Mutations in the murine erythroid α-spectrin gene alter spectrin mRNA and protein levels and spectrin incorporation into the red blood cell membrane skeleton

Wandersee, Nancy J.; Birkenmeier, Connie S.; Bodine, David M.; Mohandas, Narla; Barker, Jane E.

doi:10.1182/blood-2002-01-0113

Cited by 23 publications

(28 citation statements)

References 45 publications

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“…Thus, sph 3J and sph 4J mutations located to novel positions within Spna1 compared with previously described sph alleles ( Figure 1B). 2,6,21,42,43 Severe hemolytic anemia in sph 3J and sph 4J sph 3J and sph 4J homozygotes displayed characteristics of severe hemolytic anemia. The RBC count, hemoglobin, and hematocrit values were significantly decreased (Table 1), whereas the percentage reticulocytes and spleen weights were dramatically increased, indicating a compensatory acceleration of erythropoiesis (Table 2).…”

Section: Identification Of Mutant Micementioning

confidence: 99%

“…Unlike normal spleens, mutant spleens were devoid of iron ( Figure 3C), likely reflecting extensive use as the result of markedly accelerated erythropoiesis, consistent with other mouse models with severe anemia. 2 Differential alterations in membrane skeletal proteins in sph 3J and sph 4J mice Quantitative SDS-PAGE and Western blot analysis of RBC membrane skeletal proteins in severely anemic mice is complicated by 43 ; sph Dem has an in-frame deletion of exon 11 that deletes 46 amino acids from repeat 5 21 ; sph 2BC has a guanine to thymine substitution in intron 41 that results in a frame shift and premature stop codon in repeat 19 42 ; sph 1J is a deletion of the C-terminal 13 amino acids 42 ; sph 3J is a missense mutation in repeat 19 of the ␣␤-spectrin dimer nucleation site; sph 4J is a missense mutation in the C-terminus within the EF-hand domain just upstream of sph 1J deletion; and sph Ihj is a premature stop codon in repeat 18. (C) The sph 3J mutation creates an RsaI recognition site that was used to genotype mice after PCR amplification.…”

Section: Histopathology Confirms Extreme Hemolysis In Mutant Micementioning

confidence: 99%

“…39 We can only speculate as to why band 3 deficiency was not detected in previous studies of the sph mutants upon SDS-PAGE. 2,20,21,42 A likely contributing factor is improved SDS-PAGE techniques and, in the past, reliance on discontinuous Laemmli gels for mouse studies, which often fail to clearly delineate band 3 protein upon Coomassie blue staining. 21 In many cases, band 3 was the standard to which everything else was compared.…”

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Analysis of novel sph (spherocytosis) alleles in mice reveals allele-specific loss of band 3 and adducin in α-spectrin–deficient red cells

Robledo

Lambert

Birkenmeier

et al. 2010

Blood

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Five spontaneous, allelic mutations in the ␣-spectrin gene, Spna1, have been identified in mice (spherocytosis [sph], sph 1J , sph 2J , sph 2BC , sph Dem ). All cause severe hemolytic anemia. Here, analysis of 3 new alleles reveals previously unknown consequences of red blood cell (RBC) spectrin deficiency. In sph 3J , a missense mutation (H2012Y) in repeat 19 introduces a cryptic splice site resulting in premature termination of translation. In sph Ihj , a premature stop codon occurs (Q1853Stop) in repeat 18. Both mutations result in markedly reduced RBC membrane spectrin content, decreased band 3, and absent ␤-adducin. Reevaluation of available, previously described sph alleles reveals band 3 and adducin deficiency as well. In sph 4J , a missense mutation occurs in the C-terminal EF hand domain (C2384Y). Notably, an equally severe hemolytic anemia occurs despite minimally decreased membrane spectrin with normal band 3 levels and present, although reduced, ␤-adducin. The severity of anemia in sph 4J indicates that the highly conserved cysteine residue at the C-terminus of ␣-spectrin participates in interactions critical to membrane stability. The data reinforce the notion that a membrane bridge in addition to the classic protein 4.1-p55-glycophorin C linkage exists at the RBC junctional complex that involves interactions between spectrin, adducin, and band 3. (Blood. 2010;115:1804-1814) IntroductionThe membrane skeleton, a multiprotein complex attached to the cytoplasmic surface of the red blood cell (RBC) lipid bilayer, is critical to RBC strength and deformability. 1 The major component of the skeleton, spectrin, consists of ␣ and ␤ subunits, encoded in mice by the Spna1 and Spnb1 genes, respectively. 2 Spectrin tetramers are cross-linked into a 2-dimensional hexagonal array by short actin protofilaments at "junctional complexes," which also include protein 4.1, dematin (protein 4.9), adducin, tropomyosin, tropomodulin, and p55. 3 The spectrin array is attached to the overlying plasma membrane by ankyrin, which binds ␤-spectrin to the integral membrane protein band 3 (anion exchanger, SLC4A1), and by protein 4.1-p55-glycophorin C interactions at the junctional complexes. The structural components and function of the RBC membrane skeleton have been comprehensively reviewed elsewhere. 2,[4][5][6][7] Each spectrin molecule is composed of a series of approximately 106 amino acid repeats that fold into triple helices; ␣-spectrin contains 21 numbered repeats, although repeat 10 is actually an SH3 domain, and ␤-spectrin contains 16 repeats. 6 ␣-and ␤-spectrin align side-to-side ("nucleate") in an antiparallel manner to form heterodimers. 8 Repeats 18 to 21 at the C-terminus of ␣-spectrin and repeats 1 to 4 at the N-terminus of ␤-spectrin form the nucleation site that initiates "zippering" of the 2 subunits together via electrostatic interactions. 6,9,10 Heterodimers selfassociate to form heterotetramers, the major form of spectrin in RBCs. The self-association site is at opposite ends of the respective nucleation si...

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Section: Identification Of Mutant Micementioning

confidence: 99%

Section: Histopathology Confirms Extreme Hemolysis In Mutant Micementioning

confidence: 99%

mentioning

confidence: 99%

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Analysis of novel sph (spherocytosis) alleles in mice reveals allele-specific loss of band 3 and adducin in α-spectrin–deficient red cells

Robledo

Lambert

Birkenmeier

et al. 2010

Blood

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“…There was no binding to GST or to other spectrin fragments. The ␣17-C construct comprises repeats 17,18,19,20,21, and the C-terminal element with four EF-hands. We next examined the binding of FIa1 to all these parts of the large fragment individually and obtained a positive result for only one of them.…”

Section: Mapping the Pfemp3 Binding Site In Spectrin-mentioning

confidence: 99%

“…In contrast to the ␤-spectrin N terminus, very little is known regarding the ␣-spectrin C terminus that is in apposition to the ␤-spectrin N terminus. Studies from sph J mice (where a nonsense mutation in exon 52 of the erythroid ␣-spectrin gene eliminates the C-terminal 13 amino acids) strongly suggested the ␣-spectrin C terminus is also critical to the stability of the junctional complex (21).…”

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Plasmodium falciparum Erythrocyte Membrane Protein 3 (PfEMP3) Destabilizes Erythrocyte Membrane Skeleton

Pei

Guo

Coppel

et al. 2007

Journal of Biological Chemistry

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Plasmodium falciparum erythrocyte membrane protein 3 (PfEMP3) is a parasite-derived protein that appears on the cytoplasmic surface of the host cell membrane in the later stages of the parasite's development where it associates with membrane skeleton. We have recently demonstrated that a 60-residue fragment (FIa1, residues 38 -97) of PfEMP3 bound to spectrin. Here we show that this polypeptide binds specifically to a site near the C terminus of ␣-spectrin at the point that spectrin attaches to actin and protein 4.1R in forming the junctions of the membrane skeletal network. We further show that this polypeptide disrupts formation of the ternary spectrin-actin-4.1R complex in solution. Importantly, when incorporated into the cell, the PfEMP3 fragment causes extensive reduction in shear resistance of the cell. We conjecture that the loss of mechanical cohesion of the membrane may facilitate the exit of the mature merozoites from the cell.The intraerythrocytic form of Plasmodium falciparum, the agent of the most severe type of human malaria, exports many (according to a proteomic estimate, up to 400) proteins into the host cell in the course of its growth and development (1-3). Certain of these proteins are known to associate with the host cell membrane skeleton and thereby modify its structure and properties. Among the changes that have been reported are an altered morphology, an increased membrane rigidity, and an enhanced propensity to adhere to the vascular endothelium (4). Several such proteins that bind to the red cell membrane skeleton have so far been characterized. When the parasite first invades red cells, it deposits RESA (the ring parasite-infected erythrocyte surface antigen) at the membrane skeleton of the newly invaded cell where it binds to spectrin and protects against thermal damage (5-7). As the intracellular parasite further matures, it traffics further proteins to the skeleton. P. falciparum erythrocyte membrane protein 1, or PfEMP1, 2 is inserted into the red cell membrane and its extracellular domain adheres to receptors on endothelial cells (8). PfEMP1 clusters on the red cell surface at dimpled areas called knobs by binding of its intracellular domain to the parasite-encoded protein KAHRP (knob-associated histidine-rich protein) from which knobs are formed (9) and to spectrin and actin (10). KAHRP itself is stabilized at the membrane by interactions with the fourth repeat of spectrin ␣-chain (11). MESA (the mature parasite-infected erythrocyte surface antigen) binds to the 30-kDa domain of protein 4.1R and displaces the host protein p55 (12, 13). Its role in parasite biology is still uncertain, but interference with MESA binding is lethal to the parasite (14). The P. falciparum erythrocyte membrane protein 3 (PfEMP3), with which we are concerned here, is a large protein of 315 kDa that is expressed from the late ring stage onward and is exported via the Maurer's clefts, vesicular structures of parasite origin, into the cytoplasm of the red cell, where it associates with membrane skeleton. H...

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Spectrin repeat proteins in the nucleus

Young

Kothary

2005

Bioessays

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Spectrin repeat sequences are among the more common repeat elements identified in proteins, typically occurring in large structural proteins. Examples of spectrin repeat-containing proteins include dystrophin, alpha-actinin and spectrin itself--all proteins with well-demonstrated roles of establishing and maintaining cell structure. Over the past decade, it has become clear that, although these proteins display a cytoplasmic and plasma membrane distribution, several are also found both at the nuclear envelope, and within the intranuclear space. In this review, we provide an overview of recent work regarding various spectrin repeat-containing structural proteins in the nucleus. As well, we hypothesize about the regulation of their nuclear localization and possible nuclear functions based on domain architecture, known interacting proteins and evolutionary relationships. Given their large size, and their potential for interacting with multiple proteins and with chromatin, spectrin repeat-containing proteins represent strong candidates for important organizational proteins within the nucleus. Supplementary material for this article can be found on the BioEssays website (http://www.interscience.wiley.com/jpages/0265-9247/suppmat/index.html).

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Mutations in the murine erythroid α-spectrin gene alter spectrin mRNA and protein levels and spectrin incorporation into the red blood cell membrane skeleton

Cited by 23 publications

References 45 publications

Analysis of novel sph (spherocytosis) alleles in mice reveals allele-specific loss of band 3 and adducin in α-spectrin–deficient red cells

Analysis of novel sph (spherocytosis) alleles in mice reveals allele-specific loss of band 3 and adducin in α-spectrin–deficient red cells

Plasmodium falciparum Erythrocyte Membrane Protein 3 (PfEMP3) Destabilizes Erythrocyte Membrane Skeleton

Spectrin repeat proteins in the nucleus

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