Mosaicism for FMR1 gene full mutation and intermediate allele in a female foetus: A postzygotic retraction event

Fragile X syndrome is caused by the expansion of an unstable CGG repeat in the 5′UTR of FMR1 gene. The occurrence of mosaicism is not uncommon, especially in male patients, whereas in females it is not so often reported. Here we report a female foetus that was subject to prenatal diagnosis, because of her mother being a premutation carrier. The foetus was identified as being a mosaic for an intermediate allele and a full mutation of FMR1 gene, in the presence of a normal allele. The mosaic status was confirmed in three different tissues of the foetus – amniotic fluid, skin biopsy and blood – the last two obtained after pregnancy termination. Karyotype analysis and X-chromosome STR markers analysis do not support the mosaicism as inheritance of both maternal alleles. Oligonucleotide array-CGH excluded an imbalance that could contain the primer binding site with a different repeat size. The obtained results give compelling evidence for a postzygotic expansion mechanism where the foetus mosaic pattern originated from expansion of the mother's premutation into a full mutation and consequent regression to an intermediate allele in a proportion of cells. These events occurred in early embryogenesis before the commitment of cells into the different tissues, as the three tested tissues of the foetus have the same mosaic pattern. The couple has a son with Fragile X mental retardation syndrome and choose to terminate this pregnancy after genetic counselling.     

A functional polymorphism in interleukin-1α (IL1A) gene is associated with risk of alopecia areata in Chinese populations

Alopecia areata (AA) is an inflammatory hair loss disorder with a major genetic component, which may cause great psychosocial distress for those affected. Studies have shown that interleukin-1 (IL-1) is a very potent inducer of hair loss and a significant human hair growth inhibitor. The 4-bp insertion/deletion (Indel) polymorphism (rs3783553) within the 3′ untranslated regions of IL1A gene has been suggested to be associated with risk of various types of cancers, possibly through regulating expression of IL-1α levels. In the current study, we estimated the susceptibility to AA associated with rs3783553 in two independent case–control panels of Eastern and Southern Chinese populations, totally containing 313 AA cases and 626 healthy controls. Logistic regression analysis showed that the heterozygote and the homozygote 4-bp ins/ins confer a significantly lower risk of AA in both panels and total subjects [odds ratio (OR) = 0.55, 95% confidence interval (C.I.) = 0.41–0.75, P = 6.24 × 10^− 5; OR = 0.47, 95% C.I. = 0.28–0.76, P = 0.001, respectively]. Stratification analysis based on age onset showed that the protective roles of ins/del and ins/ins genotype against developing AA was more obvious in AA patients with early age onset (< 30 years) under dominant model (OR = 0.48, 95% C.I. = 0.29–0.77, P = 0.001). The results of luciferase assay showed that rs3783553 could influence expression of IL-1α in a miR-122 dependant manner. Taken together, our results suggested that the IL1A 4-bp indel polymorphism may be a marker for genetic susceptibility to patchy (mild) AA in Chinese populations, likely through miR-122 mediated regulation.     

The genetic basis of triple A (Allgrove) syndrome in a Greek family

Triple A (or Allgrove) syndrome is an autosomal recessive genetic disorder. Patients typically suffer from chronic adrenal insufficiency due to resistance to ACTH (Addison's disease), achalasia of the cardia, and defective tear formation (alacrima). The syndrome is caused by mutations in the AAAS gene which encodes the protein ALADIN, a constituent of eukaryotic nuclear pore complexes. The multi-systemic nature and variable manifestations of the triple A syndrome often confound its diagnosis and limit our understanding of its exact pathogenesis. We performed mutational screening of the AAAS gene in a Greek family of four individuals, including an affected propositus with typical symptoms of late-onset triple A syndrome. Our results are consistent with an autosomal recessive pattern of inheritance within the family, caused by a functional c.43C > A mutation in exon 1 of the AAAS gene. All members of the family were also homozygous for a silent c.855C > T nucleotide change within exon 9 of the AAAS gene, representing a common single nucleotide polymorphism. The compromising c.43C > A mutation is predicted to cause a p.Gln15Lys amino acid substitution in the ALADIN protein. However, it has been suggested that the functional impact of this mutation may be more severe, causing a shift in the reading frame of AAAS gene via formation of an aberrant premature donor splice site within exon 1. We propose that mutational analysis of the AAAS gene should be considered in adult patients with one or more clinical signs of the disease, as diagnosis of late-onset cases can be ambiguous.     

Two newly identified exons in human GRM1 express a novel splice variant of metabotropic glutamate 1 receptor

To date, five human metabotropic glutamate (mGlu) 1 receptor splice variants (1a, 1b, 1d, 1f, and 1g) have been described, all of which involve alternative C-terminal splicing. mGlu1a receptor contains a long C-terminal domain (341 amino acids), which has been shown to scaffold with several proteins and contribute to the structure of the post-synaptic density. However, several shorter mGlu1 receptor splice variants lack the sequence required for these interactions, and no major functional differences between these short splice variants have been described. By using RT-PCR we have shown that two human melanoma cell lines express both mGlu1a and mGlu1b receptors. In addition, using 3′RACE, we identified three previously unknown mGlu1 receptor mRNAs. Two differ in the length of their 3′ untranslated region (UTR), and encode the same predicted protein as mGlu1g receptor—the shortest of all mGlu1 receptor splice variants. The third mRNA, named mGlu1h, encodes a predicted C-terminal splice variant of 10 additional amino acids. mGlu1h mRNA was observed in two different melanoma cell lines and is overexpressed, compared with melanoma precursor cells, melanocytes. Most importantly, this new splice variant, mGlu1h receptor, is encoded by two previously unidentified exons located within the human GRM1 gene. Additionally, these new exons are found exclusively within the GRM1 genes of higher primates and are highly conserved. Therefore, we hypothesize that mGlu1h receptors play a distinct role in primate glutamatergic signaling.