A novel mutation in the preprovasopressin gene identified in a kindred with autosomal dominant neurohypophyseal diabetes insipidus

Autosomal dominant neurohypophyseal diabetes insipidus (ADNDI) is a defect in free water conservation caused by mutations in the single gene that encodes both vasopressin (VP) and its binding protein, neurophysin II (NP II). Most of the human mutations in this gene have been in the portion encoding the NP molecule; the resultant abnormal gene products are believed to cause cellular toxicity as improperly folded precursor molecules accumulate in the endoplasmic reticulum. We identified a new American kindred with ADNDI and found a novel mutation in the VP molecule. A 78-yr-old man was noted to have hypotonic polyuria and plasma hyperosmolarity; the urinary concentration defect was reversed by administration of VP. His symptomatology dated to childhood, and his family history was consistent with autosomal transmission of the polyuric syndrome, with affected members in three generations, including several females. Affected individuals were found to be heterozygous for a 3-bp deletion in exon 1 of arginine VP (AVP)-NP II, predicting a deletion of phenylalanine 3 (known to be critical for receptor binding) in the VP nonapeptide. Neuro 2A cells stably transfected with the mutant AVP-NP construct showed increased rates of apoptosis as assessed by flow cytometric methods. These observations support the concept that cellular toxicity of abnormal AVP-NP gene products underlies the development of ADNDI, and the data further demonstrate that mutations affecting the AVP moiety can result in initiation of these pathological processes.     

Glu^47缺失造成的常染色体显性遗传垂体性尿崩症的家系分析

目的寻找常染色体显性遗传垂体性尿崩症（ADNDI）的基因突变位点。方法在一临床确诊的ADNDI家系，提取外周血的基因组DNA，PCR扩增精氨酸加压素前体基因（AVP－NPⅡ），并进行全长测序，亚克隆测序确认突变位点。结果本家系中所有患者在AVP－NPⅡ基因2号外显子的1824－1829位AGGAGG存在一个AGG密码子的缺失，而其他表型正常的成员测序结果正常。结论AVP－NPⅡ基因1824-1829位AGGAGG中的一个AGG的缺失导致NPⅡ第47位谷氨酸（Glu）的缺失，可能影响NPⅡ蛋白对AVP的运输，进一步造成AVP降解增加，发生尿崩症。     

一个常染色体显性遗传性垂体性尿崩症家系AVP-NPⅡ基因的连锁和突变分析

目的 寻找中国人常染色体显性遗传性垂体性尿崩症（autosomal dominant neumhypophyseal diabetesinsipidus，ADNDⅠ）的致病基因。方法 采集ADNDⅠ家系，抽提基因组DNA，对AVP-NPⅡ基因进行微卫星标记（STR）连锁分析和PCR直接测序。结果 连锁分析结果显示，AVP-NPⅡ基因位点与ADNDⅠ表型连锁，但PCR产物直接测序未发现任何碱基的改变。结论 推测ADNDⅠ存在遗传多样性，很可能有其他致病基因突变影响机体正常水代谢，导致ADNDⅠ的发生。     

Glu~(47)缺失造成的常染色体显性遗传垂体性尿崩症的家系分析

目的寻找常染色体显性遗传垂体性尿崩症(ADNDI)的基因突变位点。方法在一临床确诊的ADNDI家系,提取外周血的基因组DNA,PCR扩增精氨酸加压素前体基因(AVP-NPⅡ),并进行全长测序,亚克隆测序确认突变位点。结果本家系中所有患者在AVP-NPⅡ基因2号外显子的1824-1829位AGGAGG存在一个AGG密码子的缺失,而其他表型正常的成员测序结果正常。结论AVP-NPⅡ基因1824-1829位AGGAGG中的一个AGG的缺失导致NPⅡ第47位谷氨酸(Glu)的缺失,可能影响NPⅡ蛋白对AVP的运输,进一步造成AVP降解增加,发生尿崩症。     

Molecular analysis of autosomal dominant neurohypophyseal diabetes insipidus

The status of the arginine vasopressin-neurophysin-II (AVP-NPII) gene was studied in three families with autosomal dominant neurohypophyseal diabetes insipidus (AD-NDI). Restriction fragments of genomic DNA containing AVP-NPII sequences from affected individuals were not detectably different in size from those of normal controls. Thus, these individuals with ADNDI do not have apparent large deletions, insertions, or rearrangements of an AVP-NPII allele. Four restriction fragment length polymorphisms were detected with a probe for the adjacent gene on chromosome 20, oxytocin-neurophysin-I (OT-NPI). Linkage studies in these three families between the restriction fragment length polymorphism haplotypes and ADNDI phenotype strongly suggest cosegregation. This indicates that the genetic locus for ADNDI maps within or near the AVP-NPII locus and suggests that a defective AVP-NPII allele may be the basis of ADNDI.     

Progressive decline of vasopressin secretion in familial autosomal dominant neurohypophyseal diabetes insipidus presenting a novel mutation in the vasopressin-neurophysin II gene

OBJECTIVE: Familial autosomal dominant neurohypophyseal diabetes insipidus (FNDI) is a rare form of central diabetes insipidus (DI), which is caused by mutations in the vasopressin-neurophysin II (AVP-NPII) gene. The present study evaluated the AVP secretion over time and analysed the structure of the AVP-NPII gene in a Brazilian family with FNDI. SUBJECTS AND DESIGN: Four affected members and one nonaffected member from one Brazilian family with FNDI were studied. The diagnosis of central DI was established by fluid deprivation test and hypertonic saline infusion. Two affected members were assessed twice within a 6-year interval. For molecular analysis, genomic DNA was extracted and the AVP-NPII gene was amplified by polymerase chain reaction. RESULTS: The functional assessment of patients with FNDI over time confirmed a progressive loss in AVP secretion. Two patients were first diagnosed as partial central DI and, several years later, they developed severe central DI. Sequencing analysis revealed a heterozygous new point mutation in the nucleotide 1892 in the coding sequence for neurophysin-II of the AVP-NPII gene (1892G>C) predicting an amino acid substitution (A68P) in all affected members. CONCLUSION: Our data demonstrate a gradual vasopressinergic deficiency due to a novel mutation in the AVP-NPII gene in a Brazilian family with FNDI. The accumulation of A68P mutated precursor might have a cytotoxicity effect, leading to a gradual death of magnocellular neurones, and a progressive decline in AVP secretion.     

一中国人家系常染色体显性遗传垂体性尿崩症基因突变研究

目的 探讨中国人的常染色体显笥遗传垂体性尿崩症（ADNDI）的分子发病机制。方法 对一个家系中4例ADNDI患者、4例未发病者及1例来自其他家庭的患者的精氨酸加压素－运载蛋白Ⅱ（AVP-NPⅡ）基因外显子1和2进行聚合酶链反应－单链构像多态性（PCR－SSCP）及基因测序研究。结果 SSCP分析表明：ADNDI的同一个家系中的患者、正常人及来自其他家系非遗传尿崩症患者的AVP－NPⅡ外显子2增加了两亿异常条带,为突变杂合子。ADNDI家系中患者（先证者、先证者祖母）AVP－NPⅡ基因外显子2PCR扩培产物在使用不同的DNA测序仪、采用正反引物测序均显示同样结果,即在AVP－NPⅡ基因第1826－1831位置两个连续的GAG中脱薄一个GAG.珲种突变导致AVP－NPⅡ基因合成的NPⅡ前体缺少Glu47。由于NPⅡ多肽的Glu47同AVP形成一个盐桥,缺乏Glu47将使AVP同NPⅡ的粘着力下降,加速AVP的分解。结论 碱基缺失为中国人常染色体显性遗传垂体性尿崩症发病原因之一。     

A novel mutation in the coding region for neurophysin-II is associated with autosomal dominant neurohypophyseal diabetes insipidus

OBJECTIVE Autosomal dominant neurohypophyseal diabetes insipidus (ADNDI) is a rare cause of diabetes insipidus, in which AVP serum levels are insufficient. AVP is synthesized along with neurophysin-II (NPII) as an AVP-NPII precursor polypeptide in the hypothalamus. After proteolytic cleavage during axonal transport, AVP and NPII are reassembled and stored loosely bound to each other in the posterior pituitary until both are released into the circulation. In this study, we investigated the genetic basis of ADNDI in a German kindred with 10 affected members spanning three generations. DESIGN Genomic DNA was isolated from peripheral blood leucocytes. The entire coding region of the AVP-NPII gene of one of the affected persons was amplified by polymerase chain reaction (PCR) and subjected to nucleotide sequence analysis. Sequencing results were confirmed by restriction enzyme analysis of PCR products. PATIENTS Six affected and two unaffected members of a family with ADNDI and 54 unrelated healthy control subjects were studied. RESULTS The index patient was found by direct sequencing to be heterozygous for a G to T transversion at nucleotide position 1884 (exon 2) of the AVP-NPII gene. This mutation introduced a new recognition site for the restriction enzyme Ava II, which was used to test for the presence of the mutation in other family members and in control subjects. The mutation was detected in all family members with ADNDI, but was not found in unaffected family members or in control subjects. The mutation encodes a valine in place of the normal glycine at amino acid 65 of NPII, which is known to be highly conserved during evolution. CONCLUSIONS In this family, the autosomal dominant neurohypophyseal diabetes insipidus phenotype cosegregates with a point mutation in a region of the AVP-neurophysin-II gene which codes for the carboxy-terminal domain of neurophysin-II. Although the altered amino acid is not directly involved in AVP binding, the mutation might lead to conformational changes that impair the dimerization of neurophysin-II molecules. This could in turn affect the AVP binding affinity of neurophysin-II or might interfere with the transport of the AVP-neurophysin-II precursor in the AVP-producing cells of the hypothalamus.     

A new mutation of the arginine vasopressin-neurophysin II gene in a family with autosomal dominant neurohypophyseal diabetes insipidus.

Familial neurohypophyseal diabetes insipidus (FNDI) is an autosomally dominant inherited disorder with a typical onset at one to six years of age. The genetic locus of FNDI is the arginine vasopressin-neurophysin II (AVP-NPII) gene. The gene encoding the precursor hormone (prepro-AVP-neurophysin II) is located in the chromosomal region 20p13 and contains three exons. Mutations that cause FNDI have been found to occur within the signal peptide of the prepro-AVP-neurophysin II precursor, within the coding sequence for neurophysin II and the vasopressin-coding sequence. A family (four members with FNDI, two without FNDI) in three consecutive generations was investigated. Index case was a now 22-year old man with a history of severe polyuria (18 L/day) and polydipsia first recognized at about 4-5 months of age. The arginine vasopressin-neurophysin II gene was investigated by direct sequencing of PCR products amplified from each exon. Subsequently, a restriction analysis was performed to verify the sequencing results. The affected individuals were found to have a missense mutation in exon 2 at nucleotide position 1887 (G to C) of the AVP-NPII gene. Using both restriction enzyme digestion and sequence analysis, the mutation was found in all affected family members, but not in the unaffected members studied. This mutation (1887 G to C) represents a novel mutation of the AVP-NPII gene.     

Clinical and molecular evidence of abnormal processing and trafficking of the vasopressin preprohormone in a large kindred with familial neurohypophyseal diabetes insipidus due to a signal peptide mutation.

The autosomal dominant form of familial neurohypophyseal diabetes insipidus (adFNDI) is a rare disease characterized by postnatal onset of polyuria and a deficient neurosecretion of the antidiuretic hormone, arginine vasopressin (AVP). Since 1991, adFNDI has been linked to 31 different mutations of the gene that codes for the vasopressin-neurophysin II (AVP-NPII) precursor. The aims of the present study were to relate the clinical phenotype to the specific genotype and to the molecular genetic effects of the most frequently reported adFNDI mutation located at the cleavage site of the signal peptide of AVP-NPII [Ala(-1)Thr]. Genetic analysis and clinical studies of AVP secretion, urinary AVP, and urine output were performed in 16 affected and 16 unaffected family members and 11 spouses of a Danish adFNDI kindred carrying the Ala(-1)Thr mutation. Mutant complementary DNA carrying the same mutation was expressed in a neurogenic cell line (Neuro2A), and the cellular effects were studied by Western blotting, immunocytochemistry, and AVP measurements. The clinical studies showed a severe progressive deficiency of plasma and urinary AVP that manifested during childhood. The expression studies demonstrated that the Ala(- 1)Thr mutant cells produced 8-fold less AVP than wild-type cells and accumulated excessive amounts of 23-kDa NPII protein corresponding to uncleaved prepro-AVP-NPII. Furthermore, a substantial portion of the intracellular AVP-NPII precursor appeared to be colocalized with an endoplasmic reticulum antigen (Grp78). These results provide independent confirmation that this Ala(-1)Thr mutation produces adFNDI by directing the production of a mutant preprohormone that accumulates in the endoplasmic reticulum, because it cannot be cleaved from the signal peptide and transported to neurosecretory vesicles for further processing and secretion.     

Clinical and molecular analysis of a Chinese family with autosomal dominant neurohypophyseal diabetes insipidus associated with a novel missense mutation in the vasopressin-neurophysin II gene

The objective of this study is to identify the genetic defects in a Chinese family with autosomal dominant familial neurohypophyseal diabetes insipidus. Complete physical examination, fluid deprivation, and DDAVP tests were performed in three affected and three healthy members of the family. Genomic DNA was extracted from leukocytes of venous blood of these individuals for polymerase chain reaction amplification and direct sequencing of all three coding exons of arginine vasopressin-neurophysin II (AVP-NPII) gene. Seven members of this family were suspected to have symptomatic vasopressin-deficient diabetes insipidus. The water deprivation test in all the patients confirmed the diagnosis of vasopressin-deficient diabetes insipidus, with the pedigree demonstrating an autosomal dominant inheritance. Direct sequence analysis revealed a novel mutation (c.193T>A) and a synonymous mutation (c.192C>A) in the AVP-NPII gene. The missense mutation resulted in the substitution of cysteine by serine at a highly conserved codon 65 of exon 2 of the AVP-NPII gene in all affected individuals, but not in unaffected members. We concluded that a novel missense mutation in the AVP-NPII gene caused neurohypophyseal diabetes insipidus in this family, due to impaired neurophysin function as a carrier protein for AVP. The Cys65 is essential for NPII in the formation of a salt bridge with AVP. Presence of this mutation suggests that the portion of the neurophysin peptide encoded by this sequence is important for the normal expression of vasopressin.     

Autosomal dominant neurohypophyseal diabetes insipidus due to substitution of histidine for tyrosine(2) in the vasopressin moiety of the hormone precursor

The autosomal dominant form of familial neurohypophyseal diabetes insipidus (adFNDI) has been linked to 40 different mutations of the gene encoding the vasopressin-neurophysin II (AVP-NPII) precursor. All of these mutations have been located in either the signal peptide or neurophysin II moiety. We now report a three-generation Turkish kindred in which severe adFNDI cosegregates with a novel missense mutation in the part of the AVP-NPII gene encoding the AVP moiety. This mutation (T-->C at position 285 in the genomic sequence) was found in only one allele and predicts a substitution of histidine for tyrosine at position 2 in AVP. Like other adFNDI mutations, this substitution is expected to impair folding and processing of the precursor, in this case by interfering with normal binding of the AVP and NPII moieties. It is associated clinically with inability to concentrate urine during fluid deprivation, a greater than 80% deficiency of AVP secretion, and absence of the posterior pituitary bright spot on magnetic resonance imaging. These findings are consistent with the hypothesis that mutations in the AVP-NPII gene cause adFNDI by directing the production of a folding incompetent precursor that prevents the expression of the normal allele via a cytotoxic effect on the magnocellular neurons.     

A novel heterozygous missense mutation in the vasopressin moiety is identified in a Japanese person with neurohypophyseal diabetes insipidus

The autosomal dominant familial neurohypophyseal diabetes insipidus (adFNDI) is caused by diverse mutations in one allele of the gene that encodes the arginine vasopressin (AVP) precursor protein, AVP-neurophysin II (AVP-NP II). Most of the mutations identified so far are located in either the signal peptide or NP II moiety. Two recently published mutations in the AVP gene identified in kindreds with adFNDI predict a substitution of histidine for tyrosine at position 2 and a deletion of phenylalanine at position 3 in AVP. They are unique among adFNDI mutations in that they are the only adFNDI mutations that affect amino acid residues in the AVP moiety of the pro-hormone. Here, we report a novel heterozygous missense mutation in the AVP moiety of the AVP-NP II gene in a Japanese person with neurohypophyseal diabetes insipidus (DI). This mutation occurs at position 2 in AVP and predicts a substitution of serine for tyrosine (Y21S). It is expected to interfere with normal binding of AVP with NP II, and thus result in misfolding of the precursor proteins. The data of this study support the notion that mutations affecting the AVP moiety can result in the initiation of the pathological processes.     

Impaired trafficking of mutated AVP prohormone in cells expressing rare disease genes causing autosomal dominant familial neurohypophyseal diabetes insipidus

OBJECTIVE AND STUDY DESIGN: Two different mutations in the arginine vasopressin (AVP) gene associated with autosomal dominant familial neurohypophyseal diabetes insipidus (adFNDI) predict Y21H (AVP2) and V67A (NP36) amino acid substitutions of the AVP prohormone. They are unique in that they change, respectively, the AVP moiety and a region of the neurophysin II domain not so far affected by any mutations. To test whether they affect the cellular handling of the AVP prohormone in a similar manner to previously investigated mutations, they were examined by heterologous expression in cell lines. RESULTS: Both mutations resulted in significantly reduced amounts of immunoreactive AVP in the cell culture medium as determined by radioimmunoassay analysis. Metabolic labelling combined with immunoprecipitation demonstrated that processing and secretion of the mutant prohormones was reduced but not prevented. Finally, confocal laser scanning microscopy showed that normal AVP prohormone and/or its processed products were localized in the tips of the cellular processes, whereas both mutant prohormones were accumulated in the endoplasmic reticulum (ER) and in the case of the V67A prohormone, also in perinuclear structures outside the ER. CONCLUSION: Both mutations result in reduced AVP prohormone processing and secretion probably due to retention in the ER. This supports, at least partly, the hypothesis that the mutations lead to the production of a mutant hormone precursor that fails to fold and/or dimerize properly and, as a consequence, is retained by the ER protein quality control machinery. Perinuclear accumulation of the V67A prohormone outside the ER indicates that additional mechanisms could be involved.     

Differential cellular handling of defective arginine vasopressin (AVP) prohormones in cells expressing mutations of the AVP gene associated with autosomal dominant and recessive familial neurohypophyseal diabetes insipidus

An unusual mutation in the arginine vasopressin (AVP) gene, predicting a P26L amino acid substitution of the AVP prohormone, is associated with autosomal recessive familial neurohypophyseal diabetes insipidus (FNDI). To investigate whether the cellular handling of the P26L prohormone differed from that of the Y21H prohormone associated with autosomal dominant inheritance of FNDI, the mutations were examined by heterologous expression in cell lines. Immunoprecipitation demonstrated retarded processing and secretion of the Y21H prohormone, whereas the secretion of the P26L prohormone seemed to be unaffected. Confocal laser scanning microscopy showed accumulation of the Y21H prohormone in the endoplasmic reticulum, whereas the P26L prohormone and/or processed products were localized in secretory granules in the cellular processes. RIA analysis showed reduced amounts of immunoreactive Y21H-AVP and P26L-AVP in the cell culture medium. Thus, the recessive mutation does not seem to affect the intracellular trafficking but rather the final processing of the prohormone. Our results provide an important negative control in support of the hypothesis that autosomal dominant inheritance of FNDI is caused by mutations in the AVP gene that alter amino acid residues important for folding and/or dimerization of the neurophysin II moiety of the AVP prohormone and subsequent transport from the endoplasmic reticulum.     

Clinical and molecular analysis of three families with autosomal dominant neurohypophyseal diabetes insipidus associated with a novel and recurrent mutations in the vasopressin-neurophysin II gene

OBJECTIVE: To test further the hypothesis that autosomal dominant neurohypophyseal diabetes insipidus (adFNDI) is caused by heterozygous mutations in the vasopressin-neurophysin II (AVP-NPII) gene that exert a dominant negative effect by producing a precursor that misfolds, accumulates and eventually destroys the neurosecretory neurons. METHODS: Antidiuretic function, magnetic resonance imaging (MRI) of the posterior pituitary and AVP-NPII gene analysis were performed in 10 affected members of three unreported families with adFNDI. RESULTS: As in previously studied patients, adFNDI apparently manifested after birth, was due to a partial or severe deficiency of AVP, and was associated with absence or diminution of the hyperintense MRI signal normally emitted by the posterior pituitary, and with a heterozygous mutation in the AVP-NPII gene. In family A, a transition 275G-->A, which predicts replacement of cysteine 92 by tyrosine (C92Y), was found in the index patient, but not in either parent, indicating that it arose de novo. The six affected members of family B had a transversion 160G-->C, which predicts replacement of glycine 54 by arginine (G54R). It appeared de novo in the oldest affected member, and was transmitted in a dominant manner. In family C, six of 15 living affected members were tested and all had a novel transition, 313T-->C, which predicts replacement of cysteine 105 by arginine (C105R). It, too, was transmitted in a dominant manner. As in other patients with adFNDI, the amino acids replaced by the mutations in these three families are known to be particularly important for correct and efficient folding of the precursor. CONCLUSIONS: These findings are consistent with the malfolding/toxicity hypothesis underlying the pathogenesis of adFNDI. Moreover, they illustrate the value of genetic analysis in all patients who develop idiopathic diabetes insipidus in childhood, even if no other family members are affected.     

A novel variation in the AVP gene resulting in familial neurohypophyseal diabetes insipidus in a large Italian kindred

Familial neurohypophyseal diabetes insipidus (FNDI) is mostly an autosomal dominant inherited disorder presenting with severe polydipsia and polyuria typically in early childhood. To date, 69 different variations in the AVP gene encoding the AVP prohormone have been identified in autosomal dominant FNDI (adFNDI). In this study we present a family of seven generations, in which a novel variation in the AVP gene seems to cause adFNDI. Clinical assessment by 24 h urine collection, water deprivation test, desmopressin (dDAVP) challenge, and magnetic resonance imaging (MRI) of the posterior pituitary are presented. The diagnosis of adFNDI was confirmed by direct DNA sequence analysis of the AVP gene. Inheritance pattern and clinical history clearly pointed towards adFNDI. Inability of concentrating urine upon dehydration was demonstrated by a water deprivation test, and neurohypophyseal diabetes insipidus was strongly suspected after dDAVP administration, during which renal concentration ability quadrupled. MRI revealed a very weak pituitary “bright spot” in each of six subjects and a further reduction in the size of the neurohypophysis in a 7-year follow-up MRI scan in one subject. DNA sequence analysis revealed heterozygousity for a novel g.1785T > C gene variation predicting a p.Leu63Pro substitution in four affected subjects. Genetic testing in the diagnostic evaluation of families in which diabetes insipidus segregates is highly recommended in that interpretation of clinical assessments can be difficult. Furthermore, presymptomatic diagnosis can ease the parental concern of the carrier status of their offspring, and also avoid unnecessary surveillance of those being unaffected.     

Autosomal dominant neurohypophyseal diabetes insipidus with linkage to chromosome 20p13 but without mutations in the AVP-NPII gene

CONTEXT: Autosomal dominant neurohypophyseal diabetes insipidus (ADNDI) has been known as a rare disorder transmitted as an autosomal dominant trait, characterized by polyuria and polydipsia, and caused by deficient neurosecretion of arginine vasopressin precursor (AVP-NPII). We reported an ADNDI family with linkage to chromosome 20p13 but without mutations in the AVP-NPII gene. OBJECTIVE: The objective of this study was to identify the corresponding locus responsible for ADNDI in a family without AVP-NP II gene mutations. SUBJECTS AND METHODS: Two families with ADNDI were diagnosed by water deprivation test. The AVP-NPII gene was amplified by PCR and sequenced. A genomewide scan was performed in one family using 400 microsatellite markers covering 22 autosomes. RESULTS: A 3-bp deletion (1827-1829delAGG) of AVP-NPII gene was identified in the affected individuals in one family. Although no mutations could be detected in the coding, the promoter, and intronic regions of AVP-NPII gene in the other family, a maximum LOD score of 1.202999 (theta = 0.00) was obtained at marker D20S889 by genomewide scan, and a 7-cM interval on chromosome 20p13 was defined by fine mapping with markers D20S199-D20S849. Furthermore, the intragenic region that regulates AVP-NPII and oxytocin expression as an enhancer element and the UBCE7IP5 gene that participates in prohormone degradation were sequenced. No alterations could be detected either. CONCLUSION: The corresponding locus responsible for ADNDI is possibly heterogeneous regarding the slightly different clinical features in these two families.