Childhood Pompe disease: clinical spectrum and genotype in 31 patients.

BACKGROUND: As little information is available on children with non-classic presentations of Pompe disease, we wished to gain knowledge of specific clinical characteristics and genotypes. We included all patients younger than 18 years, who had been evaluated at the Pompe Center in Rotterdam, the Netherlands, between 1975 and 2012, excluding those with the classic-infantile form. None were treated with enzyme replacement therapy at the time of evaluation. We collected information on first symptoms, diagnosis, use of a wheelchair and/or respirator, and enzyme and mutation analysis and assessed muscle strength, pulmonary function, and cardiac parameters. RESULTS: Thirty-one patients participated. Median age at symptom onset was 2.6 years (range 0.5-13y) and at diagnosis 4.0 years. Most first problems were delayed motor development and problems related to limb-girdle weakness. Fatigue, persistent diarrhea and problems in raising the head in supine position were other first complaints. Ten patients were asymptomatic at time of diagnosis. Five of them developed symptoms before inclusion in this study. Over 50 % of all patients had low or absent reflexes, a myopathic face, and scoliosis; 29 % were underweight. Muscle strength of the neck flexors, hip extensors, hip flexors, and shoulder abductors were most frequently reduced. Pulmonary function was decreased in over 48 % of the patients; 2 patients had cardiac hypertrophy. Patients with mutations other than the c.-32-13T > G were overall more severely affected, while 18 out of the 21 patients (86 %) with the c.-32-13T > G/'null' genotype were male. CONCLUSIONS: Our study shows that Pompe disease can present with severe mobility and respiratory problems during childhood. Pompe disease should be considered in the differential diagnosis of children with less familiar signs such as disproportional weakness of the neck flexors, unexplained fatigue, persistent diarrhea and unexplained high CK/ASAT/ALAT. Disease presentation appears to be different from adult patients. The majority of affected children with GAA genotype c.-32-13T > G/'null' appeared to be male.

Novel GAA sequence variant c.1211 A>G reduces enzyme activity but not protein expression in infantile and adult onset Pompe disease.

Pompe disease is a clinically and genetically heterogeneous autosomal recessive disorder caused by lysosomal acid α-glucosidase (GAA) deficiency. We report on two affected members of a non-consanguineous Caucasian family, including a classical infantile-onset patient with severe cardiomyopathy (IO) and his paternal grandmother with the adult-onset (AO) form. Two compound heterozygous sequence variants of the GAA gene were identified in each patient by mutation analyses (IO=c.1211A>G and c.1798C>T; AO=c.1211A>G and c.692+5G>T). For this study, the biochemical phenotype resulting from the missense mutation c.1211A>G in exon 8, which converts a highly conserved aspartate to glycine (p.Asp404Gly), was of specific interest because it had not been reported previously. Western blotting revealed a robust expression of all GAA isoforms in quadriceps muscle of both patients (fully CRIM positive), while enzymatic activity was 3.6% (IO) and 6.6% (AO) of normal controls. To further validate these findings, the c.1211A>G sequence variant was introduced in wild type GAA cDNA and over-expressed in HEK293T cells. Site-directed mutagenesis analyses confirmed that the mutation does not affect processing or expression of GAA protein, but rather impairs enzyme function. Similar results were reported for c.1798C>T (p.Arg600Cys), which further supports the biochemical phenotype observed in IO. The third mutation (c.692+5G>T, in intron 3) was predicted to affect normal splicing of the GAA mRNA, and qPCR indeed verified a 4-fold lower mRNA expression in AO. It is concluded that the novel sequence variant c.1211A>G results in full CRIM but significantly lower GAA activity, which in combination with c.1798C>T leads to infantile-onset Pompe disease. We surmise that the difference in disease severity between the two family members in this study is due to a milder effect of the intronic mutation c.692+5G>T (vs. c.1798C>T) on phenotype, partially preserving GAA activity and delaying onset in the proband (paternal grandmother).

Enzyme analysis for Pompe disease in leukocytes; superior results with natural substrate compared with artificial substrates.

Enzyme analysis for Pompe disease in leukocytes has been greatly improved by the introduction of acarbose, a powerful inhibitor of interfering alpha-glucosidases, which are present in granulocytes but not in lymphocytes. Here we show that the application of acarbose in the enzymatic assay employing the artificial substrate 4-methylumbelliferyl-alpha-D: -glucoside (MU-alphaGlc) is insufficient to clearly distinguish patients from healthy individuals in all cases. Also, the ratios of the activities without/with acarbose only marginally discriminated Pompe patients and healthy individuals. By contrast, when the natural substrate glycogen is used, the activity in leukocytes from patients (n = 82) with Pompe disease is at most 17% of the lowest control value. The use of artificial substrate in an assay with isolated lymphocytes instead of total leukocytes is a poor alternative as blood samples older than one day invariably yield lymphocyte preparations that are contaminated with granulocytes. To diagnose Pompe disease in leukocytes we recommend the use of glycogen as substrate in the presence of acarbose. This assay unequivocally excludes Pompe disease. To also exclude pseudo-deficiency of acid alpha-glucosidase caused by the sequence change c.271G>A (p.D91N or GAA2; homozygosity in approximately 1:1000 caucasians), a second assay employing MU-alphaGlc substrate plus acarbose or DNA analysis is required.

Cardiac evaluation in children and adults with Pompe disease sharing the common c.-32-13T>G genotype rarely reveals abnormalities.

BACKGROUND AND OBJECTIVE: Pompe disease is an inherited metabolic disorder caused by deficiency of acid alpha-glucosidase. All affected neonates have a severe hypertrophic cardiomyopathy, leading to cardiac failure and death within the first year of life. We investigated the presence and extent of cardiac involvement in children and adults with Pompe disease with the common c.-32-13T>G genotype to determine the usefulness of cardiac screening in these patients with relatively 'milder' phenotypes. METHODS: Cardiac dimensions and function were evaluated through echocardiography, electrocardiography and Holter monitoring. The total group comprised 68 patients with Pompe disease, of whom 22 patients had disease onset before the age of 18. RESULTS: Two patients (3%) had cardiac abnormalities possibly related to Pompe disease: Electrocardiography showed a Wolff-Parkinson-White pattern in an 8-year-old girl, and one severely affected adult patient had a mild hypertrophic cardiomyopathy. This hypertrophy did not change during treatment with recombinant human alpha-glucosidase. In addition, four adult patients showed minor cardiac abnormalities which did not exceed the prevalence in the general population and were attributed to advanced age, hypertension or pre-existing cardiac pathology unrelated to Pompe disease. CONCLUSIONS: Cardiac involvement is rare in Pompe patients with the common c.-32-13T>G genotype. The younger patients were not more frequently affected than the adults. Electrocardiographic evaluation appears to be appropriate as initial screening tool. Extensive cardiac screening seems indicated only if the electrocardiogram is abnormal or the patient has a history of cardiac disease.

Molecular and functional characterization of eight novel GAA mutations in Italian infants with Pompe disease.

We characterized 29 unrelated patients presenting with the severe form of Pompe disease (Glycogen Storage Disease Type II, acid maltase deficiency) and identified 26 pathogenic mutations divided over 28 different genotypes. Among the eight new mutations, five were exonic point mutations (c.572A>G, c.1124G>T, c.1202A>G, c.1564C>G and c.1796C>A) leading to codon changes (p.Y191C, p.R375L, p.Q401R, p.P522A and p.S599Y); two were intronic point mutations (c.-32-3C>A and c.1636+5G>C) affecting mRNA processing; one was a single base deletion (c.742delC) generating a truncated protein (p.L248PfsX20). A comprehensive evaluation, based on different methodological approaches, confirmed the detrimental effect of the eight mutations on the protein and its function. Structural alterations potentially induced by the five missense mutations were also predicted through visual inspection of the atomic model of the GAA protein, in terms of both function and spatial orientation of specific residues as well as disturbance generated by amino acid substitutions. Although the remarkable heterogeneity of the mutational spectrum in Pompe disease was already known, our data demonstrate and confirm the power of molecular and functional analysis in predicting the natural course of Pompe disease.

Broad spectrum of Pompe disease in patients with the same c.-32-13T->G haplotype.

BACKGROUND: Pompe disease (acid maltase deficiency, glycogen storage disease type II; OMIM 232300) is an autosomal recessive lysosomal storage disorder characterized by acid alpha-glucosidase deficiency due to mutations in the GAA gene. Progressive skeletal muscle weakness affects motor and respiratory functions and is typical for all forms of Pompe disease. Cardiac hypertrophy is an additional fatal symptom in the classic infantile subtype. c.-32-13T-->G is the most common mutation in adults. OBJECTIVE: To delineate the disease variation among patients with this mutation and to define the c.-32-13T-->G haplotypes in search for genotype-phenotype correlations. METHODS: We studied 98 compound heterozygotes with a fully deleterious mutation (11 novel mutations are described) and the common c.-32-13T-->G mutation. RESULTS: All patients were Caucasian. None had the classic infantile form of Pompe disease. The clinical course varied far more than anticipated (age at diagnosis <1 to 78 years; age at onset: <1 to 52 years). The acid alpha-glucosidase activities in a subset of patients ranged from 4 to 19.9 nmol/mg/h. Twelve different c.-32-13T-->G haplotypes were identified based on 17 single-nucleotide polymorphisms located in the GAA gene. In 76% of the cases, c.-32-13T-->G was encountered in the second most common GAA core haplotype (DHRGEVVT). In only one case was c.-32-13T-->G encountered in the major GAA core haplotype (DRHGEIVT). CONCLUSION: Patients with the same c.-32-13T-->G haplotype (c.q. GAA genotype) may manifest first symptoms at different ages, indicating that secondary factors may substantially influence the clinical course of patients with this mutation.

Seven cases of Pompe disease from Greece.

We present seven cases of Pompe disease (McKusick 232300; glycogen storage disease type II; acid maltase deficiency) from Greece. The onset of symptoms varied from early childhood to late adulthood, and the patients had quite variable duration of disease. All but one of them had muscle weakness and all had mildly to highly elevated serum creatine kinase. The diagnosis in all cases was confirmed by the finding of acid alpha-glucosidase (EC 3.2.1.3/20) deficiency in cultured skin fibroblasts. Thirteen mutant alleles were identified and nine different pathogenic mutations were encountered. Four were new: c.2071_2072insAGCCG leads to frameshift and total loss of function; c.1856G > A (p.Ser619Asn) leads to 90-95% loss of function; and the splice-site mutations c.1552-3C > G and c.2331+4A > G reduce the number of correct splicing events by more than 90%. The splice-site mutation c.-32-13T > G (IVS1-13T > G) was encountered four times and seems equally common among Greek and other caucasians. The other mutations: c.925G > A (p.Gly309Arg), c.[307T > G; 271G > A] (p.Cys103Gly; Asp91Asn), c.271del and c.1655T > C (p.Leu552Pro) have been reported earlier. Our study highlights the heterogeneity of Pompe disease in Greece and provides tools for diagnosis and carrier detection.

Human acid alpha-glucosidase from rabbit milk has therapeutic effect in mice with glycogen storage disease type II.

Pompe's disease or glycogen storage disease type II (GSDII) belongs to the family of inherited lysosomal storage diseases. The underlying deficiency of acid alpha-glucosidase leads in different degrees of severity to glycogen storage in heart, skeletal and smooth muscle. There is currently no treatment for this fatal disease, but the applicability of enzyme replacement therapy is under investigation. For this purpose, recombinant human acid alpha-glucosidase has been produced on an industrial scale in the milk of transgenic rabbits. In this paper we demonstrate the therapeutic effect of this enzyme in our knockout mouse model of GSDII. Full correction of acid alpha-glucosidase deficiency was obtained in all tissues except brain after a single dose of i.v. enzyme administration. Weekly enzyme infusions over a period of 6 months resulted in degradation of lysosomal glycogen in heart, skeletal and smooth muscle. The tissue morphology improved substantially despite the advanced state of disease at the start of treatment. The results have led to the start of a Phase II clinical trial of enzyme replacement therapy in patients.

Frequency of glycogen storage disease type II in The Netherlands: implications for diagnosis and genetic counselling.

Glycogen storage disease type II (GSD H) is an autosomal recessive myopathy. Early and late-onset phenotypes are distinguished - infantile, juvenile and adult. Three mutations in the acid alpha-glucosidase gene are common in the Dutch patient population: IVS1(-13T-->G), 525delT and delexon18. 63% of Dutch GSD II patients carry one or two of these mutations, and the genotype-phenotype correlation is known. To determine the frequency of GSD II, we have screened an unselected sample of neonates for the occurrence of these three mutations. Based on the calculated carrier frequencies, the predicted frequency of the disease is 1 in 40000 divided by 1 in 138 000 for infantile GSD II and 1 in 57 000 for adult GSD II. This is about two to four times higher than previously suggested, which is a reason to become more familiar with the presentation of GSD II in its different clinical forms and to adjust the risk assessment for genetic counselling.

Accumulation and release of iron in polarly and non-polarly cultured trophoblast cells isolated from human term placentas.

We investigated the usefulness of membrane grown human term trophoblast cells in transferrin-mediated iron transfer studies. We showed that diferric transferrin is taken up both at the microvillous and at the basal membrane by means of receptor-mediated endocytosis. Uptake from the microvillous side is predominant. This corresponded with a much higher expression of transferrin receptors at the microvillous membrane as compared to the basal one. Iron appeared to accumulate in the cell. Accumulation was higher when transferrin was supplied at the microvillous side. Transfer of iron could not be assessed because uptake of transferrin by the cells was much less than passive diffusion of transferrin through the cell-free filter. The observation of iron accumulation was unexpected for a transfer epithelium. Could it be that part of the iron taken up by the cells is rapidly released whereas the remaining part accumulates? In this case the rate of iron uptake should be higher than the rate of iron accumulation. This question was assessed with non-polarly cultured trophoblast cells. We showed that like in polar cells iron accumulated in ferritin. A new experimental design enabled us to demonstrate that indeed the rate of transferrin-mediated iron is in excess over iron accumulation. We thus provide evidence for a mechanism that enables rapid transfer of iron across the syncytiotrophoblast cell layer.

Glycogen storage disease type II: birth prevalence agrees with predicted genotype frequency.

OBJECTIVES: To compare the overall birth prevalence of diagnosed glycogen storage disease type II (GSD II) with the predicted frequency based on mutation screening, in order to determine whether GSD II is an underdiagnosed condition, and to analyze which medical disciplines recognize GSD II. METHODS: Retrospective data on all enzymatic diagnoses of GSD II were collected from diagnostic labs throughout the Netherlands, covering the period from January 1, 1972 to December 31, 1996. Age-specific diagnostic incidence rates were calculated for the entire study period. By adding together the diagnostic incidences for all age groups, we calculated the birth prevalence of diagnosed GSD II and compared these figures with the predicted frequency based on mutation screening in a random sample from the general population. The medical specialization of the referring clinicians was also recorded. RESULTS: GSD II was diagnosed in 154 individuals, including 11 prenatal diagnoses. The birth prevalences of the various phenotypes were 1/101,000 (infantile form), 1/720,000 (juvenile form) and 1/53,000 (adult form). The birth prevalence of the adult and infantile phenotype together was 1/35,000. Eighty-two percent of the patients were diagnosed in university hospitals. Of the patients with infantile GSD II, 71% were diagnosed by a pediatrician, whereas most patients with adult GSD II were diagnosed by a neurologist (80%). CONCLUSIONS: There is no evidence for the underdiagnosis of GSD II in the Netherlands, as the calculated birth prevalences of the disease are consistent with previous predictions based on mutation screening in a random sample of newborns. The worldwide birth prevalence of the disease may well be higher than 1 in 100,000. GSD II is mainly diagnosed in university hospitals.

Non-transferrin iron uptake by trophoblast cells in culture. Significance of a NADH-dependent ferrireductase.

This study shows that trophoblast cells in culture are able to take up 59Fe from both Fe(III)nitrilotriacetate (NTA) and Fe-ascorbate. Fe in the presence of ascorbate is assumed to be Fe(III) in equilibrium with Fe(II). Kinetic parameters for non-transferrin iron uptake are determined from initial rate experiments, yielding Vmax=366 pmol/mg protein/5 min and Km=0.96 microM for Fe(III)NTA and Vmax=4043 pmol/mg protein/5 min and Km= 1.3 microM for Fe-ascorbate. Since trophoblast cells in culture reduce extracellular Fe(III)CN, and uptake of 59Fe from Fe-ascorbate is higher than that from Fe(III)NTA, it is suggested that reduction of Fe(III) precedes uptake. Uptake of 59Fe from both Fe-ascorbate and Fe(III)NTA is inhibited by Fe(II)chelator ferrozine and membrane-impermeable Fe(III)CN, further supporting this hypothesis. Studies with microvillous membrane vesicles (MMV) and basal membrane vesicles (BMV) reveal the presence of a NADH-dependent ferrireductase. Reduction of Fe(III)CN follows Michaelis-Menten kinetics, both with respect to [NADH] and [Fe]. NADPH is ineffective as electron donor. The rate of Fe(III)CN reduction by BMV is 2.5 times higher compared to MMV, while Km values for Fe(III)CN and NADH are not significantly different. These results reveal that a transmembrane NADH-dependent ferrireductase plays a role in uptake of non-transferrin iron. The possibility that this enzyme system is involved in iron transfer across the basal membrane is discussed.

Recombinant human acid alpha-glucosidase: high level production in mouse milk, biochemical characteristics, correction of enzyme deficiency in GSDII KO mice.

Glycogen storage disease type II (GSDII) is caused by lysosomal acid alpha-glucosidase deficiency. Patients have a rapidly fatal or slowly progressive impairment of muscle function. Enzyme replacement therapy is under investigation. For large-scale, cost-effective production of recombinant human acid alpha-glucosidase in the milk of transgenic animals, we have fused the human acid alpha-glucosidase gene to 6.3 kb of the bovine alphaS1-casein gene promoter and have tested the performance of this transgene in mice. The highest production level reached was 2 mg/ml. The major fraction of the purified recombinant enzyme has a molecular mass of 110 kDa and resembles the natural acid alpha-glucosidase precursor from human urine and the recombinant precursor secreted by CHO cells, with respect to pH optimum, Km, Vmax, N-terminal amino acid sequence and glycosylation pattern. The therapeutic potential of the recombinant enzyme produced in milk is demonstrated in vitro and in vivo. The precursor is taken up in a mannose 6-phosphate receptor-dependent manner by cultured fibroblasts, is converted to mature enzyme of 76 kDa and depletes the glycogen deposit in fibroblasts of patients. When injected intravenously, the milk enzyme corrects the acid alpha-glucosidase deficiency in heart and skeletal muscle of GSDII knockout mice.

Morphological differentiation of cytotrophoblasts cultured in Medium 199 and in keratinocyte growth medium.

In culture, cytotrophoblast cells differentiate biochemically as well as morphologically into syncytiotrophoblast-like structures. Morphological and biochemical differentiation can be affected by the composition of the culture medium. The aim of this study was to analyze the morphological differentiation (syncytium formation) of cytotrophoblasts cultured in Medium 199 (M199) and keratinocyte growth medium (KGM). Term human cytotrophoblast cells were cultured in either M199 or KGM with daily refreshment of the media. Both media induced biochemical differentiation, as monitored by measuring hCG secretion. Syncytium formation was visualized by immunocytochemical staining of desmosomes (cell membranes). Cytotrophoblasts rapidly formed aggregates; however, single cells were seen throughout culture. Though the aggregates developed into syncytia, approximately 15% of the nuclei were still found in cell aggregates at the end of the culture period (4 days). The final percentage of nuclei in syncytia (60-70%) did not differ between the culture media used. Syncytium formation occurred more rapidly in KGM medium. Approximately 50% of the nuclei were found in syncytia after 40 and 50 h in KGM and M199, respectively. The number of nuclei per syncytium was slightly higher in M199, but the average surface area of the syncytia was larger in KGM cultured cells (162-132 mm2). These differences did not reach significance. We conclude that there is no major difference in morphological differentiation between cytotrophoblast cells in KGM or M199. Moreover, both media sustain equal rates of hCG secretion.

Glycogen storage disease type II: identification of a dinucleotide deletion and a common missense mutation in the lysosomal alpha-glucosidase gene.

In nine Dutch patients with the infantile form of glycogen storage disease type II (GSDII), who were compound heterozygous for either 525delT or exon18del (1), sequence analysis was performed to search for the mutations in the second lysosomal alpha-glucosidase allele. One patient had a novel TG deletion at cDNA position 379 + 380. Surprisingly five of the nine patients had the same two base pair changes: A921 --> T and G925 --> A. The first change is a well-known polymorphism but the second one is a novel mutation and results in the substitution of Gly309 by Arg. By screening 43 other GSDII patients the same mutation was found in two other cases, one from The Netherlands and one from France. To verify its deleterious effect, the mutation was introduced in the wild type lysosomal alpha-glucosidase cDNA and expressed in COS cells.

Glycogen Storage Disease type II: genetic and biochemical analysis of novel mutations in infantile patients from Turkish ancestry.

Glycogen Storage Disease type II (GSDII) is caused by the deficiency of lysosomal alpha-glucosidase (acid maltase). This paper reports on the characterization of the molecular defects in 6 infantile patients from Turkish ancestry. Five of the 6 patients had reduced levels of the lysosomal alpha-glucosidase precursor. Conversion to mature enzyme was impaired in all cases, and the lysosomal alpha-glucosidase activity in all patients fibroblasts was less than 0.5% of control. DNA sequence analysis revealed 3 new mutations. One mutation, found in 3 patients in homozygous form, was a double insertion in exon 19 (2471AG-->CAGG) leading to a frameshift after Pro 913. It is the first insertion mutation described in the lysosomal alpha-glucosidase gene. Two patients were homozygous for missense mutations leading to the substitution of Ser to Pro at amino acid 566 (S566P) in one case and of Pro to Arg at amino acid 768 (P768R) in the other. One patient was found to have a Gly to Arg missense mutation at amino acid 643 (G643R), previously identified in an adult patient (Hermans et al., 1993), combined with a silent second allele. The latter 3 mutations were introduced in the wild type lysosomal alpha-glucosidase cDNA and expressed in COS cells to analyze their effect. Precursor species of 110 kD were formed but the maturation was impaired. As a result there was an overall deficiency of catalytic activity, which is in accordance with the findings in the patients fibroblasts and with the clinical phenotype.

Generalized glycogen storage and cardiomegaly in a knockout mouse model of Pompe disease.

Glycogen storage disease type II (GSDII; Pompe disease), caused by inherited deficiency of acid alpha-glucosidase, is a lysosomal disorder affecting heart and skeletal muscles. A mouse model of this disease was obtained by targeted disruption of the murine acid alpha-glucosidase gene (Gaa) in embryonic stem cells. Homozygous knockout mice (Gaa -/-) lack Gaa mRNA and have a virtually complete acid alpha-glucosidase deficiency. Glycogen-containing lysosomes are detected soon after birth in liver, heart and skeletal muscle cells. By 13 weeks of age, large focal deposits of glycogen have formed. Vacuolar spaces stain positive for acid phosphatase as a sign of lysosomal pathology. Both male and female knockout mice are fertile and can be intercrossed to produce progeny. The first born knockout mice are at present 9 months old. Overt clinical symptoms are still absent, but the heart is typically enlarged and the electrocardiogram is abnormal. The mouse model will help greatly to understand the pathogenic mechanism of GSDII and is a valuable instrument to explore the efficacy of different therapeutic interventions.

Transferrin in cultured human term cytotrophoblast cells: synthesis and heterogeneity.

Transferrin (Tf) mRNA was recently demonstrated in rat and mouse placental tissue. Rat placental cells were shown to secrete transferrin. The cell type with which Tf mRNA was associated was not investigated. We therefore studied the ability of immunopurified human term cytotrophoblast cells in culture to synthesize Tf, by means of pulse-label experiments with 35S-methionine and report that these cells do synthesize Tf. Tf mRNA was demonstrated in the cell lysates by means of RT-PCR. Tf isolated from cytotrophoblast and syncytiotrophoblast cells was shown to be different from both maternal and fetal serum Tf with respect to the distribution of isoforms as demonstrated by means of iso-electric focusing. The iso-electric points were found at lower pH values (pH 5.0-5.4), compared to the iso-electric points of maternal and fetal serum Tf, suggesting a higher degree of sialylation and glycan chain complexity.

A novel acid alpha-glucosidase mutation identified in a Pakistani family with glycogen storage disease type II.

A novel mutation, C118T, in exon 2 of the acid alpha-glucosidase gene has been found in an infant with glycogen storage disease type II. This mutation is predicted to result in protein truncation. The phenotype was that of the severe infantile form of the disorder with lack of motor development, but with eye regard, social smile and vocalization. The parents were heterozygous for C118T and belong to an Islamic community opposed to termination of pregnancy. As the C118T mutation results in the loss of one of two AvaI sites present in an informative PCR product, reliable premarriage carrier detection became possible and was acceptable to the members of this extended family.