Acidic amino acid tag enhances response to enzyme replacement in mucopolysaccharidosis type VII mice

We have tested an acidic oligopeptide-based targeting system for delivery of enzymes to tissues, especially bone and brain, in a murine mucopolysaccharidosis type VII (MPS VII) model. This strategy is based upon tagging a short peptide consisting of acidic amino acids (AAA) to N terminus of human beta-glucuronidase (GUS). The pharmacokinetics, biodistribution, and the pathological effect on MPS VII mouse after 12 weekly infusions were determined for recombinant human untagged and tagged GUS. The tagged GUS was taken up by MPS VII fibroblasts in a mannose 6-phosphate receptor-dependent manner. Intravenously injected AAA-tagged enzyme had five times more prolonged blood clearance compared with the untagged enzyme. The tagged enzyme was delivered effectively to bone, bone marrow, and brain in MPS VII mice and was effective in reversing the storage pathology. The storage in osteoblasts was cleared similarly with both enzyme types. However, cartilage showed a little response to any of the enzymes. The tagged enzyme reduced storage in cortical neurons, hippocampus, and glia cells. A highly sensitive method of tandem mass spectrometry on serum indicated that the concentration of serum dermatan sulfate and heparan sulfate in mice treated with the tagged enzyme decreased more than the untagged enzyme. These preclinical studies suggest that this AAA-based targeting system may enhance enzyme-replacement therapy.     

Matrix vesicles in osteomalacic hypophosphatasia bone contain apatite-like mineral crystals.

Hypophosphatasia, a heritable disease characterized by deficient activity of the tissue nonspecific isoenzyme of alkaline phosphatase (TNSALP), results in rickets and osteomalacia. Although identification of TNSALP gene defects in hypophosphatasia establishes a role of ALP in skeletal mineralization, the precise function remains unclear. The initial site of mineralization (primary mineralization) normally occurs within the lumen of TNSALP-rich matrix vesicles (MVs) of growth cartilage, bone, and dentin. We investigated whether defective calcification in hypophosphatasia is due to a paucity and/or a functional failure of MVs secondary to TNSALP deficiency. Nondecalcified autopsy bone and growth plate cartilage from five patients with perinatal (lethal) hypophosphatasia were studied by nondecalcified light and electron microscopy to assess MV numbers, size, shape, and ultrastructure and whether hypophosphatasia MVs contain apatite-like mineral, as would be the case if these MVs retained their ability to concentrate calcium and phosphate internally despite a paucity of TNSALP in their investing membranes. We found that hypophosphatasia MVs are present in approximately normal numbers and distribution and that they are capable of initiating internal mineralization. There is retarded extravesicular crystal propagation. Thus, in hypophosphatasia the failure of bones to calcify appears to involve a block of the vectorial spread of mineral from initial nuclei within MVs, outwards, into the matrix. We conclude that hypophosphatasia MVs can concentrate calcium and phosphate internally despite a deficiency of TNSALP activity.     

Correlations of genotype and phenotype in hypophosphatasia.

Hypophosphatasia, a rare inherited disorder characterized by defective bone mineralization, is highly variable in its clinical expression. The disease is due to various mutations in the tissue-non-specific alkaline phosphatase ( TNSALP ) gene. We report here the use of clinical data, site-directed mutagenesis and computer-assisted modelling to propose a classification of 32 TNSALP gene mutations found in 23 European patients, 17 affected with lethal hypophosphatasia and six with non-lethal hypophosphatasia. Transfection studies of the missense mutations found in non-lethal hypophosphatasia showed that six of them allowed significant residual in vitro enzymatic activity, suggesting that these mutations corresponded to moderate alleles. Each of the six patients with non-lethal hypophosphatasia carried at least one of these alleles. The three-dimensional model study showed that moderate mutations were not found in the active site, and that most of the severe missense mutations were localized in crucial domains such as the active site, the vicinity of the active site and homodimer interface. Some mutations appeared to be organized in clusters on the surface of the molecule that may represent possible candidates for regions interacting with the C-terminal end involved in glycosylphosphatidylinositol (GPI) attachment or with other dimers to form tetramers. Finally, our results show a good correlation between clinical forms of the disease, mutagenesis experiments and the three-dimensional structure study, and allowed us to clearly distinguish moderate alleles from severe alleles. They also confirm that the extremely high phenotypic heterogeneity observed in patients with hypophosphatasia was due mainly to variable residual enzymatic activities allowed by missense mutations found in the human TNSALP gene.     

Characterization and pharmacokinetic study of recombinant human N-acetylgalactosamine-6-sulfate sulfatase

Mucopolysaccharidosis IVA (MPS IVA) is an autosomal recessive disorder caused by a deficiency of N-acetylgalactosamine-6-sulfate sulfatase (GALNS). The aims of this study were to establish Chinese hamster ovary (CHO) cells overexpressing recombinant human GALNS (rhGALNS) and to assess pharmacokinetics and tissue distribution of purified enzymes by using MPS IVA knock-out mouse (Galns(-/-)). The CHO-cell derived rhGALNS was purified from the media by a two-step affinity chromatography procedure. The rhGALNS was administered intravenously to 3-month-old Galns(-/-) mice at a single dose of 250U/g of body weight. The treated mice were examined by assaying the GALNS activity at baseline and up to 240min to assess clearance of the enzyme from blood circulation. The mice were sacrificed 4h after infusion of the enzyme to study the enzyme distribution in tissues. The rhGALNS was purified 1317-fold with 71% yield. The enzyme was taken up by Galns(-/-) chondrocytes (150U/mg/15h). The uptake was inhibited by mannose-6-phosphate. The enzyme activity disappeared from circulation with a half-life of 2.9min. After enzyme infusion, the enzyme was taken up and detected in multiple tissues (40.7% of total infused enzymes in liver). Twenty-four hours after a single infusion of the fluorescence-labeled enzymes into MPS IVA mice, biodistribution pattern showed the amount of tagged enzyme retained in bone, bone marrow, liver, spleen, kidney, and heart. In conclusion, we have shown that the phosphorylated rhGALNS is delivered to multiple tissues, including bone, and that it functions bioactively in Galns(-/-) chondrocytes implying a potential enzyme replacement treatment.     

Perinatal hypophosphatasia: radiology, pathology and molecular biology studies in a family harboring a splicing mutation (648+1A) and a novel missense mutation (N400S) in the tissue-nonspecific alkaline phosphatase (TNSALP) gene.

We report on a postmortem diagnosis of perinatal lethal hypophosphatasia, an inborn error of metabolism characterized by a liver/bone/kidney alkaline phosphatase (ALP)-related defective bone mineralization due to mutations in the tissue-nonspecific alkaline phosphatase (TNSALP) gene. Radiological and pathological studies identified a perinatal lethal hypophosphatasia showing a generalized bone mineralization defect including asymmetry of the cervical vertebral arches in a 22 +4 weeks' gestation fetus. Both parents revealed low serum ALP activities supporting the diagnosis. Sequencing analysis of the TNSALP gene showed two heterozygous mutations, 648+1A, a mutation affecting the donor splice site in exon 6, and N400S, a novel missense mutation in exon 11, located near the active site and very close to histidins 364 and 437, two crucial residues of the active site. Sequencing of exons 6 and 11 in the parents showed that 648+1A was from maternal origin and N400S from paternal origin. DNA-based prenatal testing in the subsequent pregnancy following a chorionic villous sampling performed at 10 weeks of gestation showed no mutation and a healthy infant was born at term.     

Molecular effects of the tissue-nonspecific alkaline phosphatase gene polymorphism (787T > C) associated with bone mineral density

Based on studies of hypophosphatasia, which is a systemic skeletal disorder resulting from tissuenonspecific alkaline phosphatase (TNSALP) deficiency, TNSALP was suggested to be indispensable for bone mineralization. Recently, we demonstrated that there was a significant difference in bone mineral density (BMD) among haplotypes, which was lowest among TNSALP (787T [Tyr-246Tyr]) homozygotes, highest among TNSALP (787T > C [Tyr246His]) homozygotes, and intermediate among heterozygotes. To analyze protein translated from the TNSALP gene 787T > C, we performed the biosynthesis of TNSALPs using TNSALP cDNA expression vectors. TNSALP (787T) and TNSALP (787T > C) were synthesized similarly as a high-mannose-type 66-kDa form, becoming an 80-kDa form. Expression of the human 787T > C TNSALP gene using the cultured mouse marrow stromal cell line ST2 demonstrated that the protein translated from 787T > C exhibited an ALP-specific activity similarly to that of 787T. Interestingly, the Km value for TNSALP in ST2 cells transfected with the 787T > C TNSALP gene was decreased significantly compared to that of cells carrying the 787T gene (P < 0.01). These results suggest that the significant difference in Km values between the proteins translated from 787T > C and 787T may contribute to regulatory effects on bone metabolism.     

A novel missense mutation of the tissue-nonspecific alkaline phosphatase gene detected in a patient with hypophosphatasia

Hypophosphatasia is a rare heritable inborn error of metabolism characterized by abnormal bone mineralization associated with a deficiency of alkaline phosphatase. The clinical expression of hypophosphatasia is highly variable, ranging from death in utero to pathologic fractures first presenting in adulthood. We investigated the tissue-nonspecific alkaline phosphatase (TNSALP) gene from a Japanese female patient with hypophosphatasia. By a quantitative polymerase chain reaction (PCR) method, the amount of TNSALP mRNA appeared to be almost equal to that in normal individuals. Gene analysis clarified that the hypophosphatasia originated from a missense mutation and a nucleotide deletion. The missense mutation, a C ? T transition at position 1041 of cDNA, results in an amino acid change from Leu to Phe at codon 272, which has not yet been reported. The previously reported deletion of T at 1735 causes a frame shift mutation downstream from Leu at codon 503. Family analysis showed that the mutation 1041T and the deletion 1735T had been inherited from the proband's father and mother, respectively. An expression experiment revealed that the mutation 1041T halved the expression of alkaline phosphatase activity. Using homology analysis, the Leu-272 was confirmed to be highly conserved in other mammals.     

Asfotase Alfa in Perinatal/Infantile-Onset and Juvenile-Onset Hypophosphatasia: A Guide to Its Use in the USA

Subcutaneous asfotase alfa (Strensiq?), a first-in-class bone-targeted human recombinant tissue-nonspecific alkaline phosphatase (TNSALP) replacement therapy, is approved in the USA for the treatment of patients with perinatal/infantile- or juvenile-onset hypophosphatasia (HPP). In clinical trials, asfotase alfa was an effective and generally well tolerated treatment for perinatal/infantile- and juvenile onset-HPP through at least 3 and 5 years’ treatment, respectively. Relative to untreated age-matched, juvenile-onset-HPP historical control cohorts, survival and ventilation-free survival were significantly prolonged in asfotase alfa-treated patients, consequent to preceding improvements in bone mineralization.     

Denaturing gradient gel electrophoresis analysis of the tissue nonspecific alkaline phosphatase isoenzyme gene in hypophosphatasia

Hypophosphatasia, a heritable form of rickets/osteomalacia, was first described in 1948. The biochemical hallmark, subnormal alkaline phosphatase (ALP) activity in serum, reflects a generalized disturbance involving the tissue-nonspecific isoenzyme of ALP (TNSALP). Deactivating mutations in the gene that encodes TNSALP have been reported in patients worldwide. Nevertheless, hypophosphatasia manifests an extraordinary range of clinical severity spanning death in utero to merely premature loss of adult teeth. There is no known medical treatment. To delineate the molecular pathology which explains the disease variability and to clarify the pattern(s) of inheritance for mild cases of hypophosphatasia, we developed comprehensive mutational analysis of TNSALP. High efficiency of mutation detection was possible by denaturing gradient gel electrophoresis (DGGE). Primers and conditions were established for all TNSALP coding exons (2-12) and adjacent splice sites so that the amplicons incorporated a GC clamp on one end. For each amplicon, the optimum percentage denaturant was determined by perpendicular DGGE. In 19 severely affected pediatric subjects (having perinatal or infantile hypophosphatasia or early presentation during childhood) from among our large patient population, we detected 2 TNSALP mutations each in 16 patients (84%) as expected for autosomal recessive disease. For 2 patients (11%), only 1 TNSALP mutation was detected by DGGE. However, one subject (who died from perinatal hypophosphatasia) had a large deletion as the second mutation. In the other (with infantile hypophosphatasia), no additional mutation was detected by DNA sequencing of all protein-coding exons. Possibly, she too has a deletion. For the final patient, with unclassifiable hypophosphatasia (5%), we detected only a single mutation which has been reported to cause relatively mild autosomal dominant disease; the other allele appeared to be intact. Hence, DGGE analysis was 100% efficient in detecting mutations in the coding exons and adjacent splice sites of TNSALP in this group of severely affected patients but, as expected, failed to detect a large deletion. To date, at least 78 different TNSALP mutations (in about 70 hypophosphatasia patients) have been reported globally. In our large subset of severely affected patients, we identified 8 novel TNSALP mutations (Ala34Ser, Val111Met, Delta G392, Thr117His, Arg206Gln, Gly322Arg, Leu397Met, and Gly409Asp) and 1 new TNSALP polymorphism (Arg135His) furthering the considerable genotypic variability of hypophosphatasia.     

Characterization of eleven novel mutations (M45L, R119H, 544delG, G145V, H154Y, C184Y, D289V, 862+5A, 1172delC, R411X, E459K) in the tissue-nonspecific alkaline phosphatase (TNSALP) gene in patients with severe hypophosphatasia. Mutations in brief no. 217. Online

Hypophosphatasia is a rare inherited disorder characterized by defective bone mineralization and deficiency of serum and tissue liver/ bone/kidney tissue alkaline phosphatase (L/B/K ALP) activity. We report the characterization of tissue-nonspecific alkaline phosphatase (TNSALP) gene mutations in a series of 9 families affected by severe hypophosphatasia. Fourteen distinct mutations were found, 3 of which were previously reported in the North American or Japanese populations. Seven of the 11 new mutations were missense mutations (M45L, R119H, G145V, C184Y and H154Y, D289V, E459K), the four others were 2 single nucleotide deletions (544delG and 1172delC), a mutation affecting donor splice site (862 + 5A) and a nonsense mutation (R411X).     

Evidence of a founder effect for the tissue-nonspecific alkaline phosphatase (TNSALP) gene E174K mutation in hypophosphatasia patients

Hypophosphatasia is a rare inborn error of metabolism characterised by defective bone mineralisation caused by a deficiency of liver-, bone- or kidney-type alkaline phosphatase due to mutations in the tissue-nonspecific alkaline phosphatase (TNSALP) gene. The clinical expression of the disease is highly variable, ranging from stillbirth with a poorly mineralised skeleton to pathologic skeletal fractures which develop in late adulthood only. This clinical heterogeneity is due to the strong allelic heterogeneity in the TNSALP gene. We found that mutation E174K is the most frequent in Caucasian patients, and that it was carried by 31% of our patients with mild hypophosphatasia. Because the mutation was found in patients of various geographic origins, we investigated whether it had a unique origin or rather multiple origins due to recurrence of de novo mutations. Three intragenic polymorphisms, S93S, 472+12delG and V505A, were genotyped in patients carrying E174K and in normal unrelated individuals. Our results show that all the E174K mutations are carried by a common ancestral haplotype, also found at low frequency in normal and hypophosphatasia chromosomes. We conclude that the TNSALP gene E174K mutation is the result of a relatively ancient ancestral mutation that occurred on a single chromosome in the north of Western Europe and spread throughout the rest of Europe and into the New World as a result of human migration.     

First identification of a gene defect for hypophosphatasia: evidence that alkaline phosphatase acts in skeletal mineralization

Hypophosphatasia is a heritable disorder characterized by defective osteogenesis and deficient liver/bone/kidney alkaline phosphatase (L/B/K ALP) activity. Severe forms of the disease are inherited in an autosomal recessive fashion. We examined cultured skin fibroblasts from twelve patients with severe hypophosphatasia. All were deficient in L/B/K ALP activity, yet produced normal levels of the corresponding mRNA. Sequence analysis of L/B/K ALP cDNA isolated from one of the patient-derived fibroblast lines revealed a point mutation that converted amino acid 162 of mature L/B/K ALP from alanine to threonine. The patient was homozygous and the parents, who are second cousins, heterozygous for this mutation. Introduction of the mutation into an otherwise normal cDNA disrupted the expression of active enzyme, demonstrating that a defect in the L/B/K ALP gene resulted in hypophosphatasia and that the enzyme is, therefore, essential for normal skeletal mineralization.     

Abnormal vitamin B6 metabolism in alkaline phosphatase knock-out mice causes multiple abnormalities, but not the impaired bone mineralization

The tissue non-specific alkaline phosphatase (TNAP) knock-out mouse is a model of infantile hypophosphatasia displaying impaired bone mineralization, epileptic seizures, apnoea, abnormal apoptosis in the thymus, abnormal lumbar nerve roots, and postnatal death. Administration of vitamin B6 suppresses the epileptic seizures in TNAP-/- mice. This paper examines to what extent the diverse abnormalities seen in these mice are due to impaired utilization of vitamin B6, using two complementary approaches: administration of vitamin B6 to TNAP null mice and deprivation of vitamin B6 in wild-type and TNAP heterozygous mice. Administration of exogenous pyridoxal HCl delayed the onset of epileptic attacks and increased the life span of TNAP-/- mice. The episodes of apnoea ceased and the appearance of lumbar nerve roots improved, but hypomineralization and accumulation of osteoid continued to worsen with age. Control mice fed a vitamin B6-depleted diet developed epileptic seizures indistinguishable from those observed in TNAP-/- mice, abnormal apoptosis in the thymus, and thinning of the nerve roots, but showed no evidence of bone mineralization abnormalities. Depletion of vitamin B6 did not affect the ability of primary cultures of osteoblasts to deposit bone mineral in vitro. While abnormal metabolism of vitamin B6 explains many of the abnormalities in this mouse model of infantile hypophosphatasia, it is not the basis of the abnormal mineralization that characterizes this disease.     

First Identification of a Gene Defect for Hypophosphatasia: Evidence That Alkaline Phosphatase Acts in Skeletal Mineralization

Hypophosphatasia is a heritable disorder characteriazed by defective osteogenesis and deficient liver/bone/kidney alkaline phosphatase (L/B/K ALP) activity. Severe forms of the disease are inherited in an autosomal recessive fashion. We examined cultured skin fibroblasts from twelve patients with severe hypophosphatasia. All were deficient in L/B.K ALP activity, yet produced normal levels of the corresponding mRNA. Sequence analysis of L/B/K ALP cDNA isolated from one of the patient-derived fibroblast lines revealed a point mutation that converted amino acid 162 of mature L/B/K ALP from alanine to threonine. The patient was homozygous and the parents, who are second cousins, heterozygous for this mutation. Introduction of the mutation into an otherwise normal cDNA disrupted the expression of active enzyme, demonstrating that a defect in the L/B/K ALP gene resulted in hypophosphatasia and that the enzyme is, therefore, essential for normal skeletal mineralization.     

Hypophosphatasia: the mutations in the tissue-nonspecific alkaline phosphatase gene

Hypophosphatasia is an inborn error of metabolism caused by a deficiency of liver-, bone- or kidney-type alkaline phosphatase due to mutations in the tissue-nonspecific alkaline phosphatase (ALPL) gene. Most of the 65 distinct mutations described to date are missense mutations, a result which must be correlated with the great variability of clinical expression ranging from stillbirth without mineralized bone to pathologic fractures developing only late in adulthood. Correlations of genotype and phenotype have been established on the basis of clinical data exhibited by the patients, transfection studies, computer-assisted modeling, and examination of biochemical properties of ALP in cultured fibroblasts of patients. Screening for mutations in the TNSALP gene allows genetic counseling and prenatal diagnosis of the disease in families with severe forms of hypophosphatasia, and screening may also be helpful in confirming diagnosis of hypophosphatasia when biochemical and clinical data are not clear. Screening is also the necessary first step in further studies to elucidate dominant transmission of the disease and of liver-, bone- and kidney-type alkaline phosphatase activity mechanism.     

Adult hypophosphatasia without apparent skeletal disease: “odontohypophosphatasia“ in four heterozygote members of a family

Summary Twenty members of a family with adult hypophosphatasia were examined clinically and biochemically. Severe caries causing early loss of permanent teeth was the only clinical symptom which could be attributed to hypophosphatasia. None of them had a history of defective bone mineralization, rachitic skeletal alterations, and recurrent pseudofractures or fractures. An iliac crest bone biopsy of the proposita showed a normal finding corresponding to the age of the patient.Four family members in two subsequent generations were affected, thus suggesting an autosomal dominant inheritance. Their serum and leukocyte alkaline phosphatases were reduced. The phosphoethanolamine (PEA) excretion in the urine was increased to a level which suggests a heterozygote state. The serum alkaline phosphatase activity could be ascribed to the liver isoenzyme fraction. This was shown by polyacrylamide electrophoresis, by inhibition studies with organ-specific inhibitors, heat inactivation, inhibition by antibodies, and treatment with neuraminidase.The proposita had an unexplained, diffuse fatty infiltration of the liver. Thus, not only alterations of bone but also of liver metabolism in hypophosphatasia should be considered.The variety of adult hypophosphatasia described in this paper is characterized by the lack of severe bone abnormalities, the apparently autosomal dominant inheritance, and the reduction of bone and intestinal isoenzyme in the serum. Our study suggests that hypophosphatasia is a heterogenous disorder which includes both severe and clinically mild forms.     

低磷酸酶血症一家系组织非特异性碱性磷酸酶TNSALP基因突变分析

 目的 对1例儿童型低磷酸酶血症（HPP）患者及家系进行临床分析及基因突变检测,以探讨HPP的致病机制。方法 针对1例罕见的HPP患者的典型临床特点,进行实验室检验及影像学检查。进而收集患者及其亲属外周血,提取基因组DNA。针对ALPL基因12个外显子及附近内含子区合成引物,经PCR扩增后,直接对产物测序检测突变。结果 显示患者血碱性磷酸酶水平显著降低,骨骼具有佝偻病样改变;患者ALPL基因存在c.18delA及c.G407C两种突变。前者所致移码突变使得翻译提前终止,形成的截短蛋白 (p.V7Yfs18X)丧失了发挥酶活性及骨骼矿化作用的重要区域;而c.G407C导致其编码的氨基酸由精氨酸变为脯氨酸（R136P）。进一步检索PubMed及ALPL基因突变数据库,以上突变在国内外均未见报道。临床表现正常的患者母亲及祖母、父亲分别携带c.18delA和c.G407C突变,该家系符合常染色体隐性遗传。结论 ALPL基因c.18delA和c.G407C两种新突变,与HPP临床表现密切相关。     

Enzyme replacement therapy in a murine model of Morquio A syndrome

Mucopolysaccharidosis IVA (MPS IVA) is an autosomal recessive disorder caused by a deficiency of N-acetylgalactosamine-6-sulfate sulfatase (GALNS), leading to accumulation of keratan sulfate (KS) and chrondroitin-6-sulfate. The pharmacokinetics and biodistributions were determined for two recombinant human GALNSs produced in CHO cell lines: native GALNS and sulfatase-modifier-factor 1 (SUMF1) modified GALNS. Preclinical studies of enzyme replacement therapy (ERT) by using two GALNS enzymes were performed on MPS IVA mice. The half-lives in blood circulation of two phosphorylated GALNS enzymes were similar (native, 2.4 min; SUMF1, 3.3 min). After intravenous doses of 250 units/g body weight were administered, each enzyme was primarily recovered in liver and spleen, with detectable activity in other tissues including bone and bone marrow. At 4 h post-injection, enzyme activity was retained in the liver, spleen, bone and bone marrow at levels that were 20-850% of enzyme activity in the wild-type mice. After intravenous doses of 250 units/g of native GALNS, and 250, 600 or 1000 units/g of SUMF1-GALNS were administered weekly for 12 weeks, MPS IVA mice showed marked reduction of storage in visceral organs, sinus lining cells in bone marrow, heart valves, ligaments and connective tissues. A dose-dependent clearance of storage material was observed in brain. The blood KS level assayed by tandem mass spectrometry was reduced nearly to normal level. These preclinical studies demonstrate the clearance of tissue and blood KS by administered GALNS, providing the in vivo rationale for the design of ERT trials in MPS IVA.     

ACE activity is modulated by the enzyme ��-galactosidase A

Fabry disease is a multisystem X-linked disorder resulting from α-galactosidase A (α-GalA) gene mutations leading to the accumulation of globotriaosylceramide mainly in endothelium compromising heart, kidney, and brain. In Fabry patients, progressive renal failure is frequently treated with angiotensin I-converting enzyme (ACE) inhibitors. We were interested in the possible interactions between ACE inhibitors therapy and the only causative therapy for Fabry disease, the enzyme replacement therapy (ERT) using recombinant human α-GalA (rhα-GalA). Our results suggest that ACE activity was significantly inhibited in plasma of Fabry patients and the blood pressure level decreased just after ERT (at the end of the rhα-GalA infusion). Interestingly, 2 weeks later, ACE activity was significantly upregulated and the plasma levels of angiotensin II increased in the patients treated with rhα-GalA following the elevations of ACE activity. The same inhibitory effect on ACE activity was also observed in rats after rhα-GalA infusion. Furthermore, ACE activity in CHO cells transfected with the human ACE was inhibited dose and time-dependently by rhα-GalA. In vitro, the incubation of plasma from healthy volunteers with rhα-GalA significantly reduced ACE activity. Finally, rhα-GalA also inhibited ACE activity and released galactose residues from purified rabbit lung ACE dose-dependently. In summary, our results suggest that rhα-GalA interacts with ACE and inhibits its activity, possibly by removing the galactose residues from the enzyme. This modulation might have profound impact on the clinical outcome of Fabry patients treated with rhα-GalA.