Abstract:Objective To investigate the clinical features and molecular mechanism of hidrotic ectodermal dysplasia (HED). Methods A clinical and gene study was performed for five generations (91 people) in the family of one proband with HED. GJB6 gene detection was performed for 7 patients and 3 normal people in this family. Results Among the 91 people in this family, there were 17 HED patients, who were manifested as having dysplasia of the fingernails and toenails and sparse or absent hair or body hair. The male patients had a greater degree of sparse hair compared with female patients. In the younger generations, damage to the fingernails and toenails was gradually alleviated. There were patients in each generation, the patient's mother or father definitely had this disease. Both males and females developed this disease, and the inheritance pattern was autosomal dominant inheritance. A heterozygous missense mutation, 31G→A, in GJB6 gene was detected in all patients in this family, but this mutation was not detected in family members without the clinical manifestations of HED. Conclusions HED is a hereditary disease with autosomal dominant inheritance and has the clinical features of dysplasia of the fingernails and toenails, hyperkeratosis of palms and soles, and sparse or absent hair or body hair. Male patients have a greater degree of sparse hair. In the younger generations, damage to the fingernails and toenails is gradually alleviated. The missense mutation 31G→A in the GJB6 gene may be one of the molecular mechanisms for HED.
Bhalla G,Agrawal KK,Chand P,et al.Effect of complete dentures on craniofacial growth of an ectodermal dysplasia patient:a clinical report[J].J Prosthodontics,2013,22(6):495-500.
[2]
Rojasa1 LV,Silvab GDd.Hypohidrotic ectodermal dysplasia:clinical and radiographic characteristics[J].Revista Odontológica Mexicana,2015,19(4):e249-e253.
[3]
Vasconcelos Carvalho M,Romero Souto de Sousa J,Paiva Correa de Melo F,et al.Hypohidrotic and hidrotic ectodermal dysplasia:a report of two cases[J].Dermatol Online J,2013,19(7):18985.
[4]
Sitton JE,Reimund EL.Extramedullary hematopoiesis of the cranial dura and anhidrotic ectodermal dysplasia[J].Neuropediatrics,1992,23(2):108-110.
Radhakrishna1 U,Blouin1 JL,Mehenni1 H,et al.The gene for autosomal dominant hidrotic ectodermal dysplasia (Clouston syndrome) in a large Indian family maps to the 13q11-q12.1 pericentromeric region[J].Am J Med Genet,1997,71(1):80-86.
[8]
Lamartine J,Laoudj D,Blanchet-Bardon C,et al.Refined localization of the gene for Clouston syndrome (hidrotic ectodermal dysplasia) in a large French family[J].Br J Dermatol,2000,142(2):248-252.
[9]
Di WL,Rugg EL,Leigh IM,et al.Multiple epidermal connexins are expressed in different keratinocyte subpopulations including connexin 31[J].J Invest Dermatol,2001,117(4):958-964.
[10]
Xia A,Katori Y,Oshima T,et al.Expression of connexin 30 in the developing mouse cochlea[J].Brain Res,2001,898(2):364-367.
[11]
Smith FJ,Morley SM,McLean WH.A novel connexin 30 mutation in Clouston syndrome[J].J Invest Dermatol,2002,118(3):530-532.
[12]
Baris HN,Zlotogorski A,Peretz-Amit G,et al.A novel GJB6 missense mutation in hidrotic ectodermal dysplasia 2(Clouston syndrome) broadens its genotypic basis[J].Br J Dermatol,2008,159(6):1373-1376.
[13]
Zhang XJ,Chen JJ,Yang S,et al.A mutation in the connexin 30 gene in Chinese Han patients with hidrotic ectodermal dysplasia[J].J Dermatol Sci,2003,32(1):11-17.
