Novel Nonsense Mutation in the Na+/HCO3 - Cotransporter Gene (SLC4A4) in a Patient with Permanent Isolated Proximal Renal Tubular Acidosis and Bilateral Glaucoma
Takashi IgarashiJun InatomiTakashi SekineGeorge SekiMitsunobu ShimadzuFUMIKO TOZAWAYasuhiro TakeshimaToru TakumiToshikazu TakahashiNorishige YoshikawaHajime NakamuraHitoshi Endou
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Abstract. Permanent isolated proximal renal tubular acidosis (pRTA) with ocular abnormalities is a systemic disease involving short stature, isolated pRTA, mental retardation, and ocular abnormalities. Kidney Na + /HCO 3 - cotransporter (kNBC1) cDNA from peripheral lymphocytes from a patient with permanent isolated pRTA and bilateral glaucoma was screened, and a novel homozygous mutation, namely a cytosine-to-thymine transition at nucleotide 234, which resulted in the formation of a stop codon at codon 29, was identified. This homozygous mutation, Q29X, was identified in the unique 5′-end of the kNBC1 gene ( SLC4A4 ) of the patient. Cosegregation of this Q29X mutation with the disease and heterozygosity in the parents of the affected patient were observed. The absence of this mutation in 156 alleles from 78 Japanese individuals indicates that this mutation is directly related to the disease and is not a common DNA sequence polymorphism. This nonsense mutation predicts a truncated kNBC1 protein that lacks the 1007 amino acids of the carboxyl-terminus, and the effect on kNBC1 cotransport activity is likely to be a loss of function. In contrast, the pancreatic Na + /HCO 3 - cotransporter of the patient is not likely to be affected by this nonsense mutation. These results have implications for understanding the role of kNBC1 in the pathophysiologic processes of pRTA associated with ocular abnormalities and mental retardation.Keywords:
Nonsense mutation
Stop codon
Compound heterozygosity
Nonsense mutations often result from single nucleotide substitutions that change a sense codon (coding for an amino acid) to a nonsense or premature termination codon (PTC) within the coding region of a gene. The impact of nonsense mutations is two-fold: (1) the PTC-containing mRNA is degraded by a surveillance pathway called nonsense-mediated mRNA decay (NMD) and (2) protein translation stops prematurely at the PTC codon, and thus no functional full-length protein is produced. As such, nonsense mutations result in a large number of human diseases. Nonsense suppression is a strategy that aims to correct the defects of hundreds of genetic disorders and reverse disease phenotypes and conditions. While most clinical trials have been performed with small molecules, there is an increasing need for sequence-specific repair approaches that are safer and adaptable to personalized medicine. Here, we discuss recent advances in both conventional strategies as well as new technologies. Several of these will soon be tested in clinical trials as nonsense therapies, even if they still have some limitations and challenges to overcome.
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Stop codon
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Nonsense mutations introduce premature termination codons and underlie 11% of genetic disease cases. High concentrations of aminoglycosides can restore gene function by eliciting premature termination codon readthrough but with low efficiency. Using a high-throughput screen, we identified compounds that potentiate readthrough by aminoglycosides at multiple nonsense alleles in yeast. Chemical optimization generated phthalimide derivative CDX5-1 with activity in human cells. Alone, CDX5-1 did not induce readthrough or increase TP53 mRNA levels in HDQ-P1 cancer cells with a homozygous TP53 nonsense mutation. However, in combination with aminoglycoside G418, it enhanced readthrough up to 180-fold over G418 alone. The combination also increased readthrough at all three nonsense codons in cancer cells with other TP53 nonsense mutations, as well as in cells from rare genetic disease patients with nonsense mutations in the CLN2, SMARCAL1 and DMD genes. These findings open up the possibility of treating patients across a spectrum of genetic diseases caused by nonsense mutations.
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Nonsense-Mediated Decay
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Friedreich's ataxia is a neurodegenerative disorder associated with a GAA trinucleotide repeat expansion in intron 1 of the frataxin (FXN) gene. It is the most common autosomal recessive cerebellar ataxia, with a mean age of onset at 16 years. Nearly 95-98% of patients are homozygous for a 90-1300 GAA repeat expansion with only 2-5% demonstrating compound heterozygosity. Compound heterozygous individuals have a repeat expansion in one allele and a point mutation/deletion/insertion in the other. Compound heterozygosity and point mutations are very rare causes of Friedreich's ataxia and nonsense mutations are a further rarity among point mutations. We report a rare compound heterozygous Friedrich's ataxia patient who was found to have one expanded GAA FXN allele and a nonsense point mutation in the other. We summarize the four previously published cases of nonsense mutations and compare the phenotype to that of our patient. We compared clinical information from our patient with other nonsense FXN mutations reported in the literature. This nonsense mutation, to our knowledge, has only been described once previously; interestingly the individual was also of Cuban ancestry. A comparison with previously published cases of nonsense mutations demonstrates some common clinical characteristics.
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The second most common cause of congenital adrenal hyperplasia is 11β-hydroxylase deficiency, an autosomal recessive disorder. We performed genetic analysis of CYP11B1, the gene encoding steroid 11β-hydroxylase, in three patients with classic 11β-hydroxylase deficiency. Herein we describe the first splice donor site mutation, a new nonsense mutation, and a new missense mutation in this disorder. An African-American patient was found to be a compound heterozygote for a codon 318+1G→A substitution at the 5′-splice donor site of intron 5, in combination with Q356X, a nonsense mutation previously reported in an African-American patient. A Caucasian patient was found to be a compound heterozygote with a novel missense mutation, T318R, in combination with a previously reported 28-bp deletion in exon 2. A different mutation at codon 318 (T318M) has been described previously. A Caucasian patient was heterozygous for a novel nonsense mutation (Q19X) in exon 2. The second mutation was not identified in this patient. Multiple apparent polymorphisms were also observed. Two of these polymorphisms in CYP11B1 represent sequences from CYP11B2, suggesting that gene conversion may have occurred. In summary, we have identified three novel mutations and two previously reported mutations in CYP11B1 patients with 11β-hydroxylase deficiency. Our data suggest the presence of a mutational hot spot at codon 318 of CYP11B1, and the possibility of a founder effect in frequently identified mutations.
Nonsense mutation
Compound heterozygosity
Steroid 11-beta-hydroxylase
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Compound heterozygosity
Heterozygote advantage
Nonsense
Congenital muscular dystrophy
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Acrodermatitis enteropathica is rare autosomal recessive disorder characterized by a severe nutritional zinc deficiency. We and others have recently identified the human gene encoding an intestinal zinc transporter of the ZIP family, SLC39A4, as the mutated gene in acrodermatitis enteropathica (AE). A first mutation screening in 8 AE families (15 patients out of 36 individuals) revealed the presence of six different mutations described elsewhere. Based on these results, we have evaluated the involvement of SLC39A4 in 14 patients of 12 additional AE pedigees coming either from France, Tunisia, Austria or Lithuania. A total of 7 SLC39A4 mutations were identified (1 deletion, 2 nonsense, 2 missense, and 2 modifications of splice site), of which 4 are novel: a homozygous nonsense mutation in 3 consanguineous Tunisian families [c.143T>G (p.Leu48X)], a heterozygous nonsense mutation (c.1203G>A (p.Trp401X)) in a compound heterozygote from Austria also exhibiting an already known missense mutation, and distinct homozygous mutations in families from France or Tunisia [c.475-2A>G and c.184T>C (p.Cys62Arg)]. Furthermore, two other potential mutations [c.850G>A (p.Glu284Lys) and c.193-113T>C] were also observed at homozygous state in a French family formerly described. This study brings to 21 the number of reported SLC39A4 mutations in AE families.
Acrodermatitis enteropathica
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(1) Background: A premature termination codon (PTC) can be induced by a type of point mutation known as a nonsense mutation, which occurs within the coding region. Approximately 3.8% of human cancer patients have nonsense mutations of p53. However, the non-aminoglycoside drug PTC124 has shown potential to promote PTC readthrough and rescue full-length proteins. The COSMIC database contains 201 types of p53 nonsense mutations in cancers. We built a simple and affordable method to create different nonsense mutation clones of p53 for the study of the PTC readthrough activity of PTC124. (2) Methods: A modified inverse PCR-based site-directed mutagenesis method was used to clone the four nonsense mutations of p53, including W91X, S94X, R306X, and R342X. Each clone was transfected into p53 null H1299 cells and then treated with 50 μM of PTC124. (3) Results: PTC124 induced p53 re-expression in H1299-R306X and H1299-R342X clones but not in H1299-W91X and H1299-S94X clones. (4) Conclusions: Our data showed that PTC124 more effectively rescued the C-terminal of p53 nonsense mutations than the N-terminal of p53 nonsense mutations. We introduced a fast and low-cost site-directed mutagenesis method to clone the different nonsense mutations of p53 for drug screening.
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