RÉSUMÉ
α-Gal, the main xenotransplantation antigen, can lead to hyperacute rejection (HAR) in xenotransplantation. This study was purposed to investigate the effect of recombinant α-galactosidase (α-Gal antigen) on the Holstein-Friesian(H-F) red blood cells (RBC). The enzymelysis method was used to digest the α-Gal antigen on H-F RBC; the saline and anti-human globulin methods were used to perform the agglutination test of H-F RBC and human plasma; the flow cytometry was used to detect the α-Gal antigen on surface of H-F RBC, fluorescence intensity of FITC-IB4 and FITC-IgG labeled RBC. The results indicated that the saline and anti-human globulin method showed α-galactosidase-treated H-F RBC fail to agglutinate with human pooled plasma; the flow cytometry showed the fluorescence intensity of FITC-IB4 and FITC-IgG labeled RBC decrease 99.0% and 87.8%, respectively. It is concluded that the novel α-galactosidase can be used to cleared the α-Gal antigen on the surface of H-F RBC and α-galactosidase-treated H-F RBC may be considered as human blood substitute.
Sujet(s)
Animaux , Bovins , Femelle , Humains , Substituts sanguins , Érythrocytes , Allergie et immunologie , Transplantation hétérologueRÉSUMÉ
The aim of this study was to investigate the effect of alanine solution as α-N-acetylgalactosaminidase enzyme reaction buffer on the enzymatic activity of A antigen. The binding ability of α-N-acetylgalactosaminidase with RBC in different reaction buffer such as alanine solution, glycine solution, normal saline (0.9% NaCl), PBS, PCS was detected by Western blot. The results showed that the efficiency of A to O conversion in alanine solution was similar to that in glycine solution, and Western blot confirmed that most of enzymes blinded with RBC in glycine or alanine solution, but few enzymes blinded with RBC in PBS, PCS or normal saline. The evidences indicated that binding of enzyme with RBC was a key element for A to O blood group conversion, while the binding ability of α-N-acetylgalactosaminidase with RBC in alanine or glycine solution was similar. It is concluded that alanine solution can be used as enzyme reaction buffer in A to O blood group conversion. In this buffer, the α-N-acetylgalactosaminidase is closely blinded with RBC and α-N-acetylgalactosaminidase plays efficient enzymatic activity of A antigen.
Sujet(s)
Humains , Système ABO de groupes sanguins , Allergie et immunologie , Alanine , Groupage sanguin et épreuve de compatibilité croisée , Méthodes , Solutions , alpha-N-Acetylgalactosaminidase , Allergie et immunologieRÉSUMÉ
αGal, a xenotransplantations antigen (XTA), can lead to hyper acute reaction (HAR) in xenotransplantation. α-Galactosidase from B. fragilis is a novel galactosidase belong to CAZy GH110 which can clear the terminal αGal from branched and linear oligosaccharides. This study was purposed to investigate the removal effect of a novel α-galactosidase on α-Gal XTA on surface of red blood cells. The αGal XTA from the red blood cells of cattle, pig, dog and rabbit was digested by using recombinant α-galactosidase; the α-Gal antigens on surface of cells was detected by flow cytometry. The results showed that the XTA was disappeared completely or mainly. It is concluded that the novel α-galactosidase is a potential enzyme to remove the XTA on the surface of xenotransplants and can be used to overcome the HAR in xenotransplantation.
Sujet(s)
Animaux , Bovins , Chiens , Souris , Lapins , Antigènes hétérophiles , Allergie et immunologie , Épitopes , Érythrocytes , Allergie et immunologie , Macaca mulatta , Souris de lignée BALB C , Suidae , Transplantation hétérologue , alpha-Galactosidase , Allergie et immunologieRÉSUMÉ
This study was aimed to prepare a reconstructed B. Fragilis-derived recombinant α-galactosidase developed for human B to O blood group conversion. Based on the construction of recombinant E. Coli (DE3) which can express α-galactosidase, the inducing time and inducer concentration were optimized for high expression of α-galactosidase. Then, the expression products in supernatant were purified by cation and anion exchange column chromatography. The purified α-galactosidase was used to treat B group red blood cells in phosphate buffer (pH 6.8) for 2 hours to prepare O group red blood cells. The results showed that the optimal inducing conditions for α-galactosidase expression were IPTG 0.1 mmol/L, 37°C and 2 hours. The specific enzyme activity of purified protein increased from 0.42 U/mg to 2.1 U/mg as compared with pre-purification. And, the conditions of B to O blood group conversion were 26°C, pH 6.8 (neutral pH condition) and 2 hours. Moreover, 225 µg of the enzyme could converse 1 ml B red blood cells to O completely. It is concluded that the technology of expression and purification of recombinant α-galactosidase has been established, and the purified protein can converse B red blood cells to O completely, which means that an effective enzyme conversing B red blood cells to O has been obtained.
Sujet(s)
Humains , Système ABO de groupes sanguins , Allergie et immunologie , Bacteroides fragilis , Clonage moléculaire , Escherichia coli , Métabolisme , Protéines recombinantes , alpha-GalactosidaseRÉSUMÉ
<p><b>BACKGROUND</b>Human group O red blood cells have great benefit in specialized transfusion areas such as armed conflict and natural calamity. The group B antigen differs structurally from group O antigen only by the addition of one terminal alpha-linked galactose residue. In this study we aimed to remove the terminal galactose from group B red blood cell to get group O red blood cell.</p><p><b>METHODS</b>alpha-galactosidase cDNA was cloned by RT-PCR from Catimor coffee beans grown on Hainan Island of China. The vector for alpha-galactosidase cDNA expression was constructed and transferred into Pichia pastoris cells by electroporation. The transgenic cells were cloned by fermentation and the recombinant alpha-galactosidase was purified by ion exchange chromatography. After studying the biochemical characters of alpha-galactosidase, we have used it in converting human erythrocytes from group B to group O.</p><p><b>RESULTS</b>The purity of recombinant alpha-galactosidase was higher than 96%, which was thought to be suitable for the use of blood conversion. Enzymatically converted human group O red blood cells (ECHORBC) exhibited membrane integrity, metabolic integrity, normal cell deformation and morphology. There were no coagulation between ECHORBC and any group of human blood. The ECHORBC will keep normal structure and function for a period of 21 days at 4 degrees C in monoammoniumphosphate nutrient solution. Experiments with Rhesus monkeys and gibbons showed that transfusion of enzymatically converted erythrocytes was safe.</p><p><b>CONCLUSION</b>ECHORBC can be easily obtained from group B red blood cell by alpha-galactosidase digestion. This study suggests that ECHORBC could be transfused to patients safely and efficiently.</p>
Sujet(s)
Animaux , Humains , Système ABO de groupes sanguins , Classification , Métabolisme , Transfusion sanguine , Clonage moléculaire , Café , Érythrocytes , Métabolisme , Macaca mulatta , Contrôle de qualité , Protéines recombinantes , Pharmacologie , alpha-Galactosidase , Allergie et immunologie , Pharmacologie , ToxicitéRÉSUMÉ
This study was aimed to investigate the survival rate and difference of transfused modified and unmodified RBC at 24 hours. The modified and unmodified RBC from mice, monkey, pig and human were labeled by using FITC, then these blood RBCs were transfused to homogeneous and heterogeneous animals. The result showed that 24 hour survival rate of unmodified mice RBC transfused to mice was 74%, while survival rate of 2.0 mmol/L mPEG-SPA modified mice RBC transfused to mice was 45%, difference between them was significant. The 24 hour survived rate of unmodified human RBC transfused to mice was 8%, while 24 hours survival rate of 2.0 mmol/L mPEG-SPA modified human RBC transfused to mice was 5% without statistical difference. The 24 hour survived rate of homogeneous transfusion of modified monkey RBC was 90%, while survival rate of modified human and pig RBC was zero on 24 hours after transfusion to monkey. It is concluded that RBC labeling methods and mice species are unrelated to 24 hours survival rate, but mPEG variety and concentration are related to mouse RBC life-span. It is incredible to use mouse RBC homogeneous transfusion result instead of human RBC to evaluate longevity and safety of modified human RBC. But modified human RBC transfused to mice can be a model to evaluate longevity of modified human RBC. It is very difficult to get the result about modified RBC life span by RBC transfusion among great heterogeneous mammal animals. So evaluation in large mammal animal models needs to be further studied.
Sujet(s)
Animaux , Humains , Mâle , Souris , Survie cellulaire , Transfusion d'érythrocytes , Méthodes , Macaca mulatta , Polyéthylène glycols , Pharmacologie , SuidaeRÉSUMÉ
This study was aimed to explore impact of removal of cell membrane G alalpha1-3Gal beta1-4Glc NAc epitopes (called alpha-Gal) and chemical modification of other xenoantigen on bovine red blood cell (bRBC) and porcine red blood cell (pRBC) antigenicity and to compare their modified erythrocytes, in order to provide basis for development of human blood substitute with rich source, high safety and efficacy. bRBC and pRBC were subjected to both enzymatic removal of membrane alpha-Gal with recombinant coffee bean alpha-galactosidase (rC alpha-GalE) and covalent attachment of benzotriazole carbonate-linked methoxypolyethylene glycol (mPEG-BTC, MW = 20 kD). The effects of treatment were measured by hemagglutination, flow cytometric assay of IgG binding and clinical cross-match testing to human sera. The results showed that although alpha-galactosidase treatment reduced hemagglutination titers to levels similar to negative control, the combination of the treatments was most effective. Clinically used cross-match tests between bRBC, pRBC and human sera demonstrated increased compatibility. Bovine RBC were more robust than pRBC, and had less xenoantigens, and had longer half life than pRBC in vivo. These characteristics suggested that bRBCs were more suitable to investigation as an alternatives to hRBC in clinical transfusion than pRBC. These data suggested that strategies to remove or mask xenoantigens on bRBC reduce antigenicity sufficiently to allow in vitro cross-match compatibility to human sera, and therefore bRBC following modification may be considered as human blood substitute.
Sujet(s)
Animaux , Bovins , Humains , Antigènes hétérophiles , Allergie et immunologie , Substituts sanguins , Diholoside , Allergie et immunologie , Épitopes , Allergie et immunologie , Membrane érythrocytaire , Allergie et immunologie , Transfusion d'érythrocytes , Méthodes , Érythrocytes , Allergie et immunologie , Métabolisme , Suidae , alpha-Galactosidase , Allergie et immunologieRÉSUMÉ
In order to study whether plasma can affect the structure and function of red blood cells during their storage period, the differences of pH value, concentration of K(+), Na(+), osmotic fragility, plasma hemoglobin, AchE, ATP, 2.3-DPG, P50 in suspended RBC, washed RBC, and RBC with various plasma volume at different storage times were compared. The results showed that plasma helped the blood to keep the RBC at high pH value, low K(+), high Na(+) and maintain RBC-ATP, oxygen carry capacity and deformability, but no effect on maintenance of osmotic fragility, and levels of plasma hemoglobin, AchE, ATP and 2.3-DPG was found in preservated blood. In conclusion, human plasma may be in favour of the preservation of red blood cells.
Sujet(s)
Humains , 2,3-Diphosphate de glycérate , Sang , Adénosine triphosphate , Sang , Conservation de sang , Méthodes , Érythrocytes , Chimie , Biologie cellulaire , Concentration en ions d'hydrogène , Plasma sanguin , Physiologie , Potassium , Sang , Reproductibilité des résultats , Sodium , SangRÉSUMÉ
In order to meet the demand for safe transfusion in special conditions and to utilize the donated blood supply efficiently, technology has been developed to convert erythrocytes from type A, B, or AB to "universal donor" blood. Conversion of blood type B to O was performed by means of recombinant alpha-galactosidase digestion. The results showed that blood type B to O was converted successfully, 1 transfusion unit of red cells of group B (100 ml totally) could converted to universal blood cells in the optimal conditions including pH 5.6, 26 degrees C, 2 hours, obturation and sterilization. It is concluded that the universal red blood cells converted from group B to group O are conformed to demand of identification rules of biological products, no harmful effects of alpha-galactosidase on cell structure and function are observed. The converted red cells can stored in 4 degrees C for 21 days.
Sujet(s)
Humains , Système ABO de groupes sanguins , Classification , Allergie et immunologie , Incompatibilité sanguine , Transfusion sanguine , Méthodes , Café , Électrophorèse sur gel de polyacrylamide , Test ELISA , Érythrocytes , Allergie et immunologie , Métabolisme , Isoantigènes , Métabolisme , Protéines recombinantes , Métabolisme , Pharmacologie , alpha-Galactosidase , Génétique , Métabolisme , PharmacologieRÉSUMÉ
In order to obtain an adequate supply of alpha-galactosidase for research and practical use, the fermentation, purification and identification of the recombinant coffee bean a-galactosidase were carried out. Baffled flasks containing 100mL BMGY were inoculated with the pPIC9K-Gal/GS115 strain and allowed to grow at 30 degrees C, 250- 300r/min until a maximum optical density at 600nm (OD600) between 2.0 to 6.0 was attained. Entire 400 mL seed culture was transferred aseptically to the 5-liter fermenter, which contained 4 liter sterilized basal salts medium and 4% glycerol. The batch culture grew at 30 degrees C, pH 5.0 until the glycerol was completely consumed, and a glycerol feed was initiated to increase the cell biomass prior to induction with methanol. The culture was centrifuged at 8000 x g and the supernatant was collected. Following ultrafiltration, the retentate was balanced in 20 mmol/L sodium formicate buffer, pH 3.8 and loaded onto a cation-exchange column, HiTrap SP. The column was washed with the same buffer and bound proteins were eluted with 1 mol/L NaCl. The fractions containing recombinant a-galactosidase were pooled and concentrated with PEG20 000. Subsequently, the biochemical properties of the enzyme were determined with typical methods. At last, the fresh human blood A and B erythrocytes were incubated with the purified alpha-galactosidase at 26 degrees C for 2 4 hours. Hemagglutinins were assayed by the standard method. After an elapsed fermentation times (EFT) of 18h, the fed-batch phase was initiated to increase the cell biomass. A cellular yield of nearly 200 g/liter wet cells was achieved when induction was initiated. 72h later, the alpha-galactosidase activity against artificial substrate PNPG (PNP-alpha-galactopyranoside) achieved 36 000u per liter culture. The crude fementation supernatant contained few impurities as detected by SDS-PAGE. The supernatant was purified by cation-exchange chromatography, the target alpha-galactosidase was eluted with 40% 1mol/L NaCl and showed a 41kD band on SDS-PAGE. After concentration, the final recovery was about 41%. The Michaelis constant of the recombinant alpha-galactosidase was determined as 0.275 mmol/L, which slightly lower than the nature enzyme and suggested a higher affinity with specific substrate. When human blood type B erythrocytes pretreated with 100u/mL recombinant alpha-galactosidase reacted with bood type B antiserum, no hemagglutination occurred. This suggested that the B antigens had been removed by the enzyme successfully. These results demonstrated that the recombinant alpha-galactosidase could be produced in largescale and made it possible to explore the application of alpha-galactosidase in more fields.