells

Expression of the complex gene encoding multiple isoforms of structural protein 4.1 is regulated by alternative pre-mRNA splicing. During erythropoiesis, developmental stage-specific inclusion of exon 16 generates protein 4.1 isoforms having a fully functional spectrin-actin binding domain. Here we show that human mammary epithelial cells (HMEC), coincident with the dramatic morphological changes induced by altered culture conditions, exhibit a novel pre-mRNA splicing switch involving a new exon (exon 17B, 450 nucleotides) in the COOH-terminal coding region. 4.1 RNA expressed in proliferating HMEC adherent to culture dishes mostly excluded exon 17B, whereas 4.1 transcripts processed in nondividing suspension cultures of HMEC strongly included this exon. This pre-mRNA splicing switch was reversible: cells transferred from poly(2-hydroxyethyl methacrylate) back to plastic resumed cell division and down-regulated exon 17B expression. More detailed studies revealed complex tissue-specific alternative splicing of exon 17B and another new exon 17A (51 nucleotides). These results predict the existence of multiple 4.1 protein isoforms with diverse COOH termini. Moreover, they strongly suggest that regulation of gene expression during differentiation of epithelial cells is mediated not only by transcriptional mechanisms, but also by post-transcriptional processes such as alternative pre-mRNA splicing.

Evolutionarily Conserved Alternative Pre-mRNA Splicing Regulates Structure and Function of the Spectrin-Actin Binding Domain of Erythroid Protein 4.1

A developmental alternative splicing switch, involving exon 16 of protein 4.1 pre-mRNA, occurs during mammalian erythropoiesis. By controlling expression of a 21-amino acid peptide required for high-affinity interaction of protein 4.1 with spectrin and actin, this switch helps to regulate erythrocyte membrane mechanical stability. Here we show that key aspects of protein 4.1 structure and function are conserved in nucleated erythroid cells of the amphibian Xenopus laevis. Analysis of protein 4.1 cDNA sequences cloned from Xenopus erythrocytes and oocytes showed that tissue-specific alternative splicing of exon 16 also occurs in frogs. Importantly, functional studies with recombinant Xenopus erythroid 4.1 demonstrated specific binding to and mechanical stabilization of 4.1-deficient human erythrocyte membranes. Phylogenetic sequence comparison showed two evolutionarily conserved peptides that represent candidate spectrin-actin binding sites. Finally, in situ hybridization of early embryos showed high expression of 4.1 mRNA in ventral blood islands and in developing brain structures. These results demonstrate that regulated expression of structurally and functionally distinct protein 4.1 isoforms, mediated by tissue-specific alternative splicing, has been highly evolutionarily conserved. Moreover, both nucleated amphibian erythrocytes and their enucleated mammalian counterparts express 4.1 isoforms functionally competent for spectrin-actin binding.

Mechanochemistry of the alternatively spliced spectrin-actin binding domain in membrane skeletal protein 4.1.

Protein 4.1's interaction with the erythroid skeletal proteins spectrin and actin and its essential role in regulating membrane strength are both attributable to expression of an alternatively spliced 63-nucleotide exon. The corresponding 21-amino acid (21-aa) cassette is within the previously identified spectrin-actin binding domain (10 kDa molecular mass) of erythroid protein 4.1. This cassette is absent, however, in several isoforms that are generated by tissue- and development-specific RNA splicing. Four isoforms of the 10-kDa domain were constructed for comparative assessment of functions particularly relevant to red cells. In vitro translated isoforms containing the 21-aa cassette, denoted 10k21 and 10k19,21, were able to bind spectrin, stabilize spectrin-actin complexes, and associate with red cell membrane. Isoforms replacing or lacking the 21-aa cassette, 10k19 and 10k0, did not function in these assays. A bacterially expressed fusion protein with glutathione-S-transferase, designated GST-10k21, congealed spectrin-actin into a network in vitro as found with purified protein 4.1. Additionally, incorporation of GST-10k21 into mechanically weak, 4.1-deficient membranes increased mechanical strength of these membranes to normal. GST-10k19 did not function in these assays. These results show that the 21-aa sequence in protein 4.1 is critical to mechanical integrity of the red cell membrane. These results also allow the role of protein 4.1 in membrane mechanics to be interpreted primarily in terms of its spectrin-actin binding function. Alternatively expressed sequences within the 10-kDa domain of nonerythroid protein 4.1 are suggested to have different, yet to be defined functions.

Genomic structure of the locus encoding protein 4.1. Structural basis for complex combinational patterns of tissue-specific alternative RNA splicing.

Protein 4.1 (P4.1) is a multifunctional protein with heterogeneity in molecular weight, intracellular localization, tissue- and development-specific expression patterns. We have analyzed the genomic structure of the locus encoding mouse P4.1 and have systematically analyzed diverse P4.1 mRNA isoforms expressed in erythroid and nonerythroid tissues. Our results indicate that the mouse protein 4.1 gene, over 90 kilobases long, comprises at least 23 exons (13 constitutive exons, 10 alternative exons) interrupted by 22 introns. The donor and acceptor splice site sequences match the consensus sequences for the exon-intron boundaries of most eukaryotic genes. No significant sequence difference was observed between splice junctions of alternative and constitutive exons. Apparently, most alternative exon-encoded peptides are located within particular functional domains of the P4.1 protein: two peptides encoded by alternative exons 4 and 5 are located near or within the glycophorin/calmodulin binding domain, whereas three other alternative exon-encoded peptides (19-amino acid encoded by exon 14, 14-amino acid encoded by exon 15, and 21-amino acid encoded by exon 16) are located near or within the spectrin-actin binding domain. Selective use of exon 2', which carries an upstream translation initiation codon (AUG), may produce an elongated P4.1 isoform (135 kDa) that is predominantly expressed in nonerythroid tissues. Combinatorial splicing of these exons may generate different isoforms that exhibit complicated tissue-specific expression patterns.

Differentiation-associated switches in protein 4.1 expression. Synthesis of multiple structural isoforms during normal human erythropoiesis.

Erythroid differentiation is accompanied by dramatic alterations in morphology and membrane mechanical properties resulting, in large part, from reorganization of the membrane skeletal protein network. The 80-kD protein 4.1 is an important organizational component of this membrane skeleton. Recently, it has been recognized that multiple structural isoforms of 4.1 are encoded by a single gene via alternative pre-mRNA splicing, and that an upstream ATG can be spliced in and used for translation of high molecular weight 4.1. We are exploring the hypothesis that differentiation-associated switches in protein 4.1 structure play an important role in membrane reorganization. To study changes in 4.1 gene expression during normal human differentiation, we analyzed 4.1 protein and mRNA structure at various developmental stages. Using immunofluorescence microscopy, we observed high molecular weight 4.1 isoforms in preproerythroblasts producing punctate, predominantly cytoplasmic staining with a perinuclear area of intense fluorescence, while mature red cells expressed very little high molecular weight 4.1. Isoforms containing an alternatively expressed 102-nucleotide exon near the COOH terminus were abundant in both preproerythroblasts and mature cells but produced a punctate distribution of fluorescence over the entire preproerythroblast and intense membrane-associated fluorescence in the erythrocyte. Characterization of RNA by polymerase chain reaction and nuclease protection assays revealed a differentiation-associated switch in pre-mRNA splicing in the spectrin-actin binding domain. Since this domain plays a critical role in regulating membrane material properties, we speculate that this switch may be crucial to reorganization of the skeletal network during erythropoiesis. We conclude that 4.1 isoforms are differentially expressed and differentially localized during erythropoiesis, and that this isoform family is likely to have diverse functions during terminal differentiation.

Hereditary elliptocytosis due to both qualitative and quantitative defects in membrane skeletal protein 4.1

Protein 4.1 is an important structural component of the membrane skeleton that helps determine erythrocyte morphology and membrane mechanical properties. In a previous study we identified a case of human hereditary elliptocytosis (HE) in which decreased membrane mechanical stability was due to deletion of 80 amino acids encompassing the entire 10-Kd spectrin-actin binding domain. A portion of this domain (21 amino acids) is encoded by an alternatively spliced exon that is expressed in late but not early erythroid cells. We now report a case of canine HE in which the abnormal phenotype is caused by failure to express this alternative peptide in the mature red blood cell (RBC) membrane skeleton, in conjunction with quantitative deficiency of protein 4.1. Western blotting of RBC membranes from a dog with HE showed a truncated protein 4.1 that did not react with antibodies directed against the alternative peptide. In addition, sequencing of cloned reticulocyte protein 4.1 cDNA showed a precise deletion of 63 nucleotides comprising this exon. Normal dog reticulocytes did express this exon. Expression of this 21 amino acid peptide during erythroid maturation is therefore essential for proper assembly of a mechanically competent membrane skeleton, because RBCs lacking this peptide have unstable membranes.

Hereditary Elliptocytosis Due To Both Qualitative and Quantitative Defects in Membrane Skeletal Protein 4.1

Protein 4.1 is an important structural component of the membrane skeleton that helps determine erythrocyte morphology and membrane mechanical properties. In a previous study we identified a case of human hereditary elliptocytosis (HE) in which decreased membrane mechanical stability was due to deletion of 80 amino acids encompassing the entire 10-Kd spectrin-actin binding domain. A portion of this domain (21 amino acids) is encoded by an alternatively spliced exon that is expressed in late but not early erythroid cells. We now report a case of canine HE in which the abnormal phenotype is caused by failure to express this alternative peptide in the mature red blood cell (RBC) membrane skeleton, in conjunction with quantitative deficiency of protein 4.1. Western blotting of RBC membranes from a dog with HE showed a truncated protein 4.1 that did not react with antibodies directed against the alternative peptide. In addition, sequencing of cloned reticulocyte protein 4.1 cDNA showed a precise deletion of 63 nucleotides comprising this exon. Normal dog reticulocytes did express this exon. Expression of this 21 amino acid peptide during erythroid maturation is therefore essential for proper assembly of a mechanically competent membrane skeleton, because RBCs lacking this peptide have unstable membranes.

Molecular analysis of insertion/deletion mutations in protein 4.1 in elliptocytosis. I. Biochemical identification of rearrangements in the spectrin/actin binding domain and functional characterizations.

Protein 4.1 (80 kD) interacts with spectrin and short actin filaments to form the erythrocyte membrane skeleton. Mutations of spectrin and protein 4.1 are associated with elliptocytosis or spherocytosis and anemia of varying severity. We analyzed two mutant protein 4.1 molecules associated with elliptocytosis: a high molecular weight 4.1 (95 kD) associated with mild elliptocytosis without anemia, and a low molecular weight 4.1 (two species at 68 and 65 kD) associated with moderate elliptocytosis and anemia. 4.1(95) was found to contain a approximately 15-kD insertion adjacent to the spectrin/actin binding domain comprised, at least in part, of repeated sequence. 4.1(68/65) was found to lack the entire spectrin-actin binding domain. The mechanical stability of erythrocyte membranes containing 4.1(95) was identical to that of normal membranes, consistent with the presence of an intact spectrin-actin binding domain in protein 4.1. In contrast, membranes containing 4.1(68/65) have markedly reduced mechanical stability as a result of deleting the spectrin-actin binding domain. The mechanical stability of these membranes was improved following reconstitution with normal 4.1. These studies have thus enabled us to establish the importance of the spectrin-actin binding domain in regulating the mechanical stability of the erythrocyte membrane.

Molecular analysis of insertion/deletion mutations in protein 4.1 in elliptocytosis. II. Determination of molecular genetic origins of rearrangements.

Protein 4.1 is an approximately 80-kD structural protein in the membrane skeleton which underlies and supports the erythrocyte plasma membrane. The preceding companion paper presents a biochemical study of two abnormal protein 4.1 species from individuals with the red blood cell disorder, hereditary elliptocytosis. These variants, "protein 4.1(68/65)" and "protein 4.1(95)," have altered molecular weights due to internal deletions and duplications apparently localized around the spectrin-actin binding domain. Here we use polymerase chain reaction (PCR) techniques to clone and sequence the corresponding mutant reticulocyte mRNAs, and correlate the deletion/duplication end points with exon boundaries of the gene. Protein 4.1(68/65) mRNA lacks sequences encoding the functionally important spectrin-actin binding domain due to a 240 nucleotide (nt) deletion spanning the codons for Lys407-Gly486. Protein 4.1(95) mRNA encodes a protein with two spectrin-actin binding domains by virtue of a 369 nt duplication of codons for Lys407-Gln529. These deletions and duplications correspond to gene rearrangements involving three exons encoding 21, 59, and 43 amino acids, respectively. The duplicated 21 amino acid exon in the 4.1(95) gene retains its proper tissue-specific expression pattern, being spliced into reticulocyte 4.1 mRNA and out of lymphocyte 4.1 mRNA.