Cowden syndrome and Bannayan Riley Ruvalcaba syndrome represent one condition with variable expression and age-related penetrance: results of a clinical study of PTEN mutation carriers.

BACKGROUND: The most commonly reported phenotypes described in patients with PTEN mutations are Bannayan-Riley-Ruvalcaba syndrome (BRRS), with childhood onset, macrocephaly, lipomas and developmental delay, and Cowden Syndrome (CS), an adult-onset condition recognised by mucocutaneous signs, with a risk of cancers, in particular those of the thyroid and breast. It has been suggested that BRRS and CS are the same condition, but the literature continues to separate them and seek a genotype-phenotype correlation. OBJECTIVE: To study the clinical features of patients with known PTEN mutations and observe any genotype-phenotype correlation. METHODS: In total, 42 people (25 probands and 17 non-probands) from 26 families of all ages with PTEN mutations were recruited through the UK clinical genetics services. A full clinical history and examination were undertaken. RESULTS: We were unable to demonstrate a genotype-phenotype correlation. Furthermore, our findings in a 31-year-old woman with CS and an exon 1 deletion refutes previous reports that whole exon deletions are only found in patients with a BRRS phenotype. CONCLUSION: Careful phenotyping gives further support for the suggestion that BRRS and CS are actually one condition, presenting variably at different ages, as in other tumour-suppressor disorders such as neurofibromatosis type 1. This has important counselling implications, such as advice about cancer surveillance, for children diagnosed with BRRS.

Hereditary hyperferritinemia cataract syndrome: ocular, genetic, and biochemical findings.

PURPOSE: To describe the cataract morphology and genetic and biochemical findings in a four-generation family with hereditary hyperferritinemia cataract syndrome (HHCS). METHODS: Family members of the proband with HHCS were investigated. DNA sequencing was carried out to identify the iron responsive element (IRE) of the L-ferritin gene in affected and non-affected family members. Molecular modeling allowed prediction of the structure of the mutant IRE in affected cases. Serum ferritin and transferrin saturation were determined using standard methods. All family members underwent slit lamp examination by an ophthalmologist to document presence of cataract or lens status. Cataract morphology was documented where present. RESULTS: This family with HHCS had the genetic heterozygous mutation G32C in the IRE of the L-ferritin mRNA. Lens opacities were detectable in young members of the family, and morphology of cataracts was consistent with previous reports. Biochemical testing demonstrated high serum ferritin levels in affected individuals. CONCLUSIONS: The morphology of cataracts in HHCS seems to be similar in all cases. In the heterozygous G32C mutation, the age at onset of cataracts is very early. Greater awareness of this condition among ophthalmologists will lead to effective family counseling of those affected, by genetic testing or simple biochemical tests. Serum ferritin levels can be effectively used to screen for this condition in suspected families.

A clinical and molecular study of 26 females with Xp deletions with special emphasis on inherited deletions.

We have undertaken a clinical study of 26 females with deletions of Xp including five mother-daughter pairs. Cytogenetic and molecular analyses have mapped the breakpoints of the deletions. We determined the parental origin of each abnormality and studied the X-inactivation patterns. We describe the clinical features and compare them with the amount of Xp material lost. We discuss the putative loci for features of Turner syndrome and describe how our series contributes further to their delineation. We conclude that (1) fertility can be retained even with the loss of two-thirds of Xp, thus, if there are genes on Xp for ovarian development, they must be at Xp11-Xp11.2; (2) in our sample of patients there is no evidence to support the existence of a single lymphogenic gene on Xp; (3) there is no evidence for a second stature locus in proximal Xp; (4) there is no evidence to support the existence of a single gene for naevi; (5) we suggest that the interval in Xp21.1-Xp11.4 between DXS997 and DXS1368 may contain a gene conferring a predisposition to hypothyroidism.