Linkage analysis in blepharophimosis-ptosis syndrome confirms localisation to 3q21-24

Functional study on new FOXL2 mutations found in Chinese patients with blepharophimosis, ptosis, epicanthus inversus syndrome

BACKGROUND

Blepharophimosis, ptosis, epicanthus inversus syndrome (BPES) is a rare inheritable disease that mainly affects eyelid development associated with (type I) or without (type II) ovarian dysfunction, resulting in premature ovarian failure (POF). Mutations in the gene forkhead box L2 (FOXL2) have been shown to be responsible for BPES. The aim of this study was to determine and functionally validate the FOXL2 mutation in a Chinese BPES family.

METHODS

Twelve individuals including five BPES patients from a Chinese family were enrolled. Genomic DNA was extracted from peripheral blood of enrolled subjects. The coding region of the FOXL2 gene was amplified and mutations were determined by sequencing analyses. Functional analysis was carried out to study changes in expression and transcriptional activity of the mutant FOXL2 protein.

RESULTS

A novel mutation in the FOXL2 gene (c.931C > T) was detected in all five BPES patients, which converts a histidine residue into a tyrosine (p.H311Y) in the FOXL2 protein. Functional analysis revealed that this point mutation reduces FOXL2 protein expression, concomitant with decreased transcriptional activity on the steroidogenic acute regulatory (StAR) gene promotor.

CONCLUSIONS

Our results expand the mutational spectrum of the FOXL2 gene and provide additional insights to the research on the molecular pathogenesis of FOXL2 in BPES.

Genetic analysis of the FOXL2 gene using quantitative real-time PCR in Chinese patients with blepharophimosis-ptosis-epicanthus inversus syndrome

PURPOSE

The purpose of this study was to identify the mutation(s) or deletion(s) of the forkhead box protein L2 (FOXL2) gene in Chinese patients with blepharophimosis-ptosis-epicanthus inversus syndrome (BPES).

METHODS

Genomic DNA extracted from peripheral blood was collected from two Chinese families and from one sporadic case. PCR direct sequencing and quantitative real-time PCR-based copy number screening for the whole exon of FOXL2 were performed.

RESULTS

Direct sequencing revealed an indel mutation c.50C→TA in the sporadic case which resulted in a frameshift generating 78 novel amino acids and terminating prematurely at codon 95. Deletions in the FOXL2 gene were confirmed by quantitative real-time PCR (q-real-time PCR) in two families in which intragenic mutations were excluded by direct sequencing. These changes containing deletions and a de novo mutation were not detected either in the non-carrier relatives or in 100 normal controls.

CONCLUSIONS

This study identified two deletions and a de novo mutation in the FOXL2 gene in Chinese BPES patients. This is the first study to report FOXL2 gene deletions detected by q-real-time PCR in this ethnic group. This technique enriches the diagnostic methods of molecular genetics in BPES patients. The de novo mutation expands the mutation spectrum of FOXL2.

Identification of a novel mutation in FOXL2 gene that leads to blepharophimosis ptosis epicanthus inversus and telecanthus syndrome in a Tunisian consanguineous family

Mutations in FOXL2 gene are responsible for blepharophimosis ptosis epicanthus inversus and telecanthus syndrome (BPES). The BPES syndrome is a rare autosomal dominant genetic disease characterized by eyelid malformations associated with premature ovarian failure (BPES type I) or not (BPES type II). The human FOXL2 protein (376 aa) contains a 100 amino-acid DNA-binding forkhead domain (residues 52-152) and a polyalanine tract (residues 221-234). In the present study, we report the molecular investigation of four affected members with BPES syndrome in a Tunisian consanguineous family. To identify the causative mutation, we performed a direct sequencing of the FOXL2 gene. The sequence analysis of the coding exon revealed a novel frameshift mutation g.1113 dup C, c.876 dup C, p.P292 Fs. The mutation is located downstream of the polyalanine tract and causes the protein extension to 532 aa. This study reports for the first time a novel frameshift mutation in two-generation consanguineous Tunisian family with BPES. Our results expand the spectrum of FOXL2 mutations.

Mutation analysis of the FOXL2 gene in Chinese patients with blepharophimosis–ptosis–epicanthus inversus syndrome

Blepharophimosis-ptosis-epicanthus inversus syndrome (BPES) is an autosomal dominant disorder characterized by blepharophimosis, ptosis and epicanthus inversus. Based on the presence and absence of premature ovarian failure, two clinical types have been distinguished. Both types of BPES have been mapped to chromosome 3q23 and are mostly due to mutations of a forkhead transcription factor FOXL2 gene which locates at this region. We screened for FOXL2 mutations in Chinese patients with BPES. A novel mutation (g.901-930dup30) which could result in an expansion of the polyalanine tract was found in two BPES type II families and one sporadic case. In addition, a new g.952delC mutation was identified in two patients from a BPES family of undetermined type. The previously reported g.892C>T (p.Q219X) was also found in 12 patients from a large BPES family of type I. No mutations were detected in three other BPES families and three sporadic cases. So we speculate that in a fraction of the BPES patients the genetic defect may represent a change in gene dosage or a rearrangement outside the transcription unit of FOXL2.

Mutational analysis of forkhead transcriptional factor 2 (FOXL2) in Korean patients with blepharophimosis-ptosis-epicanthus inversus syndrome

We screened for mutations in the forkhead transcription factor gene, FOXL2, in Korean patients with sporadic or familial blepharophimosis-ptosis-epicanthus inversus syndrome (BPES) by polymerase chain reaction-single-stranded conformation polymorphism (PCR-SSCP) and direct sequencing. Five of nine BPES families and three of seven sporadic cases were detected to have FOXL2 mutations. We identified four types of FOXL2 mutations, two of which are novel. A new 14 bp deletion (939-952del14) causing a frameshift from G235W and the extension of the predicted protein to 527 amino acids was detected in a BPES family patient. In addition, a novel 845C > A transversion, resulting in a nonsense mutation (S203X), was found in a sporadic case of BPES. The previously reported in-frame 30 bp duplication (909-938dup30) was the most common mutation and was found in eight patients of four BPES families and one sporadic case. A known 17 bp duplication (1080-1096dup17) was observed in a sporadic BPES case. We were unable to find a causal mutation in four BPES families and four sporadic cases. These results suggest that in a fraction of BPES patients, the genetic defect might be associated with a mutation in the non-coding region of the FOXL2 gene or in other genes.

Orbitoblepharophimosis syndrome: a 16-year perspective

The orbitoblepharophimosis syndrome is a congenital malformation of the orbitopalpebral region. It is an autosomal-dominant condition typified by palpebral and orbital phimosis, ptosis, epicanthus inversus with telecanthus, and enophthalmia. It has three forms: minor, major, and extreme. It is a rare malformation affecting both sexes. The gene responsible is 3q21-24. Surgical treatment involves three to four operations: orbital remodeling by burring and grafting (intraorbital and extraorbital), epicanthus correction, and ptosis operation. Results varied depending on the severity of the form and the quality of the tissues. The authors present a series of 50 patients who were treated for this syndrome over the past 16 years.

FOXL2 and BPES: mutational hotspots, phenotypic variability, and revision of the genotype-phenotype correlation

Blepharophimosis syndrome (BPES), an autosomal dominant syndrome in which an eyelid malformation is associated (type I) or not (type II) with premature ovarian failure (POF), has recently been ascribed to mutations in FOXL2, a putative forkhead transcription factor gene. We previously reported 22 FOXL2 mutations and suggested a preliminary genotype-phenotype correlation. Here, we describe 21 new FOXL2 mutations (16 novel ones) through sequencing of open reading frame, 5' untranslated region, putative core promoter, and fluorescence in situ hybridization analysis. Our study shows the existence of two mutational hotspots: 30% of FOXL2 mutations lead to polyalanine (poly-Ala) expansions, and 13% are a novel out-of-frame duplication. In addition, this is the first study to demonstrate intra- and interfamilial phenotypic variability (both BPES types caused by the same mutation). Furthermore, the present study allows a revision of the current genotype-phenotype correlation, since we found exceptions to it. We assume that for predicted proteins with a truncation before the poly-Ala tract, the risk for development of POF is high. For mutations leading to a truncated or extended protein containing an intact forkhead and poly-Ala tract, no predictions are possible, since some of these mutations lead to both types of BPES, even within the same family. Poly-Ala expansions may lead to BPES type II. For missense mutations, no correlations can be made yet. Microdeletions are associated with mental retardation. We conclude that molecular testing may be carefully used as a predictor for POF risk in a limited number of mutations.

Two families with blepharophimosis/ptosis/epicanthus inversus syndrome have mutations in the putative forkhead transcription factor FOXL2

Blepharophimosis/ptosis/epicanthus inversus syndrome (BPES) is an autosomal dominant disorder that is characterized by distinctive eyelid abnormalities. Two clinical subtypes have been described in which type I, but not type II, is associated with premature ovarian failure. Both types of BPES are linked to 3q22-23, and the gene has recently been identified as the putative forkhead transcription factor FOXL2. We report mutation screening of FOXL2 in two families with this condition. The two mutations detected were frameshift mutations resulting from a small insertion or duplication within the gene. Both mutations would result in the production of novel carboxyl terminii, one terminating the predicted protein earlier than the wild type, and the other giving rise to a larger protein product, assuming these proteins or their mRNA were not degraded. Based on the present data, this would suggest that the first family should be type I and the second, type II. Although there is evidence of infertility in the first family, all 3 females in the youngest generation have normal pelvic ultrasound and hormone levels, suggesting that the divide between types I and II may not be as distinct as has been suggested.

Identification of BPESC1, a novel gene disrupted by a balanced chromosomal translocation, t(3;4)(q23;p15.2), in a patient with BPES

The blepharophimosis syndrome (BPES) is a rare genetic disorder characterized by blepharophimosis, ptosis, epicanthus inversus, and telecanthus. In type I, BPES is associated with female infertility, while in type II, the eyelid defect occurs by itself. The BPES syndrome has been mapped to 3q23. Previously, we constructed a YAC-, PAC-, and cosmid-based physical map surrounding the 3q23 translocation breakpoint of a t(3;4)(q23;p15.2) BPES patient, containing a 110-kb PAC (169-C 10) and a 43-kb cosmid (11-L 10) spanning the breakpoint. In this report, we present the identification of BPESC1 (BPES candidate 1), a novel candidate gene that is disrupted by the translocation on chromosome 3. Cloning of the cDNA has been performed starting from a testis-specific EST, AI032396, found in cosmid 11-L 10. The cDNA sequence of BPESC1 is 3518 bp in size and contains an open reading frame of 351 bp. No significant similarities with known proteins have been found in the sequence databases. BPESC1 contains three exons and spans a genomic fragment of 17.5 kb. Expression of BPESC1 was observed in adult testis tissue. We performed mutation analysis in 28 unrelated familial and sporadic BPES patients, but, apart from the disruption by the translocation, found no other disease-causing mutations. These data make it unlikely that BPESC1 plays a major role in the pathogenesis of BPES.

Ovarian differentiation and gonadal failure

Ovarian failure can result from several different genetic mechanisms-X chromosomal abnormalities, autosomal recessive genes causing various types of XX gonadal dysgenesis, and autosomal dominant genes. The number and precise location of loci on the X are still under investigation, but it is clear that, in aggregate, these genes are responsible for ovarian maintenance, given that monosomy X shows germ cells that undergo accelerated atresia. Despite recent hypotheses, at present there is no evidence for a gene directing primary ovarian differentiation; this process may be constitutive. Phenotypic/karyotypic correlation and limited molecular confirmation have long shown that proximal Xp and proximal Xq contain regions of the most importance to ovarian maintenance. Terminal deletions at Xp11 result in 50% primary amenorrhea and 50% premature ovarian failure or fertility. Deletions at Xq13 usually produce primary amenorrhea. Terminal deletions nearer the telomeres on either Xp of Xq bring about premature ovarian failure more often than complete ovarian failure. The X-linked zinc finger gene (ZFX) and diaphanous 2 Drosophila homologue (DIAPH2) are the only candidate genes for ovarian maintenance that map to the X chromosome. Additional, as yet unidentified, genes along the X chromosome must be involved. The search for these genes in humans is hampered by the lack of candidate genes that map to the X chromosome, the scarcity of patients with fortuitous autosomal translocations, and small pedigrees, which hinder mapping of the loci. In addition, difficulties with human germ cell research also make it challenging to dissect genes important to ovarian development. Autosomal genes also are involved in ovarian differentiation and gonadal failure. Follicle-stimulating hormone receptor and ataxia telangiectasia are examples of autosomal genes known to cause human ovarian failure. Transgenic mouse models point to many other candidate autosomal genes, and sequencing of the human homologues in affected women should lead to the discovery of new genes responsible for human ovarian failure. Identification, functional analysis, and mapping of novel genes specifically expressed in the ovary of mice and women eventually should lead to fruitful dissection of essential genes in mammalian ovarian development and maintenance.

Closing in on the BPES gene on 3q23: mapping of a de Novo reciprocal translocation t(3;4)(q23;p15.2) breakpoint within a 45-kb cosmid and mapping of three candidate genes, RBP1, RBP2, and beta'-COP, distal to the breakpoint

BPES is a genetic disorder presenting with blepharophimosis, ptosis of the eyelids, epicanthus inversus, and telecanthus. BPES type I is associated with female infertility, whereas type II presents without additional symptoms. Hitherto, it remains unknown whether BPES type I results from a defect in a single gene or from a contiguous gene syndrome. Previous cytogenetic and linkage analyses have assigned a BPES locus to 3q23, in a 5-cM interval between D3S1615 and D3S1316. In this report, we describe the molecular and physical characterization of the 3q23 breakpoint in a BPES patient with a t(3;4)(q23;p15.2) translocation. Eight YACs located around and within the D3S1615-D3S1316 interval were mapped relative to the 3q23 breakpoint; 5 YACs spanning the 3q23 breakpoint were identified. Thirteen STSs and ESTs were localized on the YAC map. Subsequent hybridization of 2 YACs spanning the breakpoint to the Human RPCI1 PAC Library and the Human Chromosome 3 LLNL Cosmid Library resulted in the identification of 12 PACs and 50 cosmids respectively, allowing the construction of a detailed PAC and cosmid physical map. A refined position-telomeric to the breakpoint-of 3 candidate genes, cellular retinol-binding proteins 1 and 2 (RBP1, RBP2) and the coatomer beta' subunit (beta'-COP), was obtained on this physical map. Furthermore, a PAC and cosmid contig encompassing the breakpoint was constructed. PAC 169-C 10 and cosmid 11-L 10 crossing the breakpoint have sizes of 110 and 45 kb, respectively. The isolation of coding sequences in these clones and in the rest of the contig will greatly facilitate further efforts toward positional cloning of the gene(s) involved in BPES.

Refinement of a translocation breakpoint associated with blepharophimosis-ptosis-epicanthus inversus syndrome to a 280-kb interval at chromosome 3q23

Blepharophimosis syndrome (BPES) is an autosomal dominant disorder of craniofacial development, the features of which include blepharophimosis, ptosis, and epicanthus inversus. Although it has been suggested that BPES is genetically heterogeneous, a major locus for this condition resides at chromosome 3q23. We have previously mapped a translocation breakpoint associated with BPES to the D3S1316-D3S1615 interval. The markers in this region have subsequently been shown to lie in a different order, with the BPES locus mapping to the 1-cM D3S1576 and D3S1316 interval. In the current investigation, a physical map, consisting of 60 yeast artificial chromosome (YAC) clones and 1 bacterial artificial chromosome, that spans this region has been constructed. Ten expressed sequence tags and the cellular retinol-binding protein I locus have been mapped to the contig. YAC end isolation has led to the creation of novel STSs that have been used to reduce the size of the BPES critical region to a 280-kb interval, which has been cloned in two nonchimeric YACs.

Genes and premature ovarian failure

Premature ovarian failure (POF) is an heterogeneous syndrome. Among genetic causes, X monosomy as in Turner syndrome or X deletions and translocations are known to be responsible for POF. The genes involved in ovarian function, located on the X chromosome are still unknown. On the other hand, autosomal abnormalities have been identified in POF patients such as mutations of the FSH gene, the LH and FSH receptor genes, chromosome 3q containing the blepharophimosis gene, the ATM gene (Ataxia-telangiectasia gene). Mutations in the AIRE gene (responsible for APECED syndrome) can involve ovarian insufficiency. It is likely that studies on the function of the protein AIRE might improve our knowledge on follicular development. Furthermore, different mouse models of ovarian failure such as mouse lacking connexins or mice lacking GDF9 (growth derived factor 9), might increase our knowledge of ovarian failure. In the future, a better knowledge of the cellular and biochemical components involved in folliculogenesis and apoptosis should elucidate the mechanisms of POF.

Blepharophimosis: a causally heterogeneous malformation frequently associated with developmental disabilities

We report on 22 individuals referred for genetic evaluation because of blepharophimosis. Fourteen of these patients had the blepharophimosis syndrome: 5 familial and 9 sporadic. Mental retardation or developmental delay was seen in 8 of the 12 children in whom this could be assessed. Eight of 22 children had a malformation syndrome other than the blepharophimosis syndrome. All 8 of these children were mentally retarded or developmentally delayed. Two of these 8 had recognized disorders (branchio-oto-renal syndrome and a ring 4 chromosome); the remaining 6 had unrecognized malformation syndromes. Based on this information, it is suggested that children with blepharophimosis be evaluated carefully for underlying conditions and that they be observed for developmental disabilities because of the frequent association.

A novel case of unilateral blepharophimosis syndrome and mental retardation associated with de novo trisomy for chromosome 3q

We have evaluated a 3 2/12 year old girl who presented with unilateral blepharophimosis, ptosis of the eyelid, and mental retardation. Additional dysmorphic features include microcephaly, high, narrow forehead, short stubby fingers, and adduction of the right first toe. Cytogenetic analysis showed an unbalanced karyotype consisting of 46,XX,add(7)(q+) that was de novo in origin. Fluorescence in situ hybridisation (FISH) using microdissected library probe pools from chromosomes 1,2,3,7, and 3q26-qter showed that the additional material on 7q was derived from the distal end of the long arm of chromosome 3. Our results indicate that the patient had an unbalanced translocation, 46,XX,der(7)t(3;7)(q26-qter;q+) which resulted in trisomy for distal 3q. All currently reported cases of BPES (blepharophimosis-ptosis-epicanthus inversus syndrome) with associated cytogenetic abnormalities show interstitial deletions or balanced translocations involving 3q22-q23 or 3p25.3. Our patient shares similar features to BPES, except for the unilateral ptosis and absence of epicanthus inversus. It is possible that our patient has a contiguous gene defect including at least one locus for a type of blepharophimosis, further suggesting that multiple loci exist for eyelid development.

A gene for isolated congenital ptosis maps to a 3-cM region within 1p32-p34.1

Hereditary isolated congenital ptosis is an autosomal dominant disorder with incomplete penetrance characterized by a variable degree of unilateral or bilateral drooping of the upper eyelids. We report linkage of this disorder in a large family to markers on chromosome 1p. In our sample of 37 meioses, nine informative markers did not recombine with the disease. D1S2677 gave a maximum two-point LOD score of 8.8 on the assumption of 90% penetrance (theta = 0). D1S447/2733 and D1S1616 flank the disease locus, with two-point LOD scores of 5.6/6.6 (theta = .04) and 4.9 (theta = .05), respectively, defining a region of 2.8 cM. FISH of YACs containing flanking recombinant markers localizes the gene to chromosome 1p32-p34.1. These data establish a map location for an isolated congenital ptosis gene and demonstrate that this disorder is genetically distinct from other extraocular muscle-specific disorders such as congenital fibrosis of the extraocular muscles and blepharophimosis.