Genotype‐specific progression of hereditary medullary thyroid cancer

Although already 25 years into the genomic era, age‐related progression of hereditary medullary thyroid cancer (MTC), the prevalence of which is estimated at one in 80,000 inhabitants, remains to be delineated for most unique RET (REarranged during Transfection) mutations. Included in this study were 567 RET carriers. The age‐related progression of MTC across histopathological groups (normal thyroid/C‐cell hyperplasia; node‐negative MTC; node‐positive MTC) was statistically significant for 13 unique RET mutations (p.Cys611Phe/c.1832G > T; p.Cys611Tyr; p.Cys618Ser/c.1852T > A; p.Cys620Arg; p.Cys634Arg; p.Cys634Phe; p.Cys634Ser; p.Cys634Tyr; p.Glu768Asp; p.Leu790Phe/c.2370G > T; p.Val804Met; p.Ser891Ala; p.Met918Thr), whereas two unique RET mutations (p.Cys618Phe; p.Cys634Gly) trended toward statistical significance. When grouped by mutational risk (highest; high; moderate – high; low – moderate; polymorphism), the age‐related progression of MTC was significant for all four categories of RET mutations, which differed significantly across and within the three histopathological groups. For high, for moderate–high, and for low–moderate risk RET mutations, the age‐related progression of MTC by mutated codon was broadly comparable across and within the three histopathological groups, and essentially unaffected by the amino acid substitutions examined. These data argue in favor of splitting the American Thyroid Association's moderate‐risk category into moderate–high and low–moderate risk categories, while emphasizing the need to contradistinguish the latter from rare nonpathogenic polymorphisms.     

Mucolipidosis II‐Related Mutations Inhibit the Exit from the Endoplasmic Reticulum and Proteolytic Cleavage of GlcNAc‐1‐Phosphotransferase Precursor Protein (GNPTAB)

Mucolipidosis (ML) II and MLIII alpha/beta are two pediatric lysosomal storage disorders caused by mutations in the GNPTAB gene, which encodes an α/β‐subunit precursor protein of GlcNAc‐1‐phosphotransferase. Considerable variations in the onset and severity of the clinical phenotype in these diseases are observed. We report here on expression studies of two missense mutations c.242G>T (p.Trp81Leu) and c.2956C>T (p.Arg986Cys) and two frameshift mutations c.3503_3504delTC (p.Leu1168GlnfsX5) and c.3145insC (p.Gly1049ArgfsX16) present in severely affected MLII patients, as well as two missense mutations c.1196C>T (p.Ser399Phe) and c.3707A>T (p.Lys1236Met) reported in more mild affected individuals. We generated a novel α‐subunit‐specific monoclonal antibody, allowing the analysis of the expression, subcellular localization, and proteolytic activation of wild‐type and mutant α/β‐subunit precursor proteins by Western blotting and immunofluorescence microscopy. In general, we found that both missense and frameshift mutations that are associated with a severe clinical phenotype cause retention of the encoded protein in the endoplasmic reticulum and failure to cleave the α/β‐subunit precursor protein are associated with a severe clinical phenotype with the exception of p.Ser399Phe found in MLIII alpha/beta. Our data provide new insights into structural requirements for localization and activity of GlcNAc‐1‐phosphotransferase that may help to explain the clinical phenotype of MLII patients.     

Association analysis between HFM1 variation and primary ovarian insufficiency in Chinese women

HFM1 is a meiosis‐specific gene and expressed in germ‐line tissues. More recently, evidence has indicated that variations in HFM1 gene could be causative for primary ovarian insufficiency (POI), also known as premature ovarian failure. The aim of this study was to investigate the association between HFM1 gene variants and sporadic POI in Chinese women. A total of 138 POI patients and 316 healthy controls (matched for ethnic background, sex, and age of the patients) were recruited in this study. We screened the entire HFM1 coding region by direct sequencing in all subjects and identified six variants of HFM1 gene in POI group, namely c.148G>A/p.Glu50Lys, c.1241A>C/p.His414Pro, c.2325C>A/p.Phe775Leu, c.3367T>C/p.Ser1123Pro, c.3580C>T/p.Arg1194Cys, and c.1686‐1G>C. The variation rate of HFM1 in POI group is significantly higher than control group (p < 0.01). The p.His414Pro and p.Arg1194Cys were predicted to be probably damaging to the HFM1 protein function, while p.Glu50Lys, p.Phe775Leu and p.Ser1123Pro mutants might not have any deleterious effect on the structure or function of the protein by online predictors. Taken together, our data suggested that HFM1 gene might be associated with primary ovarian insufficiency in Chinese population.     

Single‐molecule detection of cancer mutations using a novel PCR‐LDR‐qPCR assay

Detection of low‐abundance mutations in cell‐free DNA is being used to identify early cancer and early cancer recurrence. Here, we report a new PCR‐LDR‐qPCR assay capable of detecting point mutations at a single‐molecule resolution in the presence of an excess of wild‐type DNA. Major features of the assay include selective amplification and detection of mutant DNA employing multiple nested primer‐binding regions as well as wild‐type sequence blocking oligonucleotides, prevention of carryover contamination, spatial sample dilution, and detection of multiple mutations in the same position. Our method was tested to interrogate the following common cancer somatic mutations: BRAF:c.1799T>A (p.Val600Glu), TP53:c.743G>A (p.Arg248Gln), KRAS:c.35G>C (p.Gly12Ala), KRAS:c.35G>T (p.Gly12Val), KRAS:c.35G>A (p.Gly12Asp), KRAS:c.34G>T (p.Gly12Cys), and KRAS:c.34G>A (p.Gly12Ser). The single‐well version of the assay detected 2–5 copies of these mutations, when diluted with 10,000 genome equivalents (GE) of wild‐type human genomic DNA (hgDNA) from buffy coat. A 12‐well (pixel) version of the assay was capable of single‐molecule detection of the aforementioned mutations at TP53, BRAF, and KRAS (specifically p.Gly12Val and p.Gly12Cys), mixed with 1,000–2,250 GE of wild‐type hgDNA from plasma or buffy coat. The assay described herein is highly sensitive, specific, and robust, and potentially useful in liquid biopsies.     

Genetic studies of multiple consanguineous Pakistani families segregating oculocutaneous albinism identified novel and reported mutations

Oculocutaneous albinism (OCA) is an autosomal‐recessive disorder of a defective melanin pathway. The condition is characterized by hypopigmentation of hair, dermis, and ocular tissue. Genetic studies have reported seven nonsyndromic OCA genes, among which Pakistani OCA families mostly segregate TYR and OCA2 gene mutations. Here in the present study, we investigate the genetic factors of eight consanguineous OCA families from Pakistan. Genetic analysis was performed through single‐nucleotide polymorphism (SNP) genotyping (for homozygosity mapping), whole exome sequencing (for mutation identification), Sanger sequencing (for validation and segregation analysis), and quantitative PCR (qPCR) (for copy number variant [CNV] validation). Genetic mapping in one family identified a novel homozygous deletion mutation of the entire TYRP1 gene, and a novel deletion of exon 19 in the OCA2 gene in two apparently unrelated families. In three further families, we identified homozygous mutations in TYR (NM_000372.4:c.1424G > A; p.Trp475*), NM_000372.4:c.895C > T; p.Arg299Cys), and SLC45A2 (NM_016180:c.1532C > T; p.Ala511Val). For the remaining two families, G and H, compound heterozygous TYR variants NM_000372.4:c.1037‐7T > A, NM_000372.4:c.1255G > A (p.Gly419Arg), and NM_000372.4:c.1255G > A (p.Gly419Arg) and novel variant NM_000372.4:c.248T > G; (p.Val83Gly), respectively, were found. Our study further extends the evidence of TYR and OCA2 as genetic mutation hot spots in Pakistani families. Genetic screening of additional OCA cases may also contribute toward the development of Pakistani specific molecular diagnostic tests, genetic counseling, and personalized healthcare.     

Phenotypic and genotypic spectrum of Turkish patients with isovaleric acidemia

We aim to investigate the genetic basis of isovaleryl-CoA dehydrogenase (IVD) gene mutations and genotype–phenotype correlations in Turkish patients. Accordingly, bi-directional sequencing was performed to screen 26 patients with isovaleric acidemia (IVA). Nine novels (c.145delC, c.234 + 3G > C, c.506_507insT, p.Glu85Gln, p.Met147Val, p.Ala268Val, p.Ile287Met, p.Gly346Asp and p.Arg382Trp) and six previously reported (c.456 + 2T > C, p.Arg21His, p.Arg21Pro, p.Arg363Cys, p.Arg363His p.Glu379Lys) pathogenic mutations were identified. Pathogenicity of the novel mutations was supported using computational programs. No clear genotype–phenotype correlation could be determined. One of the cases with the novel c.234 + 3G > C mutation has portoseptal liver fibrosis, the clinical condition that was first reported for IVA. This study is the first comprehensive report from Turkey related to IVA genetics that provides information about the high number of disease-causing novel mutations.     

RNASEH2C c.194G>A is a Chinese-specific founder mutation in three unrelated patients with Aicardi-Goutières syndrome 3

Biallelic pathogenic variants in RNASEH2C cause Aicardi-Goutières syndrome 3 (AGS3, MIM #610329), a rare early-onset encephalopathy characterized by intermittent unexplained fever, chilblains, irritability, progressive microcephaly, dystonia, spasticity, severe psychomotor retardation and abnormal brain imaging. Currently, approximately 50 individuals with AGS3 and 19 variants in RNASEH2C have been revealed. Here, we reported the novel clinical manifestations and genotypic information of three unrelated Chinese patients with AGS3 caused by pathogenic variants in RNASEH2C. In addition to three novel missense variants (c.101G>A, p.Cys34Tyr; c.401T>A, p.Leu134Gln and c.434G>T, p.Arg145Leu), one missense variant (c.194G>A, p.Gly65Asp) reoccurred in all patients but was completely absent in South Asian and other ethnicities. Our study expanded the variant spectrum of RNASEH2C and identified RNASEH2C c.194G>A as a Chinese-specific founder mutation. The novel phenotypes, including mouth ulcers, hip dysplasia, retarded dentition and hypogonadism, observed in our patients greatly enriched the clinical characteristics of AGS3.     

Novel phenotype of achondroplasia due to biallelic FGFR3 pathogenic variants

Pathogenic variants in the fibroblast growth factor receptor 3 (FGFR3) gene are responsible for a broad spectrum of skeletal dysplasias, including achondroplasia (ACH). The classic phenotype of ACH is caused by two highly prevalent mutations, c.1138G > A and c.1138G > C (p.Gly380Arg). In the homozygous state, these variant results in a severe skeletal dysplasia, neurologic deficits, and early demise from respiratory insufficiency. Although homozygous biallelic mutations have been reported in patients with ACH in combination with hypochondroplasia or other dominant skeletal dysplasias, thus far, no cases of heterozygous biallelic pathogenic ACH‐related variants in FGFR3 have been reported. We describe a novel phenotype of an infant with two ACH‐related mutations in FGFR3, p.Gly380Arg and p.Ser344Cys. Discordant features from classic ACH include atypical radiographic findings, severe obstructive sleep apnea, and focal, migrating seizures. We also report the long‐term clinical course of her father, who harbors the p.Ser344Cys mutation that has only been reported once previously in a Japanese patient. The phenotype of heterozygous biallelic mutations in FGFR3 associated with ACH is variable, underscoring the importance of recognition and accurate diagnosis to ensure appropriate management.     

Transport, enzymatic activity, and stability of mutant sulfamidase (SGSH) identified in patients with mucopolysaccharidosis type III A

Mucopolysaccharidosis type IIIA (MPSIIIA) is an autosomal recessive lysosomal storage disease caused by mutations in the N-sulfoglucosamine sulfohydrolase gene (SGSH; encoding sulfamidase, also sulphamidase) leading to the lysosomal accumulation and urinary excretion of heparan sulfate. Considerable variation in the onset and severity of the clinical phenotype is observed. We report here on expression studies of four novel mutations: c.318C>A (p.Ser106Arg), c.488T>C (p.Leu163Pro), c.571G>A (p.Gly191Arg), and c.1207_1209delTAC (p.Tyr403del), and five previously known mutations: c.220C>T (p.Arg74Cys), c.697C>T (p.Arg233X), c.1297C>T (p.Arg433Trp), c.1026dupC (p.Leu343fsX158), and c.1135delG (p.Val379fsX33) identified in MPSIIIA patients. Transient expression of mutant sulfamidases in BHK or CHO cells revealed that all the mutants were enzymatically inactive with the exception of c.318C>A (p.Ser106Arg), which showed 3.3% activity of the expressed wild-type enzyme. Western blot analysis demonstrated that the amounts of expressed mutant sulfamidases were significantly reduced compared with cells expressing wild type. No polypeptides were immunodetectable in extracts of cells transfected with the cDNA carrying the c.697C>T (p.Arg233X) nonsense mutation. In vitro translation and pulse-chase experiments showed that rapid degradation rather than a decrease in synthesis is responsible for the low, steady-state level of the mutant proteins in cells. The amounts of secreted mutant precursor forms, the cellular stability, the proteolytic processing, and data from double-label immunofluorescence microscopy suggest that the degradation of the majority of newly synthesized c.220C>T (p.Arg74Cys), c.571G>A (p.Gly191Arg), c.1297C>T (p.Arg433Trp), c.1026dupC (p.Leu343fsX158), and c.1135delG (p.Val379fsX33) mutant proteins probably occurs in the ER, whereas c.488T>C (p.Leu163Pro) mutant protein showed instability in the lysosomes.     

Identification and functional analysis of novel variants of the human melanocortin 1 receptor found in melanoma patients

The melanocortin 1 receptor, a Gs protein‐coupled receptor expressed in epidermal melanocytes, is a major determinant of skin pigmentation and phototype and an important contributor to melanoma risk. MC1R activation stimulates synthesis of black, strongly photoprotective eumelanin pigments. Several MC1R alleles are associated with red hair, fair skin, increased sensitivity to ultraviolet radiation, and increased skin cancer risk. The MC1R gene is highly polymorphic, but only a few naturally occurring alleles have been functionally characterized, which complicates the establishment of accurate correlations between the signaling properties of mutant alleles and defined cutaneous phenotypes. We report the functional characterization of six MC1R alleles found in Spanish melanoma patients. Two variants (c.152T>C, p.Val51Ala and c.865T>C, p.Cys289Arg) have never been described, and the others (c.112G>A, p.Val38Met; c.122C>T, p.Ser41Phe; c.383T>C, p.Met128Thr; and c.842A>G, p.Asn281Ser) have not been analyzed for function. p.Asn281Ser corresponds to a functionally silent polymorphism. The other mutations are associated with varying degrees of loss of function (LOF), from moderate decreases in coupling to the cAMP pathway (p.Val38Met and p.Val51Ala) to nearly complete absence of functional coupling (p.Ser41Phe, p.Met128Thr, and p.Cys289Arg). The LOF p.Met128Thr and p.Cys289Arg mutants are trafficked to the cell surface, but are unable to bind agonists efficiently. Conversely, LOF of p.Val38Met, p.Ser41Phe, and p.Val51Ala is due to reduced cell surface expression as a consequence of retention in the endoplasmic reticulum (ER). Therefore, LOF of MC1R alleles is frequently associated with aberrant forward trafficking and accumulation within the ER or with inability to bind properly the activatory ligand. Hum Mutat 30:1–12, 2009. © 2009 Wiley‐Liss, Inc.     

Novel B3GALTL mutations in classic Peters plus syndrome and lack of mutations in a large cohort of patients with similar phenotypes

Peters plus syndrome (PPS) is a rare autosomal‐recessive disorder characterized by Peters anomaly of the eye, short stature, brachydactyly, dysmorphic facial features, developmental delay, and variable other systemic abnormalities. In this report, we describe screening of 64 patients affected with PPS, isolated Peters anomaly and PPS‐like phenotypes. Mutations in the coding region of B3GALTL were identified in nine patients; six had a documented phenotype of classic PPS and the remaining three had a clinical diagnosis of PPS with incomplete clinical documentation. A total of nine different pathogenic alleles were identified. Five alleles are novel including one frameshift, c.168dupA, p.(Gly57Argfs*11), one nonsense, c.1234C>T, p.(Arg412*), two missense, c.1045G>A, p.(Asp349Asn) and c.1181G>A, p.(Gly394Glu), and one splicing, c.347+5G>T, mutations. Consistent with previous reports, the c.660+1G>A mutation was the most common mutation identified, seen in eight of the nine patients and accounting for 55% of pathogenic alleles in this study and 69% of all reported pathogenic alleles; while two patients were homozygous for this mutation, the majority had a second rare pathogenic allele. We also report the absence of B3GALTL mutations in 55 cases of PPS‐like phenotypes or isolated Peters anomaly, further establishing the strong association of B3GALTL mutations with classic PPS only.     

Ex vivo splicing assays of mutations at noncanonical positions of splice sites in USHER genes

Molecular diagnosis in Usher syndrome type 1 and 2 patients led to the identification of 21 sequence variations located in noncanonical positions of splice sites in MYO7A, CDH23, USH1C, and USH2A genes. To establish experimentally the splicing pattern of these substitutions, whose impact on splicing is not always predictable by available softwares, ex vivo splicing assays were performed. The branch‐point mapping strategy was also used to investigate further a putative branch‐point mutation in USH2A intron 43. Aberrant splicing was demonstrated for 16 of the 21 (76.2%) tested sequence variations. The mutations resulted more frequently in activation of a nearby cryptic splice site or use of a de novo splice site than exon skipping (37.5%). This study allowed the reclassification as splicing mutations of one silent (c.7872G>A (p.Glu2624Glu) in CDH23) and four missense mutations (c.2993G>A (p.Arg998Lys) in USH2A, c.592G>A (p.Ala198Thr), c.3503G>C [p.Arg1168Pro], c.5944G>A (p.Gly1982Arg) in MYO7A), whereas it provided clues about a role in structure/function in four other cases: c.802G>A (p.Gly268Arg), c.653T>A (p.Val218Glu) (USH2A), and c.397C>T (p.His133Tyr), c.3502C>T (p.Arg1168Trp) (MYO7A). Our data provide insights into the contribution of splicing mutations in Usher genes and illustrate the need to define accurately their splicing outcome for diagnostic purposes. Hum Mutat 31:1–9, 2010. © 2010 Wiley‐Liss, Inc.     

Distinct impacts of bi‐allelic WNT10A mutations on the permanent and primary dentitions in odonto‐onycho‐dermal dysplasia

Odonto‐onycho‐dermal dysplasia (OODD) is a rare autosomal recessive syndrome characterized by multiple ectodermal abnormalities. Mutations of the wingless‐type MMTV integration site family member 10A (WNT10A) gene have been associated with OODD. To date, only 11 OODD‐associated WNT10A mutations have been reported. In this report, we Characterized the clinical manifestations with focusing on dental phenotypes in four unrelated OODD patients. By Sanger sequencing, we identified five novel mutations in the WNT10A gene, including two homozygous nonsense mutations c.1176C>A (p.Cys392*) and c.742C>T (p.Arg248*), one homozygous frame‐shift mutation c.898‐899delAT (p.Ile300Profs*126), and a compound heterozygous mutation c.826T>A (p.Cys276Ser) and c.949delG (p.Ala317Hisfs*121). Our findings confirmed that bi‐allelic mutations of WNT10A were responsible for OODD and greatly expanded the mutation spectrum of OODD. For the first time, we demonstrated that bi‐allelic WNT10A mutations could lead to anodontia of permanent teeth, which enhanced the phenotypic spectrum of WNT10A mutations. Interestingly, we found that bi‐allelic mutations in the WNT10A gene preferentially affect the permanent dentition rather the primary dentition, suggesting that the molecular mechanisms regulated by WNT10A in the development of permanent teeth and deciduous teeth might be different.     

Identification of ten novel mutations in patients with eIF2B-related disorders

Autosomal recessive inherited mutations in each of the five eukaryotic initiation factor 2B (eIF2B) subunits are known to cause white matter abnormalities with a wide continuum of clinical signs and severity leading to the concept of eIF2B-related disorders. The clinical spectrum extends from fatal infantile forms to adult forms with slow or absent neurological deterioration. In this study 15 well-characterised patients with the classical form of leukoencephalopathy with vanishing white matter (VWM) or with phenotypic variants like ovarioleukodystrophy were investigated for mutations in the genes EIF2B1, EIF2B2, EIF2B3, EIF2B4, and EIF2B5 encoding eIF2B. We identified one novel nonsense mutation (EIF2B4, c.625C>T, p.Arg209X), one novel frameshift mutation (EIF2B5, c.453_454del, p.Tyr152fsX12), eight novel missense muations (EIF2B1, c.547G>T, p.Val183Phe; EIF2B2, c. 586C>T, p.Pro196Ser; EIF2B4, c.806T>G, p.Leu269Arg; EIF2B5, c.203T>C, p.Leu68Ser; EIF2B5, c.220G>A, p.Ala74Thr; EIF2B5, c.805C>G, p.Arg269Gly; EIF2B5, c.929G>T, p.Cys310Phe; EIF2B5, c.1003T>C, p.Cys335Arg), and eight previously described alterations.     

Identification and functional characterization of two missense mutations in NDRG1 associated with Charcot‐Marie‐Tooth disease type 4D

Charcot‐Marie‐Tooth disease type 4D (CMT4D) is an autosomal‐recessive demyelinating form of CMT characterized by a severe distal motor and sensory neuropathy. NDRG1 is the causative gene for CMT4D. To date, only four mutations in NDRG1 —c.442C>T (p.Arg148*), c.739delC (p.His247Thrfs*74), c.538‐1G>A, and duplication of exons 6–8—have been described in CMT4D patients. Here, using targeted next‐generation sequencing examination, we identified for the first time two homozygous missense variants in NDRG1, c.437T>C (p.Leu146Pro) and c.701G>A (p.Arg234Gln), in two Chinese CMT families with consanguineous histories. Further functional studies were performed to characterize the biological effects of these variants. Cell culture transfection studies showed that mutant NDRG1 carrying p.Leu146Pro, p.Arg148*, or p.Arg234Gln variant degraded faster than wild‐type NDRG1, resulting in lower protein levels. Live cell confocal microscopy and coimmunoprecipitation analysis indicated that these variants did not disrupt the interaction between NDRG1 and Rab4a protein. However, NDRG1‐knockdown cells expressing mutant NDRG1 displayed enlarged Rab4a‐positive compartments. Moreover, mutant NDRG1 could not enhance the uptake of DiI‐LDL or increase the fraction of low‐density lipoprotein receptor on the cell surface. Taken together, our study described two missense mutations in NDRG1 and emphasized the important role of NDRG1 in intracellular protein trafficking.     

Genetic causes of monogenic familial hypercholesterolemia in the Greek population: Lessons,mistakes, and the way forward

Familial hypercholesterolemia (FH) is a leading cause of premature atherosclerosis. Genetic defects in the LDLR, APOB and PCSK9 genes cause FH, and confirmation of a gene defect is essential for an indisputable diagnosis of the disease. FH is underdiagnosed and we aimed to revise the genetic defects that have been characterized in FH patients of Greek origin and define an effective, future strategy for genetic studies. A literature search was performed in MEDLINE and EMBASE on genetic studies with FH patients of Greek origin. To date, no APOB and PCSK9 mutations have been found in the Greek population. It must be noted however, that only a small number of patients has been screened for PCSK9 mutations. In total, 41 LDLR defects have been characterized, with 6 common mutations c.1646G>A (p.Gly546Asp), c.858C>A (p.Ser286Arg), c.81C>G (p.Cys27Trp), c.1285G>A (p.Val429Met), c.517T>C (p.Cys173Arg), and c.1775G>A (p.Gly592Glu) that account for >80% of all mutations. Due to geographic isolation, ​founder mutations exist in a subpopulation in North West Greece and the Greek Cypriot population but not in the general population. Genetic testing should focus primarily on LDLR, and subsequently on PCSK9 and APOB. The Greek population is genetically homogeneous, which allows for a quick molecular diagnosis of the disease. Cascade screening is feasible and will certainly facilitate the identification of additional patients.     

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. © 2012 Wiley Periodicals, Inc.