Linkage of otopalatodigital syndrome type 2 (OPD2) to distal Xq28: evidence for allelism with OPD1.

Otopalatodigital syndrome type 1 (OPD1) is an X-linked semidominant condition characterized by malformations of the skeleton, auditory apparatus, and palate. Previous studies have established linkage to a 16-cM region of Xq27-q28. A proposed allelic variant of OPD1, termed "OPD2," is associated with a more severe, frequently lethal phenotype with visceral and brain anomalies in addition to skeletal, auditory, and palatal defects. We report linkage of the OPD2 phenotype to a 2-cM region of distal Xq28 in a Maori kindred, with a maximum multipoint LOD score of 3.31 between the markers DXS1073 and DXS1108. This provides support for allelism between OPD1 and OPD2 and reduces the size of the disease interval to 1.8-2.1 Mb. We also demonstrate that female carriers of this disorder exhibit skewed inactivation that segregates with the high-risk haplotype and may be inversely related to the severity with which they manifest features of the disorder.

Craniosynostosis and related limb anomalies.

Many genetically determined craniosynostosis syndromes feature limb anomalies, implying that pathways of cranial suture and limb morphogenesis share some identical components. Identification of heterozygous mutations in FGFR1, FGFR2, FGFR3, TWIST and MSX2 in craniosynostosis has focused particular attention on these genes. Here we explore two themes: use of clinical/molecular analysis to provide new clues to pathophysiology and the contrasting effects of loss- and gain-of-function mutations. Apert syndrome is a severe craniosynostosis/syndactyly disorder usually caused by specific substitutions (Ser252Trp or Pro253Arg) in FGFR2. The relative severity of cranial and limb malformations varies in opposite directions for the two mutations, suggesting that these phenotypes arise by different mechanisms. Clinical and biochemical evidence supports a model in which alternative splice forms of FGFR2 mediate these distinct effects. Pro-->Arg substitutions equivalent the Pro253Arg/FGFR2 mutation occur in both FGFR1 and FGFR3, and are also associated with craniosynostosis. This suggests a common pathological mechanism, whereby enhanced affinity for a limited repertoire of tissue-specific ligand(s) excessively prolongs signalling in the cranial suture. The first MSX2 mutation in craniosynostosis was described in 1993 but this remains the only example. We have recently identified three MSX2 mutations associated with a different cranial phenotype, parietal foramina. DNA binding studies show that the craniosynostosis and parietal foramina arise from gain and loss of function, respectively.

Newly recognised craniosynostosis syndrome that does not map to known disease loci.

We describe a consanguineous family of Pakistani origin with five sibs, three of whom were affected by craniosynostosis of variable presentation. In addition, they had other congenital abnormalities principally affecting neurological, ocular, and limb development. We provide linkage evidence using intragenic and flanking microsatellite markers suggesting that the disease in this family was not caused by a mutation in one of the known craniosynostosis loci (FGFR1, FGFR2, FGFR3, MSX2, TWIST). Given the clinical novelty and parental consanguinity, we hypothesise that the affected individuals were autozygous for a recessively inherited mutation, at a novel locus, predisposing to craniosynostosis.

Potential gene conversion and source genes for recently integrated Alu elements.

Alu elements comprise >10% of the human genome. We have used a computational biology approach to analyze the human genomic DNA sequence databases to determine the impact of gene conversion on the sequence diversity of recently integrated Alu elements and to identify Alu elements that were potentially retroposition competent. We analyzed 269 Alu Ya5 elements and identified 23 members of a new Alu subfamily termed Ya5a2 with an estimated copy number of 35 members, including the de novo Alu insertion in the NF1 gene. Our analysis of Alu elements containing one to four (Ya1-Ya4) of the Ya5 subfamily-specific mutations suggests that gene conversion contributed as much as 10%-20% of the variation between recently integrated Alu elements. In addition, analysis of the middle A-rich region of the different Alu Ya5 members indicates a tendency toward expansion of this region and subsequent generation of simple sequence repeats. Mining the databases for putative retroposition-competent elements that share 100% nucleotide identity to the previously reported de novo Alu insertions linked to human diseases resulted in the retrieval of 13 exact matches to the NF1 Alu repeat, three to the Alu element in BRCA2, and one to the Alu element in FGFR2 (Apert syndrome). Transient transfections of the potential source gene for the Apert's Alu with its endogenous flanking genomic sequences demonstrated the transcriptional and presumptive transpositional competency of the element.

Distinct mutations in the receptor tyrosine kinase gene ROR2 cause brachydactyly type B.

Brachydactyly type B (BDB) is an autosomal dominant skeletal disorder characterized by hypoplasia/aplasia of distal phalanges and nails. Recently, heterozygous mutations of the orphan receptor tyrosine kinase (TK) ROR2, located within a distinct segment directly after the TK domain, have been shown to be responsible for BDB. We report four novel mutations in ROR2 (two frameshifts, one splice mutation, and one nonsense mutation) in five families with BDB. The mutations predict truncation of the protein within two distinct regions immediately before and after the TK domain, resulting in a complete or partial loss of the intracellular portion of the protein. Patients affected with the distal mutations have a more severe phenotype than do those with the proximal mutation. Our analysis includes the first description of homozygous BDB in an individual with a 5-bp deletion proximal to the TK domain. His phenotype resembles an extreme form of brachydactyly, with extensive hypoplasia of the phalanges and metacarpals/metatarsals and absence of nails. In addition, he has vertebral anomalies, brachymelia of the arms, and a ventricular septal defect-features that are reminiscent of Robinow syndrome, which has also been shown to be caused by mutations in ROR2. The BDB phenotype, as well as the location and the nature of the BDB mutations, suggests a specific mutational effect that cannot be explained by simple haploinsufficiency and that is distinct from that in Robinow syndrome.

Recessive Robinow syndrome, allelic to dominant brachydactyly type B, is caused by mutation of ROR2.

The autosomal recessive form of Robinow syndrome (RRS; MIM 268310) is a severe skeletal dysplasia with generalized limb bone shortening, segmental defects of the spine, brachydactyly and a dysmorphic facial appearance. We previously mapped the gene mutated in RRS to chromosome 9q22 (ref. 4), a region that overlaps the locus for autosomal dominant brachydactyly type B (refs 5,6). The recent identification of ROR2, encoding an orphan receptor tyrosine kinase, as the gene mutated in brachydactyly type B (BDB1; ref. 7) and the mesomelic dwarfing in mice homozygous for a lacZ and/or a neo insertion into Ror2 (refs 8,9) made this gene a candidate for RRS. Here we report homozygous missense mutations in both intracellular and extracellular domains of ROR2 in affected individuals from 3 unrelated consanguineous families, and a nonsense mutation that removes the tyrosine kinase domain and all subsequent 3' regions of the gene in 14 patients from 7 families from Oman. The nature of these mutations suggests that RRS is caused by loss of ROR2 activity. The identification of mutations in three distinct domains (containing Frizzled-like, kringle and tyrosine kinase motifs) indicates that these are all essential for ROR2 function.

Dominant mutations in ROR2, encoding an orphan receptor tyrosine kinase, cause brachydactyly type B.

Inherited limb malformations provide a valuable resource for the identification of genes involved in limb development. Brachydactyly type B (BDB), an autosomal dominant disorder, is the most severe of the brachydactylies and characterized by terminal deficiency of the fingers and toes. In the typical form of BDB, the thumbs and big toes are spared, sometimes with broadening or partial duplication. The BDB1 locus was previously mapped to chromosome 9q22 within an interval of 7.5 cM (refs 9,10). Here we describe mutations in ROR2, which encodes the orphan receptor tyrosine kinase ROR2 (ref. 11), in three unrelated families with BDB1. We identified distinct heterozygous mutations (2 nonsense, 1 frameshift) within a 7-amino-acid segment of the 943-amino-acid protein, all of which predict truncation of the intracellular portion of the protein immediately after the tyrosine kinase domain. The localized nature of these mutations suggests that they confer a specific gain of function. We obtained further evidence for this by demonstrating that two patients heterozygous for 9q22 deletions including ROR2 do not exhibit BDB. Expression of the mouse mouse orthologue, Ror2, early in limb development indicates that BDB arises as a primary defect of skeletal patterning.

Paternal origin of FGFR2 mutations in sporadic cases of Crouzon syndrome and Pfeiffer syndrome.

Crouzon syndrome and Pfeiffer syndrome are both autosomal dominant craniosynostotic disorders that can be caused by mutations in the fibroblast growth factor receptor 2 (FGFR2) gene. To determine the parental origin of these FGFR2 mutations, the amplification refractory mutation system (ARMS) was used. ARMS PCR primers were developed to recognize polymorphisms that could distinguish maternal and paternal alleles. A total of 4,374 bases between introns IIIa and 11 of the FGFR2 gene were sequenced and were assayed by heteroduplex analysis, to identify polymorphisms. Two polymorphisms (1333TA/TATA and 2710 C/T) were found and were used with two previously described polymorphisms, to screen a total of 41 families. Twenty-two of these families were shown to be informative (11 for Crouzon syndrome and 11 for Pfeiffer syndrome). Eleven different mutations in the 22 families were detected by either restriction digest or allele-specific oligonucleotide hybridization of ARMS PCR products. We molecularly proved the origin of these different mutations to be paternal for all informative cases analyzed (P=2. 4x10-7; 95% confidence limits 87%-100%). Advanced paternal age was noted for the fathers of patients with Crouzon syndrome or Pfeiffer syndrome, compared with the fathers of control individuals (34. 50+/-7.65 years vs. 30.45+/-1.28 years, P<.01). Our data on advanced paternal age corroborates and extends previous clinical evidence based on statistical analyses as well as additional reports of advanced paternal age associated with paternal origin of three sporadic mutations causing Apert syndrome (FGFR2) and achondroplasia (FGFR3). Our results suggest that older men either have accumulated or are more susceptible to a variety of germline mutations.

De novo alu-element insertions in FGFR2 identify a distinct pathological basis for Apert syndrome.

Apert syndrome, one of five craniosynostosis syndromes caused by allelic mutations of fibroblast growth-factor receptor 2 (FGFR2), is characterized by symmetrical bony syndactyly of the hands and feet. We have analyzed 260 unrelated patients, all but 2 of whom have missense mutations in exon 7, which affect a dipeptide in the linker region between the second and third immunoglobulin-like domains. Hence, the molecular mechanism of Apert syndrome is exquisitely specific. FGFR2 mutations in the remaining two patients are distinct in position and nature. Surprisingly, each patient harbors an Alu-element insertion of approximately 360 bp, in one case just upstream of exon 9 and in the other case within exon 9 itself. The insertions are likely to be pathological, because they have arisen de novo; in both cases this occurred on the paternal chromosome. FGFR2 is present in alternatively spliced isoforms characterized by either the IIIb (exon 8) or IIIc (exon 9) domains (keratinocyte growth-factor receptor [KGFR] and bacterially expressed kinase, respectively), which are differentially expressed in mouse limbs on embryonic day 13. Splicing of exon 9 was examined in RNA extracted from fibroblasts and keratinocytes from one patient with an Alu insertion and two patients with Pfeiffer syndrome who had nucleotide substitutions of the exon 9 acceptor splice site. Ectopic expression of KGFR in the fibroblast lines correlated with the severity of limb abnormalities. This provides the first genetic evidence that signaling through KGFR causes syndactyly in Apert syndrome.

Brachydactyly type B: linkage to chromosome 9q22 and evidence for genetic heterogeneity.

Brachydactyly type B (BDB), an autosomal dominant disorder, is the most severe of the brachydactylies and is characterized by hypoplasia or absence of the terminal portions of the index to little fingers, usually with absence of the nails. The thumbs may be of normal length but are often flattened and occasionally are bifid. The feet are similarly but less severely affected. We have performed a genomewide linkage analysis of three families with BDB, two English and one Portugese. The two English families show linkage to the same region on chromosome 9 (combined multipoint maximum LOD score 8.69 with marker D9S257). The 16-cM disease interval is defined by recombinations with markers D9S1680 and D9S1786. These two families share an identical disease haplotype over 18 markers, inclusive of D9S278-D9S280. This provides strong evidence that the English families have the same ancestral mutation, which reduces the disease interval to <12.7 cM between markers D9S257 and D9S1851 in chromosome band 9q22. In the Portuguese family, we excluded linkage to this region, a result indicating that BDB is genetically heterogeneous. Reflecting this, there were atypical clinical features in this family, with shortening of the thumbs and absence or hypoplasia of the nails of the thumb and hallux. These results enable a refined classification of BDB and identify a novel locus for digit morphogenesis in 9q22.

A comprehensive screen for TWIST mutations in patients with craniosynostosis identifies a new microdeletion syndrome of chromosome band 7p21.1.

Mutations in the coding region of the TWIST gene (encoding a basic helix-loop-helix transcription factor) have been identified in some cases of Saethre-Chotzen syndrome. Haploinsufficiency appears to be the pathogenic mechanism involved. To investigate the possibility that complete deletions of the TWIST gene also contribute to this disorder, we have developed a comprehensive strategy to screen for coding-region mutations and for complete gene deletions. Heterozygous TWIST mutations were identified in 8 of 10 patients with Saethre-Chotzen syndrome and in 2 of 43 craniosynostosis patients with no clear diagnosis. In addition to six coding-region mutations, our strategy revealed four complete TWIST deletions, only one of which associated with a translocation was suspected on the basis of conventional cytogenetic analysis. This case and two interstitial deletions were detectable by analysis of polymorphic microsatellite loci, including a novel (CA)n locus 7.9 kb away from TWIST, combined with FISH; these deletions ranged in size from 3.5 Mb to >11.6 Mb. The remaining, much smaller deletion was detected by Southern blot analysis and removed 2,924 bp, with a 2-bp orphan sequence at the breakpoint. Significant learning difficulties were present in the three patients with megabase-sized deletions, which suggests that haploinsufficiency of genes neighboring TWIST contributes to developmental delay. Our results identify a new microdeletion disorder that maps to chromosome band 7p21.1 and that causes a significant proportion of Saethre-Chotzen syndrome.

Conserved use of a non-canonical 5' splice site (/GA) in alternative splicing by fibroblast growth factor receptors 1, 2 and 3.

The two classes of sequences for recognition and splicing of pre-mRNA in eukaryotes, GT-AG and AT-AC, are characterized by the nearly invariant dinucleotides present at the extreme 5' (donor) and 3' (acceptor) ends of the intron. Amongst GT-AG introns, which comprise the vast majority, the more extended consensus sequence at the 5' splice site isACAG/GTAGAGT (where / indicates the exon-intron boundary). This sequence is complementary to part of the U1 snRNA and is important in intron recognition. We have determined the genomic structure of the mouse fibroblast growth factor receptor 2 gene (Fgfr2) and identified a divergent 5' splice site (ACA/GAAAGT), conserved in FGFR1 , - 2 and - 3 from humans, mice and Xenopus that is used for alternative splicing of a hexanucleotide sequence, encoding Val-Thr, at the end of exon 10. This is the only example known of the use of /GA in vertebrate splicing. Similarities to a splice site in the Antennapedia gene of Drosophila suggest that this variant motif is involved in alternative splicing of short sequences at the 5' splice site. Inclusion or exclusion of the Val-Thr dipeptide may play an important role in controlling FGFR signalling through the Ras/MAPK pathway.

Dominant coloboma-microphthalmos syndrome associated with sensorineural hearing loss, hematuria, and cleft lip/palate.

Ocular colobomas and microphthalmos, isolated or as part of a syndrome, are usually sporadic and only rarely found in large families. A 4-generation family with autosomal dominant uveal coloboma and microphthalmos associated with cleft lip and palate was re-evaluated. Wide variability in expression is evident and more recently recognized manifestations include a complete spectrum of eye involvement, impairment of extraocular movement, mid-frequency sensorineural hearing loss, and hematuria. Learning difficulties requiring remedial teaching were present in one third of those affected and a neural tube defect has occurred in one presumed affected member. This family appears to present a unique phenotype, which provides an opportunity to identify a genetic locus involved in eye, ear, renal, primary palate, and brain development.

Interstitial deletion of 2q associated with craniosynostosis, ocular coloboma, and limb abnormalities: cytogenetic and molecular investigation.

We report on the clinical and cytogenetic findings in a 9-year-old boy with a de novo deletion of 2q, shown by molecular analysis to have arisen from the paternal chromosome. Examination of microsatellite markers indicated deletion of bands 2q24.3 and 2q31. Clinical findings included craniosynostosis, bilateral ocular colobomata, and limb abnormalities, the latter being an emerging association with deletion of this region of 2q.

Prevalence of Pro250Arg mutation of fibroblast growth factor receptor 3 in coronal craniosynostosis.

BACKGROUND: The C749G (Pro250Arg) mutation in the gene for fibroblast growth factor receptor 3 (FGFR3) has been found in patients with various types of craniosynostosis. We aimed to find out the proportion of cases of apparently non-syndromic coronal craniosynostosis attributable to this mutation. METHODS: We studied 26 patients with coronal craniosynostosis but no syndromic diagnosis, who were referred to a supra-regional specialist centre. Genomic DNA was analysed by PCR and restriction-enzyme digestion to identify the C749G mutation in FGFR3. Family members of patients found to have the mutation were also tested. FINDINGS: Eight (31%) of the 26 probands were heterozygous for the C749G mutation. In two cases, the mutation showed autosomal dominant transmission with evidence of variable expressivity; the remaining six cases were sporadic. We demonstrated in six families that the mutation had arisen de novo from clinically unaffected parents. INTERPRETATION: The C749G mutation in FGFR3 is a frequent cause of apparently non-syndromic coronal craniosynostosis. Our finding will aid genetic counselling and prenatal diagnosis. The mutation rate at this nucleotide is one of the highest described in the human genome.

Genotype-phenotype correlation for nucleotide substitutions in the IgII-IgIII linker of FGFR2.

Dominantly acting, allelic mutations of the fibroblast growth factor receptor 2 (FGFR2) gene have been described in five craniosynostosis syndromes. In Apert syndrome, characterised by syndactyly of the hands and feet, recurrent mutations of a serine-proline dipeptide (either Ser252Trp or Pro253Arg) in the linker between the IgII and IgIII extracellular immunoglobulin-like domains, have been documented in more than 160 unrelated individuals. We have identified three novel mutations of this dipeptide, associated with distinct phenotypes. A C-->T mutation that predicts a Ser252Leu substitution, ascertained in a boy with mild Crouzon syndrome (craniosynostosis with normal limbs) is also present in three clinically normal members of his family. A CG-->TT mutation that predicts a Ser252Phe substitution results in a phenotype consistent with Apert syndrome. Finally, a CGC-->TCT mutation that predicts a double amino acid substitution (Ser252Phe and Pro253Ser) causes a Pfeiffer syndrome variant with mild craniosynostosis, broad thumbs and big toes, fixed extension of several digits, and only minimal cutaneous syndactyly. The observation that the Ser252Phe mutation causes Apert syndrome, whereas the other single or double substitutions are associated with milder or normal phenotypes, highlights the exquisitely specific molecular pathogenesis of the limb and craniofacial abnormalities associated with Apert syndrome. Ser252Phe is the first noncanonical mutation to be identified in this disorder, its rarity being explained by the requirement for two residues of the serine codon to be mutated. The description of independent, complex nucleotide substitutions involving identical nucleotides is unprecedented, and we speculate that this may result from functional selection of FGFR mutations in sperm.

Exclusive paternal origin of new mutations in Apert syndrome.

Apert syndrome results from one or other of two specific nucleotide substitutions, both C-->G transversions, in the fibroblast growth factor receptor 2 (FGFR2) gene. The frequency of new mutations, estimated as 1 per 65,000 live births, implies germline transversion rates at these two positions are currently the highest known in the human genome. Using a novel application of the amplification refractory mutation system (ARMS), we have determined the parental origin of the new mutation in 57 Apert families: in every case, the mutation arose from the father. This identifies the biological basis of the paternal age effect for new mutations previously suggested for this disorder.

Differential effects of FGFR2 mutations on syndactyly and cleft palate in Apert syndrome.

Apert syndrome is a distinctive human malformation characterized by craniosynostosis and severe syndactyly of the hands and feet. It is caused by specific missense substitutions involving adjacent amino acids (Ser252Trp or Pro253Arg) in the linker between the second and third extracellular immunoglobulin domains of fibroblast growth factor receptor 2 (FGFR2). We have developed a simple PCR assay for these mutations in genomic DNA, based on the creation of novel (SfiI) and (BstUI) restriction sites. Analysis of DNA from 70 unrelated patients with Apert syndrome showed that 45 had the Ser252Trp mutation and 25 had the Pro253Arg mutation. Phenotypic differences between these two groups of patients were investigated. Significant differences were found for severity of syndactyly and presence of cleft palate. The syndactyly was more severe with the Pro253Arg mutation, for both the hands and the feet. In contrast, cleft palate was significantly more common in the Ser252Trp patients. No convincing differences were found in the prevalence of other malformations associated with Apert syndrome. We conclude that, although the phenotype attributable to the two mutations is very similar, there are subtle differences. The opposite trends for severity of syndactyly and cleft palate in relation to the two mutations may relate to the varying patterns of temporal and tissue-specific expression of different fibroblast growth factors, the ligands for FGFR2.

Mutations in the third immunoglobulin domain of the fibroblast growth factor receptor-2 gene in Crouzon syndrome.

Craniosynostosis, which affects approximately 1 in 2000 children, is the result of the abnormal development and/or premature fusion of the cranial sutures. Studies of mutations in patients with craniosynostosis have shown that the family of fibroblast growth factor receptor genes are extremely important in the correct formation of the skull, and digits. Mutations in the third immunoglobulin domain of fibroblast growth factor receptor 2 (FGFR2), in part of the molecule corresponding to a tissue specific isoform (IIIc), can cause both Crouzon and Pfeiffer syndromes. Two specific mutations in the linking region between the second and third immunoglobulin domains of FGFR2 occur in Apert syndrome. We present here mutations associated with the Crouzon syndrome, also in the third immunoglobulin domain but in an upstream exon. This exon is expressed in both tissue isoforms. Five different mutations were detected in 11 unrelated individuals. A cysteine to phenylalanine change was found in six individuals. This cysteine forms half of the disulphide bridge maintaining the secondary structure of the immunoglobulin domain. The first deletion within an FGFR gene is reported. Together with mutations in exon IIIc these account for 25 mutations out of 40 Crouzon patients studied in our combined series (5).