Expression and Characterization of Glycosylated and Catalytically Active Recombinant Human α-Galactosidase A Produced in Pichia pastoris

Fabry disease is an X-linked inborn error of glycolipid metabolism caused by deficiency of the lysosomal enzyme α-galactosidase A. This enzyme is responsible for the hydrolysis of terminal α-galactoside linkages in various glycolipids. An improved method of production of recombinant α-galactosidase A for use in humans is needed in order to develop new approaches for enzyme therapy. Human α-galactosidase A for use in enzyme therapy has previously been obtained from human sources and from recombinant clones derived from human cells, CHO cells, and insect cells. In this report we describe the construction of clones of the methylotrophic yeast Pichia pastoris that produce recombinant human α-galactosidase A. Recombinant human α-galactosidase A is secreted by these Pichia clones and the level of production is more than 30-fold greater than that of previously used methods. Production was optimized using variations in temperature, pH, cDNA copy number, and other variables using shake flasks and a bioreactor. Expression of the human enzyme increased with increasing cDNA copy number at 25°C, but not at the standard growth temperature of 30°C. The recombinant α-galactosidase A was purified to homogeneity using ion exchange (POROS 20 CM, POROS 20 HQ) and hydrophobic (Toso-ether, Toso-butyl) chromatography with a BioCAD HPLC Workstation. Purified recombinant α-galactosidase A was taken up by fibroblasts derived from Fabry disease patients and normal enzyme levels could be restored under these conditions. Analysis of the carbohydrate present on the recombinant enzyme indicated the predominant presence of N-linked high-mannose structures rather than complex carbohydrates.     

Purification and characterization of human alpha-galactosidase A expressed in insect cells using a baculovirus vector

Fabry disease is an X-linked inborn error of glycolipid metabolism caused by deficiency of the lysosomal enzyme alpha-galactosidase A. The enzyme is responsible for the hydrolysis of terminal alpha-galactoside linkages in various glycolipids. To perform more extensive biochemical characterization and to develop new approaches for enzyme therapy, a method of producing and purifying recombinant alpha-galactosidase A suitable for scale-up manufacture for use in humans is needed. Previously, a catalytically active recombinant human alpha-galactosidase A was expressed using a baculovirus vector and purified using conventional chromatography. However, the level of expression was too low to permit economical production and the chromatographic techniques used for enzyme purification were not suitable for enzyme to be used in humans. Therefore, the cDNA of the enzyme was cloned to an improved baculovirus vector and the enzyme was expressed in a 15-liter bioreactor using optimized growth conditions. Infection of insect cells by the baculovirus resulted in a significant fivefold increase in the level of secreted recombinant alpha-galactosidase A activity that is compatible with economic manufacturing. The recombinant alpha-galactosidase A was purified to homogeneity using ion exchange (Poros 20-CM, Poros 20-HQ) and hydrophobic chromatography (Toso-ether, Toso-butyl) using the BioCAD HPLC workstation. These chromatographic steps are readily scalable to larger volumes and are appropriate for the purification of the recombinant human alpha-galactosidase A to be used in clinical trials of enzyme replacement therapy for Fabry disease patients.     

Synthesis and processing of alpha-galactosidase A in human fibroblasts. Evidence for different mutations in Fabry disease

The synthesis and processing of the human lysosomal enzyme alpha-galactosidase A was examined in normal and Fabry fibroblasts. In normal cells, alpha-galactosidase A was synthesized as an Mr = 50,500 precursor, which contained phosphate groups in oligosaccharide chains cleavable by endoglucosaminidase H. The precursor was processed via ill-defined intermediates to a mature Mr 46,000 form. Processing was complete within 3-7 days after synthesis. In the presence of NH4Cl and in I-cell fibroblasts, the majority of newly synthesized alpha-galactosidase A was secreted as an Mr = 52,000 form. For comparison, the processing and stability of alpha-galactosidase A were examined in fibroblasts from five unrelated patients with Fabry disease, which is caused by deficient alpha-galactosidase A activity. In one cell line, synthesis of immunologically cross-reacting polypeptides was not detectable. In another, the synthesis, processing, and stability of alpha-galactosidase A was indistinguishable from that in normal fibroblasts. In a third Fabry cell line, the mutation retarded the maturation of alpha-galactosidase A. Finally, in two cell lines, alpha-galactosidase A polypeptides were synthesized that were rapidly degraded following delivery to lysosomes. These results clearly indicate that Fabry disease comprises a heterogeneous group of mutations affecting synthesis, processing, and stability of alpha-galactosidase A.     

A biochemical and pharmacological comparison of enzyme replacement therapies for the glycolipid storage disorder Fabry disease

Fabry disease is a lysosomal storage disease arising from deficiency of the enzyme alpha-galactosidase A. Two recombinant protein therapeutics, Fabrazyme (agalsidase beta) and Replagal (agalsidase alfa), have been approved in Europe as enzyme replacement therapies for Fabry disease. Both contain the same human enzyme, alpha-galactosidase A, but they are produced using different protein expression systems and have been approved for administration at different doses. To determine if there is recognizable biochemical basis for the different doses, we performed a comparison of the two drugs, focusing on factors that are likely to influence biological activity and availability. The two drugs have similar glycosylation, both in the type and location of the oligosaccharide structures present. Differences in glycosylation were mainly limited to the levels of sialic acid and mannose-6-phosphate present, with Fabrazyme having a higher percentage of fully sialylated oligosaccharides and a higher level of phosphorylation. The higher levels of phosphorylated oligomannose residues correlated with increased binding to mannose-6-phosphate receptors and uptake into Fabry fibroblasts in vitro. Biodistribution studies in a mouse model of Fabry disease showed similar organ uptake. Likewise, antigenicity studies using antisera from Fabry patients demonstrated that both drugs were indistinguishable in terms of antibody cross-reactivity. Based on these studies and present knowledge regarding the influence of glycosylation on protein biodistribution and cellular uptake, the two protein preparations appear to be functionally indistinguishable. Therefore, the data from these studies provide no rationale for the use of these proteins at different therapeutic doses.     

Endocytosis of lysosomal alpha-galactosidase A by cultured fibroblasts from patients with Fabry disease.

The endocytosis of alpha-galactosidase A was studied in cultured fibroblasts from patients with Fabry disease. Alpha-galactosidase A was purified from human placenta by chromatography on concanavalin A-Sepharose, DEAE-cellulose, and N-epsilon-aminocaproyl-alpha-D-galactosylamine-Sepharose. Separation of the high-uptake form of the enzyme from the low-uptake form was accomplished by chromatography on ECTEOLA-cellulose. With the high-uptake form of the enzyme, the uptake was linear at low concentrations of enzyme and had a Kuptake of 0.01 U/ml of medium that corresponds to a Km of 5.0 x 10(-9) M. At high concentrations of enzyme, it became saturated. The high-uptake form could be converted to the low-uptake form by treatment with acid phosphatase. Mannose-6-P strongly inhibited the active uptake of the enzyme. Once taken up into the lysosomes of Fabry disease fibroblasts, alpha-galactosidase A activity was rapidly lost in the first 2 days of incubation at 37 degrees C, but was fairly stable for the next 6 days. The half-life of internalized alpha-galactosidase A activity was calculated to be 4 days. Crosslinking of the enzyme with hexamethylene diisocyanate did not increase the intracellular stability of alpha-galactosidase A activity.     

Fabry disease--a metabolic disorder with a challenge for endocrinologists?

OBJECTIVE: To revisit Fabry disease, a rare X-linked metabolic glycosphingolipid storage disease caused by a deficiency of the lysosomal enzyme alpha-galactosidase A (alpha-gal A). METHOD: Summary of the existing knowledge of Fabry disease including the clinical feature of Fabry disease and the recent breakthrough in the treatment of Fabry patients with the development of recombinant human alpha-gal A. CONCLUSION: The diffuse organ manifestations of Fabry disease resemble medical endocrinological diseases, and medical endocrinology might be an appropriate speciality to manage the treatment in collaboration with other specialists and clinical geneticists.     

Signal sequence and DNA-mediated expression of human lysosomal alpha-galactosidase A

Twelve complementary DNA clones for human lysosomal alpha-galactosidase A were isolated from an Okayama-Berg library constructed from SV40-transformed human fibroblasts. The identity of these clones was confirmed by complete colinearity of the nucleotide-deduced amino acid sequence with that determined by direct chemical sequencing of human placental alpha-galactosidase A. Hybridization of the alpha-galactosidase A cDNA to genomic DNA from individuals with varying numbers of X chromosomes as well as from interspecies somatic-cell hybrids showed only a single locus in the genome at Xq 13.1-Xq 22. One cDNA clone (pcD-AG210) contained the complete coding sequence for both the signal peptide and mature alpha-galactosidase A. The signal peptide of 31 amino acids contains the expected hydrophobic domains consisting of Leu-Gly-Cys-Ala-Leu-Ala-Leu and Phe-Leu-Ala-Leu-Val and has Ala at the signal peptidase cleavage site. Twelve out of fifteen G residues flanking the 5' end of the cDNA in pcD-AG210 were removed and the truncated fragment was ligated into the original vector. This construct, pcD-AG502, encoded enzymatically active human alpha-galactosidase A in monkey COS cells.     

Production in yeast of alpha-galactosidase A,a lysosomal enzyme applicable to enzyme replacement therapy for Fabry disease

A mammalian-like sugar moiety was created in glycoprotein by Saccharomyces cerevisiae in combination with bacterial alpha-mannosidase to produce a more economic enzyme replacement therapy for patients with Fabry disease. We introduced the human alpha-galactosidase A (alpha-GalA) gene into an S. cerevisiae mutant that was deficient in the outer chains of N-linked mannan. The recombinant alpha-GalA contained both neutral (Man(8)GlcNAc(2)) and acidic ([Man-P](1-2)Man(8)GlcNAc(2)) sugar chains. Because an efficient incorporation of alpha-GalA into lysosomes of human cells requires mannose-6-phosphate (Man-6-P) residues that should be recognized by the specific receptor, we trimmed down the sugar chains of the alpha-GalA by a newly isolated bacterial alpha-mannosidase. Treatment of the alpha-GalA with the alpha-mannosidase resulted in the exposure of a Man-6-P residue on a nonreduced end of oligosaccharide chains after the removal of phosphodiester-linked nonreduced-end mannose. The treated alpha-GalA was efficiently incorporated into fibroblasts derived from patients with Fabry disease. The uptake was three to four times higher than that of the nontreated alpha-GalA and was inhibited by the addition of 5 mM Man-6-P. Incorporated alpha-GalA was targeted to the lysosome, and hydrolyzed ceramide trihexoside accumulated in the Fabry fibroblasts after 5 days. This method provides an effective and economic therapy for many lysosomal disorders, including Fabry disease.     

Enzymological properties and immunological characterization of alpha-galactosidase isoenzymes from normal and Fabry human liver.

1. A method is described for the rapid isolation of alpha-galactosidases A and B (alpha-D-galactoside galactohydrolase, EC 3.2.1.22) from normal human liver. 2. When the same method is applied to Fabry liver, most of the alpha-galactosidase activity is recovered in the fraction corresponding to normal alpha-galactosidase B. In agreement with Romeo, G., D'Urso, M., Pisacane, A., Blum, E., De Falco, A. and Ruffilli, A. (1975) Biochem. Genet. 13, 615-628) [18], a small amount of alpha-galactosidase activity is found in the fraction corresponding to normal alpha-galactosidase A. 3. The kinetic properties of the B-like activity from Fabry liver are similar to those of normal alpha-galactosidase B. In agreement with Romeo et al. [18], it was found that the kinetic properties of the A-like activity from Fabry liver are similar to those of normal alpha-galactosidase A. 4. Using antisera raised against normal alpha-galactosidase A and normal alpha-galactosidase B, it is shown that the normal alpha-galactosidase isoenzymes are immunologically distinct and that the B-like activity from Fabry liver is immunologically related to normal alpha-galactosidase B. Furthermore, the A-like activity from Fabry liver is immunologically related to normal alpha-galactosidase B and not to normal alpha-galactosidase A. 5. Normal alpha-galactosidase B is converted into an A-like form during storage. 6. It is concluded that the B-like alpha-galactosidase in Fabry tissues is identical to normal alpha-galactosidase B, and that the small amount of A-like activity found in Fabry material is due to a modified form of alpha-galactosidase B.     

ConA-mediated binding and uptake of purified alpha-galactosidase A in Fabry fibroblasts

In most human tissues there are at least two different alpha-galactosidases, A and B. The former is deficient in patients hemizygous for Fabry disease. We have isolated it from human placenta and found that it was labile even at culture conditions, but was stabilized after binding to concanavalin A (conA). The alpha-galactosidase activity was markedly increased in Fabry fibroblasts when these were treated with conA and exposed to alpha-galA at 37 degrees C. The maximum activity was obtained after 1/2-2 h of incubation and was maintained for at least 4 h. The binding and uptake of conA into Fabry cells was followed by microscopical studies of fluorescein-labelled conA. We assume that alpha-galA is taken up by endocytosis of the enzyme-conA complex.     

4-Phenylbutyrate rescues trafficking incompetent mutant alpha-galactosidase A without restoring its functionality

Fabry disease is a lysosomal storage disorder caused by deficiency of alpha-galactosidase A. Most mutant enzyme is catalytically active but due to misfolding retained in the endoplasmic reticulum. We have tested 4-phenylbutyrate for its potential to rescue various trafficking incompetent mutant alpha-galactosidase A. Although we found that the trafficking blockade for endoplasmic reticulum-retained mutant alpha-Gal A was released, neither a mature enzyme was detectable in transgenic mice fibroblasts nor a reversal of lysosomal Gb3 storage in fibroblasts from Fabry patients could be observed. Because of lack of functionality of rescued mutant alpha-galactosidase A, 4-phenylbutyrate seems to be of limited use as a chemical chaperone for Fabry disease.     

Expression of the human alpha-galactosidase A in Escherichia coli K-12

We used the prokaryotic expression vector, ptrpL1, for the expression in Escherichia coli K-12 of a cDNA clone specific for the human lysosomal hydrolase, alpha-galactosidase A. The 5' terminus of the cDNA clone was engineered so that an ATG codon precedes the first codon of the mature form of the enzyme. A clone with elevated expression of this human enzyme was constructed by increasing the distance between the Shine-Dalgarno site and the ATG start codon from 6 to 8 bp. Clones with alpha-galactosidase A specific cDNA encoding the proenzyme produce a protein of 45 kDa, the size expected for the intact proenzyme. The 45-kDa protein is specifically precipitated by antibody to alpha-galactosidase A, and its expression is repressed by tryptophan and induced by 3-beta-indoleacrylic acid as expected for this expression vector. The human enzyme is produced in E. coli in a catalytically active form at levels sufficient to support the growth of cells using alpha-galactosides as sole sources of carbon and energy. In addition, bacterial colonies that produce the human enzyme turn blue in the presence of 5-bromo-4-chloro-3-indolyl-alpha-D-galactopyranoside.     

Characterization of two alpha-galactosidase mutants (Q279E and R301Q) found in an atypical variant of Fabry disease

The mutant products Q279E ((279)Gln to Glu) and R301Q ((301)Arg to Gln) of the X-chromosomal inherited alpha-galactosidase (EC 3.2.1. 22) gene, found in unrelated male patients with variant Fabry disease (late-onset cardiac form) were characterized. In contrast to patients with classic Fabry disease, who have no detectable alpha-galactosidase activity, atypical variants have residual enzyme activity. First, the properties of insect cell-derived recombinant enzymes were studied. The K(m) and V(max) values of Q279E, R301Q, and wild-type alpha-galactosidase toward an artificial substrate, 4-methylumbelliferyl-alpha-D-galactopyranoside, were almost the same. In order to mimic intralysosomal conditions, the degradation of the natural substrate, globotriaosylceramide, by the alpha-galactosidases was analyzed in a detergent-free-liposomal system, in the presence of sphingolipid activator protein B (SAP-B, saposin B). Kinetic analysis revealed that there was no difference in the degradative activity between the mutants and wild-type alpha-galactosidase activity toward the natural substrate. Then, immunotitration studies were carried out to determine the amounts of the mutant gene products naturally occurring in cells. Cultured lymphoblasts, L-57 (Q279E) and L-148 (R301Q), from patients with variant Fabry disease, and L-20 (wild-type) from a normal subject were used. The 50% precipitation doses were 7% (L-57) and 10% (L-148) of that for normal lymphoblast L-20, respectively. The residual alpha-galactosidase activity was 3 and 5% of the normal level in L-57 and L-148, respectively. The quantities of immuno cross-reacting materials roughly correlated with the residual alpha-galactosidase activities in lymphoblast cells from the patients. Compared to normal control cells, fibroblast cells from a patient with variant Fabry disease, Q279E mutation, secreted only small amounts of alpha-galactosidase activity even in the presence of 10 mM NH(4)Cl. It is concluded that Q279E and R301Q substitutions do not significantly affect the enzymatic activity, but the mutant protein levels are decreased presumably in the ER of the cells.     

Active-site-specific chaperone therapy for Fabry disease. Yin and Yang of enzyme inhibitors

Protein misfolding is recognized as an important pathophysiological cause of protein deficiency in many genetic disorders. Inherited mutations can disrupt native protein folding, thereby producing proteins with misfolded conformations. These misfolded proteins are consequently retained and degraded by endoplasmic reticulum-associated degradation, although they would otherwise be catalytically fully or partially active. Active-site directed competitive inhibitors are often effective active-site-specific chaperones when they are used at subinhibitory concentrations. Active-site-specific chaperones act as a folding template in the endoplasmic reticulum to facilitate folding of mutant proteins, thereby accelerating their smooth escape from the endoplasmic reticulum-associated degradation to maintain a higher level of residual enzyme activity. In Fabry disease, degradation of mutant lysosomal alpha-galactosidase A caused by a large set of missense mutations was demonstrated to occur within the endoplasmic reticulum-associated degradation as a result of the misfolding of mutant proteins. 1-Deoxygalactonojirimycin is one of the most potent inhibitors of alpha-galactosidase A. It has also been shown to be the most effective active-site-specific chaperone at increasing residual enzyme activity in cultured fibroblasts and lymphoblasts established from Fabry patients with a variety of missense mutations. Oral administration of 1-deoxygalactonojirimycin to transgenic mice expressing human R301Q alpha-galactosidase A yielded higher alpha-galactosidase A activity in major tissues. These results indicate that 1-deoxygalactonojirimycin could be of therapeutic benefit to Fabry patients with a variety of missense mutations, and that the active-site-specific chaperone approach using functional small molecules may be broadly applicable to other lysosomal storage disorders and other protein deficiencies.     

Fabry's disease (alpha-galactosidase-A deficiency): recent therapeutic innovations

Fabry disease (FD, OMIM 301500) is an X-linked inherited disorder of metabolism due to mutations in the gene encoding alpha-galactosidase A, a lysosomal enzyme. The enzymatic defect leads to the accumulation of neutral glycosphingolipids throughout the body, particularly within endothelial cells. Resulting narrowing and tortuosity of small blood vessels with endothelial dysfunction lead to tissue ischaemia and infarction. Inability to prevent the progression of glycosphingolipid deposition causes significant morbidity and mortality from early onset strokes, cardiomyopathy and renal failure in adulthood. Medical management is symptomatic and consists of partial pain relief with analgesic drugs (gabapentin, carbamazepine), antihypertensive drugs, whereas renal transplantation or dialysis is available for patients experiencing end-stage renal failure. However, the ability to produce high doses of alpha-galactosidase A in vitro has opened the way to preclinical studies in the mouse model, and to the development of the first clinical trials in patients with Fabry disease. Enzyme replacement therapy has recently been validated as a therapeutic agent for Fabry disease patients. Long term safety and efficacy of replacement therapy are currently being investigated. Substrate deprivation and gene therapy may also prove future alternative therapeutic options.     

Amplification and molecular cloning of murine adenosine deaminase gene sequences

A previously isolated mouse Cl-1D derived cell line (B-1/25) overproduces adenosine deaminase (EC 3.5.4.4) by 3200-fold. The present studies were undertaken to determine the molecular basis of this phenomenon. Rabbit reticulocyte lysate and Xenopus oocyte translation studies indicated that the B-1/25 cells also overproduced adenosine deaminase mRNA. Total poly(A+) RNA derived from B-1/25 was used to construct a cDNA library. After prehybridization with excess parental Cl-1D RNA to selectively prehybridize nonamplified sequences, 32P-labeled cDNA probe synthesized from B-1/25 total poly(A+) RNA was used to identify recombinant colonies containing amplified mRNA sequences. Positive clones containing adenosine deaminase gene sequences were identified by blot hybridization analysis and hybridization-selected translation in both rabbit reticulocyte lysate and Xenopus oocyte translation systems. Adenosine deaminase cDNA clones hybridized with three poly(A+) RNA species of 1.5, 1.7, and 5.2 kilobases in length, all of which were overproduced in the B-1/25 cell line. Dot blot hybridization analysis using an adenosine deaminase cDNA clone showed that the elevated adenosine deaminase level in the B-1/25 cells was fully accounted for by an increase in adenosine deaminase gene copy number. The adenosine deaminase cDNA probes and the cell lines with amplified adenosine deaminase genes should prove extremely useful in studying the structure and regulation of the adenosine deaminase gene.     

Fabry disease: molecular diagnosis of hemizygotes and heterozygotes

Fabry disease, an X-linked inborn error of glycosphingolipid catabolism, results from the deficient activity of the lysosomal hydrolase, alpha-galactosidase A. Previously, the diagnosis of affected hemizygous males and heterozygous females was based on clinical findings and the levels of alpha-galactosidase A activity in easily obtained sources such as plasma and isolated lymphocytes or granulocytes. Since the gene encoding alpha-galactosidase A undergoes random X-inactivation, the expressed level of enzymatic activity in females heterozygous for the disease gene may vary significantly, thereby making accurate carrier detection difficult. The recent cloning and characterization of the full-length cDNA encoding human alpha-galactosidase A now permits the accurate diagnosis of affected hemizygotes and heterozygous females. In families with gene rearrangements or an altered restriction endonuclease cleavage site, precise diagnosis can be accomplished by Southern hybridization analysis using the alpha-galactosidase A cDNA as probe. In families with normal restriction patterns, two restriction fragment length polymorphisms have been identified in and adjacent to the alpha-galactosidase A gene which also allow precise hemizygote and heterozygote diagnosis. In addition, the recent identification of polymorphic, random DNA sequences (DXS17 and DXS87) located near the alpha-galactosidase A locus permits molecular diagnosis in informative families. Further evaluation of DXS17, DXS87 and other closely linked random DNA probes is required in order to determine their informativeness, proximity to the alpha-galactosidase A locus and, hence, accuracy for molecular diagnosis.