Utility of genetic testing for prenatal presentations of hypophosphatasia.

Hypophosphatasia (HPP) is a rare inherited disease affecting bone and dental mineralization due to loss-of-function mutations in the ALPL gene encoding the tissue nonspecific alkaline phosphatase (TNSALP). Prenatal benign HPP (PB HPP) is a rare form of HPP characterized by in utero skeletal manifestations that progressively improve during pregnancy but often still leave symptoms after birth. Because the prenatal context limits the diagnostic tools, the main difficulty for clinicians is to distinguish PB HPP from perinatal lethal HPP, the most severe form of HPP. We previously attempted to improve genotype phenotype correlation with the help of a new classification of variants based on functional testing. Among 46 perinatal cases detected in utero or in the neonatal period for whose ALPL variants could be classified, imaging alone was thought to clearly diagnose severe lethal HPP in 35 cases, while in 11 cases, imaging abnormalities could not distinguish between perinatal lethal and BP HPP. We show here that our classification of ALPL variants may improve the ability to distinguish between perinatal lethal and PB HPP in utero.

Molecular diagnosis of hypophosphatasia and differential diagnosis by targeted Next Generation Sequencing.

Hypophosphatasia (HPP) is a rare inherited skeletal dysplasia due to loss of function mutations in the ALPL gene. The disease is subject to an extremely high clinical heterogeneity ranging from a perinatal lethal form to odontohypophosphatasia affecting only teeth. Up to now genetic diagnosis of HPP is performed by sequencing the ALPL gene by Sanger methodology. Osteogenesis imperfecta (OI) and campomelic dysplasia (CD) are the main differential diagnoses of severe HPP, so that in case of negative result for ALPL mutations, OI and CD genes had often to be analyzed, lengthening the time before diagnosis. We report here our 18-month experience in testing 46 patients for HPP and differential diagnosis by targeted NGS and show that this strategy is efficient and useful. We used an array including ALPL gene, genes of differential diagnosis COL1A1 and COL1A2 that represent 90% of OI cases, SOX9, responsible for CD, and 8 potentially modifier genes of HPP. Seventeen patients were found to carry a mutation in one of these genes. Among them, only 10 out of 15 cases referred for HPP carried a mutation in ALPL and 5 carried a mutation in COL1A1 or COL1A2. Interestingly, three of these patients were adults with fractures and/or low BMD. Our results indicate that HPP and OI may be easily misdiagnosed in the prenatal stage but also in adults with mild symptoms for these diseases.

A molecular-based estimation of the prevalence of hypophosphatasia in the European population.

The prevalence of hypophosphatasia (HP), a rare metabolic disorder due to loss-of-function mutations in the ALPL gene, has never been estimated in the European population. Only one published study evaluated the incidence of severe HP at 1/100,000 in Canada 53 years ago. Moderate forms of hypophosphatasia (mHP), including HP with moderate bone features and the mildest form odontohypophosphatasia, reflect both recessive and dominant inheritance, and are therefore expected to be more frequent than severe forms of HP. Here we estimated both the prevalences of severe and mHP in European populations. The prevalence of severe HP was estimated at 1/300,000 on the basis of the number of cases tested in our laboratory and originating from France during the period 2000-2009. The prevalence of mHP was then estimated by using the proportion of dominant mutations among severe alleles and by estimating the penetrance of the disease in heterozygotes for dominant mutations. According to a genetic model with four alleles resulting in 10 distinct genotypes, the prevalence of dominant mHP in the European population was estimated to be 1/6370, pointing out that mHP is much more frequent than severe HP.

Hypophosphatasia: a genetic-based nosology and new insights in genotype-phenotype correlation.

Hypophosphatasia (HPP) is caused by pathogenic variants in the ALPL gene. There is a large continuum in the severity, ranging from a lethal perinatal form to dental issues. We analyzed a cohort of 424 HPP patients from European geographic origin or ancestry. Using 3D modeling and results of functional tests we classified ALPL pathogenic variants according to their dominant negative effect (DNE) and their severity. The cohort was described by the genotypes resulting from alleles s (severe recessive), Sd (severe dominant), and m (moderate). Many recurrent variants showed a regional anchor pointing out founder effects rather than multiple mutational events. Homozygosity was an aggravating factor of the severity and moderate alleles were rare both in number and frequency. Pathogenic variants with DNE were found in both recessive and dominant HPP. Sixty percent of the adults tested were heterozygous for a variant showing no DNE, suggesting another mechanism of dominance like haploinsufficiency. Adults with dominant HPP without DNE were found statistically less severely affected than adults with DNE variants. Adults with dominant HPP without DNE represent a new clinical entity mostly diagnosed from 2010s, characterized by nonspecific signs of HPP and low alkaline phosphatase, and for which a high prevalence is expected. In conclusion, the genetic composition of our cohort suggests a nosology with 3 clinical forms: severe HPP is recessive and rare, moderate HPP is recessive or dominant and more common, and mild HPP, characterized by low alkaline phosphatase and unspecific clinical signs, is dominantly inherited and very common.

Delayed transport of tissue-nonspecific alkaline phosphatase with missense mutations causing hypophosphatasia.

Hypophosphatasia is a rare genetic disease characterized by diminished bone and tooth mineralization due to deficient activity of tissue-nonspecific alkaline phosphatase (TNSALP). The disease is clinically heterogeneous due to different mutations in the TNSALP gene. In order to determine whether mutated TNSALP proteins may be sequestered, degraded, or subjected to delay in their transport to the cell membrane, we built a plasmid expressing a YFP-TNSALP fluorescent fusion protein allowing the observation of cellular localization in live cells by fluorescence confocal microscopy at different time points after transfection. We studied five mutants (c. 571G>A, c. 653T>C, c. 746G>T, c. 1363G>A and c. 1468A>T) exhibiting various levels of in vitro residual enzymatic activity. While the wild-type protein reached the membrane within the first 24h after transfection, the mutants reached the membrane with delays of 24, 48 or 72 h. For all of the tested mutations, accumulation of the mutated proteins, mainly in the Golgi apparatus, was observed. We concluded that reduced ALP activity of these TNSALP mutants results from structural disturbances and delay in membrane anchoring, and not from compromised catalytic activity.

Characterization of missense mutations and large deletions in the ALPL gene by sequencing and quantitative multiplex PCR of short fragments.

Hypophosphatasia is a rare inherited bone disorder characterized by defective bone and dental mineralization and deficiency of serum and liver/bone/kidney alkaline phosphatase activity. The disease is due to mutations in the alkaline phosphatase liver-type (ALPL) gene. Gross deletions or insertions have not previously been reported in this gene. We report here the characterization of nine novel ALPL gene mutations in a series of 8 patients affected by various forms of hypophosphatasia. The newly discovered mutations included five missense mutations (c.368C --> A, c.814C--> T, c.1196C--> T, c.1199C--> T, c.1283G--> C), two small deletions (c.797_802del, c.1044_1055del), and two large deletions. The large deletions were detected by quantitative multiplex polymerase chain reaction (PCR) of short fluorescent fragments (QMPSF). We conclude that QMPSF slightly reduces the proportion of undetected mutations in hypophosphatasia and improves genetic counselling in the affected families.