13 novel putative mutations in ATP7A found in a cohort of 25 Italian families

ATP7A is a copper-transporting P-type adenosine triphosphatase whose loss of function leads to the Menkes disease, an X-linked copper metabolism multi-organ disorder (1 in 100.000 births). Here we document our experience with the ATP7A linked diseases in Italy. We analyzed the exonic structure of the ATP7A gene in 25 unrelated Italian families and studied the variants of unknown significance. We identified 22 different DNA alterations, 13 of which first reported in this study. The classical Menkes phenotype was present in 21 of the 25 families and was linked with highly damaging mutations (7 nonsense; 4 frame-shift; 2 small in-frame deletions, 2 splice site alterations, 2 gross deletions, and 1 gross duplication). Of the 4 cases with milder variants of the Menkes disease two had a missense mutation, one a leaky splice site alteration and one a nonsense mutation in exon 22. We determined in silico that all the mutations leading to the classical Menkes disease leave no residual activity of ATP7A including the apparently less severe in-frame deletions. Whereas milder forms of the disease are characterized by mutations that allow a limited residual activity of ATP7A, including the nonsense mutation observed.

     

Congenital cataract, muscular hypotonia, developmental delay and sensorineural hearing loss associated with a defect in copper metabolism

Summary Deficiencies of different proteins involved in copper metabolism have been reported to cause human diseases. Well-known syndromes, for example, are Menkes and Wilson diseases. Here we report a patient presenting with congenital cataract, severe muscular hypotonia, developmental delay, sensorineural hearing loss and cytochrome-c oxidase deficiency with repeatedly low copper and ceruloplasmin levels. These findings were suggestive of a copper metabolism disorder. In support of this, the patient’s fibroblasts showed an increased copper uptake with normal retention. Detailed follow-up examinations were performed. Immunoblotting for several proteins including ATP7A (MNK or Menkes protein), ATP7B (Wilson protein) and SOD1 showed normal results, implying a copper metabolism defect other than Wilson or Menkes disease. Sequence analysis of ATOX1 and genes coding for proteins that are known to play a role in the mitochondrial copper metabolism (COI–III, SCO1, SCO2, COX11, COX17, COX19) revealed no mutations. Additional disease genes that have been associated with cytochrome-c oxidase deficiency were negative for mutations as well. As beneficial effects of copper histidinate supplementation have been reported in selected disorders of copper metabolism presenting with low serum copper and ceruloplasmin levels, we initiated a copper histidinate supplementation. Remarkable improvement of clinical symptoms was observed, with complete restoration of cytochrome-c oxidase activity in skeletal muscle.     

A new variant deletion of a copper-transporting P-type ATPase gene found in patients with Wilson's disease presenting with fulminant hepatic failure

A candidate gene (ATP7B) for Wilson's disease, an autosomal recessive disorder of copper transport, has recently been identified. We examined the ATP7B gene in two Japanese sisters with Wilson's disease presenting with fulminant hepatic failure but who did not exhibit Kayser-Fleischer rings or abnormal neurological findings. Genomic DNA was isolated from the whole blood of the patients and their family. Entire exons of ATP7B, and their associated splice junctions, were amplified by polymerase chain reaction. The sequencing of all exons was performed by a non-radioactive sequencing method. The sequencing of exon 12 of ATP7B revealed a 9-bp deletion. The mutation deleted 922Gly, 923Tyr, and 924Phe, and three residues conserved in the Menkes gene, ATP7A, located in the fifth transmembrane region. Of the 14 family members tested, 7 were normal and 7 were heterozygous for the deletion. Mean serum copper and cerulopasmin levels were significantly lower in the family members who were heterozygous for the deletion than in the normal family members, and two heterozygous family members showed abnormally low ceruloplasmin levels; however, there were no differences in mean aspartate aminotransferase or alanine aminotransferase levels between the two groups. Received: February 13, 1999 / Accepted: October 22, 1999     

Menkes protein contributes to the function of peptidylglycine alpha-amidating monooxygenase

Menkes protein (ATP7A) is a P-type ATPase involved in copper uptake and homeostasis. Disturbed copper homeostasis occurs in patients with Menkes disease, an X-linked disorder characterized by mental retardation, neurodegeneration, connective tissue disorders, and early childhood death. Mutations in ATP7A result in malfunction of copper-requiring enzymes, such as tyrosinase and copper/zinc superoxide dismutase. The first step of the two-step amidation reaction carried out by peptidylglycine alpha-amidating monooxygenase (PAM) also requires copper. We used tissue from wild-type rats and mice and an ATP7A-specific antibody to determine that ATP7A is expressed at high levels in tissues expressing high levels of PAM. ATP7A is largely localized to the trans Golgi network in pituitary endocrine cells. The Atp7a mouse, bearing a mutation in the Atp7a gene, is an excellent model system for examining the consequences of ATP7A malfunction. Despite normal levels of PAM protein, levels of several amidated peptides were reduced in pituitary and brain extracts of Atp7a mice, demonstrating that PAM function is compromised when ATP7A is inactive. Based on these results, we conclude that a reduction in the ability of PAM to produce bioactive end-products involved in neuronal growth and development could contribute to many of the biological effects associated with Menkes disease.     

Combined ambulatory electroencephalographic and electrocardiographic recordings for evaluation of syncope

Evaluation of patients with syncope often includes a battery of noninvasive tests. In this study, 45 patients (26 with suspected neurologic and 19 with suspected cardiac syncope) were evaluated with simultaneous 24-hour electroencephalographic (EEG) and 2-channel electrocardiographic (ECG) recordings. Isolated cardiac rhythm abnormalities were noted in 21 patients, but none of these was symptomatic and no definitive arrhythmias occurred. Isolated EEG abnormalities were noted in 11 patients, 5 of whom had EEG abnormalities consistent with seizure disorders. Simultaneous EEG and ECG abnormalities were seen in 4 patients. In 2 cases, a previously unsuspected etiology for syncope was found: seizures in 1 patient with heart disease, and sinus pauses in another thought to have a seizure disorder. Thus, combined ambulatory EEG/ECG monitoring may prove useful in the evaluation of some patients with syncope.     

Potential of the international scoring system for the diagnosis of Wilson disease to differentiate Japanese patients who need anti‐copper treatment

Aim: Patients with Wilson disease show complex clinical features. Accurate diagnosis at the initial clinical manifestation is important for patients to receive effective treatment with anti‐copper agents. In this study, we assessed whether the international scoring system for the diagnosis of Wilson disease is a reliable tool for screening Japanese patients with primary copper toxicosis requiring anti‐copper treatment. Methods: Twenty‐three Japanese patients suspected of Wilson disease were enrolled in this study. We performed long‐range polymerase chain reaction to detect ATP7B mutations in this series. Finally, we retrospectively assessed the reliability of using a diagnostic score of 4 or more points as the cut‐off for this scoring system. Results: Ten patients were homozygous or compound heterozygous for ATP7B mutations including a novel mutation of 3837 bp deletion including 3 exons. The mutation would have been missed by the traditional analysis. Six patients were heterozygous for ATP7B mutations. Three of these six patients had additional diagnostic points. The other three patients were diagnosed as carriers of a mutant gene based on their low scores. One of the seven patients free from ATP7B mutation was affected by copper toxicosis. Though the score was 3 points based on increased urinary copper and copper‐positive cirrhosis, anti‐copper treatment promptly improved liver failure, which was likely due to idiopathic copper toxicosis. Conclusion: The international scoring system for diagnosis of Wilson disease is a fairly reliable tool for screening Japanese patients who need anti‐copper treatment. Caution is needed for patients with possible idiopathic copper toxicosis because the maximal score is 4 points.     

Identification of novel ATP7A mutations and prenatal diagnosis in Chinese patients with Menkes disease

Metabolic Brain Disease - Menkes disease (MD) is a fatal X-linked multisystem disease caused by mutations in ATP7A. In this study, clinical and genetic analysis was performed in 24 male MD...     

Wilson disease: revision of diagnostic criteria in a clinical series with great genetic homogeneity

Background

Wilson disease is an autosomal recessive disorder of copper metabolism caused by mutations in the ATP7B gene. An early diagnosis is crucial to prevent evolution of the disease, as implantation of early therapeutic measures fully prevents its symptoms. As population genetics data predict a higher than initially expected prevalence, it was important to define the basic diagnostic tools to approach population screening.

Methods

A highly genetically homogeneous cohort of 70 patients, belonging to 50 unrelated families, has been selected as a framework to analyze all their clinical, biochemical and genetic characteristics, to define the disease in our population, with an estimated prevalence of 1 in 12,369, and determine the most useful features that reach diagnostic value.

Results

Serum ceruloplasmin below 11.5 mg/dL and cupremia below 60 μg/mL, were the best analytical predictors of the disease in asymptomatic individuals, while cupruria or hepatic copper determination were less powerful. Genetic analysis reached a conclusive diagnosis in all 65 patients available for complete testing. Of them, 48 were carriers of at least one p.Leu708Pro mutant allele, with 24 homozygotes. Nine patients carried a promoter deletion mutation, revealing that extended sequencing beyond the ATP7B gene-coding region is essential. All mutations caused hepatic damage since early ages, increasing its severity as diagnosis was delayed, and neurological symptoms appear.

Conclusion

Serum ceruloplasmin determination followed by genetic screening would reduce costs and favor the prioritization of non-invasive procedures to reach a definitive diagnosis, even for asymptomatic cases.

     

Lentiviral gene transfer ameliorates disease progression in Long-Evans cinnamon rats: An animal model for Wilson disease

Objective. Wilson disease is a copper storage disorder caused by mutations in the ATP7B gene leading to liver cirrhosis. It has previously been shown that lentiviral vectors can govern an efficient delivery and stable expression of a transgene. The aim of this pilot study was to prove the principle of a lentiviral gene transfer in the Long-Evans cinnamon (LEC) rat, an animal model of Wilson disease. Material and methods. LEC rats were treated either by systemic application of lentiviral vectors or by intrasplenic transplantation of LEC-rat hepatocytes lentivirally transduced with ATP7B. The ATP7B gene expression was analyzed by RT-PCR and immunofluorescence analysis. The therapeutic effect was assessed by analysis of liver histology, serum ceruloplasmin oxidase activity, and liver copper content. Results, Hepatic expression of the transgene was detected at different time-points post-treatment and lasted for up to 24 weeks (end of experiment). Liver copper levels were lowered in all treatment groups compared to untreated LEC rats. Twenty-four weeks after treatment, the area of the examined liver-tissue sections occupied by fibrosis was 48.3–57.9% in untreated LEC rats and 10.7–19.8% in rats treated with cell therapy. In systemically treated rats, only small fibrous septa could be observed. Conclusions. These data prove for the first time that lentiviral ATP7B gene transfer is feasible in Wilson disease. In our pilot study the systemic approach was more promising in ameliorating disease progression than the transplantation of lentivirally transduced hepatocytes.     

Mutation analysis of copper transporter genes in patients with ethylmalonic encephalopathy,mitochondriopathies and copper deficiency phenotypes

Summary: The trace metal copper is an essential cofactor for a number of biological processes, including mitochondrial oxidative phosphorylation, free-radical eradication, neurotransmitter synthesis and maturation, and iron metabolism. Consequently, copper transport at the cell surface and the delivery of copper to intracellular proteins are critical events in normal cellular homeostasis. Four genes have been reported to influence the cellular uptake and the delivery of copper to specific cell compartments and proteins. These include hCTR1, which regulates cellular copper uptake; HAH1, which mediates the transfer of copper to the Menkes and Wilson disease transporters; CCS, which is related to the transfer of copper to superoxide dismutase; and hCOX17, which directs trafficking of copper to mitochondrial cytochrome-c oxidase. At present, no genetic disorders have been associated with defects in these four copper transporter genes. In this study, we test the possibility that defective copper uptake or intracellular translocation represents the basic defect in three categories of candidate phenotypes among 22 patients: ethylmalonic encephalopathy; mitochondriopathies of unknown aetiology; and neurodevelopmental abnormalities with clinical and chemical evidence of copper deficiency. Mutation analyses of the copper uptake protein, hCTR1, and the three copper chaperones were performed by direct sequencing of the whole coding regions. No causative mutations were identified for the four copper transporter genes in 22 patients. A heterozygous polymorphism (847G>A) for CCS was detected in 7 patients. For the distinct disease entity ethylmalonic encephalopathy, we additionally show normal mRNA levels for each of the four genes. The negative results notwithstanding, we encourage ongoing study of additional patients with candidate phenotypes. Further, our results are consistent with the notion that other unknown copper-related transporters could be involved in diseases.     

Screening for Menkes disease using the urine HVA/VMA ratio

Summary Menkes disease is a disorder of copper transport that results in early death. Early therapy with parenteral copper-histidine has been shown to markedly improve outcomes. However, early diagnosis is difficult because patients are asymptomatic in early infancy. In Menkes disease, impaired activity of dopamine β-hydroxylase, a copper-dependent enzyme, leads to increased urine ratios of homovanillic acid/vanillylmandelic acid (HVA/VMA). Urine HVA/VMA ratios ranged from 4.1 to 69.7 among 15 patients with Menkes disease, whereas only 0.18% of controls had ratios greater than 4.0. Thus, the urine HVA/VMA ratio is a useful screening method for Menkes disease.     

The genotypic and phenotypic spectrum of pyridoxine-dependent epilepsy due to mutations in <Emphasis Type="Italic">ALDH7A1</Emphasis>

Pyridoxine-dependent epilepsy is a disorder associated with severe seizures that may be caused by deficient activity of α-aminoadipic semialdehyde dehydrogenase, encoded by the ALDH7A1 gene, with accumulation of α-aminoadipic semialdehyde and piperideine-6-carboxylic acid. The latter reacts with pyridoxal-phosphate, explaining the effective treatment with pyridoxine. We report the clinical phenotype of three patients, their mutations and those of 12 additional patients identified in our clinical molecular laboratory. There were six missense, one nonsense, and five splice-site mutations, and two small deletions. Mutations c.1217_1218delAT, I431F, IVS-1(+2)T > G, IVS-2(+1)G > A, and IVS-12(+1)G > A are novel. Some disease alleles were recurring: E399Q (eight times), G477R (six times), R82X (two times), and c.1217_1218delAT (two times). A systematic review of mutations from the literature indicates that missense mutations cluster around exons 14, 15, and 16. Nine mutations represent 61% of alleles. Molecular modeling of missense mutations allows classification into three groups: those that affect NAD+ binding or catalysis, those that affect the substrate binding site, and those that affect multimerization. There are three clinical phenotypes: patients with complete seizure control with pyridoxine and normal developmental outcome (group 1) including our first patient; patients with complete seizure control with pyridoxine but with developmental delay (group 2), including our other two patients; and patients with persistent seizures despite pyridoxine treatment and with developmental delay (group 3). There is preliminary evidence for a genotype-phenotype correlation with patients from group 1 having mutations with residual activity. There is evidence from patients with similar genotypes for nongenetic factors contributing to the phenotypic spectrum.     

Loss of function mutations in RPL27 and RPS27 identified by whole‐exome sequencing in Diamond‐Blackfan anaemia

Diamond‐Blackfan anaemia is a congenital bone marrow failure syndrome that is characterized by red blood cell aplasia. The disease has been associated with mutations or large deletions in 11 ribosomal protein genes including RPS7, RPS10, RPS17, RPS19, RPS24, RPS26, RPS29, RPL5, RPL11, RPL26 and RPL35A as well as GATA1 in more than 50% of patients. However, the molecular aetiology of many Diamond‐Blackfan anaemia cases remains to be uncovered. To identify new mutations responsible for Diamond‐Blackfan anaemia, we performed whole‐exome sequencing analysis of 48 patients with no documented mutations/deletions involving known Diamond‐Blackfan anaemia genes except for RPS7, RPL26, RPS29 and GATA1. Here, we identified a de novo splicing error mutation in RPL27 and frameshift deletion in RPS27 in sporadic patients with Diamond‐Blackfan anaemia. In vitro knockdown of gene expression disturbed pre‐ribosomal RNA processing. Zebrafish models of rpl27 and rps27 mutations showed impairments of erythrocyte production and tail and/or brain development. Additional novel mutations were found in eight patients, including RPL3L, RPL6, RPL7L1T, RPL8, RPL13, RPL14, RPL18A and RPL31. In conclusion, we identified novel germline mutations of two ribosomal protein genes responsible for Diamond‐Blackfan anaemia, further confirming the concept that mutations in ribosomal protein genes lead to Diamond‐Blackfan anaemia.     

Pathogenesis and management of Wilson disease

Hepatolenticular degeneration, commonly known as Wilson disease, is an autosomal recessive inherited disease of abnormal copper metabolism, characterized by the accumulation of copper in the body due to decreased biliary excretion of copper from hepatocytes. Wilson disease protein, ATP7B, functions in copper excretion into bile and in copper secretion to the bloodstream coupled with ceruloplasmin synthesis. Various kinds of mutations of ATP7B cause Wilson disease. Wilson disease is a rare genetic disease that can be treated pharmacologically. Recognition and prompt diagnosis are very important, because Wilson disease is fatal if left untreated. In this review, I summarize the pathogenesis and management of Wilson disease.     

Truncating mutations in the Wilson disease gene ATP7B are associated with very low serum ceruloplasmin oxidase activity and an early onset of Wilson disease

Background  

Mutations in the gene ATP7B cause Wilson disease, a copper storage disorder with a high phenotypic and genetic heterogeneity. We aimed to evaluate whether 'severe' protein-truncating ATP7B mutations (SMs) are associated with low serum ceruloplasmin oxidase activities and an early age of onset when compared to missense mutations (MMs).     

Distinct phenotype of a Wilson disease mutation reveals a novel trafficking determinant in the copper transporter ATP7B

Wilson disease (WD) is a monogenic autosomal-recessive disorder of copper accumulation that leads to liver failure and/or neurological deficits. WD is caused by mutations in ATP7B, a transporter that loads Cu(I) onto newly synthesized cupro-enzymes in the trans-Golgi network (TGN) and exports excess copper out of cells by trafficking from the TGN to the plasma membrane. To date, most WD mutations have been shown to disrupt ATP7B activity and/or stability. Using a multidisciplinary approach, including clinical analysis of patients, cell-based assays, and computational studies, we characterized a patient mutation, ATP7B^S653Y, which is stable, does not disrupt Cu(I) transport, yet renders the protein unable to exit the TGN. Bulky or charged substitutions at position 653 mimic the phenotype of the patient mutation. Molecular modeling and dynamic simulation suggest that the S653Y mutation induces local distortions within the transmembrane (TM) domain 1 and alter TM1 interaction with TM2. S653Y abolishes the trafficking-stimulating effects of a secondary mutation in the N-terminal apical targeting domain. This result indicates a role for TM1/TM2 in regulating conformations of cytosolic domains involved in ATP7B trafficking. Taken together, our experiments revealed an unexpected role for TM1/TM2 in copper-regulated trafficking of ATP7B and defined a unique class of WD mutants that are transport-competent but trafficking-defective. Understanding the precise consequences of WD-causing mutations will facilitate the development of advanced mutation-specific therapies.Copper is essential for the normal development and function of human cells because it serves as a cofactor for many important metabolic enzymes. However, intracellular levels of copper must be tightly regulated (1, 2) because excess copper is toxic. Inborn mutations in the Cu(I)-ATPases, ATP7A [Online Mendelian Inheritance in Man (OMIM) accession no.*606882] or ATP7B (OMIM *300011) result in either systemic copper deficiency or copper accumulation in several tissues, causing Menkes disease or Wilson disease (WD), respectively. WD (OM#277900) is an autosomal-recessive disorder with a heterogeneous clinical presentation; in the absence of family history, diagnosis of WD requires multiple clinical and laboratory studies (3). The large number of rare mutations in the ATP7B gene [>500, (www.hgmd.cf.ac.uk/ac/gene.php?gene=ATP7B)] contribute to the difficulty in making genotype-phenotype associations. Presently, about two dozen mutations found in WD patients have been characterized in detail (4–7). These studies revealed that the most common effect of a WD mutation is ATP7B misfolding, which results in retention of newly synthesized ATP7B in the endoplasmic reticulum (ER), a marked decrease in protein stability, and loss of Cu(I)-transport activity (8, 9). Destabilization and inactivation of ATP7B explain the common phenotypic manifestations in WD, such as impaired copper export from the liver and the lack of copper incorporation into secreted cuproenzymes, such as ceruloplasmin (CPN).ATP7B and the highly homologous ATP7A (Menkes disease protein) play central roles in maintaining copper levels in cells. These proteins belong to the evolutionarily conserved family of P_1B-ATPases, which use the energy of ATP hydrolysis to transport copper from the cytosol across cellular membranes (Fig. 1A). ATP7A and ATP7B load copper onto newly synthesized cupro-proteins in the late Golgi and remove excess copper from the cytosol after relocating to vesicles, which in turn traffic to the plasma membrane to release copper into the extracellular milieu. In low and basal copper, ATP7A and ATP7B are located predominantly in a subcompartment of the trans-Golgi network (TGN) marked by syntaxin 6 (10). When copper levels increase, ATP7A and ATP7B exit the TGN in distinct vesicles; ATP7B vesicles move to the apical region in polarized epithelia, whereas ATP7A vesicles move to the basolateral region. Because copper-dependent ATP7B trafficking is a complex process, the precise sequence of events and the function of trafficking determinants in ATP7B’s structure are yet to be fully understood.Open in a separate windowFig. 1.Hypothetical ATP7B model and multiple species alignment of the conserved regions, amino acids 621–668, in the two Cu-ATPases. (A) A hypothetical ATP7B ribbon model, generated by UCSF Chimera, showing the conserved core organization (20). The two large cytoplasmic loops in the core structure are: the A domain (actuator, green), between TM4 and TM5, which contains the phosphatase activity; and the N and P domains (nucleotide binding and phosphorylation, red) between TM6 and TM7, which bind ATP (N), catalyzing formation of a phosphorylated intermediate (P) as part of the catalytic cycle. The eight TMs (yellow are): TM1 (amino acids 645–670), TM2 (including the platform helix, amino acids 694–722), TM3 (amino acids 729–749), TM4 (amino acids 765–786), TM5 (amino acids 916–942), TM6 (amino acids 967–1004), TM7 (amino acids 1307–1345), and TM8 (amino acids 1352–1373). The six N-terminal MBDs (blue, N-MBDs, also referred to as the N-terminal domain of ATP7B, N-ATP7B) (61, 62) were manually positioned onto the published model. The box approximates the region of the multiple species alignment shown in B. (B) A multiple species alignment of human ATP7B sequence 621–668 (Upper) and ATP7A sequence 621–668 (Lower). WD patient mutations are underlined and in bold. The ATP7B S653 position is marked with an asterisk (bold). Portions of MBD6 and TMD 1 are bracketed. In ATP7A, the bracketed sequence shows the deleted region that is replaced with two amino acids (IR) in a patient with Occipital Horn Syndrome. The deleted sequence of ATP7A is underlined and in bold (35). Alignments were obtained using ClustalW (63). Amino acids that are identical (*), conserved (:), and semiconserved (.) are shown.We previously developed a comprehensive set of cell-based assays that use both polarized hepatic cells and fibroblasts lacking ATP7B and ATP7A (derived from a Menkes disease patient) to evaluate the activity, stability, and trafficking of ATP7B and its mutants (11, 12). In this study, we combined these assays with additional mutational analysis and computational studies to dissect the molecular phenotype of WD mutations found in a highly conserved region of ATP7B, G⁶²¹-S⁶⁶⁸. We demonstrate that the S653Y mutation has a distinct “transport-competent/trafficking-defective” phenotype. We also show that the transmembrane segment (TM) that harbors S653 has an important and previously unanticipated role in regulating exit of ATP7B from the TGN in response to copper elevation.     

早发性癫痫脑病男性患儿 ARX 基因突变及其临床特点

目的：探讨早发性癫痫脑病男性患儿ARX基因突变及其临床表型特点。方法收集42例男性早发性癫痫脑病患儿详细的临床资料,采集患儿及家长外周血,应用PCR、直接测序和多重连接依赖的探针扩增（ MLPA）技术对ARX基因第二外显子进行突变分析。对患儿的临床表型特点进行分析。结果42例早发性癫痫脑病患儿中3例患儿存在ARX基因第二外显子大片段缺失,检出率为7．14％（3/42）。其中1例为非特异性癫痫脑病,2例为婴儿痉挛症。3例患儿均于出生后6个月内出现难以控制的癫痫发作,2例患儿在脑电监测中发现高度失律,3例患儿对多种抗癫痫手段反应差,且均表现为严重的智力运动发育落后或倒退。未检出缺失的39例患儿发作形式呈现更多样化的特点,其中5例患儿大运动发育基本正常,3例患儿对ACTH或生酮饮食手段控制癫痫有效。结论早发性癫痫脑病患儿中部分存在ARX基因第二外显子大片段缺失。具有ARX基因突变的早发性癫痫脑病患儿,其临床表现为6个月内出现难治性癫痫发作,以部分性发作及痉挛发作为主,同时有显著的智力运动发育落后、甚至倒退;少数未检出缺失的患儿的大运动发育可基本正常,对ACTH或生酮饮食反应良好。     

Diagnosis and phenotypic classification of Wilson disease1

Wilson disease is an inherited autosomal recessive disorder of hepatic copper metabolism leading to copper accumulation in hepatocytes and in extrahepatic organs such as the brain and the cornea. Originally Wilson disease was described as a neurodegerative disorder associated with cirrhosis of the liver. Later, Wilson disease was observed in children and adolescents presenting with acute or chronic liver disease without any neurologic symptoms. While diagnosis of neurologic Wilson disease is straightforward, it may be quite difficult in non‐neurologic cases. Up to now, no single diagnostic test can exclude or confirm Wilson disease with 100% certainty. In 1993, the gene responsible for Wilson disease was cloned and localized on chromosome 13q14.3 (MIM277900) ( 1 , 2 ). The Wilson disease gene ATP7B encodes a P‐type ATPase. More than 200 disease causing mutations of this gene have been described so far ( 3 ). Most of these mutations occur in single families, only a few are more frequent (like H1069Q, 3400delC and 2299insC in Caucasian ( 4 - 6 ) or R778L in Japanese ( 7 ), Chinese and Korean patients). Studies of phenotype‐genotype relations are hampered by the lack of standard diagnostic criteria and phenotypic classifications. To overcome this problem, a working party discussed these problems in depth at the 8th International Meeting on Wilson disease and Menkes disease in Leipzig/Germany (April 16–18, 2001) ² 2This meeting was organized under the auspices of the European Association for the Study of the Liver (EASL) and was financially supported by the European Commission (High‐level Scientific Conference No. HPCF‐CT‐2000‐00327) and the Austrian Society of Gastroenterology and Hepatology (O¨GGH). . After the meeting, a preliminary draft of a consensus report was mailed to all active participants and their comments were incorporated in the final text.     

PRKAR1A mutations in primary pigmented nodular adrenocortical disease

Primary Pigmented Nodular Adrenocortical Disease (PPNAD) is a rare primary bilateral adrenal defect causing corticotropin-independent Cushing’s syndrome. It occurs mainly in children and young adults. Macroscopic appearance of the adrenals is characteristic with small pigmented micronodules observed in the cortex. PPNAD is most often diagnosed in patients with Carney complex (CNC), but it can also be observed in patients without other manifestations or familial history (isolated PPNAD). The CNC is an autosomal dominant multiple neoplasia syndrome characterized by the association of myxoma, spotty skin pigmentation and endocrine overactivity. One of the putative CNC genes has been identified as the gene of the regulatory R1A subunit of protein kinase A (PRKAR1A), located at 17q22-24. Germline heterozygous inactivating mutations of PRKAR1A have been reported in about 45% of patients with CNC, and up to 80% of CNC patients with Cushing’s syndrome due to PPNAD. Interestingly, such inactivating germline PRKAR1A mutations have also been found in patients with isolated PPNAD. The hot spot PRKAR1A mutation termed c.709[-7-2]del6 predisposes mostly to isolated PPNAD, and is the first clear genotype/phenotype correlation described for this gene. Somatic inactivating mutations of PRKAR1A have been observed in macronodules of PPNAD and in sporadic cortisol secreting adrenal adenomas. Isolated PPNAD is a genetic heterogenous disease, and recently inactivating mutations of the gene of the phosphodiesterase 11A4 (PDE11A4) located at 2q31–2q35 have been identified in patients without PRKAR1A mutations. Interestingly, both PRKAR1A and PDE11A gene products control the cAMP signaling pathway, which can be altered at various levels in endocrine tumors.