Erythrocyte membrane protein defects in hereditary spherocytosis patients in Turkish population

Hereditary spherocytosis (HS) is a congenital hemolytic anemia which is characterized by spherocytes in peripheral blood and increased osmotic fragility test. The disease is caused by defects in red cell membrane cytoskeleton. In this study, we investigated erythrocyte membrane protein defects in 50 Turkish HS patients and 42 controls. We used sodium dodecyl sulfate polyacrylamide gel electrophoresis (SDS-PAGE) to identify the protein defects causing HS. The patients were from 27 families (39 kindred and 11 unrelated patients). They were aged between 6 months and 53 years and the mean age was 18··75 (±14··70) years. Protein deficiencies related to HS were demonstrated in 42% of study group. There was not any statistically significant relation between the protein deficiency and hemoglobin levels. Isolated or combined spectrin deficiency was the most common protein abnormality among our patients. Spectrin deficiency was detected in 22% of cases (11/50), ankyrin deficiency in 8% (4/50), protein 4··2 deficiency in 8% (4/50), combined spectrin and protein 4··2 deficiency in 2% (1/50), combined spectrin and ankyrin deficiency in 2% (1/50). Fifty-eight percent of cases (29/50) showed normal protein contents.     

Alteration of the erythrocyte membrane skeletal ultrastructure in hereditary spherocytosis, hereditary elliptocytosis, and pyropoikilocytosis

The membrane skeleton of normal erythrocytes is largely organized into a hexagonal lattice of junctional complexes (JC) crosslinked by spectrin tetramers, and occasional double tetramers and hexamers. To explore possible skeletal alterations in hereditary spherocytosis (HS), elliptocytosis (HE), and pyropoikilocytosis (HPP), we have studied the ultrastructure of the spread membrane skeletons from a subpopulation of HS patients with a partial spectrin deficiency ranging from 43% to 86% of normal levels, and in patients with HPP who, in addition to a mild spectrin deficiency, also carried a mutant spectrin that was dysfunctional, thus reducing the ability of spectrin dimers to assemble into tetramers. Membrane skeletons derived from Triton-treated erythrocyte ghosts were examined by negative staining electron microscopy. HS membrane skeletons contained structural elements, consisting of JC and spectrin filaments similar to the normal skeleton. However, less spectrin filaments interconnected the JC, and the decrease of spectrin filaments attached to JC appeared to correlate with the severity of spectrin deficiency. Only in severe HS associated with severe spectrin deficiency was the loss of spectrin sufficient enough to disrupt the overall skeletal architecture. In contrast, membrane skeletons prepared from red blood cells (RBCs) of subjects with HPP were strikingly different from HS RBCs with a comparable degree of spectrin deficiency. Although HPP RBCs were only mildly deficient in spectrin, their skeletal lattice was grossly disrupted, in contrast to only mild ultrastructural abnormalities of HS membrane skeletons with a nearly identical degree of spectrin deficiency. Skeletons from patients with common mild HE or asymptomatic carriers, carrying the mutant spectrin but having normal spectrin content, exhibited a moderate disruption of the skeletal lattice. We propose that the above differences in skeletal ultrastructure may underlie differences in the biomechanical properties and morphology of HS, HE, and HPP RBCs.     

Combined spectrin and ankyrin deficiency is common in autosomal dominant hereditary spherocytosis

The common autosomal dominant form of hereditary spherocytosis (HS) has been genetically linked to defects of the erythroid ankyrin gene in a few families; however, the frequency of ankyrin deficiency and its relationship to red blood cell (RBC) spectrin content are unknown. To test these questions, we measured RBC spectrin and ankyrin by radioimmunoassay in 39 patients from 20 families with dominant HS. Normal RBCs contained 242,000 +/- 20,500 spectrin heterodimers and 124,500 +/- 11,000 ankyrins per cell. In dominant HS, RBC spectrin and ankyrin ranged from about 40% to 100% of normal and were continuously distributed. Measurements in the same patient on different occasions were reproducible (+/- 5% to 10%) and RBCs from affected members of a kindred contained similar amounts of spectrin and ankyrin (+/- 3% to 4%). Spectrin and ankyrin levels were almost always less than the assay controls, but were less than the normal range in only 75% and 80% of kindreds, respectively. Remarkably, the degree of RBC spectrin and ankyrin deficiency was very similar in 19 of 20 HS kindreds. One otherwise typical family differed, with marked ankyrin deficiency (45% of control) and a relatively mild spectrin deficit (81%). We conclude that most patients with dominant HS have combined ankyrin and spectrin deficiency and that the two proteins are usually about equally deficient, suggesting that defects in ankyrin expression, ankyrin stability, or ankyrin band 3 (AE1) interactions may be common in dominant HS.     

Partial spectrin deficiency in hereditary pyropoikilocytosis

Hereditary pyropoikilocytosis (HPP) is a severe hemolytic anemia in which an instability of the red cell membrane skeleton has been correlated with structural and functional defects of spectrin. We now report that 13 unrelated HPP subjects have approximately 30% less spectrin than normal as evidenced by a decreased spectrin/band 3 ratio. We also examine the role of spectrin degradation as an underlying cause of this partial spectrin deficiency. Our studies demonstrate that the reduced spectrin content of HPP red cells remains constant during in vivo aging of the cells in the peripheral blood, as well as during in vitro incubation. Furthermore, immunoblotting experiments using an affinity-purified antispectrin antibody indicate that there is no loss of spectrin during membrane preparation and also that neither whole HPP red cells nor ghosts nor cytosol contains any abnormal spectrin degradation products. These data suggest that spectrin is not degraded and that it is stable on the membrane of the circulating HPP red cell. In contrast, however, incubation of free spectrin with a lysate of nucleated erythroid precursor cells indicates that HPP alpha I/46 spectrin, but not HPP alpha I/74 spectrin, is more susceptible to proteolytic degradation than a control. These data imply that the decreased spectrin content of HPP is not due to a single defect but that a more complex mechanism is involved. In HPP Sp alpha I/46 subjects, an increased proteolytic degradation in bone marrow erythroid precursors of cytosolic spectrin, prior to its assembly on the membrane, could contribute toward the partial spectrin deficiency.     

Molecular basis of spectrin and ankyrin deficiencies in severe hereditary spherocytosis: evidence implicating a primary defect of ankyrin.

While varying degrees of spectrin deficiency have been found in the majority of patients with hereditary spherocytosis (HS), a combined severe deficiency of both spectrin and the spectrin-binding protein, ankyrin, has been reported only in two patients with severe HS. To elucidate the molecular basis of these protein deficiencies, we have studied the synthesis, assembly, and the mRNA levels of spectrin and ankyrin in peripheral blood reticulocytes in one of the previously reported probands. Pulse-labeling studies showed that in HS reticulocytes, the synthesis of alpha-spectrin was comparable with control reticulocytes while that of beta-spectrin was increased about fourfold, presumably reflecting increased erythropoietic drive. On the HS reticulocyte membrane, the amount of newly assembled spectrin was reduced to about half of the control values, presumably reflecting a decrease in the synthesis of the spectrin binding protein, ankyrin: the ankyrin synthesis was nearly absent in the cytosol and the amounts of membrane-associated ankyrin were reduced to about half of the normal values. The changes in the amounts of spectrin and ankyrin mRNAs quantitated by slot blot and Northern blot analyses were comparable with changes in the synthesis of these proteins: The alpha spectrin mRNA was within a control range and the beta-spectrin mRNA was slightly increased, while the amounts of ankyrin mRNA were reduced to about 50% of control values. We conclude that the primary defect underlying the combined spectrin and ankyrin deficiency is a deficiency of ankyrin mRNA leading to a reduced synthesis of ankyrin which, in turn, underlies the decreased assembly of spectrin on the membrane.     

Molecular basis of spectrin deficiency in hereditary pyropoikilocytosis

Hereditary pyropoikilocytosis (HPP) is a recessively inherited hemolytic anemia characterized by severe poikilocytosis and red blood cell fragmentation. HPP red blood cells are partially deficient in spectrin and contain a mutant alpha or beta-spectrin that is defective in terms of spectrin self-association. Although the nature of the latter defect has been studied in considerable detail and many mutations of alpha-spectrin and beta spectrin have been identified, the molecular basis of spectrin deficiency is unknown. Here we report two mechanisms underlying spectrin deficiency in HPP. The first mechanism involves a thalassemia-like defect characterized by a reduced synthesis of alpha-spectrin as shown by studies involving synthesis of spectrin in two unrelated HPP probands and their parents: One parent carries the elliptocytogenic spectrin mutation, whereas the other parent is fully asymptomatic. Peripheral blood mononuclear cells as a source of erythroid burst-forming unit (BFUe) were cultured in a two-phase liquid culture system that gives rise to terminally differentiated erythroblasts. Pulse-labeling studies of an equal number of erythroblasts or morphologically identical maturity showed that the synthesis of alpha-spectrin as well as the mRNA levels as measured by the competitive polymerase chain reaction (PCR) method are markedly reduced in the presumed asymptomatic carriers and the HPP probands. In contrast, the synthesis and mRNA levels of beta-spectrin were normal. These results constitute a direct demonstration of an alpha-spectrin synthetic defect in a subset of asymptomatic carriers of HPP and HPP probands. The second mechanism underlying spectrin deficiency involves increased degradation of mutant spectrin before its assembly on the membrane. This is evidenced by pulse labeling studies of erythroblasts from a patient with HPP associated with a homozygous state for spectrin alpha I/46 mutation (leu-pro mutation at AA 207 of alpha-spectrin). These studies showed that although spectrin is synthesized in the cytosol in normal amounts, the rate of turnover of alpha-spectrin is faster resulting in about 40% to 50% reduced assembly of alpha-spectrin and beta-spectrin on the membrane. Thus, spectrin deficiency in this case is at least in part caused by increased susceptibility of the mutant spectrin to degradation before its assembly on the membrane. We conclude that at least two separate mechanisms underlie the molecular basis of spectrin deficiency in HPP.     

Hereditary Spherocytosis in Greece: Collective Data on a Large Number of Patients

This paper summarizes data from a haematological, biochemical, and clinical study carried out in 73 patients of Greek origin (38 non-splenectomized children and 35 adults; 17 splenectomized) with Hereditary Spherocytosis (HS). Mean haemoglobin levels in the non-splenectomized patients were significantly lower (122 ± 15 g/L) than those of the splenectomized group (144 ± 15 g/L). In all patients with HS (non-splenectomized and splenectomized adults, and children) the MCHC values (355 ± 22, 358 ± 16 and 356 ± 16 respectively) were significantly increased compared to a control group, while the percentage of microcytic and hyperchromic red cell subpopulations was significantly increased in the former group of adults. SDS-PAGE demonstrated that 29 patients (39.7%) had isolated spectrin deficiency, 22 patients (30.1%) had combined spectrin and ankyrin deficiency, 17 patients (23.3%) had band 3 deficiency and 1 patient had protein 4.2 deficiency. No quantitative biochemical defects were detected in 4 patients (5.5%). The biochemical findings did not correlate with the haematological and clinical phenotype of the disease.     

Erythropoiesis: Hereditary Spherocytosis in Greece: Collective Data on a Large Number of Patients

This paper summarizes data from a haematological, biochemical, and clinical study carried out in 73 patients of Greek origin (38 non-splenectomized children and 35 adults; 17 splenectomized) with Hereditary Spherocytosis (HS). Mean haemoglobin levels in the non-splenectomized patients were significantly lower (122 +/- 15 g/L) than those of the splenectomized group (144 +/- 15 g/L). In all patients with HS (non-splenectomized and splenectomized adults, and children) the MCHC values (355 +/- 22, 358 +/- 16 and 356 +/- 16 respectively) were significantly increased compared to a control group, while the percentage of microcytic and hyperchromic red cell subpopulations was significantly increased in the former group of adults. SDS-PAGE demonstrated that 29 patients (39.7%) had isolated spectrin deficiency, 22 patients (30.1%) had combined spectrin and ankyrin deficiency, 17 patients (23.3%) had band 3 deficiency and 1 patient had protein 4.2 deficiency. No quantitative biochemical defects were detected in 4 patients (5.5%). The biochemical findings did not correlate with the haematological and clinical phenotype of the disease.     

Hereditary elliptocytosis, spherocytosis and related disorders: consequences of a deficiency or a mutation of membrane skeletal proteins

The membrane skeleton, a protein lattice that laminates the internal side of the red cell membrane, contains four major proteins: spectrin, actin, protein 4.1 and ankyrin. By mass, the most abundant of these proteins is spectrin, a fibre-like protein composed of two chains, alpha and beta, which are twisted along each other into a heterodimer. At their head region, spectrin heterodimers are assembled into tetramers. At their distal end, these tetramers are interconnected into a two dimensional network by their linkage to oligomers of actin. This interaction is greatly strengthened by protein 4.1. The skeleton is attached to the membrane by ankyrin, a protein that connects the spectrin beta chain to the major transmembrane protein band 3, the anion channel protein. Additional attachment sites are those of protein 4.1 with several glycoproteins, namely glycophorin A and C, as well as direct interactions between spectrin, protein 4.1 and the negatively charged lipids of the inner membrane lipid bilayer. Hereditary spherocytosis, elliptocytosis and pyropoikilocytosis represent a group of disorders that are due to deficiency or dysfunction of one of the membrane skeletal proteins (Fig. 1). Known deficiency states include that of spectrin, ankyrin and protein 4.1. Severe spectrin and ankyrin deficiencies (with decrease in spectrin and ankyrin contents to about 50% of the normal amount) are both rare disorders associated with severe autosomal recessive hereditary spherocytosis. On the other hand, mild spectrin deficiency is found in the majority of patients with autosomal dominant spherocytosis in which the degree of spectrin deficiency correlates with the clinical severity of the disease. Protein 4.1 deficiency, in contrast, is associated with hereditary elliptocytosis, which in certain populations constitutes about 20% of all such patients. Known skeletal protein dysfunctions include mutants of both alpha and beta spectrin that involve the spectrin heterodimer self-association site. These are clinically expressed as hereditary elliptocytosis (HE) and a closely related disorder, hereditary pyropoikilocytosis (HPP). At the level of protein function, this defect can be detected by analysis of the content of spectrin dimers and tetramers in 0 degrees C low ionic strength extracts of red cell membranes. Their structural identification is accomplished by limited proteolytic digestion of spectrin followed by two-dimensional tryptic peptide mapping.(ABSTRACT TRUNCATED AT 400 WORDS)     

Combined ankyrin and spectrin deficiency in hereditary spherocytosis

Summary Hereditary spherocytosis is characterized by a reduced spectrin content of the erythrocytes. However, the underlying primary defect remains unclear in the majority of cases. Genetic studies have revealed a linkage to the gene for ankyrin in some families. By means of ELISA we measured the ankyrin, spectrin, and band-3 contents in erythrocytes of 45 patients with typical spherocytosis. They were classified as having mild or moderate spherocytosis, according to clinical severity. Sixteen patients with mild spherocytosis showed slight reductions of ankyrin and spectrin contents. In contrast, 29 patients with moderate spherocytosis exhibited a clear reduction of both ankyrin and spectrin to about 60% of normal. Band 3 and lipid phosphorus, as measures for membrane surface area, were only slightly reduced to 85%. Our results, together with the molecular genetic data indicating the linkage between spherocytosis and the gene for ankyrin, suggest an ankyrin defect or deficiency as the primary lesion in most cases of spherocytosis.Supported by theDeutsche Forschungsgemeinschaft (Schr. 86/18-1)     

β spectrinPRAGUE: a truncated β spectrin producing spectrin deficiency, defective spectrin heterodimer self-association and a phenotype of spherocytic elliptocytosis

Summary. Spherocytic elliptocytosis is a phenotypic hybrid between hereditary spherocytosis (HS) and hereditary elliptocytosis (HE) characterized by the presence of spheroovalocytes and spherocytes which exhibit increased osmotic fragility, indicating a deficiency of surface area. Both the spherocytic red cell morphology and the increased osmotic fragility distinguish this clinical entity from common HE. In contrast to common HE, the molecular basis of spherocytic elliptocytosis is unknown. Here we describe two members of a family who both have the characteristic features of spherocytic HE. We show that the underlying defect involves a G to C transversion at the -1 position of the acceptor splice site upstream of exon X of β spectrin leading to skipping of exon X from the mutant β spectrin mRNA allele. The mutant mRNA is present in reticulocytes in similar amounts as the normal mRNA. Pulse-labelling of erythroblasts prepared from peripheral blood in a two-phase liquid-culture system reveals a decreased synthesis of the truncated β spectrin, a finding which is likely to underlie the moderately severe spectrin deficiency in the two patients. In addition, this mutant spectrin, similar to the previously reported spectrins, is defective in spectrin heterodimer self-association. The spectrin deficiency, which represents a common finding in the majority of patients with HS, together with weakened spectrin heterodimer self-association, as found in the majority of patients with common HE, provides a molecular explanation for the phenotype of spherocytic elliptocytosis in this kindred and, most likely, in other patients carrying similar β spectrin mutations.     

Cytoskeletal behaviour in spectrin and in band 3 deficient spherocytic red cells: evidence for a differentiated splenic conditioning role

Based on quantitative analysis of red cell membrane proteins, hereditary spherocytosis (HS) can be divided into two main groups including isolated or ankyrin combined spectrin deficiency and band 3 reduction. Protein methyl esterification catalysed by protein carboxyl methyltransferase (PCMT type II; EC 2.1.1.77) is a post-biosynthetic modification which is involved in the metabolism of damaged membrane proteins. We utilized the evaluation of erythrocyte membrane protein methyl esterification as a marker of cytoskeletal disarray in seven HS subjects with spectrin reduction and in seven patients with HS due to band 3 deficiency. Our results support the notion that band 3 deficient erythrocytes are not affected by an extensive cytoskeletal derangement. On the contrary, we found a remarkable increase of membrane methylation in the unsplenectomized, spectrin-deficient, HS patients, suggesting a striking membrane skeleton disarray. This phenomenon was not observed in the spectrin-deficient red cells of splenectomized patients. Therefore in spectrin deficient erythrocytes the induction of cytoskeletal damage, specifically recognized by PCMT type II, could be one of the splenic steps producing conditioned spherocytes.     

Splenectomy prolongs in vivo survival of erythrocytes differently in spectrin/ankyrin- and band 3-deficient hereditary spherocytosis

Red cell (RBC) deformability and membrane-bound immunoglobulin G (IgG) were studied to better understand premature clearance of erythrocytes in hereditary spherocytosis. Averaged deformability profiles from cells having comparable cell age revealed that splenectomy was more beneficial for spectrin/ankyrin-deficient than for band 3-deficient RBCs. Splenectomy prevented an early loss of young cells in both types of deficiencies. It had an additional beneficial effect on spectrin/ankyrin-deficient but not band 3-deficient RBCs. It prolonged the survival of mature spectrin/ankyrin-deficient RBCs such that they lost their deformability more slowly than RBCs from patients who had not undergone splenectomy. Band 3-deficient RBCs lost their deformability at the same rate before and after splenectomy. In HS patients with band 3 deficiency who underwent splenectomy, RBC deformability inversely correlated with the number of RBC-bound IgG (up to 140 molecules per cell). In spectrin/ankyrin deficiency, RBC-bound IgG remained at control levels (60 IgG or less per cell). It appears that spectrin/ankyrin-deficient RBCs escaped opsonization by releasing band 3-containing vesicles because their band 3 content and deformability dropped in parallel with increasing cell age. Band 3-deficient RBCs did not lose band 3 with increasing cell age. Hence, it is possible that band 3 clusters required for bivalent binding of low-affinity-IgG, naturally occurring antibodies were retained in band 3-deficient RBCs with a relative excess of skeletal proteins but were released from spectrin/ankyrin-deficient RBCs, in which vesicle budding was facilitated by an impaired skeleton.     

Erythrocyte membrane protein alterations underlying clinical heterogeneity in hereditary spherocytosis

Summary. Hereditary spherocytosis (HS) is a very heterogenous condition both at clinical and biochemical level. To establish the relationship between these aspects we performed a clinical and biochemical study in 87 Italian HS subjcts. Patients were divided into three groups based on clinical severity (mild, typical and severe) and into five subgroups based on specific membrane abnormalities identified by polyacrylamide gel electrophoresis (isolated spectrin deficiency, spectrin deficiency combined with mild ankyrin reduction, spectin deficiency combined with severe ankyrin reduction, band 3 reduction and isolated protein 4.2 reduction). We were not able to assess any alteration in six HS patients. A good correlation between clinical HS forms and memberane protein defects is shown. We conclude that erythrocyte memberane analysis should be carried out after diagnosis of HS in order to predict the clinical course of the disease.     

Role of the interaction between Lu/BCAM and the spectrin‐based membrane skeleton in the increased adhesion of hereditary spherocytosis red cells to laminin

Lu/BCAM, the unique erythroid receptor for laminin 511/521, interacts with the erythrocyte membrane skeleton through spectrin binding. It has been reported that Hereditary Spherocytosis red blood cells (HS RBC) exhibit increased adhesion to laminin. We investigated the role of Lu/BCAM–spectrin interaction in the RBC adhesion properties of 2 splenectomised HS patients characterized by 40% spectrin deficiency. Under physiological flow conditions, HS RBC exhibited an exaggerated adhesion to laminin that was completely abolished by soluble Lu/BCAM. Triton extraction experiments revealed that a greater fraction of Lu/BCAM was unlinked to the membrane skeleton of HS RBC, as compared to normal RBC. Disruption of the spectrin interaction site in Lu/BCAM expressed in the transfected K562 cell line resulted in a weakened interaction to the skeleton and an enhanced interaction to laminin. These results demonstrated that the adhesion of HS RBC to laminin was mediated by Lu/BCAM and that its interaction with the spectrin‐based skeleton negatively regulated cell adhesion to laminin. Finally, the results of this study strongly suggest that the reinforced adhesiveness of spectrin‐deficient HS RBC to laminin is partly brought about by an impaired interaction between Lu/BCAM and the membrane skeleton.     

Cytoskeleton anomalies in disorders of red cell membrane proteins]

Cytoskeletal abnormalities in red cells were studied in 250 patients at our laboratory, especially on hereditary elliptocytosis (HE), hereditary spherocytosis (HS), and band 4.2 anomalies. First of all, on HE, we have found two patients of a dominantly-inherited trait of a new beta-spectrin variant with 216 kDa peptide. The contents of abnormal beta'-spectrin to the total spectrins were 7.6% in propositus, and 10.5% in her mother. As a functional abnormality, abnormal alpha beta'-spectrin dimer could not be converted to tetramer in both patients. Thus, our patients may differ from HE Nice. Secondarily, the causal relationship between red cell ankyrin and spectrin was studied on a typical HS case with abnormal chromosome, del (8p11.2-8p21.1). In this case, the deleted genetic locus was involved with loci of genes for SPH1 and ankyrin. The contents of ankyrin and other red cell membrane proteins, however, appeared to be normal on SDS-PAGE. In addition, as a unique disorder in Japan, unrelated five cases of membrane protein 4.2 deficiency were found at our laboratory. In these cases, the characteristic features were; 1) clinically uncompensated hemolysis, 2) ovalostomatocytosis, 3) markedly decreased deformability of the intact red cells by ektacytometry, if heat-treated, 4) two peptides of membrane protein 4.2 were detected in a trace amount by Western blot. Five phenotypes were categorized by Western blot, as based on the type of membrane protein 4.2 present; 1) 72 kDa peptide alone, 2) 72 kDa + 74 kDa in a trace amount, 3) 72 kDa + 74 kDa both in a trace amount, 4) 72 kDa + 68 kDa in a trace amount, and 5) complete deficiency.     

The instability of the membrane skeleton in thalassemic red blood cells

The thalassemias are a heterogeneous group of disorders characterized by accumulation either of unmatched alpha or beta globin chains. These in turn cause the intramedullary and peripheral hemolysis that leads to varying anemia. A partial explanation for the hemolysis came our of our studies on material properties that showed that beta-thalassemia (beta- thal) intermedia ghosts were very rigid but unstable. A clue to this instability came from the observation that the spectrin/band 3 ratio was low in red blood cells (RBCs) of splenectomized beta-thal intermedia patients. The possible explanations for the apparent decrease in spectrin content included deficient or defective spectrin synthesis in thalassemic erythroid precursors or globin chain-induced membrane changes that lead to spectrin dissociation from the membrane during ghost preparation. To explore the latter alternative, samples from different thalassemic variants were obtained, ie, beta-thal intermedia, HbE/beta-thal, HbH (alpha-thal-1/alpha-thal-2), HbH/Constant Spring (CS), and homozygous HbCS/CS. We searched for the presence of spectrin in the first lysate of the standard ghost preparation. Normal individuals and patients with autoimmune hemolytic anemia, sickle cell anemia, and anemia due to chemotherapy served as controls. Using gradient sodium dodecyl sulfate-polyacrylamide gel electrophoresis analysis, no spectrin was detected in identical aliquots of the supernatants of normals and these control samples. Varying amounts of spectrin were detected in the first lysate supernatants of almost all thalassemic patients. The identification of spectrin was confirmed by Western blotting using an affinity-purified, monospecific, rabbit polyclonal antispectrin antibody. Relative amounts of spectrin detected were as follows in decreasing order: splenectomized beta-thal intermedia including HbE/beta-thal; HbCS/CS; nonsplenectomized beta-thal intermedia, HbH/CS; and, lastly, HbH. These findings were generally confirmed when we used an enzyme-linked immunosorbent assay technique to measure spectrin in the first lysate. Subsequent analyses showed that small amounts of actin and band 4.1 also appeared in lysates of thalassemic RBCs. Therefore, the three major membrane skeletal proteins are, to a varying degree, unstably attached in severe thalassemia. From these studies we could postulate that membrane association of abnormal or partially oxidized alpha- globin chains has a more deleterious effect on the membrane skeleton than do beta-globin chains.     

Von Willebrand factor-cleaving protease (ADAMTS13) in thrombocytopenic disorders: a severely deficient activity is specific for thrombotic thrombocytopenic purpura

A severe deficiency in von Willebrand factor-cleaving protease (ADAMTS13) activity (< 5% that in normal plasma) has been observed in most patients with a diagnosis of thrombotic thrombocytopenic purpura (TTP) but not in those with a diagnosis of hemolytic uremic syndrome. However, ADAMTS13 deficiency has been claimed not to be specific for TTP, since it was observed in various thrombocytopenic and other conditions. We studied 68 patients with thrombocytopenia due to severe sepsis or septic shock (n = 17), heparin-induced thrombocytopenia (n = 16), idiopathic thrombocytopenic purpura (n = 10), or other hematologic (n = 15) or miscellaneous conditions (n = 10). Twelve of the 68 patients had subnormal levels of ADAMTS13 activity (相似文献   

Impact of severe ADAMTS13 deficiency on clinical presentation and outcomes in patients with thrombotic microangiopathies: the experience of the Harvard TMA Research Collaborative

The Harvard TMA Research Collaborative is a multi‐institutional registry‐based effort to study thrombotic microangiopathies (TMA). Laboratory and clinical parameters were recorded for 254 cases of suspected autoimmune thrombotic thrombocytopenic purpura (TTP). Patients with severe ADAMTS13 deficiency (activity ≤10%, N = 68) were more likely to be young, female and without a history of cancer treatment or transplantation. While all patients with severe deficiency were diagnosed with autoimmune TTP, those without severe deficiency frequently had disseminated intravascular coagulation, drug‐associated TMA and transplant‐related TMA. Patients with severe ADAMTS13 deficiency had superior overall survival at 360 d compared to those without severe deficiency (93·0% vs. 47·5%, P < 0·0001). Almost all patients with severe deficiency received therapeutic plasma exchange (TPE), but the use of TPE in patients with ADAMTS13 activity >10% varied significantly across the institutions in our consortium (13·2–63·8%, P < 0·0001). Nevertheless, 90‐d mortality was not different in patients with ADAMTS13 activity >10% between the three hospitals (P = 0·98). Our data show that patients with severe ADAMTS13 deficiency represent a clinically distinct cohort that responds well to TPE. In contrast, TMA without severe ADAMTS13 deficiency is associated with increased mortality that may not be influenced by TPE.