一例Rotor综合征患儿的基因变异分析

目的探讨1例Rotor综合征患儿的遗传学病因。方法收集患儿的临床资料,应用高通量测序技术对患者行全外显子组测序并进行Sanger测序验证。用单管三引物PCR分析法检测SLCO1B3基因第5内含子长散布元件-1(long-interspersed element-1,LINE-1)的插入情况。结果高通量全外显子组测序发现患儿携带SLCO1B1基因c.1738C>T纯合无义变异。SLCO1B3基因第5内含子中LINE-1的纯合插入,导致第5外显子或第5~7外显子跳跃,并在SLCO1B3转录本中引入了终止密码子。结论SLCO1B1基因c.1738C>T纯合变异以及SLCO1B3基因第5内含子LINE-1的纯合插入可能是该Rotor综合征患儿的致病原因。     

Down-regulation of OATP1B proteins correlates with hyperbilirubinemia in advanced cholestasis

Aim: Organic anion-transporting polypeptides OATP1B1 and OATP1B3 are sinusoidal membrane transporters mediating liver uptake of a wide range of substrates including conjugated and unconjugated bilirubin, xenobiotics and drugs. Absence of OATP1Bs in the liver causes Rotor syndrome. Our aim was to correlate OATP1B expression with hyperbilirubinemia in common liver diseases. Methods: Immunoreactivity of five antibodies against human OATP1Bs was tested on frozen and formalin-fixed paraffin-embedded liver tissue of mouse strains transgenic for SLCO1B1 or SLCO1B3 and on human specimens. The proportion of hepatocytes expressing OATP1Bs was then assessed immunohistologically in formalin-fixed paraffin-embedded liver samples obtained from patients with hepatocellular and primary biliary liver diseases. UGT1A1 promoter TATA-box and SLCO1B1 rs4149056 genotyping was performed to rule out individuals predisposed to hyperbilirubinemia. Results: The most specific detection of OATP1B3 was achieved with the H-52 (sc-98981) antibody. OATP1B1 was specifically recognized with the ESL (ab15441) anti-OATP1B1 antibody, but only in frozen sections. The MDQ (ab15442) anti-OATP1B1 antibody cross-reacted with both OATP1B proteins in liver tissue of the transgenic mouse strains. Expression of the OATP1B proteins was decreased in advanced liver diseases and inversely correlated with serum bilirubin levels. The reduction was more pronounced in advanced primary biliary diseases (1.9±1.1 vs. 2.7±0.6; P=0.009). Conclusions: Down-regulation of OATP1B proteins may contribute to pathogenesis of jaundice accompanying advanced cholestatic liver diseases.     

Autosomal recessive otofaciocervical syndrome type 2 with novel homozygous small insertion in PAX1 gene

Otofaciocervical syndrome (OTFCS) is described as a single gene disorder of both autosomal dominant and autosomal recessive inheritance. The major clinical features of OTFCS include ear malformations (external/middle/inner ear), facial dysmorphism, shoulder girdle abnormalities, vertebral anomalies, and mild intellectual disability. The autosomal recessive form of OTFCS syndrome (OTFCS2) has been recently reported to be caused due to homozygous mutations in PAX1 gene. Here we report a third family of OTFCS2 phenotype wherein whole exome sequencing identified a novel homozygous small insertion in PAX1 as the underlying genetic cause.     

Whole exome sequencing unravels disease‐causing genes in consanguineous families in Qatar

Whole exome sequencing (WES) has greatly facilitated the identification of causal mutations for diverse human genetic disorders. We applied WES as a molecular diagnostic tool to identify disease‐causing genes in consanguineous families in Qatar. Seventeen consanguineous families with diverse disorders were recruited. Initial mutation screening of known genes related to the clinical diagnoses did not reveal the causative mutations. Using WES approach, we identified the definitive disease‐causing mutations in four families: (i) a novel nonsense homozygous (c.1034C>G) in PHKG2 causing glycogen storage disease type 9C (GSD9C) in a male with initial diagnosis of GSD3; (ii) a novel homozygous 1‐bp deletion (c.915del) in NSUN2 in a male proband with Noonan‐like syndrome; (iii) a homozygous SNV (c.1598C>G) in exon 11 of IDUA causing Hurler syndrome in a female proband with unknown clinical diagnosis; (iv) a de novo known splicing mutation (c.1645+1G>A) in PHEX in a female proband with initial diagnosis of autosomal recessive hypophosphatemic rickets. Applying WES as a diagnostic tool led to the unambiguous identification of disease‐causing mutations in phenotypically complex disorders or correction of the initial clinical diagnosis in ?25% of our cases.     

Biallelic loss‐of‐function WNT5A mutations in an infant with severe and atypical manifestations of Robinow syndrome

Robinow syndrome (RS) is a well‐recognized Mendelian disorder known to demonstrate both autosomal dominant and autosomal recessive inheritance. Typical manifestations include short stature, characteristic facies, and skeletal anomalies. Recessive inheritance has been associated with mutations in ROR2 while dominant inheritance has been observed for mutations in WNT5A, DVL1, and DVL3. Through trio whole genome sequencing, we identified a homozygous frameshifting single nucleotide deletion in WNT5A in a previously reported, deceased infant with a unique constellation of features comprising a 46,XY disorder of sex development with multiple congenital malformations including congenital diaphragmatic hernia, ambiguous genitalia, dysmorphic facies, shortened long bones, adactyly, and ventricular septal defect. The parents, who are both heterozygous for the deletion, appear clinically unaffected. In conjunction with published observations of Wnt5a double knockout mice, we provide evidence for the possibility of autosomal recessive inheritance in association with WNT5A loss‐of‐function mutations in RS.     

Bi‐allelic mutations of CCDC88C are a rare cause of severe congenital hydrocephalus

Congenital or infantile hydrocephalus is caused by genetic and non‐genetic factors and is highly heterogeneous in etiology. In recent studies, a limited number of genetic causes of hydrocephalus have been identified. To date, recessive mutations in the CCDC88C gene have been identified as a cause of non‐syndromic congenital hydrocephalus in three reported families. Here, we report the fourth known family with two affected individuals with congenital hydrocephalus due to a homozygous mutation in the CCDC88C gene identified by whole exome sequencing. Our two newly described children, as well as the previously published ones, all shared several features including severe infantile‐onset hydrocephalus, mild to severe intellectual delay, varying degrees of motor delay, and infantile onset seizures. All identified homozygous mutations in CCDC88C abolish the PDZ binding site necessary for proper CCDC88C protein function in the Wnt signaling pathway. Our report further establishes CCDC88C as one of the few known recessive causes of severe prenatal‐onset hydrocephalus. Recognition of this syndrome has important diagnostic and genetic implications for families identified in the future.

     

Organic anion transporting polypeptides OATP1B1 and OATP1B3 and their genetic variants influence the pharmacokinetics and pharmacodynamics of raloxifene

ABSTRACT: BACKGROUND: Raloxifene, a selective estrogen receptor modulator, exhibits quite large and unexplained interindividual variability in pharmacokinetics and pharmacodynamics. The aim of this study was to determine the role of organic-anion transporting polypeptides OATP1B1 and OATP1B3 and their genetic variants in the pharmacokinetics and pharmacodynamics of raloxifene. METHODS: To test the role of OATP1B1 and OATP1B3 transporters on hepatic uptake of raloxifene and its metabolites an in vitro model of Chinese Hamster Ovary cells expressing OATP1B1 or OATP1B3 was employed. The influence of OATP1B1 and OATP1B3 genetic variants on in vivo pharmacokinetics and pharmacodynamics was evaluated in 53 osteoporotic postmenopausal women treated with raloxifene. RESULTS: Our in vitro results showed that raloxifene and two of the three metabolites, raloxifene-4'-beta- glucuronide (M2) and raloxifene-6,4'-diglucuronide (M3), interact with OATP1B1 and OATP1B3. Higher M3 and total raloxifene serum concentrations in patients correlated with lower serum levels of bone resorption marker, serum C-terminal telopeptide fragments of type I collagen, indicating a higher antiresorptive effect of raloxifene. Higher concentrations of M2 correlated with higher increase of lumbar spine bone mineral density supporting the raloxifene vertebral fracture specific protection effect. Finally, raloxifene, M3 and total raloxifene serum concentrations were significantly higher in patients with SLCO1B1 c.388A > G polymorphism and *1b haplotype implicating a considerable genetic effect on pharmacokinetics and pharmacodynamics of raloxifene. CONCLUSIONS: These findings indicate that SLCO1B1 c.388A > G polymorphism could play an important role in pharmacokinetics and pharmacodynamics of raloxifene.     

A novel homozygous AP4B1 mutation in two brothers with AP‐4 deficiency syndrome and ocular anomalies

Adaptor protein complex‐4 (AP‐4) is a heterotetrameric protein complex which plays a key role in vesicle trafficking in neurons. Mutations in genes affecting different subunits of AP‐4, including AP4B1, AP4E1, AP4S1, and AP4M1, have been recently associated with an autosomal recessive phenotype, consisting of spastic tetraplegia, and intellectual disability (ID). The overlapping clinical picture among individuals carrying mutations in any of these genes has prompted the terms “AP‐4 deficiency syndrome” for this clinically recognizable phenotype. Using whole‐exome sequencing, we identified a novel homozygous mutation (c.991C>T, p.Q331*, NM_006594.4) in AP4B1 in two siblings from a consanguineous Pakistani couple, who presented with severe ID, progressive spastic tetraplegia, epilepsy, and microcephaly. Sanger sequencing confirmed the mutation was homozygous in the siblings and heterozygous in the parents. Similar to previously reported individuals with AP4B1 mutations, brain MRI revealed ventriculomegaly and white matter loss. Interestingly, in addition to the typical facial gestalt reported in other AP‐4 deficiency cases, the older brother presented with congenital left Horner syndrome, bilateral optic nerve atrophy and cataract, which have not been previously reported in this condition. In summary, we report a novel AP4B1 homozygous mutation in two siblings and review the phenotype of AP‐4 deficiency, speculating on a possible role of AP‐4 complex in eye development.

     

A loss of function mutation in the COL9A2 gene causes autosomal recessive Stickler syndrome

Stickler syndrome is characterized by ocular, auditory, skeletal, and orofacial abnormalities. We describe a family with autosomal recessive Stickler syndrome. The main clinical findings consisted of high myopia, vitreoretinal degeneration, retinal detachment, hearing loss, and short stature. Affected family members were found to have a homozygous loss‐of‐function mutation in COL9A2, c.843_c.846 + 4del8. A family with autosomal recessive Stickler syndrome was previously described and found to have a homozygous loss‐of‐function mutation in COL9A1. COL9A1, COL9A2, and COL9A3 code for collagen IX. All three collagen IX α chains, α1, α2, and α3, are needed for formation of functional collagen IX molecule. In dogs, two causative loci have been identified in autosomal recessive oculoskeletal dysplasia. This dysplasia resembles Stickler syndrome. Recently, homozygous loss‐of‐function mutations in COL9A2 and COL9A3 were found to co‐segregate with the loci. Together the data from the present study and the previous studies suggest that loss‐of‐function mutations in any of the collagen IX genes can cause autosomal recessive Stickler syndrome. © 2011 Wiley‐Liss, Inc.     

Homozygous loss‐of‐function mutation of the LEPREL1 gene causes severe non‐syndromic high myopia with early‐onset cataract

High myopia is a severe visual impairment which can increase the risk of retinal degeneration, subretinal hemorrhage, choroidal neovascularization, cataract and retinal detachment. We recruited an autosomal‐recessive high myopia family, with affected subjects who also present early‐onset cataract, retinal degeneration and other complications. Using targeted capturing and whole exome sequencing, we identified a homozygous non‐sense mutation in the LEPREL1 gene which causes premature termination of the translation at the fifth amino acid (c.13C>T; p.Q5X), co‐segregating with the phenotypes. LEPREL1 encodes a proline hydroxylase called prolyl 3‐hydroxylase 2 (P3H2), a 2‐oxoglutarate‐dependent dioxygenase that hydroxylates collagens. The results show that LEPREL1 plays an important role in eye development and homozygous loss‐of‐function mutation of this gene can cause severely high myopia and early‐onset cataract. Our study also strongly suggests that the disruption of collagen modification is one of the pathogenic mechanisms of high myopia and cataract.     

Smith‐Lemli‐Opitz (RHS) syndrome: holoprosencephaly and homozygous IVS8‐1G→C genotype

Smith‐Lemli‐Opitz syndrome (RHS) (SLOS, OMIM 270400) is an autosomal recessive disorder of cholesterol biosynthesis caused by mutations of the 3β‐hydroxysterol Δ⁷‐Δ⁸‐reductase gene, DHCR7. We report a fetus with holoprosencephaly and multiple congenital anomalies who was homozygous for the IVS8‐1G→C mutation. Following termination of pregnancy, both the elevated amniotic fluid 7‐dehydrocholesterol level and the DHCR7 mutations were demonstrated. Two other newborn infants with IVS8‐1G→C/IVS8‐1G→C genotype are described. This report illustrates a severe phenotypic extreme of SLOS associated with a null genotype, underscores the complex relationship between SLOS and holoprosencephaly, and discusses the possible pathogenetic mechanisms of the development of holoprosencephaly in SLOS. © 2001 Wiley‐Liss, Inc.     

Mutations in TAX1BP3 Cause Dilated Cardiomyopathy with Septo‐Optic Dysplasia

We describe a Bedouin family with a novel autosomal recessive syndrome characterized by dilated cardiomyopathy and septo‐optic dysplasia. Genetic analysis revealed a homozygous missense mutation in TAX1BP3, which encodes a small PDZ domain containing protein implicated in regulation of the Wnt/β‐catenin signaling pathway, as the causative mutation. The mutation affects a conserved residue located at the core of TAX1BP3 binding pocket and is predicted to impair the nature of a crucial hydrophobic patch, thereby interrupting the structure and stability of the protein, and its ability to interact with other proteins. TAX1BP3 is highly expressed in heart and brain and consistent with the clinical findings observed in our patients; a knockdown of TAX1BP3 causes elongation defects, enlarged pericard, and enlarged head structures in zebrafish embryos. Thus, we describe a new genetic disorder that expands the monogenic cardiomyopathy disease spectrum and suggests that TAX1BP3 is essential for heart and brain development.     

Spondyloepimetaphyseal dysplasia with joint laxity (Beighton type); mutation analysis in eight affected South African families

Spondyloepimetaphyseal dysplasia with joint laxity (SEMD‐JL), type 1 is an autosomal recessive disorder which has been identified in more than 30 affected children in the Afrikaans‐speaking community of South Africa. Sequencing of B3GALT6 revealed a specific mutation, c.235A > G, in homozygous form in four families, while three others were compound heterozygotes for this mutation in combination with the c.200C > T mutation. In addition, a proband from one family carried the c.16C > T mutation combined with c.200C > T. In a series of five Iranian persons, mutations in B3GALT6 have been implicated in a syndrome characterised by skeletal abnormalities with intellectual disability, bone and connective tissue fragility. Other mutations in B3GALT6 resulted in the classical SEMD‐JL phenotype in seven Japanese families and in a syndrome which has been likened to a progeroid form of Ehlers–Danlos syndrome (EDS). It is evident that there is considerable intragenic heterogeneity in B3GALT6. One of the mutations, c.200C > T, in the affected South Africans was also present in one of the Japanese persons and the respective phenotypes were identical. The multiplicity of allelic mutations and the phenotypic differences in the affected persons supports the concept that a spectrum of connective tissue disorders is programmed by mutations in B3GALT6.     

Stüve–Wiedemann syndrome: long‐term follow‐up and genetic heterogeneity

Jung C, Dagoneau N, Baujat G, Le Merrer M, David A, Di Rocco M, Hamel B, Mégarbané A, Superti‐Furga A, Unger A, Munnich A, Cormier‐Daire V. Stüve–Wiedemann syndrome: long‐term follow‐up and genetic heterogeneity. Stüve–Wiedemann syndrome (SWS, OMIM 601559) is a severe autosomal recessive condition caused by mutations in the leukemia inhibitory receptor (LIFR) gene. The main characteristic features are bowing of the long bones, neonatal respiratory distress, swallowing/sucking difficulties and dysautonomia symptoms including temperature instability often leading to death in the first years of life. We report here four patients with SWS who have survived beyond 36 months of age with no LIFR mutation. These patients have been compared with six unreported SWS survivors carrying null LIFR mutations. We provide evidence of clinical homogeneity of the syndrome in spite of the genetic heterogeneity.     

Hidden Genetic Variation in LCA9‐Associated Congenital Blindness Explained by 5′UTR Mutations and Copy‐Number Variations of NMNAT1

Leber congenital amaurosis (LCA) is a severe autosomal‐recessive retinal dystrophy leading to congenital blindness. A recently identified LCA gene is NMNAT1, located in the LCA9 locus. Although most mutations in blindness genes are coding variations, there is accumulating evidence for hidden noncoding defects or structural variations (SVs). The starting point of this study was an LCA9‐associated consanguineous family in which no coding mutations were found in the LCA9 region. Exploring the untranslated regions of NMNAT1 revealed a novel homozygous 5′UTR variant, c.‐70A>T. Moreover, an adjacent 5′UTR variant, c.‐69C>T, was identified in a second consanguineous family displaying a similar phenotype. Both 5′UTR variants resulted in decreased NMNAT1 mRNA abundance in patients’ lymphocytes, and caused decreased luciferase activity in human retinal pigment epithelial RPE‐1 cells. Second, we unraveled pseudohomozygosity of a coding NMNAT1 mutation in two unrelated LCA patients by the identification of two distinct heterozygous partial NMNAT1 deletions. Molecular characterization of the breakpoint junctions revealed a complex Alu‐rich genomic architecture. Our study uncovered hidden genetic variation in NMNAT1‐associated LCA and emphasized a shift from coding to noncoding regulatory mutations and repeat‐mediated SVs in the molecular pathogenesis of heterogeneous recessive disorders such as hereditary blindness.     

Comprehensive genetic testing with ethnic‐specific filtering by allele frequency in a Japanese hearing‐loss population

Recent advances in targeted genomic enrichment with massively parallel sequencing (TGE+MPS) have made comprehensive genetic testing for non‐syndromic hearing loss (NSHL) possible. After excluding NSHL subjects with causative mutations in GJB2 and the MT‐RNR1 (1555A>G) variant by Sanger sequencing, we completed TGE+MPS on 194 probands with presumed NSHL identified across Japan. We used both publicly available minor allele frequency (MAF) datasets and ethnic‐specific MAF filtering against an in‐house database of 200 normal‐hearing Japanese controls. Ethnic‐specific MAF filtering allowed us to re‐categorize as common 203 variants otherwise annotated as rare or novel in non‐Japanese ethnicities. This step minimizes false‐positive results and improves the annotation of identified variants. Causative variants were identified in 27% of probands with solve rates of 35%, 35% and 19% for dominant, recessive and sporadic NSHL, respectively. Mutations in MYO15A and CDH23 follow GJB2 as the frequent causes of recessive NSHL; copy number variations in STRC are a major cause of mild‐to‐moderate NSHL. Ethnic‐specific filtering by allele frequency is essential to optimize the interpretation of genetic data.     

Loss‐of‐function of Endothelin receptor type A results in Oro‐Oto‐Cardiac syndrome

Craniofacial morphogenesis is regulated in part by signaling from the Endothelin receptor type A (EDNRA). Pathogenic variants in EDNRA signaling pathway components EDNRA, GNAI3, PCLB4, and EDN1 cause Mandibulofacial Dysostosis with Alopecia (MFDA), Auriculocondylar syndrome (ARCND) 1, 2, and 3, respectively. However, cardiovascular development is normal in MFDA and ARCND individuals, unlike Ednra knockout mice. One explanation may be that partial EDNRA signaling remains in MFDA and ARCND, as mice with reduced, but not absent, EDNRA signaling also lack a cardiovascular phenotype. Here we report an individual with craniofacial and cardiovascular malformations mimicking the Ednra ^?/? mouse phenotype, including a distinctive micrognathia with microstomia and a hypoplastic aortic arch. Exome sequencing found a novel homozygous missense variant in EDNRA (c.1142A>C; p.Q381P). Bioluminescence resonance energy transfer assays revealed that this amino acid substitution in helix 8 of EDNRA prevents recruitment of G proteins to the receptor, abrogating subsequent receptor activation by its ligand, Endothelin‐1. This homozygous variant is thus the first reported loss‐of‐function EDNRA allele, resulting in a syndrome we have named Oro‐Oto‐Cardiac Syndrome. Further, our results illustrate that EDNRA signaling is required for both normal human craniofacial and cardiovascular development, and that limited EDNRA signaling is likely retained in ARCND and MFDA individuals. This work illustrates a straightforward approach to identifying the functional consequence of novel genetic variants in signaling molecules associated with malformation syndromes.     

Gene alterations involving the CRLF2‐JAK pathway and recurrent gene deletions in Down syndrome‐associated acute lymphoblastic leukemia in Japan

In Western countries, gene alterations involving the CRLF2‐JAK signaling pathway are identified in approximately 50–60% of patients with Down syndrome‐associated acute lymphoblastic leukemia (DS‐ALL), and this pathway is considered a potential therapeutic target. The frequency of BTG1 deletions in DS‐ALL is controversial. IKZF1 deletions, found in 20–30% of DS‐ALL patients, are associated with a poor outcome and EBF1 deletions are very rare (～2%). We analyzed 38 patients to determine the frequencies and clinical implications of CRLF2‐JAK pathway genetic alterations and recurrent gene deletions in Japanese DS‐ALL patients. We confirmed a high incidence of P2RY8‐CRLF2 (29%) and JAK2 mutations (16%), though the frequency of P2RY8‐CRLF2 was slightly lower than that in Western countries (～50%). BTG1 deletions were common in our cohort (25%). IKZF1 deletions were detected in 25% of patients and associated with shorter overall survival (OS). EBF1 deletions were found at an unexpectedly high frequency (16%), and at a significantly higher level in P2RY8‐CRLF2‐positive patients than in P2RY8‐CRLF2‐negative patients (44% vs. 4%, P = 0.015). Deletions of CDKN2A/B and PAX5 were common in P2RY8‐CRLF2‐negative patients (48 and 39%, respectively) but not in P2RY8‐CRLF2‐positive patients (11% each). Associations between these genetic alterations and clinical characteristics were not observed except for inferior OS in patients with IKZF1 deletions. These results suggest that differences exist between the genetic profiles of DS‐ALL patients in Japan and in Western countries, and that P2RY8‐CRLF2 and EBF1 deletions may cooperate in leukemogenesis in a subset of Japanese DS‐ALL patients. © 2014 Wiley Periodicals, Inc.     

Deletions in the VPS13B (COH1) gene as a cause of Cohen syndrome

Cohen syndrome is an autosomal recessive disorder that is characterized by mental retardation, facial dysmorphism, microcephaly, retinal dystrophy, truncal obesity, joint laxity and intermittent neutropenia. Mutations in the VPS13B (COH1) gene underlie Cohen syndrome. In approximately 70% of the patients mutations in the gene are identified on both alleles, while in about 30% only a mutation in a single allele or no mutant allele is detected. The VPS13B locus was recently added to the growing list of benign copy number variants. We hypothesized that patients with unexplained Cohen syndrome would harbour deletions affecting the VPS13B locus. We screened 35 patients from 26 families with targeted array CGH and identified 7 copy number alterations: 2 homozygous and 5 heterozygous deletions. Our results show that deletions are an important cause of Cohen syndrome and screening for copy number alterations of VPS13B should be an integral part of the diagnostic work‐up of these patients. These findings have important consequences for the diagnosis of patients with genetic disorders in general since, as we highlight, rare benign copy number variants can underly autosomal recessive disorders and lead to disease in homozygous state or in compound heterozygosity with another mutation. © 2009 Wiley‐Liss, Inc.