Entry - #150400 - TOOTH AGENESIS, SELECTIVE, 4; STHAG4 - OMIM

 
ICD+
# 150400

TOOTH AGENESIS, SELECTIVE, 4; STHAG4


Alternative titles; symbols

TOOTH AGENESIS, SELECTIVE, 4, WITH OR WITHOUT ECTODERMAL DYSPLASIA
LATERAL INCISORS, ABSENCE OF
LATERAL INCISORS, PEGGED OR MISSING
SUCCEDANEOUS TEETH, AGENESIS OF


Phenotype-Gene Relationships

Location Phenotype Phenotype
MIM number 		Inheritance Phenotype
mapping key 		Gene/Locus Gene/Locus
MIM number
2q35 Tooth agenesis, selective, 4 150400 AD, AR 3 WNT10A 606268
Clinical Synopsis
 
Phenotypic Series
 

INHERITANCE
- Autosomal dominant
- Autosomal recessive
HEAD & NECK
Eyes
- Sparse eyebrows (in some patients)
- Short eyelashes (in some patients)
Teeth
- Agenesis of variable number of permanent teeth (upper and lower premolars most commonly missing)
- Small, peg-shaped teeth (in some patients)
- Conical teeth (in some patients)
SKIN, NAILS, & HAIR
Skin
- Dry skin (in some patients)
- Abnormal sweating (rare)
Nails
- Nail abnormalities (in some patients)
Hair
- Sparse hair (in some patients)
MISCELLANEOUS
- Higher frequency of absent maxillary and mandibular molars with biallelic mutations
- Some patients with tooth agenesis exhibit mild features of ectodermal dysplasia, including sparse hair, sparse eyebrows, short eyelashes, abnormalities of the nails, and dry skin
MOLECULAR BASIS
- Caused by mutation in the wingless-type MMTV integration site family, member 10A gene (WNT10A, 606268.0002)
▲ Close

TEXT

A number sign (#) is used with this entry because of evidence that selective tooth agenesis-4 with or without ectodermal dysplasia (STHAG4) is caused by homozygous, heterozygous, or compound heterozygous mutation in the WNT10A gene (606268) on chromosome 2q35.

For a general phenotypic description and a discussion of genetic heterogeneity of selective tooth agenesis, see STHAG1 (106600).

Clinical Features

Joehr (1934) reported absence of the upper lateral incisors or peg-shaped lateral incisors in one-third of a Swiss group. The latter feature was a partial expression of the gene. All affected members of the isolate were descendants of one man, born in the 18th century.

Woolf (1971) found that in 71 of 103 families of probands with missing maxillary lateral incisors, one or more first-, second-, or third-degree relatives had a missing or peg-shaped maxillary incisor. He concluded that at least part of the genetic component is autosomal dominant with reduced penetrance and variable expressivity. Families showed a high degree of intrafamilial concordance for type of minor anomaly, especially if the proband had bilaterally absent lateral incisors. Adolph H. Schultz (1891-1976), distinguished anthropologist (Biegert, 1976), gave an early report of an affected family he observed personally on the occasion of a large gathering. A peculiarity was that only females were affected and only females transmitted the trait. Sometimes vestigial lateral incisors in parents were followed by complete absence in children and then reappearance of vestigial incisors in the third generation.

Witkop (1987) reported 2 kindreds in which 3 individuals (2 in one family and 1 in the second) had agenesis of the succedaneous (permanent, or secondary) teeth. Both parents in each family had pegged or missing maxillary lateral incisors. In the offspring with the missing succedaneous teeth, permanent molar teeth were present. Witkop (1987) suggested that agenesis of the succedaneous teeth results from the homozygous state of the gene determining the trait for small/pegged/missing maxillary lateral incisors. Witkop (1987) stated that the prevalence of the small-pegged-missing incisor trait in the United States is approximately 1 in 67 (1.5%) and estimated that, on this basis, the prevalence of agenesis of succedaneous teeth should be about 1 in 18,000. Anodontia of permanent teeth unassociated with a syndrome is inherited as an autosomal recessive (206780).

Nieminen et al. (1995) reported 5 Finnish families with incisor and premolar hypodontia. The diagnosis in the probands was based on congenital absence of 1 to 4 teeth or the presence of 1 or more peg-shaped incisors. All members of the family were studied clinically and panoramic tomograms were taken. Hypodontia of deciduous dentition was assessed anamnestically. Nieminen et al. (1995) referred to this disorder as incisor and premolar hypodontia because of the teeth that are most often affected, and placed the prevalence of this type of hypodontia at 5 to 10% among European and Asian populations.

Hoo (2000) reported a family with 2 sibs with anodontia of permanent teeth. Both parents had normal dentition, but the paternal grandmother, her twin sister, and a paternal aunt all had only 2 maxillary incisors, and the maternal grandmother had only 2 mandibular incisors. The author concluded that this family provides further evidence for the hypothesis of Witkop (1987) that agenesis of permanent teeth is a homozygous state of the gene responsible for pegged or missing maxillary lateral incisors.

In a population-based cohort of 94 Swedish families including 102 individuals with nonsyndromic tooth agenesis (mean of 8.2 missing teeth), Arzoo et al. (2014) identified 26 probands (27.7%) with mutation in the WNT10A gene, 17 of whom had monoallelic mutations and 11 biallelic mutations. Individuals with biallelic mutations had a higher number of missing teeth (mean, 11.1) than those with monoallelic mutations (mean, 6.8). Upper and lower premolars were the most common type of missing teeth (59.7% of all missing teeth). Probands with biallelic mutations had a higher frequency of absent maxillary and mandibular molars (p = 3.63 x 10(-6)) and mandibular central incisors (p = 6.91 x 10(-3)). There were no differences in type or number of missing teeth between males and females.


Inheritance

Autosomal dominant inheritance of selective tooth agenesis with incomplete penetrance was proposed by Grahnen (1956) and several workers thereafter, including Burzynski and Escobar (1983) who calculated the penetrance to be 86% from data from Grahnen (1956). However, the possibility of polygenic inheritance was suggested by Suarez and Spence (1974) and Peck et al. (1993).

In a population-based cohort study including 102 Swedish individuals with selective tooth agenesis, Arzoo et al. (2014) identified 17 probands with monogenic and 11 with biallelic mutations in the WNT10A gene. Patients with biallelic mutations had a higher proportion of relatives with oligodontia (5/11 or 45%) compared to patients with monoallelic mutations (1/17 or 6%).


Mapping

Nieminen et al. (1995) performed linkage analysis using intragenic microsatellite markers in 20 affected individuals from 5 Finnish families with incisor and premolar hypodontia. Pairwise lod scores excluded both the MSX1 (142983) and MSX2 (123101) genes as causative loci for hypodontia in these families.


Molecular Genetics

In patients with a recessive form of ectodermal dysplasia (OODD; 257980) caused by mutation in the WNT10A gene (606268), Bohring et al. (2009) observed a pattern of tooth anomalies comparable to that seen in patients with anodontia of permanent dentition (206780) and selective tooth agenesis-4, and suggested that testing for mutations in WNT10A might be worthwhile in the latter patients.

In an American family with variable hypodontia involving the lateral incisors and premolar teeth, Kantaputra and Sripathomsawat (2011) analyzed the candidate gene WNT10A and identified heterozygosity for a missense mutation (F228I; 606268.0003) in the father, who had congenitally absent maxillary first premolars and 3 third molars, and his oldest son, who had absent maxillary permanent lateral incisors and mandibular second premolars. A second son, who had absence of the maxillary permanent lateral incisors, mandibular second premolars, and a mandibular permanent lateral incisor, was heterozygous for a different missense mutation (D217N; 606268.0007) that he inherited from his mother, who had normal dentition. A third son, who was compound heterozygous for the mutations, had only microdontia of the left mandibular second molar. None of the family members had other manifestations of ectodermal dysplasia.

Van den Boogaard et al. (2012) identified WNT10A mutations in 19 (56%) of 34 unrelated patients with nonsyndromic tooth agenesis (see, e.g., 606268.0002-606268.0004), 8 of whom were homozygous, 4 compound heterozygous, and 7 heterozygous for the mutations. MSX1 (142983), PAX9 (167416), and AXIN2 (604025) mutations were present in 3%, 9%, and 3% of the patients, respectively. The authors concluded that WNT10A is a major gene in the etiology of isolated hypodontia.

Van den Boogaard et al. (2012) also identified homozygosity, heterozygosity, or compound heterozygosity for the same C107X (606268.0002) and F228I (606268.0003) WNT10A mutations in 11 patients with tooth agenesis who displayed mild features of ectodermal dysplasia, including sparse hair, sparse eyebrows, short eyelashes, and abnormalities of the toenails. The authors stated that characteristic features of OODD, including facial telangiectases, evident palmoplantar keratoderma, and smooth tongue were not observed in the latter patients, but noted that hypoplastic lingual papillae can be difficult to identify and that specific imaging methods were not applied in their study. Overall, no specific pattern of tooth agenesis was observed for WNT10A mutation carriers, and van den Boogaard et al. (2012) stated that the percentages of tooth agenesis per tooth type were similar to those from a larger population of nonsyndromic oligodontia patients (Creton et al., 2007).

In a cohort of 34 probands referred with features of ectodermal dysplasia, who were negative for mutation in the EDA gene (300451), Plaisancie et al. (2013) sequenced the WNT10A and EDAR (604095) genes and identified heterozygosity, homozygosity, or compound heterozygosity for mutations in WNT10A in 16 (44%) of the probands. The C107X and F228I mutations represented 43% and 18% of the detected WNTA10A variants, respectively. Mutations in EDAR were identified in 5 (14%) of the probands (see ECTD10A, 129490, and ECTD10B, 224900), and no mutations were detected in the remaining 15 probands. The authors observed associated ectodermal features in 15 of the 16 patients with WNT10A mutations, consisting primarily of hair anomalies, with sparse, thin, or thick hair; nail involvement, with thin nails or reduced nail growth; and sweating anomalies, with either hypo- or hyperhidrosis. Noting that features of ectodermal dysplasia were present in only 11 of the 30 patients studied by van den Boogaard et al. (2012), Plaisancie et al. (2013) suggested that this reflected different methods of recruitment.

In 6 of 9 unrelated Thai patients with agenesis or isolated hypodontia of the maxillary permanent canines, Kantaputra et al. (2014) identified 3 different heterozygous mutations in the WNT10A gene (see, e.g., 606268.0009). One of the affected individuals also had pegged maxillary permanent lateral incisors with dens invaginatus. Two mothers of the patients carried the mutation and had pegged maxillary permanent lateral incisors.


Animal Model

Schultz (1934) found selective tooth agenesis in 1 gorilla and 1 gibbon.

REFERENCES

  1. Arzoo, P. S., Klar, J., Bergendal, B., Norderyd, J., Dahl, N. WNT10A mutations account for 1/4 of population-based isolated oligodontia and show phenotypic correlations. Am. J. Med. Genet. 164A: 353-359, 2014. [PubMed: 24449199, related citations] [Full Text]

  2. Biegert, J. Adolph H. Schultz. Zum Tod des Zuericher Anthropologen. Folia Primatol. 26: 2-4, 1976. [PubMed: 783024, related citations]

  3. Bohring, A., Stamm, T., Spaich, C., Haase, C., Spree, K., Hehr, U., Hoffmann, M., Ledig, S., Sel, S., Wieacker, P., Ropke, A. WNT10A mutations are a frequent cause of a broad spectrum of ectodermal dysplasias with sex-biased manifestation pattern in heterozygotes. Am. J. Hum. Genet. 85: 97-105, 2009. [PubMed: 19559398, images, related citations] [Full Text]

  4. Burzynski, N., Escobar, V. Classification and genetics of numeric anomalies of dentition. Birth Defects Orig. Art. Ser. 19: 95-106, 1983. [PubMed: 6362744, related citations]

  5. Creton, M. A., Cune, M. S., Verhoeven, J. W., Meijer, G. J. Patterns of missing teeth in a population of oligodontia patients. Int J. Prosthodont. 20: 409-413, 2007. [PubMed: 17695874, related citations]

  6. Grahnen, H. Hypodontia in the permanent dentition. Odont. Rev. 7 (suppl. 3): 1-100, 1956.

  7. Hoo, J. J. Anodontia of permanent teeth (OMIM # 206780) and pegged/missing maxillary lateral incisors (OMIM # 150400) in the same family. (Letter) Am. J. Med. Genet. 90: 326-327, 2000. [PubMed: 10710232, related citations] [Full Text]

  8. Joehr, A. C. Reduktionserscheinungen an den oberen seitlichen Schneidezaehnen. Arch. Klaus Stift. Vererbungsforsch. 9: 73-133, 1934.

  9. Kantaputra, P., Kaewgahya, M., Kantaputra, W. WNT10A mutations also associated with agenesis of the maxillary permanent canines, a separate entity. Am. J. Med. Genet. 164A: 360-363, 2014. [PubMed: 24311251, related citations] [Full Text]

  10. Kantaputra, P., Sripathomsawat, W. WNT10A and isolated hypodontia. Am. J. Med. Genet. 155A: 1119-1122, 2011. [PubMed: 21484994, related citations] [Full Text]

  11. Keeler, C. E., Short, R. Hereditary absence of upper lateral incisors. J. Hered. 25: 391-392, 1934.

  12. Mandeville, L. C. Congenital absence of permanent maxillary lateral incisor teeth. A preliminary investigation. Ann. Eugen. 15: 1-10, 1950.

  13. Montagu, M. F. A. The significance of the variability of the upper lateral incisor teeth in man. Hum. Biol. 12: 323-358, 1940.

  14. Nieminen, P., Arte, S., Pirinen, S., Peltonen, L., Thesleff, I. Gene defect in hypodontia: exclusion of MSX1 and MSX2 as candidate genes. Hum. Genet. 96: 305-308, 1995. [PubMed: 7649547, related citations] [Full Text]

  15. Peck, L., Peck, S., Attia, Y. Maxillary canine-first premolar transposition associated dental anomalies: genetic bases. Angle Orthod. 63: 99-109, 1993. [PubMed: 8498708, related citations] [Full Text]

  16. Plaisancie, J., Bailleul-Forestier, I., Gaston, V., Vaysse, F., Lacombe, D., Holder-Espinasse, M., Abramowicz, M., Coubes, C., Plessis, G., Faivre, L., Demeer, B., Vincent-Delorme, C., and 10 others. Mutations in WNT10A are frequently involved in oligodontia associated with minor signs of ectodermal dysplasia. Am. J. Med. Genet. 161A: 671-678, 2013. [PubMed: 23401279, related citations] [Full Text]

  17. Rantanen, A. V. On the frequency of the missing and peg-shaped maxillary lateral incisor among Finnish students. Am. J. Phys. Anthrop. 14: 491-496, 1956. [PubMed: 13381833, related citations] [Full Text]

  18. Salinas, C. F. Personal Communication. Charleston, S. C. 10/8/1978.

  19. Schultz, A. H. The hereditary tendency to eliminate the upper lateral incisors. Hum. Biol. 4: 34-40, 1932.

  20. Schultz, A. H. Inherited reductions in the dentition of man. Hum. Biol. 6: 627-631, 1934.

  21. Suarez, B. K., Spence, M. A. The genetics of hypodontia. J. Dent. Res. 53: 781-785, 1974. [PubMed: 4526369, related citations] [Full Text]

  22. van den Boogaard, M.-J., Creton, M., Bronkhorst, Y., van der Hout, A., Hennekam, E., Lindhout, D., Cune, M., Ploos van Amstel, H. K. Mutations in WNT10A are present in more than half of isolated hypodontia cases. J. Med. Genet. 49: 327-331, 2012. [PubMed: 22581971, related citations] [Full Text]

  23. Witkop, C. J., Jr. Studies of intrinsic disease in isolates with observations on penetrance and expressivity of certain anatomical traits. In: Pruzansky, S.: Congenital Anomalies of the Face and Associated Structures. Springfield, Ill.: Charles C Thomas (pub.) 1961.

  24. Witkop, C. J., Jr. Agenesis of succedaneous teeth: an expression of the homozygous state of the gene for the pegged or missing maxillary lateral incisor trait. Am. J. Med. Genet. 26: 431-436, 1987. [PubMed: 3812593, related citations] [Full Text]

  25. Woolf, C. M. Missing maxillary lateral incisors: a genetic study. Am. J. Hum. Genet. 23: 289-296, 1971. [PubMed: 5089845, related citations]


Contributors:
Marla J. F. O'Neill - updated : 03/06/2017
Marla J. F. O'Neill - updated : 01/04/2017
Ingrid M. Wentzensen - updated : 7/2/2014
Marla J. F. O'Neill - updated : 8/9/2012
Marla J. F. O'Neill - updated : 6/30/2011
Marla J. F. O'Neill - updated : 7/30/2009
Sonja A. Rasmussen - updated : 3/6/2000
Victor A. McKusick - updated : 8/13/1999
Creation Date:
Victor A. McKusick : 6/2/1986
Edit History:
carol : 03/06/2017
carol : 01/04/2017
carol : 02/24/2015
carol : 7/2/2014
carol : 7/2/2014
carol : 7/2/2014
carol : 8/9/2012
terry : 8/9/2012
wwang : 7/13/2011
terry : 6/30/2011
wwang : 8/19/2009
terry : 7/30/2009
joanna : 4/24/2009
carol : 4/5/2007
mgross : 3/17/2004
mcapotos : 11/14/2000
mcapotos : 3/8/2000
mcapotos : 3/6/2000
mcapotos : 3/6/2000
carol : 8/18/1999
terry : 8/13/1999
terry : 7/8/1997
alopez : 6/2/1997
mark : 6/28/1996
terry : 11/17/1995
mark : 10/2/1995
mimadm : 11/5/1994
davew : 7/13/1994
carol : 5/27/1994
supermim : 3/16/1992

# 150400

TOOTH AGENESIS, SELECTIVE, 4; STHAG4


Alternative titles; symbols

TOOTH AGENESIS, SELECTIVE, 4, WITH OR WITHOUT ECTODERMAL DYSPLASIA
LATERAL INCISORS, ABSENCE OF
LATERAL INCISORS, PEGGED OR MISSING
SUCCEDANEOUS TEETH, AGENESIS OF


ORPHA: 99798;   DO: 0050591;  


Phenotype-Gene Relationships

Location Phenotype Phenotype
MIM number 		Inheritance Phenotype
mapping key 		Gene/Locus Gene/Locus
MIM number
2q35 Tooth agenesis, selective, 4 150400 Autosomal dominant; Autosomal recessive 3 WNT10A 606268

TEXT

A number sign (#) is used with this entry because of evidence that selective tooth agenesis-4 with or without ectodermal dysplasia (STHAG4) is caused by homozygous, heterozygous, or compound heterozygous mutation in the WNT10A gene (606268) on chromosome 2q35.

For a general phenotypic description and a discussion of genetic heterogeneity of selective tooth agenesis, see STHAG1 (106600).

Clinical Features

Joehr (1934) reported absence of the upper lateral incisors or peg-shaped lateral incisors in one-third of a Swiss group. The latter feature was a partial expression of the gene. All affected members of the isolate were descendants of one man, born in the 18th century.

Woolf (1971) found that in 71 of 103 families of probands with missing maxillary lateral incisors, one or more first-, second-, or third-degree relatives had a missing or peg-shaped maxillary incisor. He concluded that at least part of the genetic component is autosomal dominant with reduced penetrance and variable expressivity. Families showed a high degree of intrafamilial concordance for type of minor anomaly, especially if the proband had bilaterally absent lateral incisors. Adolph H. Schultz (1891-1976), distinguished anthropologist (Biegert, 1976), gave an early report of an affected family he observed personally on the occasion of a large gathering. A peculiarity was that only females were affected and only females transmitted the trait. Sometimes vestigial lateral incisors in parents were followed by complete absence in children and then reappearance of vestigial incisors in the third generation.

Witkop (1987) reported 2 kindreds in which 3 individuals (2 in one family and 1 in the second) had agenesis of the succedaneous (permanent, or secondary) teeth. Both parents in each family had pegged or missing maxillary lateral incisors. In the offspring with the missing succedaneous teeth, permanent molar teeth were present. Witkop (1987) suggested that agenesis of the succedaneous teeth results from the homozygous state of the gene determining the trait for small/pegged/missing maxillary lateral incisors. Witkop (1987) stated that the prevalence of the small-pegged-missing incisor trait in the United States is approximately 1 in 67 (1.5%) and estimated that, on this basis, the prevalence of agenesis of succedaneous teeth should be about 1 in 18,000. Anodontia of permanent teeth unassociated with a syndrome is inherited as an autosomal recessive (206780).

Nieminen et al. (1995) reported 5 Finnish families with incisor and premolar hypodontia. The diagnosis in the probands was based on congenital absence of 1 to 4 teeth or the presence of 1 or more peg-shaped incisors. All members of the family were studied clinically and panoramic tomograms were taken. Hypodontia of deciduous dentition was assessed anamnestically. Nieminen et al. (1995) referred to this disorder as incisor and premolar hypodontia because of the teeth that are most often affected, and placed the prevalence of this type of hypodontia at 5 to 10% among European and Asian populations.

Hoo (2000) reported a family with 2 sibs with anodontia of permanent teeth. Both parents had normal dentition, but the paternal grandmother, her twin sister, and a paternal aunt all had only 2 maxillary incisors, and the maternal grandmother had only 2 mandibular incisors. The author concluded that this family provides further evidence for the hypothesis of Witkop (1987) that agenesis of permanent teeth is a homozygous state of the gene responsible for pegged or missing maxillary lateral incisors.

In a population-based cohort of 94 Swedish families including 102 individuals with nonsyndromic tooth agenesis (mean of 8.2 missing teeth), Arzoo et al. (2014) identified 26 probands (27.7%) with mutation in the WNT10A gene, 17 of whom had monoallelic mutations and 11 biallelic mutations. Individuals with biallelic mutations had a higher number of missing teeth (mean, 11.1) than those with monoallelic mutations (mean, 6.8). Upper and lower premolars were the most common type of missing teeth (59.7% of all missing teeth). Probands with biallelic mutations had a higher frequency of absent maxillary and mandibular molars (p = 3.63 x 10(-6)) and mandibular central incisors (p = 6.91 x 10(-3)). There were no differences in type or number of missing teeth between males and females.


Inheritance

Autosomal dominant inheritance of selective tooth agenesis with incomplete penetrance was proposed by Grahnen (1956) and several workers thereafter, including Burzynski and Escobar (1983) who calculated the penetrance to be 86% from data from Grahnen (1956). However, the possibility of polygenic inheritance was suggested by Suarez and Spence (1974) and Peck et al. (1993).

In a population-based cohort study including 102 Swedish individuals with selective tooth agenesis, Arzoo et al. (2014) identified 17 probands with monogenic and 11 with biallelic mutations in the WNT10A gene. Patients with biallelic mutations had a higher proportion of relatives with oligodontia (5/11 or 45%) compared to patients with monoallelic mutations (1/17 or 6%).


Mapping

Nieminen et al. (1995) performed linkage analysis using intragenic microsatellite markers in 20 affected individuals from 5 Finnish families with incisor and premolar hypodontia. Pairwise lod scores excluded both the MSX1 (142983) and MSX2 (123101) genes as causative loci for hypodontia in these families.


Molecular Genetics

In patients with a recessive form of ectodermal dysplasia (OODD; 257980) caused by mutation in the WNT10A gene (606268), Bohring et al. (2009) observed a pattern of tooth anomalies comparable to that seen in patients with anodontia of permanent dentition (206780) and selective tooth agenesis-4, and suggested that testing for mutations in WNT10A might be worthwhile in the latter patients.

In an American family with variable hypodontia involving the lateral incisors and premolar teeth, Kantaputra and Sripathomsawat (2011) analyzed the candidate gene WNT10A and identified heterozygosity for a missense mutation (F228I; 606268.0003) in the father, who had congenitally absent maxillary first premolars and 3 third molars, and his oldest son, who had absent maxillary permanent lateral incisors and mandibular second premolars. A second son, who had absence of the maxillary permanent lateral incisors, mandibular second premolars, and a mandibular permanent lateral incisor, was heterozygous for a different missense mutation (D217N; 606268.0007) that he inherited from his mother, who had normal dentition. A third son, who was compound heterozygous for the mutations, had only microdontia of the left mandibular second molar. None of the family members had other manifestations of ectodermal dysplasia.

Van den Boogaard et al. (2012) identified WNT10A mutations in 19 (56%) of 34 unrelated patients with nonsyndromic tooth agenesis (see, e.g., 606268.0002-606268.0004), 8 of whom were homozygous, 4 compound heterozygous, and 7 heterozygous for the mutations. MSX1 (142983), PAX9 (167416), and AXIN2 (604025) mutations were present in 3%, 9%, and 3% of the patients, respectively. The authors concluded that WNT10A is a major gene in the etiology of isolated hypodontia.

Van den Boogaard et al. (2012) also identified homozygosity, heterozygosity, or compound heterozygosity for the same C107X (606268.0002) and F228I (606268.0003) WNT10A mutations in 11 patients with tooth agenesis who displayed mild features of ectodermal dysplasia, including sparse hair, sparse eyebrows, short eyelashes, and abnormalities of the toenails. The authors stated that characteristic features of OODD, including facial telangiectases, evident palmoplantar keratoderma, and smooth tongue were not observed in the latter patients, but noted that hypoplastic lingual papillae can be difficult to identify and that specific imaging methods were not applied in their study. Overall, no specific pattern of tooth agenesis was observed for WNT10A mutation carriers, and van den Boogaard et al. (2012) stated that the percentages of tooth agenesis per tooth type were similar to those from a larger population of nonsyndromic oligodontia patients (Creton et al., 2007).

In a cohort of 34 probands referred with features of ectodermal dysplasia, who were negative for mutation in the EDA gene (300451), Plaisancie et al. (2013) sequenced the WNT10A and EDAR (604095) genes and identified heterozygosity, homozygosity, or compound heterozygosity for mutations in WNT10A in 16 (44%) of the probands. The C107X and F228I mutations represented 43% and 18% of the detected WNTA10A variants, respectively. Mutations in EDAR were identified in 5 (14%) of the probands (see ECTD10A, 129490, and ECTD10B, 224900), and no mutations were detected in the remaining 15 probands. The authors observed associated ectodermal features in 15 of the 16 patients with WNT10A mutations, consisting primarily of hair anomalies, with sparse, thin, or thick hair; nail involvement, with thin nails or reduced nail growth; and sweating anomalies, with either hypo- or hyperhidrosis. Noting that features of ectodermal dysplasia were present in only 11 of the 30 patients studied by van den Boogaard et al. (2012), Plaisancie et al. (2013) suggested that this reflected different methods of recruitment.

In 6 of 9 unrelated Thai patients with agenesis or isolated hypodontia of the maxillary permanent canines, Kantaputra et al. (2014) identified 3 different heterozygous mutations in the WNT10A gene (see, e.g., 606268.0009). One of the affected individuals also had pegged maxillary permanent lateral incisors with dens invaginatus. Two mothers of the patients carried the mutation and had pegged maxillary permanent lateral incisors.


Animal Model

Schultz (1934) found selective tooth agenesis in 1 gorilla and 1 gibbon.

See Also:

Keeler and Short (1934); Mandeville (1950); Montagu (1940); Rantanen (1956); Salinas (1978); Schultz (1932); Witkop (1961)

REFERENCES

  1. Arzoo, P. S., Klar, J., Bergendal, B., Norderyd, J., Dahl, N. WNT10A mutations account for 1/4 of population-based isolated oligodontia and show phenotypic correlations. Am. J. Med. Genet. 164A: 353-359, 2014. [PubMed: 24449199] [Full Text: https://doi.org/10.1002/ajmg.a.36243]

  2. Biegert, J. Adolph H. Schultz. Zum Tod des Zuericher Anthropologen. Folia Primatol. 26: 2-4, 1976. [PubMed: 783024]

  3. Bohring, A., Stamm, T., Spaich, C., Haase, C., Spree, K., Hehr, U., Hoffmann, M., Ledig, S., Sel, S., Wieacker, P., Ropke, A. WNT10A mutations are a frequent cause of a broad spectrum of ectodermal dysplasias with sex-biased manifestation pattern in heterozygotes. Am. J. Hum. Genet. 85: 97-105, 2009. [PubMed: 19559398] [Full Text: https://doi.org/10.1016/j.ajhg.2009.06.001]

  4. Burzynski, N., Escobar, V. Classification and genetics of numeric anomalies of dentition. Birth Defects Orig. Art. Ser. 19: 95-106, 1983. [PubMed: 6362744]

  5. Creton, M. A., Cune, M. S., Verhoeven, J. W., Meijer, G. J. Patterns of missing teeth in a population of oligodontia patients. Int J. Prosthodont. 20: 409-413, 2007. [PubMed: 17695874]

  6. Grahnen, H. Hypodontia in the permanent dentition. Odont. Rev. 7 (suppl. 3): 1-100, 1956.

  7. Hoo, J. J. Anodontia of permanent teeth (OMIM # 206780) and pegged/missing maxillary lateral incisors (OMIM # 150400) in the same family. (Letter) Am. J. Med. Genet. 90: 326-327, 2000. [PubMed: 10710232] [Full Text: https://doi.org/10.1002/(sici)1096-8628(20000214)90:4<326::aid-ajmg12>3.0.co;2-o]

  8. Joehr, A. C. Reduktionserscheinungen an den oberen seitlichen Schneidezaehnen. Arch. Klaus Stift. Vererbungsforsch. 9: 73-133, 1934.

  9. Kantaputra, P., Kaewgahya, M., Kantaputra, W. WNT10A mutations also associated with agenesis of the maxillary permanent canines, a separate entity. Am. J. Med. Genet. 164A: 360-363, 2014. [PubMed: 24311251] [Full Text: https://doi.org/10.1002/ajmg.a.36280]

  10. Kantaputra, P., Sripathomsawat, W. WNT10A and isolated hypodontia. Am. J. Med. Genet. 155A: 1119-1122, 2011. [PubMed: 21484994] [Full Text: https://doi.org/10.1002/ajmg.a.33840]

  11. Keeler, C. E., Short, R. Hereditary absence of upper lateral incisors. J. Hered. 25: 391-392, 1934.

  12. Mandeville, L. C. Congenital absence of permanent maxillary lateral incisor teeth. A preliminary investigation. Ann. Eugen. 15: 1-10, 1950.

  13. Montagu, M. F. A. The significance of the variability of the upper lateral incisor teeth in man. Hum. Biol. 12: 323-358, 1940.

  14. Nieminen, P., Arte, S., Pirinen, S., Peltonen, L., Thesleff, I. Gene defect in hypodontia: exclusion of MSX1 and MSX2 as candidate genes. Hum. Genet. 96: 305-308, 1995. [PubMed: 7649547] [Full Text: https://doi.org/10.1007/BF00210412]

  15. Peck, L., Peck, S., Attia, Y. Maxillary canine-first premolar transposition associated dental anomalies: genetic bases. Angle Orthod. 63: 99-109, 1993. [PubMed: 8498708] [Full Text: https://doi.org/10.1043/0003-3219(1993)063<0099:MCFPTA>2.0.CO;2]

  16. Plaisancie, J., Bailleul-Forestier, I., Gaston, V., Vaysse, F., Lacombe, D., Holder-Espinasse, M., Abramowicz, M., Coubes, C., Plessis, G., Faivre, L., Demeer, B., Vincent-Delorme, C., and 10 others. Mutations in WNT10A are frequently involved in oligodontia associated with minor signs of ectodermal dysplasia. Am. J. Med. Genet. 161A: 671-678, 2013. [PubMed: 23401279] [Full Text: https://doi.org/10.1002/ajmg.a.35747]

  17. Rantanen, A. V. On the frequency of the missing and peg-shaped maxillary lateral incisor among Finnish students. Am. J. Phys. Anthrop. 14: 491-496, 1956. [PubMed: 13381833] [Full Text: https://doi.org/10.1002/ajpa.1330140322]

  18. Salinas, C. F. Personal Communication. Charleston, S. C. 10/8/1978.

  19. Schultz, A. H. The hereditary tendency to eliminate the upper lateral incisors. Hum. Biol. 4: 34-40, 1932.

  20. Schultz, A. H. Inherited reductions in the dentition of man. Hum. Biol. 6: 627-631, 1934.

  21. Suarez, B. K., Spence, M. A. The genetics of hypodontia. J. Dent. Res. 53: 781-785, 1974. [PubMed: 4526369] [Full Text: https://doi.org/10.1177/00220345740530040201]

  22. van den Boogaard, M.-J., Creton, M., Bronkhorst, Y., van der Hout, A., Hennekam, E., Lindhout, D., Cune, M., Ploos van Amstel, H. K. Mutations in WNT10A are present in more than half of isolated hypodontia cases. J. Med. Genet. 49: 327-331, 2012. [PubMed: 22581971] [Full Text: https://doi.org/10.1136/jmedgenet-2012-100750]

  23. Witkop, C. J., Jr. Studies of intrinsic disease in isolates with observations on penetrance and expressivity of certain anatomical traits. In: Pruzansky, S.: Congenital Anomalies of the Face and Associated Structures. Springfield, Ill.: Charles C Thomas (pub.) 1961.

  24. Witkop, C. J., Jr. Agenesis of succedaneous teeth: an expression of the homozygous state of the gene for the pegged or missing maxillary lateral incisor trait. Am. J. Med. Genet. 26: 431-436, 1987. [PubMed: 3812593] [Full Text: https://doi.org/10.1002/ajmg.1320260222]

  25. Woolf, C. M. Missing maxillary lateral incisors: a genetic study. Am. J. Hum. Genet. 23: 289-296, 1971. [PubMed: 5089845]


Contributors:
Marla J. F. O'Neill - updated : 03/06/2017
Marla J. F. O'Neill - updated : 01/04/2017
Ingrid M. Wentzensen - updated : 7/2/2014
Marla J. F. O'Neill - updated : 8/9/2012
Marla J. F. O'Neill - updated : 6/30/2011
Marla J. F. O'Neill - updated : 7/30/2009
Sonja A. Rasmussen - updated : 3/6/2000
Victor A. McKusick - updated : 8/13/1999

Creation Date:
Victor A. McKusick : 6/2/1986

Edit History:
carol : 03/06/2017
carol : 01/04/2017
carol : 02/24/2015
carol : 7/2/2014
carol : 7/2/2014
carol : 7/2/2014
carol : 8/9/2012
terry : 8/9/2012
wwang : 7/13/2011
terry : 6/30/2011
wwang : 8/19/2009
terry : 7/30/2009
joanna : 4/24/2009
carol : 4/5/2007
mgross : 3/17/2004
mcapotos : 11/14/2000
mcapotos : 3/8/2000
mcapotos : 3/6/2000
mcapotos : 3/6/2000
carol : 8/18/1999
terry : 8/13/1999
terry : 7/8/1997
alopez : 6/2/1997
mark : 6/28/1996
terry : 11/17/1995
mark : 10/2/1995
mimadm : 11/5/1994
davew : 7/13/1994
carol : 5/27/1994
supermim : 3/16/1992



NOTE: OMIM is intended for use primarily by physicians and other professionals concerned with genetic disorders, by genetics researchers, and by advanced students in science and medicine. While the OMIM database is open to the public, users seeking information about a personal medical or genetic condition are urged to consult with a qualified physician for diagnosis and for answers to personal questions.
OMIM® and Online Mendelian Inheritance in Man® are registered trademarks of the Johns Hopkins University.
Copyright® 1966-2025 Johns Hopkins University.

NOTE: OMIM is intended for use primarily by physicians and other professionals concerned with genetic disorders, by genetics researchers, and by advanced students in science and medicine. While the OMIM database is open to the public, users seeking information about a personal medical or genetic condition are urged to consult with a qualified physician for diagnosis and for answers to personal questions.
OMIM® and Online Mendelian Inheritance in Man® are registered trademarks of the Johns Hopkins University.
Copyright® 1966-2025 Johns Hopkins University.
Printed: March 14, 2025