Adhesion of sickle red cells to endothelium: Myths and future directions

Sickle RBC are abnormally adherent to vascular endothelial cells. We briefly review the mechanisms that underlie this type of cell/cell adhesion, expose a number of extant myths about RBC adhesion, and discuss some aspects that need consideration via future experimentation. The relationship of this phenomenon of RBC-endothelial adhesion to the cytoadherence of parasitized sickle RBC is not yet clear.     

Role of Lu/BCAM in abnormal adhesion of sickle red blood cells to vascular endothelium

Lutheran (Lu) blood group and Basal Cell Adhesion Molecule (BCAM) antigens are both carried by two glycoprotein (gp) isoforms of the immunoglobulin superfamily representing receptors for laminin alpha5 chain. They are expressed in red blood cells, in endothelial cells of vascular capillaries and in epithelial cells of several tissues. Lu/BCAM gps are overexpressed in sickle red blood cells (SS RBCs). Stimulation of SS RBCs by epinephrine activates the PKA depending signaling pathway and induces reinforced Lu/BCAM-mediated adhesion to laminin10/11. We have analyzed the phosphorylation state of Lu/BCAM long isoform cytoplasmic tail and showed that it is phosphorylated by CKII, GSK3b and PKA. Phosphorylation of this isoform in transfected K562 cells is stimulated by effectors of the PKA pathway and induces cell adhesion to laminin10/11. Lu/BCAM gps are highly expressed in endothelial cells and exhibit potential integrin binding motifs. We showed that they interact with integrin alpha4beta1, the unique integrin expressed on the surface of young reticulocytes. Adhesion assays under flow conditions showed that SS RBCs adhere to primary human endothelial cells (HUVEC) after selective activation of intergin alpha4beta1 and that this adhesion is mediated by endothelial Lu/BCAM gps. Our studies show that Lu/BCAM gps expressed either on erythroid or on endothelial cells are involved in SS RBC-endothelium interactions and could play a role in the abnormal adhesion of SS RBCs to vascular endothelium contributing to the vaso-occlusive crises reported for sickle cell disease patients.     

Erythroid adhesion molecules in sickle cell disease: Effect of hydroxyurea

In sickle cell disease, the complex scenario of vaso-occlusive crisis (VOC) typical of this disease is clearly multifactorial and not fully understood. Cell-cell and cell-cell matrix interactions mediated by adhesive molecules present on blood cells and endothelial cells (ECs) are thought to play an important role. Early studies have shown that sickle red blood cells (RBCs) are abnormally adherent to ECs and some of the molecules involved in these interactions have been identified, such as the alpha4beta1 integrin and CD36, exclusively present on stress reticulocytes, and CD47 on mature RBCs. More recently, attention focused on Lu/BCAM, the unique RBC receptor for laminin, and on ICAM-4, a red cell-specific adhesion receptor, which is a ligand for a large repertoire of integrins (alphaLbeta2, alphaMbeta2, alphaxbeta2, alphaVbeta3). The counter-receptors on ECs and the role of plasma proteins forming bridges between blood cells and ECs have been clarified in part. It has also been shown that reticulocytes from SCD patients express higher levels of alpha4beta1 integrin and CD36, and that under hydroxyurea (HU) therapy, both cell adhesion to ECs or extracellular matrix proteins and the levels of these adhesion molecules are reduced. These findings are consistent with the view that enhanced adhesion of blood cells to ECs is largely determined by the membrane expression level of adhesion molecules and could be a crucial factor for triggering or aggravating vaso-occlusion. In SCD patients, membrane expression of Lu/BCAM (and perhaps ICAM-4) is enhanced on RBCs whose adherence to laminin or ECs is also increased. Interestingly, Lu/BCAM- and ICAM-4-mediated adhesion are enhanced by the stress mediator epinephrine through a PKA-dependent pathway initiated by a rise in intracellular cAMP and leading to receptor activation by phosphorylation according to the same signaling pathway. More recently, studies based on quantitative expression analysis of adhesion molecules on RBCs and during erythroid differentiation in patients undergoing HU therapy, surprisingly revealed that Lu/BCAM level was enhanced, although alpha4beta1, CD36 and ICAM-4 (to a lower extent) levels were indeed reduced. CD47 and CD147 expression were also enhanced in HU-treated patients. Based on these findings we suggest that the signalization cascade leading to receptor activation rather than the expression level only of adhesion molecules may be the critical factor regulating cell adhesion, although both mechanisms are not mutually exclusive.     

Mouse models of sickle cell disease

In the absence of a natural animal model for sickle cell disease, transgenic mouse models have been generated to better understand the complex pathophysiology of the disease and to evaluate potential specific therapies. In the early nineties, the simple addition of human globin genes induced the expression of hemoglobin S (HbS) or HbS-related human hemoglobins in mice still expressing mouse hemoglobin. To increase the proportion of human hemoglobin and the severity of the mouse sickle cell syndrome, the proportion of mouse hemoglobin could be decreased by a combination of mouse alpha- and beta-thalassemic defects, leading to complex genotypes and mild disease. Following the discovery of gene targeting in the mouse embryonic stem cells (ES cells), it was made possible to knock out all mouse adult globin genes (2alpha and 2beta) and to add the human homologous genes elsewhere in the mouse genome. In addition, the human gamma gene of fetal hemoglobin was protecting the fetus from HbS polymer formation. Accordingly, the resulting adult mouse models obtained in 1997, expressing human HbS-only, had a very severe anemia (Hb=5-6 g/dL). In order to survive, these "HbS-only mice" had to reduce the HbS concentration within the red blood cells. The phenotype could be less severe by adding modified human gamma genes, still expressed in adult mice. In 2006, a last "S-only" model was obtained by homologous knock in, replacing the mouse globin genes by human genes. This array of models contributes to better understand the role of different interacting factors in the complexity of sickle cell events, such as red cell defects, changes in blood flow and vaso-occlusion, hyperhemolysis, vascular tone dysregulation, oxidations, inflammation, activation and adhesion of cells, ischemia, reperfusion... In addition, each model has an appropriate usefulness to evaluate experimental therapies in vivo and to perform preclinical studies.     

The α4β1 integrin in sickle cell disease

The α4β1 integrin is an adhesion receptor expressed on reticulocytes in sickle cell disease (SCD) and mediates the adhesion of these cells to sub-endothelial matrix proteins and the endothelium. In this review, we describe the mechanism of activation of the α4β1 integrin on sickle reticulocytes and discuss novel roles for this integrin in SCD as a result of this activation. We also illustrate novel therapies in SCD that may target the integrin and alleviate vaso-occlusion.     

Role and regulation of sickle red cell interactions with other cells: ICAM-4 and other adhesion receptors

Erythrocytes containing primarily hemoglobin S (SS RBCs) are abnormally adherent. We now know that SS RBCs express numerous adhesion molecules, and that many of these can undergo activation. SS RBCs exposed briefly to epinephrine show markedly increased adhesion to both laminin and endothelial cells. In vivo, infusion of epinephrine-activated but not unstimulated SS RBCs causes RBC adhesion, vaso-occlusion, organ trapping, and shortened RBC survival in the circulation. Epinephrine treatment of SS RBCs before infusion also induces adhesion of murine leukocytes to vascular walls. Indeed, in vitro, SS RBCs can activate leukocyte adhesion and cytokine production. We now have demonstrated both in vitro and in vivo evidence for the importance of RBC signaling and have also shown that SS RBC adhesion is determined by genetic polymorphisms in the signaling pathway that activates adhesion. These advances will hopefully lead to new therapeutic modalities for sickle cell disease.     

Review of an in vitro microfluidic model of sickle cell vaso-occlusion

Vaso-occlusive events are responsible for the majority of morbidity and mortality in sickle cell disease. Predisposing conditions are unclear, and proximal causes have not been established. Despite decades of intense study, until recently there has not been a well-controlled in vitro model of sickle cell vaso-occlusion. We have reported the development and initial use of such a model. Our experimental device relies on microfluidic technology and has allowed the initial analysis of the in vitro process of vaso-occlusion in terms of control parameters such as driving pressure, local oxygen concentration and flow vessel size. Our work demonstrates the potential of this type of device to lead to greater understanding of vaso-occlusive pathology including the role of adhesion molecules and inflammatory factors and possibly to improvements in monitoring and searches for new treatments.     

L'adhérence des érythrocytes à l'endothélium vasculaire

Blood cells are in continuous contact with the vascular endothelium. Endothelial cell culture, intravital videomicroscopy allowed the investigation of blood cell-endothelium interactions in dynamic conditions.In the various diseases, diabetes mellitus, sickle cell anemia and malaria, erythrocytes have an increased adhesion to endothelial cells. The presence of advanced glycation end products (AGE) on erythrocytes of diabetics is responsible for their binding to the receptor RAGE present on the endothelium. The AGE-RAGE binding provokes an oxidant stress and induces the expression of the adhesion molecule. Furthermore, erythrocyte AGE induce an increase in vascular permeability. In sickle cell anemia, the increased adhesiveness and the sickling of red blood cells are responsible for thrombosis. Plasmodium falciparum infestation of erythrocytes induces knob formation at the cell surface and the P. falciparum protein binding to CD36, ICAM-1 and thrombospondin present on the endothelium, and facilitates the parasite dissemination. © 2999 Éditions scientifiques et médicales Elsevier SAS     

Adhesion of diabetic or sickle cell erythrocyte populations to human endothelium in culture

Erythrocyte adhesion to endothelium was measured using human endothelial cells in culture and a radiometric technique. Erythrocyte adhesion was found to be significantly increased in diabetes mellitus and sickle cell anemia. In both diseases the extent of adhesion was correlated with the clinical severity of the disease. Using 3H Leucine radio-labelled reticulocytes or red cells separated by density gradient according to their age it was possible to further investigate the red cell abnormality responsible for increased adhesion. A population of abnormal reticulocytes in sickle cell anemia exhibited a higher adhesion than the whole red cell population. Diabetic dense red cells (old red cells) appeared to be mostly responsible for the increase in erythrocyte adhesion to endothelium observed in diabetes mellitus.     

Modulation of Staphylococcus aureus adhesion by biofunctional copolymers derived from polystyrene

Biomaterials-centered infections are serious complications associated with the use of implants. The infection risk of biomaterials varies between different materials and is determined by the chemical composition of materials, the host proteins and the type of bacteria. In this study we measured the initial adhesion of Staphylococcus aureus onto polystyrene derivatives containing carboxylate and sulfonate groups. Five polymers were synthesized and characterized. We studied the role of the host protein fibronectin in promoting adhesion of Staphylococcus aureus. Fibronectin adsorption was comparable on all the tested polymers (pKd=7.2±0.2) whereas bacterial adhesion was dependent on surfaces chemical compositions. Polymers substituted with sulfonate groups showed the most important inhibition of initial bacterial adhesion.     

Clinical effects of different types of red cell concentrates in patients with thalassemia and sickle cell disease

The treatment of thalassemia is still essentially based on continuous transfusion supporting using red cell concentrates (RCC) prepared in different ways. For patients with sickle-cell disorders, either urgent or chronic red blood cell transfusion therapy, is widely used in the management of sickle cell disease (SCD) because it reduces HbS level and generally prevents recurrent vaso-occlusive disease (VOD). Recently, the introduction of pre-storage filtration to remove leukocytes and the use of techniques for multicomponent donation have increased the types of blood components available for transfusion purposes. The clinical effects of different types of blood components in thalassaemic and sickle-cell patients have not been extensively studied so far. We evaluated the impact of the various different blood components currently available on transfusion needs, transfusion intervals and adverse reactions in order to determine which is the most advantageous for transfusion-dependent thalassaemic and sickle-cell patients followed in our centre. We believe that the optimal characteristics of the RCC are aged less than 10 days from time of collection; Hb content greater than 56 g per unit; Hct: 55-60%; volume (including additive) 300 mL+/-20%; leucodepleted to less than 200,000 leukocytes per unit; low cytokine content (achievable by pre-storage filtration carried out between two and 24 hours after the collection); lack of microaggregates (achievable by pre-storage filtration or filtration in the laboratory) and protein content less than 0.5 g per unit for patients allergic to plasma proteins (achievable with manual or automated washing). It is still recommended that the blood transfused should be as fresh as possible, compatible with the centre's product availability and the centre's organisation should be continuously adapted to this aim. We always transfuse blood within 10 days of its collection, respecting Rh and Kell system phenotypes. Pre-storage filtration is strongly recommended, both in order to prevent adverse reactions through the marked leucodepletion (less than 200,000 leukocytes per unit) and for a better standardisation of the final product, including the certainty that the product does not contain clots, an assurance that bed-side filtration cannot give. The RCC should be produced using a method causing as little as possible stress to the red cell membrane. The use of RCC with a high content of Hb (less than 56 g per unit) is strongly recommended, because our study clearly shows that this reduces the number of exposures to donors and the number of accesses to hospital, thus improving the patient's quality of life.     

Cys shotgun labeling of macrophages adhering to and engulfing Ig-opsonized cells

A method is being developed to study cytoskeletal reorganization in cell adhesion processes. The initial model process is adhesion and phagocytosis of beads or red blood cells by macrophages. Live cell labeling with Cys reactive fluorophores is performed before and during phagocytosis with different color labeling dyes. Since Cys is a relatively hydrophobic amino acid, its differential exposure and labeling in principle reflects changes in tertiary or quaternary structure of specific proteins. Similar studies conducted on red blood cells under fluid shear conditions showed that specific domains in spectrin undergo extensible unfolding within sheared cells. The initial work here with macrophages also suggests some structural changes in phagocytosis although the proteins and specific sites have yet to be identified.     

LW protein: a promiscuous integrin receptor activated by adrenergic signaling.

The LW blood group antigen glycoprotein, although part of the Rh macromolecular complex, is nonetheless a member of the intercellular adhesion molecule (ICAM) family. Thus, while it is only rarely clinically important in the setting of transfusion and pregnancy, LW is likely to contribute to red cell adhesion in a variety of settings, including during hematopoiesis, as well as in vascular disorders. The best documentation of a pathophysiological role for LW in human disease is in sickle cell disease, where it contributes to red cell adhesion to endothelial cells and the development of vaso-occlusion, the hallmark of that disease. LW may also contribute to other intravascular processes, such as both venous and arterial thrombosis, due to its ability to interact with both activated platelets as well as leukocytes. The evidence that LW itself can undergo activation on red cells holds promise that pharmacotherapeutic maneuvers may be found to prevent such pathophysiologic interactions.     

Red cell transfusion in medicine: Future challenges

Many side-effects of red blood cell transfusion have been described. They include iron-overload, as well as allo- and autoantibody formation against red cells. During storage, erythrocytes undergo complex structural and biochemical changes. It has been suggested that accelerated and/or aberrant forms of the physiological erythrocyte aging process underlie the red cell storage lesion. This storage lesion may contribute to side-effects of transfusion as endothelial damage by release of internal erythrocyte constituents, (pro)inflammatory consequences, hampered microcirculation and oxygen delivery. Understanding the process that determines the fate of red blood cells after transfusion may contribute to the prevention of side-effects after red blood cell transfusion. This should be the focus of research on red blood cell transfusion in clinical transfusion medicine.     

Rosetting in Plasmodium falciparum: A cytoadherence phenotype with multiple actors

The capacity of Plasmodium falciparum-infected red blood cells to bind uninfected red blood cells (“rosetting”) has been associated with high parasite density in numerous geographic areas and with severe malaria in African children. We summarize here the associations that have emerged from field studies and describe the various experimental models of rosetting that have been developed. A variety of erythrocyte receptors, several serum factors and a number of rosette-mediating PfEMP1 adhesins have been identified. Several var genes code for rosette-forming PfEMP1 adhesins in each P. falciparum genome, so that each clonal line has the capacity to generate distinct types of rosettes. To clarify their respective role in malaria pathogenesis, each of the multiple ligand/receptor interactions should be further studied for fine specificity, binding affinity and the impact of the large population polymorphism of the parasite variant repertoires should be assessed. Interestingly, some major human erythrocyte surface polymorphisms have been identified as affecting rosette formation, consistent with a role for rosetting in life-threatening falciparum malaria.     

Endothelial signalling by Ig-like cell adhesion molecules

Leukocyte transendothelial migration is controlled by chemokine-induced signalling in leukocytes and integrin-ligand-induced bidirectional signalling in both leukocytes and endothelial cells. It is now generally accepted that endothelial signalling following leukocyte adhesion, serves to facilitate the crossing of the endothelium, be it via the paracellular or transcellular route. This brief overview discusses the main findings within this area and highlights some recent findings that shed new light on adhesion-induced signalling in the context of leukocyte transendothelial migration.     

Clinical correlation of positive direct antiglobulin tests in patients with sickle cell disease

Serologic findings of immune-mediated hemolytic anemia (autoimmune hemolytic anemia and cold agglutinin disease) are not infrequent in patients with sickle cell disease and can he clinically significant. Features of sickle cell disease that may affect the emergence and intensity of immune-mediated hemolysis include the antigenic stimulation of chronic red blood cell (RBC) transfusions, increased autoantibody production, RBC membrane defects, and functional asplenism. We describe two patients with sickle cell disease and serologic findings of autoimmune hemolytic anemia, but only one had increased RBC destruction attributed to the autoantibody. That patient's RBCs had IgG and complement on the surface, while those of the other patient had IgG without complement. Functional asplenism may diminish the role of an IgG autoantibody that does not hind complement, since RBCs coated with complement are removed by the liver. Therefore, complement-binding autoantibodies may have particular significance in immune-mediated hemolysis in patients with sickle cell disease.     

The red cell LW blood group protein is an intercellular adhesion molecule which binds to CD11/CD18 leukocyte integrins

Leukocyte adhesion involves the leukocyte-specific integrins CD11a/CD18, CD11b/CD18 and CD11c/CD18, which bind to intercellular adhesion molecules (ICAM). Three ICAM have been described, and are expressed on leukocytes and various other cells, but are absent from red cells. Here, we show that the red cell Landsteiner-Wiener (LW) blood group glycoprotein is an ICAM which binds to the leukocyte-specific integrins. This finding has important implications in red cell physiology.     

Erythrophagocytosis in sickle cell anemia: statistical evidence for a biological phenomenon

The precise role of erythrophagocytosis in sickle cell disease is not known. Using hematological data from three studies and 791 subjects comprising of eight epidemiological groups, we found a strong statistical support for the hypothesis that erythrophagocytosis is increased in sickle cell trait, that neutrophils and lymphocytes are the most likely cells involved in erythrophagocytosis in these subjects and that increased erythrophagocytosis may for a mechanistic explanation for an increased risk of vaso-occlusive crisis in sickle cell trait. Statistically, erythrophagocytosis was not increased in subjects with homozygous sickle cell disease. Our findings offer an interesting mechanistic implication about the presence of a strong autoimmune component of sickle cell trait that can be explained by the well recognized interplay between the receptor molecule signal regulatory protein-alpha (SIRP-alpha) on the phagocyte and its ligand, CD47, on the red blood cell. Our findings also support further and closer evaluation of the other hypothesized mechanisms by which neutrophils and lymphocytes partake in differential degree of erythrophagocytosis in subjects heterozygous for the sickle hemoglobin. Finally, translation of these findings into a clinical realm suggests that the extent of erythrophagocytosis, as measured by peripheral blood hematological indicators, can serve as an important indicator of the likelihood of future vaso-occlusive crisis events in subjects of sickle cell trait.     

Conception, élaboration et caractérisation de matériaux bioactifs

One promising strategy to control the interactions between biomaterial surfaces and attaching cells involves grafting of adhesion peptides as RGD peptides (R: arginine; G: glycine; D: aspartic acid) to materials on which protein adsorption, which mediates unspecific cell adhesion, is essentially suppressed. This review gives an overview of RGD modified materials, that have been used for cell adhesion, and provides information about technical aspects of RGD immobilization on materials. The impacts of RGD peptide surface density, spatial arrangement as well as integrin affinity and selectivity on cell responses like adhesion and migration are discussed. We have tried to relate one of numerous scientifics adventures initiated by Charles Baquey within our laboratory. This review is dedicated to him for his enthusiasm in the development of project and for his wish of always leading of a professional blooming of his students.