Christine M. Eng

A Phase 1/2 Clinical Trial of Enzyme Replacement in Fabry Disease: Pharmacokinetic, Substrate Clearance, and Safety Studies

Fabry disease results from deficient alpha-galactosidase A (alpha-Gal A) activity and the pathologic accumulation of the globotriaosylceramide (GL-3) and related glycosphingolipids, primarily in vascular endothelial lysosomes. Treatment is currently palliative, and affected patients generally die in their 40s or 50s. Preclinical studies of recombinant human alpha-Gal A (r-halphaGalA) infusions in knockout mice demonstrated reduction of GL-3 in tissues and plasma, providing rationale for a phase 1/2 clinical trial. Here, we report a single-center, open-label, dose-ranging study of r-halphaGalA treatment in 15 patients, each of whom received five infusions at one of five dose regimens. Intravenously administered r-halphaGalA was cleared from the circulation in a dose-dependent manner, via both saturable and non-saturable pathways. Rapid and marked reductions in plasma and tissue GL-3 were observed biochemically, histologically, and/or ultrastructurally. Clearance of plasma GL-3 was dose-dependent. In patients with pre- and posttreatment biopsies, mean GL-3 content decreased 84% in liver (n=13), was markedly reduced in kidney in four of five patients, and after five doses was modestly lowered in the endomyocardium of four of seven patients. GL-3 deposits were cleared to near normal or were markedly reduced in the vascular endothelium of liver, skin, heart, and kidney, on the basis of light- and electron-microscopic evaluation. In addition, patients reported less pain, increased ability to sweat, and improved quality-of-life measures. Infusions were well tolerated; four patients experienced mild-to-moderate reactions, suggestive of hypersensitivity, that were managed conservatively. Of 15 patients, 8 (53%) developed IgG antibodies to r-halphaGalA; however, the antibodies were not neutralizing, as indicated by unchanged pharmacokinetic values for infusions 1 and 5. This study provides the basis for a phase 3 trial of enzyme-replacement therapy for Fabry disease.

Frequency and Carrier Risk Associated with Common BRCA1 and BRCA2 Mutations in Ashkenazi Jewish Breast Cancer Patients

Based on breast cancer families with multiple and/or early-onset cases, estimates of the lifetime risk of breast cancer in carriers of BRCA1 or BRCA2 mutations may be as high as 85%. The risk for individuals not selected for family history or other risk factors is uncertain. We determined the frequency of the common BRCA1 (185delAG and 5382insC) and BRCA2 (6174delT) mutations in a series of 268 anonymous Ashkenazi Jewish women with breast cancer, regardless of family history or age at onset. DNA was analyzed for the three mutations by allele-specific oligonucleotide hybridization. Eight patients (3.0%, 95% confidence interval [CI] 1.5%-5.8%) were heterozygous for the 185delAG mutation, two (0.75%, 95% CI 0.20-2.7) for the 5382insC mutation, and eight (3.0%, 95% CI 1.5-5.8) for the 6174delT mutation. The lifetime risk for breast cancer in Ashkenazi Jewish carriers of the BRCA1 185delAG or BRCA2 6174delT mutations was calculated to be 36%, approximately three times the overall risk for the general population (relative risk 2.9, 95% CI 1.5-5.8). For the 5382insC mutation, because of the low number of carriers found, further studies are necessary. The results differ markedly from previous estimates based on high-risk breast cancer families and are consistent with lower estimates derived from a recent population-based study in the Baltimore area. Thus, presymptomatic screening and counseling for these common mutations in Ashkenazi Jewish women not selected for family history of breast cancer should be reconsidered until the risk associated with these mutations is firmly established, especially since early diagnostic and preventive-treatment modalities are limited.

Fabry disease: thirty-five mutations in the alpha-galactosidase A gene in patients with classic and variant phenotypes.

BackgroundFabry disease, an X-linked inborn error of glycosphingolipid catabolism, results from mutations in the α-galactosidase A (α-Gal A) gene located at Xq22.1. To determine the nature and frequency of the molecular lesions causing the classical and milder variant Fabry phenotypes and for precise carrier detection, the α-Gal A lesions in 42 unrelated Fabry hemizygotes were determined.Materials and MethodsGenomic DNA was isolated from affected probands and their family members. The seven α-galactosidase A exons and flanking intronic sequences were PCR amplified and the nucleotide sequence was determined by solid-phase direct sequencing.ResultsTwo patients with the mild cardiac phenotype had missense mutations, I91T and F113L, respectively. In 38 classically affected patients, 33 new mutations were identified including 20 missense (M1T, A31V, H46R, Y86C, L89P, D92Y, C94Y, A97V, R100T, Y134S, G138R, A143T, S148R, G163V, D170V, C202Y, Y216D, N263S, W287C, and N298S), two nonsense (Q386X, W399X), one splice site mutation (IVS4 + 2T → C), and eight small exonic insertions or deletions (304del1, 613del9, 777del1, 1057del2, 1074del2, 1077del1, 1212del3, and 1094ins1), which identified exon 7 as a region prone to gene rearrangements. In addition, two unique complex rearrangements consisting of contiguous small insertions and deletions were found in exons 1 and 2 causing L45R/H46S and L120X, respectively.ConclusionsThese studies further define the heterogeneity of mutations causing Fabry disease, permit precise carrier identification and prenatal diagnosis in these families, and facilitate the identification of candidates for enzyme replacement therapy.

Twenty novel mutations in the alpha-galactosidase A gene causing Fabry disease.

BackgroundFabry disease, an X-linked inborn error of glycosphingolipid catabolism, results from the deficient activity of the lysosomal exoglycohydrolase α-galactosidase A (EC 3.2.1.22; α-Gal A). The nature of the molecular lesions in the α-Gal A gene in 30 unrelated families was determined to provide precise heterozygote detection, prenatal diagnosis, and define genotype-phenotype correlations.Materials and MethodsGenomic DNA was isolated from affected males and/or carrier females from 30 unrelated families with Fabry disease. The entire α-Gal A coding region and flanking intronic sequences were analyzed by PCR amplification and automated sequencing.ResultsTwenty new mutations were identified, each in a single family: C142R, G183D, S235C, W236L, D244H, P259L, M267I, I289F, Q321E, C378Y, C52X, W277X, IVS4+4, IVS6+2, IVS6−1, 35del13, 256del1, 892ins1, 1176del4, and 1188del1. In the remaining 10 unrelated Fabry families, 9 previously reported mutations were detected: M42V, R112C, S148R, D165V, N215S (in 2 families), Q99X, C142X, R227X, and 1072del3. Haplotype analysis using markers closely flanking the α-Gal A gene indicated that the two patients with the N215S lesion were unrelated. The IVS4+4 mutation was a rare intronic splice site mutation that causes Fabry disease.ConclusionsThese studies further define the heterogeneity of mutations in the α-Gal A gene causing Fabry disease, permit precise heterozygote detection and prenatal diagnosis, and help delineate phenotype-genotype correlations in this disease.

Fabry disease: molecular carrier detection and prenatal diagnosis by analysis of closely linked polymorphisms at Xq22.1.

Fabry disease is an X-linked recessive inborn error of glycosphingolipid catabolism that results from the deficient activity of the lysosomal enzyme alpha-galactosidase A (alpha-Gal A). A rapid, reliable, and universal linkage method was developed for molecular carrier detection and prenatal diagnosis. By determining the informativeness and phase of amplifiable intragenic RFLPs (NcoI and SacI), flanking RFLPs (DXS94 and DXS17), and flanking microsatellite polymorphisms at Xq22.1 (DXS458, DXS454, DXS7424, DXS178, and DXS101), accurate carrier detection, and/or prenatal diagnosis was accomplished in three prototypic, unrelated Fabry families. All linkage diagnoses were confirmed by identification and analysis of the specific alpha-Gal A lesion in each family. Thus, molecular carrier detection and prenatal diagnoses can be performed rapidly and reliably by linkage analysis with intragenic and closely-linked polymorphisms at Xq22.1 in Fabry families whose specific alpha-Gal A lesions have not been determined.

Human α-Galactosidase: Characterization and Eukaryotic Expression of the Full-Length cDNA and Structural Organization of the Gene

Human α-galactosidase (EC 3.2.1.22) is a lysosomal hydrolase encoded by a single gene located in the chromosomal region Xq21.33-q22. The deficient activity of this enzyme results in Fabry disease, an X-linked recessive disorder which leads to premature death in affected males. For studies of the structure and function of α-galactosidase and for characterization of the genetic lesions in families with Fabry disease, the full-length cDNA was isolated, sequenced and used to obtain the human chromosomal gene. The 1393 bp full-length cDNA had a 60 nt 5’ untranslated region and encoded a precursor peptide of 429 amino acids including a signal peptide of 31 residues. The functional integrity of this cDNA was demonstrated by transient expression in COS-1 cells. The entire ~12 kb chromosomal gene, including ~9 and ~11 kb of 5’ and 3’ flanking sequence, was isolated. The gene had seven exons whose sequences were identical to those in the full-length cDNA. The 5’ flanking region of this housekeeping gene contained Spl and CCAAT box promoter elements as well as sequences corresponding to the AP-1, “OCTA” and “core” enhancer elements. Four direct repeats of the “chorion box” enhancer were preceded by an upstream “HTF” island. All intron-exon splice junctions conformed to the GT/AG consensus sequence. The novel lack of a 3’ untranslated sequence in the α-galactosidase cDNA was confirmed by sequencing the genomic 3’ region.

22. Experiences in molecular-based prenatal screening for Ashkenazi Jewish genetic diseases

Multiple-option prenatal carrier testing in the Ashkenazi Jewish community for three and now eight disorders has been readily accepted in this prenatal, health-oriented and knowledgeable population. Counseling of screenees concerning the nature (severity, treatability, etc.), inheritance, and frequencies of each disorder was essential for informed test choices and future reproductive decision making. The value of couple testing for a group of disorders when 1 in about 6 would be found to be a carrier of at least one disease was emphasized. These studies identified issues of education, confidentiality, posttest anxiety, and self-esteem that must be continuously addressed in the Ashkenazi population. However, an important value of these studies is that they provide a framework for the development of mass carrier screening programs in the general population or in specific segments of the population with similar demographic characteristics and in more diverse prenatal populations.

MOLECULAR PRENATAL DIAGNOSIS OF GLYCOGEN STORAGE DISEASE TYPE Ia

Glycogen storage disease type Ia (GSD Ia, von Gierke disease) is an autosomal recessive inborn error of metabolism caused by the deficiency of d‐glucose‐6‐phosphatase (G6Pase). Since this enzyme is expressed primarily in hepatocytes, couples at risk for GSD type Ia relied on fetal liver biopsy for prenatal diagnosis. The recent isolation of the G6Pase gene and identification of several disease‐causing mutations have permitted molecular prenatal diagnosis using amniocytes or chorionic villi. Chorionic villus sampling (CVS) was performed in an Ashkenazi Jewish family in whom a previous child was homoallelic and both parents were heterozygous for the R83C mutation. Molecular analysis revealed that the fetus was not affected. The prenatal diagnosis was confirmed postnatally by biochemical and molecular studies. Thus, the molecular prenatal diagnosis of GSD type Ia can be safely and accurately made in the first trimester.

Body mass, age, and the APC I1307K allele in Ashkenazi Jewish prostate cancer patients.

The I1307K mutation of the adenopolyposis coli gene (APC), located on chromosome 5q21-q22, is associated with an increased risk of cancer in Ashkenazi Jews. In the present study, we analyzed age and body mass of Ashkenazi Jewish prostate cancer patients, with and without the APC I1307K mutation. Participants in our study were found through urology and radiation oncology clinics, and all eligible patients were asked to take part. A familial history was obtained by interview or self-report questionnaire. Histological confirmation of diagnosis was obtained for all subjects. The I1307K allele of the APC gene was detected by amplification of lymphocyte DNA from peripheral blood according to standard polymerase chain reaction (PCR) and dot blot procedures. We studied 135 Ashkenazi Jewish men with prostate cancer. The youngest was 49, the oldest 80, average age 68 +/- 6.88 (mean +/- SD). The older patients carrying the wild type APC allele tended to have a lower body mass than the younger ones (r = -.27, P =.002). Of 71 patients under 70 years old, 65 carried the wild type APC allele, and had a body mass index of 28. 7 +/- 4.23 kg/m(2). The six men under age 70 carrying the I1307K APC allele had a body mass index of 26.87 +/- 1.44 kg/m(2). The difference in body mass index of the two groups is significant (P =. 032, t test for unequal variance). Increased body mass is a prostate cancer risk factor, and hereditary prostate cancer is associated with younger patients. Therefore, our finding, that patients under age 70 carrying the I1307K allele are significantly thinner than those carrying the wild type allele, suggests that the APC I1307K allele is also a prostate cancer risk factor. Our results are in accord with other studies indicating that APC mutations increase the risk of prostate cancer.