Periodontal Defects in the A116T Knock-in Murine Model of Odontohypophosphatasia.

Mutations in ALPL result in hypophosphatasia (HPP), a disease causing defective skeletal mineralization. ALPL encodes tissue nonspecific alkaline phosphatase (ALP), an enzyme that promotes mineralization by reducing inorganic pyrophosphate, a mineralization inhibitor. In addition to skeletal defects, HPP causes dental defects, and a mild clinical form of HPP, odontohypophosphatasia, features only a dental phenotype. The Alpl knockout (Alpl (-/-)) mouse phenocopies severe infantile HPP, including profound skeletal and dental defects. However, the severity of disease in Alpl (-/-) mice prevents analysis at advanced ages, including studies to target rescue of dental tissues. We aimed to generate a knock-in mouse model of odontohypophosphatasia with a primarily dental phenotype, based on a mutation (c.346G>A) identified in a human kindred with autosomal dominant odontohypophosphatasia. Biochemical, skeletal, and dental analyses were performed on the resulting Alpl(+/A116T) mice to validate this model. Alpl(+/A116T) mice featured 50% reduction in plasma ALP activity compared with wild-type controls. No differences in litter size, survival, or body weight were observed in Alpl(+/A116T) versus wild-type mice. The postcranial skeleton of Alpl(+/A116T) mice was normal by radiography, with no differences in femur length, cortical/trabecular structure or mineral density, or mechanical properties. Parietal bone trabecular compartment was mildly altered. Alpl(+/A116T) mice featured alterations in the alveolar bone, including radiolucencies and resorptive lesions, osteoid accumulation on the alveolar bone crest, and significant differences in several bone properties measured by micro-computed tomography. Nonsignificant changes in acellular cementum did not appear to affect periodontal attachment or function, although circulating ALP activity was correlated significantly with incisor cementum thickness. The Alpl(+/A116T) mouse is the first model of odontohypophosphatasia, providing insights on dentoalveolar development and function under reduced ALP, bringing attention to direct effects of HPP on alveolar bone, and offering a new model for testing potential dental-targeted therapies in future studies.

The molecular aetiology of haemophilia A in a New Zealand patient group.

The genetic basis of haemophilia A (HA) is well-established, and many haematology services are supported by molecular biology laboratories that offer factor VIII genetic testing for HA patients. This report describes the results from factor VIII gene (F8) analysis of a New Zealand cohort of 45 proband HA patients. We screened all proband HA patients attending local clinics to determine the molecular basis of disease in each case. We also aimed to evaluate the significance of founder effect in this population and to explain an unusual case of HA in a female patient. HA patients were screened for the common F8 gene inversion mutations using previously described PCR-based techniques, and for single base substitution mutations using denaturing high performance liquid chromatography and DNA sequencing. Analysis of microsatellite markers located within or near F8 was used to determine identity by descent and trace inheritance patterns of disease alleles. X-chromosome inactivation (XCI) patterns were detected using methylation specific PCR. Pathogenic F8 gene mutations were detected in all 45 HA patients in this cohort and non-random XCI was confirmed in a female haemophiliac. We report nine novel F8 mutations, including two splicing mutations, a five nucleotide deletion and a large deletion at the 5' end of the gene. The molecular aetiology of HA was similar to that described in other studies but the distribution of mutations was unusual due to founder effects, with almost a quarter of all probands being descended from just three individuals.