Homozygous sequence variants in the <i>WNT10B</i> gene underlie split hand/foot malformation

Ullah, Asmat; Gul, Ajab; Umair, Muhammad; Irfanullah,; Ahmad, Farooq; Aziz, Abdul; Wali, Abdul; Ahmad, Wasim

doi:10.1590/1678-4685-GMB-2016-0162

Abstract

Split-hand/split-foot malformation (SHFM), also known as ectrodactyly is a rare genetic disorder. It is a clinically and genetically heterogeneous group of limb malformations characterized by absence/hypoplasia and/or median cleft of hands and/or feet. To date, seven genes underlying SHFM have been identified. This study described four consanguineous families (A-D) segregating SHFM in an autosomal recessive manner. Linkage in the families was established to chromosome 12p11.1–q13.13 harboring WNT10B gene. Sequence analysis identified a novel homozygous nonsense variant (p.Gln154*) in exon 4 of the WNT10B gene in two families (A and B). In the other two families (C and D), a previously reported variant (c.300_306dupAGGGCGG; p.Leu103Argfs*53) was detected. This study further expands the spectrum of the sequence variants reported in the WNT10B gene, which result in the split hand/foot malformation.

Keywords:
Split-Hand-Foot Malformation 6; WNT10B gene; sequence variants

Introduction

Split-hand/split-foot malformation (SHFM) is a congenital limb defect characterized by absence of medial digital rays, median clefts of the hands and feet, aplasia and/or hypoplasia of the phalanges, and syndactyly (McKusick, 1998McKusick VA (1998) Mendelian inheritance in man. A catalog of human genes and geneticdisorders. 12th edition. Johns Hopkins University Press, Baltimore, 3,972 p.; Duijf et al., 2003Duijf PH, van Bokhoven H and Brunner HG (2003) Pathogenesis of split-hand/split-foot malformation. Hum Mol Genet 12:51-60.). In severe cases, feet exhibit a lobster claw-like appearance with a deep median groove. Asymmetric manifestations, variable syndactyly and nonpenetrance of the disorder have also been described (Ozen et al., 1999Ozen RS, Baysal BE, Devlin B, Farr JE, Gorry M, Ehrlich GD and Richard CW (1999) Fine mapping of the split-hand/split-foot locus (SHFM3) at 10q24: Evidence for anticipation and segregation distortion. Am J Hum Genet 64:1646-1654.). Few SHFM patients have been found with signs of intellectual disability, ectodermal and craniofacial defects, and orofacial clefting (Elliott and Evans, 2006Elliott AM and Evans JA (2006) Genotype-phenotype correlations in mapped split hand foot malformation (SHFM) patients. Am J Med Genet 140A:1419-1427.). Clinical features of SHFM vary from patient to patient and within the same individual (Duijf et al., 2003Duijf PH, van Bokhoven H and Brunner HG (2003) Pathogenesis of split-hand/split-foot malformation. Hum Mol Genet 12:51-60.; Elliott and Evans 2008Elliott AM and Evans JA (2008) The association of split hand foot malformation (SHFM) and congenital heart defects. Birth Defects Res 82:425-434.; Sowinska-Seidler et al., 2014Sowinska-Seidler A, Badura-Stronka M, Latos-Bielenska A, Stronka M and Jamsheer A (2014) Heterozygous DLX5 nonsense mutation associated with isolated split hand/foot malformation with reduced penetrance and variable expressivity in two unrelated families. Birth Def Res A Clin Mol Teratol 100:764-771.). Both isolated (non-syndromic) and syndromic forms of SHFM have been reported in the literature.

Seven types of non-syndromic SHFM have been mapped on different human chromosomes. Four of these forms (SHFM-1, SHFM-3, SHFM-4, SHFM-5) inherit in autosomal dominant pattern, SHFM-2 in X-linked inherited, and SHFM-6 in autosomal recessive pattern. The four autosomal dominant forms were mapped on chromosome 7q21 (SHFM-1; MIM183600) (Scherer et al., 1994Scherer SW, Poorkaj P, Allen T, Kim J, Geshuri D, Nunes M, Soder S, Stephens K, Pagon RA, Patton MA, et al. (1994) Fine mapping of the autosomal dominant split hand/split foot locus on chromosome 7 band q21.3-q22.1. Am J Hum Genet 55:12-20.), 10q24 (SHFM-3; MIM246560) (Nunes et al., 1995Nunes ME, Schutt G, Kapur RP, Luthardt F, Kukolich M, Byers P and Evans JP (1995) A second autosomal split hand/split foot locus maps to chromosome 10q24-q25. Hum Mol Genet 4:2165-2170.; Gurrieri et al., 1996Gurrieri F, Prinos P, Tackels D, Kilpatrick MW, Allanson J, Genuardi M, Vuckov A, Nanni L, Sangiorgi E, Garofalo G, et al. (1996) A split hand-split foot (SHFM3) gene is located at 10q24-25. Am J Med Genet 62:427-436.; Raas-Rothschild et al., 1996Raas-Rothschild A, Manouvrier S, Gonzales M, Farriaux JP, Lyonnet S and Munnich A (1996) Refined mapping of a gene for split hand-split foot malformation (SHFM3) on chromosome 10q25. J Med Genet 33:996-1001.), 3q27 (SHFM-4; MIM605289) (Ianakiev et al., 2000Ianakiev P, Kilpatrick MW, Toudjarska I, Basel D, Beighton P and Tsipouras P (2000) Split-hand/split-foot malformation is caused by mutations in the p63 gene on 3q27. Am J Hum Genet 67:59-66.) and 2q31 (SHFM-5; MIM606708) (Boles et al., 1995Boles RG, Pober BR, Gibson LH, Willis CR, McGrath J, Roberts DJ and Yang-Feng TL (1995) Deletion of chromosome 2q24-q31 causes characteristic digital anomalies: case report and review. Am J Med Genet 55:155-160.). The autosomal recessive form (SHFM-6; MIM 225300) has been mapped on chromosome 12q13.11-q13 (Ugur and Tolun, 2008Ugur SA and Tolun A (2008) Homozygous WNT10B mutation and complex inheritance in split hand/foot malformation. Hum Mol Genet 17:2644-2653.). The X-linked form was mapped on Xq26, which was later refined to a small region of 5.0 cM (Faiyaz-Ul-Haque et al., 2005Faiyaz-Ul-Haque M, Zaidi SH, King LM, Haque S, Patel M, Ahmad M, Siddique T, Ahmad W, Tsui LC and Cohn DH (2005) Fine mapping of the X-linked split-hand/split-foot malformation (SHFM2) locus to a 5.1-Mb region on Xq26.3 and analysis of candidate genes. Clin Genet 67:93-97.). Based on genome-wide linkage analysis in a single family with autosomal recessive inheritance pattern, Gurnett et al. (2006)Gurnett CA, Dobbs MB, Nordsieck EJ, Keppel C, Goldfarb CA, Morcuende JA and Bowcock AM (2006) Evidence for an additional locus for split hand/foot malformation in chromosome region 8q21.11-q22.3. Am J Med Genet A 140:1744-1748. mapped a novel locus for SHFM on chromosome 8q21.11–q22.3. For these seven loci, only three (SHFM1, SHFM4, SHFM6) have been solved at the gene level. A causative gene of the wingless-type MMTV integration site family, member 10 (WNT10B, MIM 601906) has been reported of causing SHFM-6 (Ugur and Tolun, 2008Ugur SA and Tolun A (2008) Homozygous WNT10B mutation and complex inheritance in split hand/foot malformation. Hum Mol Genet 17:2644-2653.). Ianakiev et al. (2000)Ianakiev P, Kilpatrick MW, Toudjarska I, Basel D, Beighton P and Tsipouras P (2000) Split-hand/split-foot malformation is caused by mutations in the p63 gene on 3q27. Am J Hum Genet 67:59-66. reported the gene TP63 (tumor protein p63, MIM 603273), which encodes a homolog of the tumor suppressor responsible for the SHFM-4 phenotype. Shamseldin et al. (2012)Shamseldin HE, Faden MA, Alashram W and Alkuraya FS (2012) Identification of a novel DLX5 mutation in a family with autosomal recessive split hand and foot malformation. J Med Genet 49:16-20. reported a mutation in the gene DLX5 responsible for the SHFM-1 phenotype in a consanguineous family. We reported intragenic variants in the DLX5 and DLX6 genes that caused the SHFM-1 phenotype in two different families (Ullah et al., 2016aUllah A, Ullah MF, Khalid ZM and Ahmad W (2016a) A novel heterozygous frameshift mutation in DLX5 gene underlies isolated split hand foot malformation type 1. Pediatr Int 58:1348-1350.,bUllah A, Hammid A, Umair M and Ahmad W (2016b) A novel heterozygous intragenic sequence variant in DLX6 probably underlies first case of autosomal dominant split-hand/foot malformation type 1. Mol Syndromol 8:79-84.). Goodman et al. (2002)Goodman FR, Majewski F, Collins AL and Scambler PJ (2002) A 117 kb microdeletion removing HOXD9, HOXD13 and EVX2 causes synpolydactyly. Am J Hum Genet 70:547-555. proposed that SHFM-5 and other digit defects may be caused by haploinsufficiency of genes (EVX2, DLX1, DLX2) located at the 5′ end of the HOXD cluster. Recently, Umair et al. (2017)Umair M, Ullah A, Abbas S, Ahmad F, Basit S and Ahmad W (2017) First direct evidence of involvement of a homozygous loss-of-function variant in the EPS15L1 gene underlying split-hand/split-foot malformation. Clin Genet doi: 10.1111/cge.13152.
https://doi.org/10.1111/cge.13152... reported a homozygous variant in the EPS15L1 gene located on chromosome 19p13.11 causing isolated SHFM in a Pakistani family.

In this study, we investigated four consanguineous families of Pakistani origin showing split hand and foot malformation phenotypes. Linkage in the families was established to SHFM6 on chromosome 12p11.1-q13.13. Sequence analysis of the WNT10B gene detected a novel nonsense and a previously reported variant in affected individuals.

Materials and Methods

Family history

Approval to conduct the study was obtained from the Institutional Review Board (IRB) of Quaid-i-Azam University, Islamabad Pakistan. Four consanguineous families with clinical manifestations of split hand and foot malformations (SHFM were recruited from remote areas of Pakistan. Pedigree reconstruction (Figure 1) provided convincing evidence of an autosomal recessive mode of inheritance of the disorder. Six individuals with SHFM were identified in four families. This included a male (IV-1) and a female (IV-2) in family A, a female (IV-1) in the fourth generation in family B, two males (IV-2, IV-3) in the fourth generation in family C, and one male (V-1) in the fifth generation in family D. All affected and unaffected individuals in the four families were examined by medical specialists at local government hospitals. Blood samples were collected from both affected and unaffected individuals of the families after obtaining written consent.

Figure 1
Haplotypes constructed in families (A to D) segregating SHFM6. Black symbols represent affected individuals while clear symbols represent unaffected individuals. The shaded black alleles are forming risk haplotype, while the alleles shown in white are not co-segregating with the disease. Genetic distances in centi-Morgans (cM) are according to the Rutgers combined linkage-physical map (Build 36.2).

Isolation of Genomic DNA

Peripheral blood samples were obtained from 19 individuals in EDTA containing vacutainer sets (BD, Franklin Lakes, NJ, USA). Genomic DNA extraction was performed using a standard phenol-chloroform procedure. DNA was quantified using a Nanodrop-1000 spectrophotometer (Thermal Scientific, Wilmington, MA).

Genotyping

Linkage in the families was searched by genotyping microsatellite markers mapped in the flanking regions of autosomal dominant and autosomal recessive forms of SHFM. This included SHFM1 (D7S2537, D7S2481, D7S630, D7S492, D7S627, D7S1813, D7S657, D7S527, D7S479) at chromosome 7q21, SHFM3 (D10S520, D10S91, D10S1736, D10S1726, D10S603, D10S1710, D10S383, D10S1264) at chromosome 10q24, SHFM4 (D3S3570, D3S3600, D3S3596, D3S1661, D3S2747, D3S1662, D3S2311, D3S1305) at chromosome 3q27, SHFM5 (D2S124, D2S2345, D2S294, D2S2302, D2S1274, D2S2257, D2S2173, D2S2978) at chromosome 2q31, SHFM6 (D12S1034, D12S823, D12S1042, D12S1337, D12S1698, D12S87, D12S1584, D12S1621, D12S291, D12S1301, D12S1713, D12S1701, D12S339, D12S1590, D12S1620, D12S1635, D12S347, D12S297, D12S368, D12S398, D12S1604, D12S325) at chromosome 12q11-q13, and another SHFM locus mapped on chromosome 8q21.11–q22.3 (D8S526, D8S2321, D8S1119, D8S1818, D8S1129, D8S1714, D8S556) (Gurnett et al., 2006Gurnett CA, Dobbs MB, Nordsieck EJ, Keppel C, Goldfarb CA, Morcuende JA and Bowcock AM (2006) Evidence for an additional locus for split hand/foot malformation in chromosome region 8q21.11-q22.3. Am J Med Genet A 140:1744-1748.). PCR amplification of the microsatellite markers was performed as previously described (Ullah et al., 2015Ullah A, Raza SI, Ali RH, Naveed AK, Jan A, Rizvi SDA, Satti R and Ahmad W (2015) A novel deletion mutation in the DSG4 gene underlies autosomal recessive hypotrichosis with variable phenotype in two unrelated consanguineous families. Clin Exp Dermatol 40:78-84.). The amplified PCR products were resolved on 8% non-denaturing polyacrylamide gels, stained with ethidium bromide, and genotypes were assigned by visual inspection. DNA ladders of 5, 10 and 20 bp (MBI Fermentas®, Life Sciences, York, UK) were used to determine allele size for respective microsatellite markers. Markers used in the genotyping were arranged according to Rutgers combined linkage-physical map (Build 36.2) of the human genome (Matise et al., 2007Matise TC, Chen F and Chen W (2007) A second-generation combined linkage physical map of the human genome. Genome Res 17:1783-1786.). Haplotypes were analyzed by SIMWALK2 (Sobel and Lange, 1996Sobel E and Lange K (1996) Descent graphs in pedigree analysis: applications to haplotyping, location scores, and markersharing statistics. Am J Hum Genet 58:1323-1337.).

Sequencing of the WNT10B gene

Primers used for PCR amplification, sequencing and coding of intron-exon junctions of the WNT10B gene were the same as described earlier (Khan et al., 2012Khan S, Basit S, Zimri FK, Ali N, Ali G, Ansar M and Ahmad W (2012) A novel homozygous missense mutation in WNT10B in familial split-hand/foot malformation. Clin Genet 82:48-55.). The PCR-amplified products were purified with a commercially available kit (Axygen MD, USA) and sequenced using ABI BigDye Terminator Sequencing Kit v.3.1 (Applied Biosystems, Foster City, CA, USA). Sequence variants were identified via the BIOEDIT sequence alignment editor, version 6.0.7 (Ibis Biosciences, CA, USA).

In silico analysis

The pathogenicity index of the sequence variants identified here was calculated using the following softwares: Mutation Taster (http://www.mutationtaster.org/), Polymorphism Phenotyping V2 (PolyPhen-2) (http://genetics.bwh.harvard.edu/pph2/) and Sorting Intolerant From Tolerant (SIFT) (http://sift.bii.a-star.edu.sg/). The frequency of the variants in the general population was determined using the Exome Variant Server (EVS) (http://evs.gs.washington.edu/EVS/), and 1000 genomes.

Results

Clinical features

Affected individuals in the four families showed classical phenotypes of SHFM, which segregated in an autosomal recessive manner. At the time of the study, ages of the patients varied between 2 to 10 years. Patients were born after normal pregnancies. All the affected individuals showed cleft hand and cleft foot deformities associated with mesoaxial syndactyly (Figure 2).

Figure 2
Clinical features of split hand/foot malformation (SHFM) observed in family A. (a) Female patient (IV-1) showing cleft hand deformity with absence of middle finger in right hand, and syndactyly of 1^st and 2^nd finger. (b) Radiograph showing pre-axial syndactyly of index finger and thumb at distal phalanx as well as in 3^rd and 4^th metacarpals. (c, d) The same patient (IV-1) showing cleft hand deformity with central type syndactyly in her left hand, and with an additional bud on the 2^nd metacarpal; distal phalanx in the middle finger is missing. (e, h) Classical cleft feet deformities characterized by central deficiency in the same affected individual, radiographs showing hallux valgus deformities in the big toe, missing central toes and presence of postaxial syndactyly in the metatarsal bones; some of the tarsal bones are missing. (i, j) Male affected individual (IV-2) showing cleft hand deformity associated with missing of 2^nd and 3^rd finger. (k, n) The same affected member showing cleft feet deformity; radiological study showing bilateral cleft hand/feet deformities associated with preaxial and postaxial syndactyly in the hands and feet, respectively. (o) Clinical features of an affected girl (IV-1) in family B showing missing big toe along with 2^nd and 3^rd toes. (p) An affected individual (IV-2) in family C showing absence of middle phalanx of 3^rd finger in right hand, severe bilateral hypoplasia and fusion of the 3^rd and 4^th finger. (q, r) The same patient, showing pre-axial syndactyly in toes 1 and 2 in both feet, and an additional bud on the 3^rd toe in right foot. (s) Radiographic features of the right hand of the patient (IV-2) showing radial ray malformation including hypoplasia of 1^st metacarpal, complex fusion of middle finger to ring finger, relatively large proximal phalanx of 5^th finger, fingers showing contractures and deviations. (t-u) Radiographs of the feet showing fusion of the 1^st and 2^nd toes. (v) Affected individual (IV-3) in family C showing bilateral cleft foot with missing 2^nd and 3^rd digits, central deficiency with rudimentary bud of lesser toe, classical cleft foot, and basal syndactyly formation. (w) Affected individual (V-1) in family D showing cleft foot deformity, i.e. longitudinal deficiency of digital ray of the foot except rays 1 or 5, central deficiency and varus deformity of lesser toe, claw toe deformity, classical cleft foot and fusion of the middle and distal phalanx of 5^th toe.

In family A, the affected female (IV-1) showed cleft hand deformity with absence of the middle finger in the right hand. Radiographs showed pre-axial syndactyly of the index finger and thumb at the distal phalanx as well as in the 3rd and 4th metacarpals (Figure 2a,b). The same patient showed cleft hand deformity with central syndactyly in her left hand with an additional bud on the 2nd metacarpal. The distal phalanx of the middle finger was also missing (Figure 2c,d). Classical cleft feet deformities, characterized by central deficiency, were present. Radiographs showed hallux valgus deformities of the big toe and missing central toes associated with postaxial syndactyly in the metatarsal bones. Some of the tarsal bones were absent (Figure 2e-h). The male individual of the same family (IV-2) showed the same SHFM phenotypes as the female (IV-1). Abnormalities such as syndactyly, radial ray malformation, dysplastic hands, and cleft feet were noted (Figure 2i-j). The radiological study revealed bilateral cleft hand/feet deformities associated with pre-axial and postaxial syndactyly in hands and feet, respectively (Figure 2k-n).

In family B, an affected girl (IV-1) was missing the big toe and toes 2 and 3 in the right foot. The left foot and the hands were apparently normal (Figure 2o).

One of the affected members (IV-2) of family C showed aplasia of the middle phalanx of the 3rd finger in the right hand, severe bilateral hypoplasia and fusion of the 3rd and 4th finger (Figure 2p). Fusion of the big toe and 2nd toe in both feet, and an additional rudimentary bud were observed in the 3rd toe of the right foot. Radial ray malformation including hypoplasia of the 1st metacarpal, as well as complex fusion of the middle and ring fingers. Fingers with contractures and deviations were observed in radiographs of the right hand of patient IV-2 (Figure 2q-u). The other affected member (IV-3) of family C showed bilateral cleft foot with missing 2nd and 3rd toes, characterized by central deficiency with rudimentary bud of lesser toe, classical cleft foot, and basal syndactyly formation (Figure 2v).

In family D, the affected person (V-1) showed cleft foot deformity, i.e. longitudinal deficiency of the digital ray of the foot except rays 1 and 5, central deficiency and varus deformity of the lesser toe, claw toe deformity, classical cleft foot and fusion of middle and distal phalanx of the 5th toe (Figure 2w). Abnormalities in skin, teeth, face, nails, and eyes were not observed in affected members of the four families. Parents of the affected people were normal and healthy.

Linkage and mutation analysis

Linkage in the families was tested by genotyping microsatellite markers. Haplotypes revealed that affected individuals were homozygous for markers linked to the WNT10B gene on chromosome 12q11-q13 (Figure 1). Subsequently, the WNT10B gene was sequenced in affected and unaffected members of the families. Sequence analysis detected a novel homozygous nonsense variant (c.460C > G, p.Gln154*) in exon 4 of the WNT10B gene in all the three affected members of the families A and B. In the two other families (C and D) a 7 bp duplication mutation (c.300_306dupAGGGCGG; p.Leu103Alafs*53) was detected in the affected members (Figure 3). The two sequence variants were present in heterozygous state in the obligate carriers in the families and were not identified in 150 ethnically matched control individuals. This absence and the available databases of genetic variations (ExAc, 1000 genome, EVS or dbSNP) confirm that these were not polymorphisms.

Figure 3
Sequence analysis of WNT10B gene showing a novel nonsense variant (c.460C > G, p.Gln154*) in affected individuals in family A and B. The upper panel (a) represents nucleotide sequences in an affected individual, the middle panel (b) in a heterozygous carrier and lower panel (c) in a normal individual; arrows indicate position of the sequence variant. (d) 7-bp duplication mutation (c.300_306dupAGGGCGG; L103Rfs*53) in the gene WNT10B found in affected individuals in family C and D, (e) in the heterozygous carrier, and (f) in an unaffected member of the family. Underline 7-bp sequence AGGGCGG is duplicated in affected members; arrows indicate position of duplication. (g, h) Leucine (L) amino acid represented in green is conserved across four different species. (i) Comparison of amino acid sequence of normal and mutated human WNT10B protein showing nonsense mutation (p.Gln154*) identified in family A and B. (j) Amino acid sequence comparison of normal and mutated human WNT10B protein showing substitution of leucine with arginine at amino acid position 103 and frame shift (Leu103Argfs*53). Comparison of amino acid sequence of human WNT10B protein with other orthologs.

Discussion

To date, five sequence variants in the WNT10B gene causing SHFM have been reported. Clinical findings resulting from these variants are summarized in Table 1. Ugur and Tolun (2008)Ugur SA and Tolun A (2008) Homozygous WNT10B mutation and complex inheritance in split hand/foot malformation. Hum Mol Genet 17:2644-2653. reported a large consanguineous family of Turkish origin in which affected individuals were homozygous for p.Arg332Trp in the WNT10B gene. Blattner et al. (2010)Blattner A, Huber AR and Rothlisberger B (2010) Homozygous nonsense mutation in WNT10B and sporadic split-hand/foot malformation (SHFM) with autosomal recessive inheritance. Am J Med Genet A 152:2053-2056. found a 4 bp duplication (c.458_461dupAGCA) in a Swiss woman affected with sporadic SHFM6. Previously, four families of Pakistani origin carrying variants in the WNT10B gene have been reported. This included a missense variant (p.Thr329Arg) (Khan et al., 2012Khan S, Basit S, Zimri FK, Ali N, Ali G, Ansar M and Ahmad W (2012) A novel homozygous missense mutation in WNT10B in familial split-hand/foot malformation. Clin Genet 82:48-55.), 4 bp deletion (c.1165_1168delAAGT), and 7 bp duplication (c.300_306dupAGGGCGG) (Aziz et al., 2014Aziz A, Khan S, Zimri FK, Muhammad N, Rashid S and Ahmad W (2014) Novel homozygous mutations in the WNT10B gene underlying autosomal recessive split hand/foot malformation in three consanguineous families. Gene 534:265-271.). A family reported by Khan et al. (2012)Khan S, Basit S, Zimri FK, Ali N, Ali G, Ansar M and Ahmad W (2012) A novel homozygous missense mutation in WNT10B in familial split-hand/foot malformation. Clin Genet 82:48-55. showed absence of fingers and thumbs, which were not observed in the families studied by Ugur and Tolun (2008)Ugur SA and Tolun A (2008) Homozygous WNT10B mutation and complex inheritance in split hand/foot malformation. Hum Mol Genet 17:2644-2653. and Blattner et al. (2010)Blattner A, Huber AR and Rothlisberger B (2010) Homozygous nonsense mutation in WNT10B and sporadic split-hand/foot malformation (SHFM) with autosomal recessive inheritance. Am J Med Genet A 152:2053-2056..

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Table 1
Comparison of the clinical features, due to sequence variants in the WNT10B gene, observed in participants of the present study and those reported previously.

In the present study, we have reported four additional Pakistani families with SHFM6 in autosomal recessive pattern. The SHFM features observed in affected members of the families included syndactyly, cleft hand/foot malformation, hallux valgus deformities, aplasia, hypoplasia, radial ray malformation, presence of extra rudimentary bone, hypoplastic finger and missing of phalanges. Features observed in affected members of the four families were similar to those reported previously (Ugur and Tolun, 2008Ugur SA and Tolun A (2008) Homozygous WNT10B mutation and complex inheritance in split hand/foot malformation. Hum Mol Genet 17:2644-2653.; Khan et al., 2012Khan S, Basit S, Zimri FK, Ali N, Ali G, Ansar M and Ahmad W (2012) A novel homozygous missense mutation in WNT10B in familial split-hand/foot malformation. Clin Genet 82:48-55.; Aziz et al., 2014Aziz A, Khan S, Zimri FK, Muhammad N, Rashid S and Ahmad W (2014) Novel homozygous mutations in the WNT10B gene underlying autosomal recessive split hand/foot malformation in three consanguineous families. Gene 534:265-271.). However, polydactyly in few affected members of the families reported by Khan et al. (2012)Khan S, Basit S, Zimri FK, Ali N, Ali G, Ansar M and Ahmad W (2012) A novel homozygous missense mutation in WNT10B in familial split-hand/foot malformation. Clin Genet 82:48-55. and Aziz et al. (2014)Aziz A, Khan S, Zimri FK, Muhammad N, Rashid S and Ahmad W (2014) Novel homozygous mutations in the WNT10B gene underlying autosomal recessive split hand/foot malformation in three consanguineous families. Gene 534:265-271. were not observed in our study.

Microsatellite-based genotyping established linkage in the four families to SHFM6 on chromosome 12q11-q13, harboring the WNT10B gene. The gene WNT10B contains five exons spanning 6.5 kb of genomic DNA and gives rise to a 389 amino acids protein. WNT10B is a 45 kDa glycoprotein that plays a role in fetal limb bud development and adult hematopoiesis. Sequence analysis of the gene led to the identification of a novel nonsense variant (p.Gln154*) in two families (A and B) and a previously reported duplication (c.300_306dupAGGGCGG; p.Leu103Argfs*53) in the other families (C and D). The sequence variant (p.Gln154*) identified in family A and B is the first nonsense and sixth variant detected in the WNT10B gene. The premature stop codon at position 154 (p.Gln154*) results in a truncated transcript, which is probably degraded by nonsense mediated mRNA decay (Maquat, 1996Maquat LE (1996) Defects in RNA splicing and the consequence of shortened translational reading frames. Am J Hum Genet 59:279-286., 2005Maquat LE (2005) Nonsense-mediated mRNA decay in mammals. J Cell Sci 118:1773-1776.). The 7 bp duplication (c.300_306dupAGGGCGG; Leu103Argfs*53) found in the other two families (C, D) changes the downstream nucleotide sequence, resulting in a premature stop codon (TGA). Thus, the mutant transcript produced is probably also degraded by nonsense-mediated mRNA decay.

The gene WNT10B belongs to the WNT gene family. Proteins encoded by the WNT gene family are involved in the activation of a canonical signaling pathway, acting as ligands for cell surface receptors complexes composed of frizzled (FZ) and low-density lipoprotein receptor-related protein 5/6 (LRP5/6) family members. Gordon and Nusse (2006)Gordon MD and Nusse R (2006) Wnt signaling: Multiple pathways, multiple receptors, and multiple transcription factors. J Biol Chem 281:22429-22433. reported that binding of WNT to FZ and LRP5/6 results in the disruption of the APC/Axin/GSK3 complex that is required for the targeted degradation of β-catenin.

In conclusion, we have reported a novel and a previously known sequence variant in the WNT10B gene in four consanguineous families affected by SHFM. This further extended the spectrum of mutations in the WNT10B gene that result in split hand/foot malformation. These findings can improve diagnosis and genetic counseling, and form the basis of prenatal testing.

Acknowledgments

We are highly indebted to the family members for their invaluable cooperation and participation in this study. Muhammad Umair was supported by HEC Indigenous Ph.D. Fellowship.

References

Aziz A, Khan S, Zimri FK, Muhammad N, Rashid S and Ahmad W (2014) Novel homozygous mutations in the WNT10B gene underlying autosomal recessive split hand/foot malformation in three consanguineous families. Gene 534:265-271.
Blattner A, Huber AR and Rothlisberger B (2010) Homozygous nonsense mutation in WNT10B and sporadic split-hand/foot malformation (SHFM) with autosomal recessive inheritance. Am J Med Genet A 152:2053-2056.
Boles RG, Pober BR, Gibson LH, Willis CR, McGrath J, Roberts DJ and Yang-Feng TL (1995) Deletion of chromosome 2q24-q31 causes characteristic digital anomalies: case report and review. Am J Med Genet 55:155-160.
Duijf PH, van Bokhoven H and Brunner HG (2003) Pathogenesis of split-hand/split-foot malformation. Hum Mol Genet 12:51-60.
Elliott AM and Evans JA (2006) Genotype-phenotype correlations in mapped split hand foot malformation (SHFM) patients. Am J Med Genet 140A:1419-1427.
Elliott AM and Evans JA (2008) The association of split hand foot malformation (SHFM) and congenital heart defects. Birth Defects Res 82:425-434.
Faiyaz-Ul-Haque M, Zaidi SH, King LM, Haque S, Patel M, Ahmad M, Siddique T, Ahmad W, Tsui LC and Cohn DH (2005) Fine mapping of the X-linked split-hand/split-foot malformation (SHFM2) locus to a 5.1-Mb region on Xq26.3 and analysis of candidate genes. Clin Genet 67:93-97.
Goodman FR, Majewski F, Collins AL and Scambler PJ (2002) A 117 kb microdeletion removing HOXD9, HOXD13 and EVX2 causes synpolydactyly. Am J Hum Genet 70:547-555.
Gordon MD and Nusse R (2006) Wnt signaling: Multiple pathways, multiple receptors, and multiple transcription factors. J Biol Chem 281:22429-22433.
Gurnett CA, Dobbs MB, Nordsieck EJ, Keppel C, Goldfarb CA, Morcuende JA and Bowcock AM (2006) Evidence for an additional locus for split hand/foot malformation in chromosome region 8q21.11-q22.3. Am J Med Genet A 140:1744-1748.
Gurrieri F, Prinos P, Tackels D, Kilpatrick MW, Allanson J, Genuardi M, Vuckov A, Nanni L, Sangiorgi E, Garofalo G, et al. (1996) A split hand-split foot (SHFM3) gene is located at 10q24-25. Am J Med Genet 62:427-436.
Ianakiev P, Kilpatrick MW, Toudjarska I, Basel D, Beighton P and Tsipouras P (2000) Split-hand/split-foot malformation is caused by mutations in the p63 gene on 3q27. Am J Hum Genet 67:59-66.
Khan S, Basit S, Zimri FK, Ali N, Ali G, Ansar M and Ahmad W (2012) A novel homozygous missense mutation in WNT10B in familial split-hand/foot malformation. Clin Genet 82:48-55.
Maquat LE (1996) Defects in RNA splicing and the consequence of shortened translational reading frames. Am J Hum Genet 59:279-286.
Maquat LE (2005) Nonsense-mediated mRNA decay in mammals. J Cell Sci 118:1773-1776.
Matise TC, Chen F and Chen W (2007) A second-generation combined linkage physical map of the human genome. Genome Res 17:1783-1786.
McKusick VA (1998) Mendelian inheritance in man. A catalog of human genes and geneticdisorders. 12th edition. Johns Hopkins University Press, Baltimore, 3,972 p.
Nunes ME, Schutt G, Kapur RP, Luthardt F, Kukolich M, Byers P and Evans JP (1995) A second autosomal split hand/split foot locus maps to chromosome 10q24-q25. Hum Mol Genet 4:2165-2170.
Ozen RS, Baysal BE, Devlin B, Farr JE, Gorry M, Ehrlich GD and Richard CW (1999) Fine mapping of the split-hand/split-foot locus (SHFM3) at 10q24: Evidence for anticipation and segregation distortion. Am J Hum Genet 64:1646-1654.
Raas-Rothschild A, Manouvrier S, Gonzales M, Farriaux JP, Lyonnet S and Munnich A (1996) Refined mapping of a gene for split hand-split foot malformation (SHFM3) on chromosome 10q25. J Med Genet 33:996-1001.
Scherer SW, Poorkaj P, Allen T, Kim J, Geshuri D, Nunes M, Soder S, Stephens K, Pagon RA, Patton MA, et al. (1994) Fine mapping of the autosomal dominant split hand/split foot locus on chromosome 7 band q21.3-q22.1. Am J Hum Genet 55:12-20.
Shamseldin HE, Faden MA, Alashram W and Alkuraya FS (2012) Identification of a novel DLX5 mutation in a family with autosomal recessive split hand and foot malformation. J Med Genet 49:16-20.
Sobel E and Lange K (1996) Descent graphs in pedigree analysis: applications to haplotyping, location scores, and markersharing statistics. Am J Hum Genet 58:1323-1337.
Sowinska-Seidler A, Badura-Stronka M, Latos-Bielenska A, Stronka M and Jamsheer A (2014) Heterozygous DLX5 nonsense mutation associated with isolated split hand/foot malformation with reduced penetrance and variable expressivity in two unrelated families. Birth Def Res A Clin Mol Teratol 100:764-771.
Umair M, Ullah A, Abbas S, Ahmad F, Basit S and Ahmad W (2017) First direct evidence of involvement of a homozygous loss-of-function variant in the EPS15L1 gene underlying split-hand/split-foot malformation. Clin Genet doi: 10.1111/cge.13152.
» https://doi.org/10.1111/cge.13152
Ugur SA and Tolun A (2008) Homozygous WNT10B mutation and complex inheritance in split hand/foot malformation. Hum Mol Genet 17:2644-2653.
Ullah A, Raza SI, Ali RH, Naveed AK, Jan A, Rizvi SDA, Satti R and Ahmad W (2015) A novel deletion mutation in the DSG4 gene underlies autosomal recessive hypotrichosis with variable phenotype in two unrelated consanguineous families. Clin Exp Dermatol 40:78-84.
Ullah A, Ullah MF, Khalid ZM and Ahmad W (2016a) A novel heterozygous frameshift mutation in DLX5 gene underlies isolated split hand foot malformation type 1. Pediatr Int 58:1348-1350.
Ullah A, Hammid A, Umair M and Ahmad W (2016b) A novel heterozygous intragenic sequence variant in DLX6 probably underlies first case of autosomal dominant split-hand/foot malformation type 1. Mol Syndromol 8:79-84.

Associate Editor: Maria Rita Passos-Bueno

Publication Dates

Publication in this collection
22 Jan 2018
Date of issue
Jan-Mar 2018

History

Received
15 June 2016
Accepted
10 Apr 2017

License information: This is an open-access article distributed under the terms of the Creative Commons Attribution License (type CC-BY), which permits unrestricted use, distribution and reproduction in any medium, provided the original article is properly cited.

[1] Aziz A, Khan S, Zimri FK, Muhammad N, Rashid S and Ahmad W (2014) Novel homozygous mutations in the WNT10B gene underlying autosomal recessive split hand/foot malformation in three consanguineous families. Gene 534:265-271.

[2] Blattner A, Huber AR and Rothlisberger B (2010) Homozygous nonsense mutation in WNT10B and sporadic split-hand/foot malformation (SHFM) with autosomal recessive inheritance. Am J Med Genet A 152:2053-2056.

[3] Boles RG, Pober BR, Gibson LH, Willis CR, McGrath J, Roberts DJ and Yang-Feng TL (1995) Deletion of chromosome 2q24-q31 causes characteristic digital anomalies: case report and review. Am J Med Genet 55:155-160.

[4] Duijf PH, van Bokhoven H and Brunner HG (2003) Pathogenesis of split-hand/split-foot malformation. Hum Mol Genet 12:51-60.

[5] Elliott AM and Evans JA (2006) Genotype-phenotype correlations in mapped split hand foot malformation (SHFM) patients. Am J Med Genet 140A:1419-1427.

[6] Elliott AM and Evans JA (2008) The association of split hand foot malformation (SHFM) and congenital heart defects. Birth Defects Res 82:425-434.

[7] Faiyaz-Ul-Haque M, Zaidi SH, King LM, Haque S, Patel M, Ahmad M, Siddique T, Ahmad W, Tsui LC and Cohn DH (2005) Fine mapping of the X-linked split-hand/split-foot malformation (SHFM2) locus to a 5.1-Mb region on Xq26.3 and analysis of candidate genes. Clin Genet 67:93-97.

[8] Goodman FR, Majewski F, Collins AL and Scambler PJ (2002) A 117 kb microdeletion removing HOXD9, HOXD13 and EVX2 causes synpolydactyly. Am J Hum Genet 70:547-555.

[9] Gordon MD and Nusse R (2006) Wnt signaling: Multiple pathways, multiple receptors, and multiple transcription factors. J Biol Chem 281:22429-22433.

[10] Gurnett CA, Dobbs MB, Nordsieck EJ, Keppel C, Goldfarb CA, Morcuende JA and Bowcock AM (2006) Evidence for an additional locus for split hand/foot malformation in chromosome region 8q21.11-q22.3. Am J Med Genet A 140:1744-1748.

[11] Gurrieri F, Prinos P, Tackels D, Kilpatrick MW, Allanson J, Genuardi M, Vuckov A, Nanni L, Sangiorgi E, Garofalo G, et al. (1996) A split hand-split foot (SHFM3) gene is located at 10q24-25. Am J Med Genet 62:427-436.

[12] Ianakiev P, Kilpatrick MW, Toudjarska I, Basel D, Beighton P and Tsipouras P (2000) Split-hand/split-foot malformation is caused by mutations in the p63 gene on 3q27. Am J Hum Genet 67:59-66.

[13] Khan S, Basit S, Zimri FK, Ali N, Ali G, Ansar M and Ahmad W (2012) A novel homozygous missense mutation in WNT10B in familial split-hand/foot malformation. Clin Genet 82:48-55.

[14] Maquat LE (1996) Defects in RNA splicing and the consequence of shortened translational reading frames. Am J Hum Genet 59:279-286.

[15] Maquat LE (2005) Nonsense-mediated mRNA decay in mammals. J Cell Sci 118:1773-1776.

[16] Matise TC, Chen F and Chen W (2007) A second-generation combined linkage physical map of the human genome. Genome Res 17:1783-1786.

[17] McKusick VA (1998) Mendelian inheritance in man. A catalog of human genes and geneticdisorders. 12th edition. Johns Hopkins University Press, Baltimore, 3,972 p.

[18] Nunes ME, Schutt G, Kapur RP, Luthardt F, Kukolich M, Byers P and Evans JP (1995) A second autosomal split hand/split foot locus maps to chromosome 10q24-q25. Hum Mol Genet 4:2165-2170.

[19] Ozen RS, Baysal BE, Devlin B, Farr JE, Gorry M, Ehrlich GD and Richard CW (1999) Fine mapping of the split-hand/split-foot locus (SHFM3) at 10q24: Evidence for anticipation and segregation distortion. Am J Hum Genet 64:1646-1654.

[20] Raas-Rothschild A, Manouvrier S, Gonzales M, Farriaux JP, Lyonnet S and Munnich A (1996) Refined mapping of a gene for split hand-split foot malformation (SHFM3) on chromosome 10q25. J Med Genet 33:996-1001.

[21] Scherer SW, Poorkaj P, Allen T, Kim J, Geshuri D, Nunes M, Soder S, Stephens K, Pagon RA, Patton MA, et al. (1994) Fine mapping of the autosomal dominant split hand/split foot locus on chromosome 7 band q21.3-q22.1. Am J Hum Genet 55:12-20.

[22] Shamseldin HE, Faden MA, Alashram W and Alkuraya FS (2012) Identification of a novel DLX5 mutation in a family with autosomal recessive split hand and foot malformation. J Med Genet 49:16-20.

[23] Sobel E and Lange K (1996) Descent graphs in pedigree analysis: applications to haplotyping, location scores, and markersharing statistics. Am J Hum Genet 58:1323-1337.

[24] Sowinska-Seidler A, Badura-Stronka M, Latos-Bielenska A, Stronka M and Jamsheer A (2014) Heterozygous DLX5 nonsense mutation associated with isolated split hand/foot malformation with reduced penetrance and variable expressivity in two unrelated families. Birth Def Res A Clin Mol Teratol 100:764-771.

[25] Umair M, Ullah A, Abbas S, Ahmad F, Basit S and Ahmad W (2017) First direct evidence of involvement of a homozygous loss-of-function variant in the EPS15L1 gene underlying split-hand/split-foot malformation. Clin Genet doi: 10.1111/cge.13152.
» https://doi.org/10.1111/cge.13152

[26] Ugur SA and Tolun A (2008) Homozygous WNT10B mutation and complex inheritance in split hand/foot malformation. Hum Mol Genet 17:2644-2653.

[27] Ullah A, Raza SI, Ali RH, Naveed AK, Jan A, Rizvi SDA, Satti R and Ahmad W (2015) A novel deletion mutation in the DSG4 gene underlies autosomal recessive hypotrichosis with variable phenotype in two unrelated consanguineous families. Clin Exp Dermatol 40:78-84.

[28] Ullah A, Ullah MF, Khalid ZM and Ahmad W (2016a) A novel heterozygous frameshift mutation in DLX5 gene underlies isolated split hand foot malformation type 1. Pediatr Int 58:1348-1350.

[29] Ullah A, Hammid A, Umair M and Ahmad W (2016b) A novel heterozygous intragenic sequence variant in DLX6 probably underlies first case of autosomal dominant split-hand/foot malformation type 1. Mol Syndromol 8:79-84.

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