Frank-ter Haar syndrome associated with sagittal craniosynostosis and raised intracranial pressure

This male patient was the firstborn child, delivered by caesarean section for macrocephaly and cephalopelvic disproportion. Hypertelorism and dysmorphia were noted at birth, without evidence of fetal head constraint. He was referred to the Plastic Surgery Department for severe hypertelorism and forehead bossing. On examination at 20 months the head circumference was 49 cm (>99.6^th centile), with marked hypertelorism, frontal skull bossing, a wide open anterior fontanelle, and a persistent metopic suture. The cephalic index was 86% confirming the clinical appearance of mild brachycephaly (normal range 76-85%). Limb examination revealed severe bilateral cavo varus of the feet and bilateral metacarpo-phalangeal (MCP) joint hyperextension and contractures.

CT head and 3D studies at age 1 year and 10 months demonstrated patency of the major cranial sutures and confirmed the clinical findings of hypertelorism and an open anterior fontanelle. Surgical correction for bilateral cavo varus at age 7 years and 4 months was complicated by cardiopulmonary decompensation, pulmonary hypertension and a marked oxygen requirement during the post-operative period. Echocardiography demonstrated severe mitral valve prolapse with moderate mitral regurgitation, mild tricuspid valve prolapse and mild aortic regurgitation, however ventricular function was good at the time.

The diagnosis of Frank-ter Haar syndrome was initially suspected at the age of 18 months. The G-banded karyotype was normal (46,XY). Alternative clinical diagnoses considered included Winchester syndrome and geleophysic dysplasia, but genetic testing for these disorders was normal. The diagnosis was confirmed following the identification of the SH3PXD2B mutation at age 12 years and 4 months (Figure 2, Figure 3).

The mitral valve function subsequently deteriorated resulting in ventricular dilatation and requiring mitral valve repair at 12 years and 5 months. Examination at age 12 years and 11 months revealed a progressive lower limb oedema, which had been developing over a 2 year period, and was initially suspected to be a complication of his cardiac condition. Originally affecting the right leg only, it had progressed to involve the left groin, left leg and genitalia, and appeared to be lymphatic in origin. Lymphoscintigraphy studies at age 13 years and 10 months demonstrated profound lymphatic abnormalities in both lower legs and functional hypoplasia of the main draining lymphatics.

This patient has a left-sided astigmatism and meibomian gland dysfunction; however he does not have any of the ocular complications classically associated with Frank-ter Haar syndrome, such as megalocornea and glaucoma [7, 16]. Intraocular pressures have been within the normal range, without clinical evidence of glaucoma. He has been attending a mainstream school with learning support, and is under occupational therapy for difficulties with fine motor skills, washing and dressing as a result of the severe hand contractures and deformity.

This is the second affected sibling in the family, delivered by caesarean section for maternal proteinuria without evidence of fetal head constraint. Facial features including hypertelorism were noticed at birth. Examination on presentation to the craniofacial department at age 6 years and 6 months demonstrated hypertelorism, brachycephaly (cephalic index 89%), a flat nasal bridge, prominent ears, a class III malocclusion and hypoplastic teeth. Her fingers and toes appeared shortened and exostoses on the dorsal aspect of the radius and ulna were visible on examination of the arms.

CT head and 3D studies were carried out at age 6 years and 10 months to further delineate the craniofacial features. This demonstrated sagittal synostosis, however the skull was not scaphocephalic in shape, but instead appeared brachycephalic in keeping with the clinical examination findings. There was evidence of limited space within the supratentorial compartment, and small ventricles. Although neurological development had previously been within normal limits, difficulties with literacy and recurrent headaches were reported at this time, also suggestive of raised ICP. ICP monitoring (Codman Microsensor, Codman and Shurtleff Inc., Raynham, Mass.) demonstrated elevated pressures with a mean of 22 mmHg and 5 significant associated B-waves. Calvarial expansion was successfully undertaken. She made a good post-operative recovery, and the headaches subsequently resolved.

This sibling has also developed cardiac complications but has been less severely affected than her older sibling. Echocardiography at age 7 years and 6 months demonstrated mild-moderate mitral regurgitation with mitral valve prolapse, and minimal aortic regurgitation. Left ventricular function is currently stable. The diagnosis of Frank-ter Haar syndrome was made at age 7 years and 7 months following genetic analysis of the family (Figure 2).

This patient has not developed any of the ocular complications classically associated with Frank-ter Haar syndrome and intraocular pressures and appearance of the retina have been within normal limits. She has been attending a mainstream school, but has experienced some difficulties with literacy.

Patient 3 is the younger affected male sibling. He was delivered by caesarean section following a normal pregnancy, without evidence of fetal head constraint. Facial features in keeping with Frank-ter Haar syndrome were noticed soon after birth including hypertelorism, a broad forehead, wide anterior fontanelle, brachycephaly and prominent ears. The diagnosis of Frank-ter Haar syndrome was made at age 6 years and 5 months, following genetic analysis of the family (Figure 2).

CT head and 3D studies were performed at age 6 years and 9 months following the outcome of these investigations in Patient 2. Evidence of sagittal synostosis without scaphocephaly, a flattened occiput and shortened AP diameter were identified on CT. There was hypoplasia of the inferior vermis but an otherwise normal appearance of the brain. Given the history of raised ICP in his sibling, ICP monitoring was undertaken at age 6 years and 10 months, demonstrating a mean pressure of 10 mmHg but 7 B waves, indicating raised ICP.

Examination at age 7 years and 1 month demonstrated an anterior open bite, class III malocclusion, hypoplasic teeth and skeletal features including short fingers and toes, and a mild positional talipes. The cephalic index was 88% in keeping with the clinical appearance of brachycephaly. Calvarial expansion was performed at age 7 years and 7 months.

Cardiac complications have also been documented, but have been less severe than the other affected siblings, with evidence of mild mitral regurgitation on echocardiography. No ocular complications have been reported, and intraocular pressures have been within the normal range. He has required some learning support for literacy and numeracy, but developmental progress and performance at school have been within normal limits.

We genotyped DNA samples from three affected patients, one unaffected sibling and their parents using the Affymetrix GeneChip® Human Mapping 250K Sty Array. Linkage analysis was performed assuming autosomal recessive inheritance, full penetrance, consanguinity and a disease allele frequency of 0.0001. Multipoint LOD scores were calculated using the program ALLEGRO [17]. We identified three regions of shared homozygosity on chromosomes 5 (150943995–173861414; hg18 coordinates), 8 (134041593–146264218) and 12 (115552170–123960781). Following the identification of mutations in Frank-ter Haar syndrome [7], it was noted that the region of homozygosity on chromosome 5 included the SH3PXD2B gene. All coding exons of SH3PXD2B were therefore PCR amplified in samples from the family (primer sequences available on request). As exon 13 failed to amplify (using primers 13F, 5^′-AACATCTCCATTGGTGGTCC-3^′ and 13R, 5^′-GATGTGTTTGGCTGGCATC-3^′, positions of primers are shown in Figure 2) in the affected individuals, an alternative primer pair (13-2F, 5^′-CATGTAAGATATTCCCGGAACATGGT-3^′; 13-2R, 5^′-CCCCATGTCATTTTTCAGCTGGAACA-3^′) was designed to rule out the possibility of a SNP underlying the primer and preventing annealing. This also failed to amplify in the 3 affected individuals, confirming a homozygous deletion of exon 13 of SH3PXD2B. Further primer pairs were designed throughout the 3^′ untranslated region (UTR) to identify the extent of the deletion (primer sequences available on request), a primer pair near the end of the 3^′ UTR successfully amplified in the affected individuals (13-7F, 5^′-TACCTTACATCCCAGGGCAAACGGACAGCT-3^′; 13-7R, 5^′-GCGTGGCCTTGTGGCAGAGGTTTAAAATGAC-3^′), the reverse primer of which was then used in a long PCR with the 12F primer (5^′-AATCCAACTAGGTCCCCAGC-3^′). This yielded a truncated product of ~3.5 kb rather than the normal 11,464 kb, which was sequenced to identify the exact breakpoint. All family members produced this smaller PCR product, demonstrating that unaffected members are heterozygous carriers of the allele bearing the deletion, which preferentially amplifies during PCR. The non-deleted allele was demonstrated by PCR between 12F and 13-8R (5^′-CATAACACATCCTGAAGATAAACAGCCTAGACA-3^′). The complete deletion of the coding part of exon 13 is predicted to abolish over half of the protein, including the SH3 domains and a proline-rich domain (Figure 3).