Ayman El-Seedy

Influence of the Duplication of CFTR Exon 9 and Its Flanking Sequences on Diagnosis of Cystic Fibrosis Mutations

The DNA sequences of seven regions in the human genome were examined for sequence identity with exon 9 of the cystic fibrosis transmembrane conductance regulator (CFTR) gene, which is mutated in cystic fibrosis, and its intronic boundaries. These sequences were 95% to 96% homologous. Based on this nucleotide sequence similarity, PCR primers for CFTR exon 9 can potentially anneal with other homologous sequences in the human genome. Sequence alignment analysis of the CFTR exon 9 homologous sequences revealed that five registered mutations in the Cystic Fibrosis Mutation Database may be due to the undesired annealing of primers to a homologous sequence, resulting in inappropriate PCR amplification. For this reason, we propose that certain pseudomutations may result from the similarity between CFTR exon 9 (and its flanking introns) and related sequences in the human genome. Here we show that two mutations previously described in the CFTR database (c.1392 + 6insC; c.1392 + 12G>A) were inappropriately attributed to two individuals who sought carrier testing. A more detailed study by either direct sequencing or subcloning and sequencing of PCR products using specially designed primers revealed that these apparent mutations were not, in fact, present in CFTR. In addition, we present new PCR conditions that permit specific amplification of CFTR exon 9 and its flanking regions.

CFTR mutation combinations producing frequent complex alleles with different clinical and functional outcomes

Genotype–phenotype correlations in cystic fibrosis (CF) may be difficult to establish because of phenotype variability, which is associated with certain CF transmembrane conductance regulator (CFTR) gene mutations and the existence of complex alleles. To elucidate the clinical significance of complex alleles involving p.Gly149Arg, p.Asp443Tyr, p.Gly576Ala, and p.Arg668Cys, we performed a collaborative genotype–phenotype correlation study, collected epidemiological data, and investigated structure–function relationships for single and natural complex mutants, p.[Gly576Ala;Arg668Cys], p.[Gly149Arg;Gly576Ala;Arg668Cys], and p.[Asp443Tyr;Gly576Ala;Arg668Cys]. Among 153 patients carrying at least one of these mutations, only three had classical CF and all carried p.Gly149Arg in the triple mutant. Sixty‐four had isolated infertility and seven were healthy individuals with a severe mutation in trans, but none had p.Gly149Arg. Functional studies performed on all single and natural complex mutants showed that (1) p.Gly149Arg results in a severe misprocessing defect; (2) p.Asp443Tyr moderately alters CFTR maturation; and (3) p.Gly576Ala, a known splicing mutant, and p.Arg668Cys mildly alter CFTR chloride conductance. Overall, the results consistently show the contribution of p.Gly149Arg to the CF phenotype, and suggest that p.[Arg668Cys], p.[Gly576Ala;Arg668Cys], and p.[Asp443Tyr;Gly576Ala;Arg668Cys] are associated with CFTR‐related disorders. The present study emphasizes the importance of comprehensive genotype–phenotype and functional studies in elucidating the impact of mutations on clinical phenotype. Hum Mutat 33:1557–1565, 2012.

Consequences of partial duplications of the human CFTR gene on cf diagnosis: Mutations or ectopic variations

CFTR exon 10 and its flanking regions are duplicated in the human genome. These duplications present mutations compared to the normal exon 10 sequence. Due to the polymorphic sequence of the 3 intron 9 sequence, it may appear difficult to sequence exon 10 and some mutations described in this exon could, in fact, be variations observed in an ectopic duplicated sequence. In our previous work we described a methodology to carry out PCR only of exon 10 and not of ectopic regions. In this work, we analyzed mutations described in the CF data base as being CFTR mutations but also found in ectopic regions: c.1392G>T, c.1338_1339delAT, c.1235delC, and c.1247A>G. We have shown that these mutations appear to be authentic mutations in CFTR exon 10 and not ectopic variations in analyzed patients. These mutations validate the usefulness of our new strategy in the mutation analysis of this region of CFTR.

Cystic Fibrosis Transmembrane Conductance Regulator (CFTR) gene mutations in North Egyptian population: implications for the genetic diagnosis in Egypt

Cystic fibrosis (CF) occurrence in Arab populations is not common and still remains underidentified. Furthermore, the lack of disease awareness and diagnosis facilities have mislead the identification of cystic fibrosis for decades. The knowledge about cystic fibrosis (CF) in Egypt is very limited, and a few reports have drawn attention to the existence of CF or CFTR-related disorders (CFTR-RDs) in the Egyptian population. Therefore a comprehensive genetic analysis of the CFTR gene was realized in patients of North Egypt. DNA samples of 56 Egyptian patients were screened for the CFTR gene mutations. The 27 exons and their flanking regions of the CFTR gene were amplified by PCR, using the published primer pairs, and were studied by automated direct DNA sequencing to detect disease-causing mutations. Moreover, large duplication/deletion was analysed by MLPA technique. CFTR screening revealed the identification of thirteen mutations including four novel ones: c.92G>A (p.Arg31His), c.2782G>C (p.Ala928Pro), c.3718-24G>A, c.4207A>G (p.Arg1403Gly) and nine previously reported mutations: c.454A>T (p.Met152Leu), c.902A>G (p.Tyr301Cys), c.1418delG, c.2620-15C>G, c.2997_3000delAATT, c.3154T>G (p.Phe1052Val), c.3872A>G (p.Gln1291Arg), c.3877G>A (p.Val1293Ile), c.4242+10T>C. Furthermore, eight polymorphisms were found: c.743+40A>G, c.869+11C>T, c.1408A>G, c.1584G>A, c.2562T>G, c.3870A>G, c.4272C>T, c.4389G>A. These mutations and polymorphisms were not previously described in the Egyptian population except for the c.1408A>G polymorphism. Here we demonstrate the importance of the newly discovered mutations in Egyptian patients and the presence of CF, whereas the p.Phe508del mutation is not detected. The identification of CFTR mutations will become increasingly important in undocumented populations. The current findings will help us expand the mutational spectrum of CF and establish the first panel of the CFTR gene mutations in the Egyptian population and design an appropriate strategy for future genetic diagnosis of CF.

N1303K (c.3909C>G) mutation and splicing: implication of its c.[744-33GATT(6); 869+11C>T] complex allele in CFTR exon 7 aberrant splicing.

Cystic Fibrosis is the most common recessive autosomal rare disease found in Caucasians. It is caused by mutations on the Cystic Fibrosis Transmembrane Conductance Regulator gene (CFTR) that encodes a protein located on the apical membrane of epithelial cells. c.3909C>G (p.Asn1303Lys, old nomenclature: N1303K) is one of the most common worldwide mutations. This mutation has been found at high frequencies in the Mediterranean countries with the highest frequency in the Lebanese population. Therefore, on the genetic level, we conducted a complete CFTR gene screening on c.3909C>G Lebanese patients. The complex allele c.[744-33GATT(6); 869+11C>T] was always associated with the c.3909C>G mutation in cis in the Lebanese population. In cellulo splicing studies, realized by hybrid minigene constructs, revealed no impact of the c.3909C>G mutation on the splicing process, whereas the associated complex allele induces minor exon skipping.

CFTR Gene Mutations in the Egyptian Population: Current and Future Insights for Genetic Screening Strategy

Cystic Fibrosis (CF) is the most common lethal rare genetic disease in the Caucasian populations. It is caused by a variety of sequence alterations in the Cystic Fibrosis Transmembrane Regulator (CFTR) gene. In Caucasian, one over 3,500 new born children suffers from the disease and one over 30 of them is at least carrier of a severe mutation in the CFTR gene. CF and CFTR-related disorders (CFTR-RDs) are two distinct clinical outcomes of the gene mutations. The CF mutation induces a severe phenotype involving different organs, whereas a CFTR-RD mutation induces less life-threatening symptoms with three main clinical entities including congenital bilateral absence of the vas deferens (CBAVD), acute recurrent or chronic pancreatitis, and disseminated bronchiectasis (Bombieri et al., 2011). In the Arab countries, the spectrum of CF mutations, incidence and prevalence of the disease are largely unknown in the Arab populations (Wei et al., 2006). This is due to the lack of disease awareness, and diagnosis facilities that mislead the identification of CF during many decades. Additionally, epidemiological studies that realized were revealed a distinguished mutational spectrum between Arab countries if compared to White-European populations. Furthermore, Arab Mediterranean countries have a different CFTR mutational profile if compared to the Arabian Peninsula. Egypt as Mediterranean North African country, this strategic position attracted many invaders throughout its history. Therefore, in addition to its Pharaonic origin, gene flow to its population occurred from the Ethiopian, Greco-Roman, Arab, Turkish, French and English settlers (Temtamy et al., 2010). The common heritage among the countries bordering the Mediterranean is not restricted to historical or cultural aspects. There are considerable commonalities in the gene pools of the Mediterranean Northern and Southern countries. This genetic sharing has resulted from considerable human movements (i.e., migration, invasion, and trade) throughout history in this area (Temtamy et al., 2010). Consequently, Egypt is not like other Arab countries and mutations in the CFTR gene have been influenced by gene flow coming from different populations. Furthermore, the high rate of consanguinity, infant and neonatal mortality in the Egyptian society will, therefore, increase CF incidence and private mutations. Indeed, another important issue is the increase number of CFTR-related disorders patients such as idiopathic bronchiectasis, congenital bilateral absence of the vas deferens, idiopathic (non-alcoholic) pancreatitis, and severe sinusitis in the Egyptian population. This observation is in agreement with data previously published (Lissens et al. In Egypt, there is no available data on …

In cellulo analyses of the p.Val322Ala mutation on the CFTR protein conformation and activity

Cystic fibrosis is caused by mutations on the Cystic Fibrosis Transmembrane conductance Regulator gene (CFTR). Exonic mutations may have variable effect on the CFTR protein and may alter the normal localization of CFTR on the apical membrane of epithelial cells or/and its function as a chloride channel. Identifying the effect of a missense mutation can be a first step in helping the medical counseling and the therapeutic strategies. In this study, the effect of the c.965T>C exonxa08 mutation that induces a valine-to-alanine substitution (p.Val322Ala) into the fifth helix of the first membrane spanning domain was determined by in silico and in cellulo analyses. The confocal microscopy analyses and functionality test showed, in the tested cell line, that this mutation should have no impact on the function of the p.Val322Ala-CFTR protein. However, regarding the importance of this Val322 amino acid in the CFTR protein, precautions and individual follow-up are still required when c.965T>C if associated with other mutation(s).

Complexity of phenotypes induced by p.Asn1303Lys-CFTR correlates with difficulty to rescue and activate this protein

Cystic Fibrosis is the most common recessive autosomal rare disease found in Caucasian. It is caused by mutations on the Cystic Fibrosis Transmembrane Conductance Regulator gene (CFTR) that encodes for a protein located on the apical membrane of epithelial cells. c.3909C>G (p.Asn1303Lys) is one of the most common worldwide mutations located in nucleotide binding domain 2. The effect of the p.Asn1303Lys mutation on misprocessing was studied by immunofluorescence and western blotting analysis in presence and absence of treatment. To evaluate the functionality of potentially rescued p.Asn1303Lys-CFTR, we assessed the channel activity by radioactive iodide efflux. No recovery of the activity was observed in transfected cultured cells treated with VX-809. Thus, our results suggest that multiple drugs may be needed for the treatment of c.3909C>G patients in order to correct and activate p.Asn1303Lys-CFTR as it shows folding and functional defects.