Colorectal cancer--an undertreated disease

PURPOSE: Because several macular dystrophies are caused by mutations in the peripherin/RDS gene, we examined autosomal dominant and sporadic cases of central areolar choroidal dystrophy for mutations in the peripherin/RDS gene. METHODS: DNA sequence analysis of the peripherin/RDS gene was performed in four sporadic cases and in ten affected and nine unaffected individuals from seven families with autosomal dominant central areolar choroidal dystrophy. RESULTS: An Arg-142-Trp mutation in the peripherin/RDS gene was found in ten affected family members in seven families. Among these, a 69-year-old man with the Arg-142-Trp mutation, who was unaffected six years before blood sample analysis, showed a parafoveal area of chorioretinal atrophy. The 65-year-old sister of this family had the Arg-142-Trp mutation with no macular abnormalities, but she might still develop central areolar choroidal dystrophy at an older age. No mutation was found in the four sporadic cases. CONCLUSION: Autosomal dominant central areolar choroidal dystrophy, studied in seven families, is caused by an Arg-142-Trp mutation in the peripherin/RDS gene.     

Retropatellar contact stress in simulated patella infera

Because mutations in the peripherin/RDS gene have been found in retinal dystrophies involving the macula, we examined various types of macular dystrophies from southern France to characterize sequence variations that may be associated with these conditions. DNA sequence analysis of the full coding and flanking regions of the peripherin/RDS gene was performed in fifteen unrelated patients with different types of macular dystrophy, including nine with retinitis pigmentosa (RP). Of the 15 probands with macular disease, two (13.3%) were found to carry a mutation in the peripherin/RDS gene. The recurrent mutation P216S was identified in a pedigree with autosomal dominant RP. A previously unreported complex allele (1064delTC associated with IVS2 + 22ins7) that is predicted to result in the premature termination of peripherin/RDS synthesis was identified in a sporadic case of macular atrophy with RP. We also report eight novel neutral sequence variations in the peripherin/RDS gene, most of them found in the 3' untranslated part of the gene.     

Morphological aspects of the median eminence--place of accumulation and secretion of regulatory neurohormones and neuropeptides

Mutations in the peripherin/RDS gene, which encodes a photoreceptor-specific membrane glycoprotein, have been identified in a variety of retinal phenotypes. However, the mechanisms by which specific mutations in this gene can cause typical features of retinal dystrophies clinically as distinct as retinitis pigmentosa or macular degeneration are still unknown. Recently, a single case of adult vitelliform macular dystrophy (AVMD) has been associated with a Y258Stop mutation. To assess the frequency of peripherin/RDS mutations in the clinically heterogeneous group of AVMD, we analyzed the entire coding region of the gene in 28 unrelated patients. We identified five novel mutations including two presumed null allele mutations. Thus, our results demonstrate that a significant portion of AVMD patients (18%) carry point mutations in peripherin/RDS, suggesting that this gene is frequently involved in the pathogenesis of this macular disorder. In addition, this study shows that the variable phenotypes in AVMD are due, at least in part, to genetic heterogeneity and are likely to be caused by mutations in disease genes thus far unknown.     

Evolution of precipitates in lead-implanted aluminum: A backscattering and channeling study

BACKGROUND: Thirty-six mutations that cause Gaucher disease, the most common glycolipid storage disorder, are known. Although both alleles of most patients with the disease contain one of these mutations, in a few patients one or both disease-producing alleles have remained unidentified. Identification of mutations in these patients is useful for genetic counseling. MATERIALS AND METHODS: The DNA from 23 Gaucher disease patients in whom at least one glucocerebrosidase allele did not contain any of the 36 previously described mutations has been examined by single strand conformation polymorphism (SSCP) analysis, followed by sequencing of regions in which abnormalities were detected. RESULTS: Eight previously undescribed mutations were detected. In exon 3, a deletion of a cytosine at cDNA nt 203 was found. In exon 6, three missense mutations were identified: a C-->A transversion at cDNA nt 644 (Ala176-->Asp), a C-->A transversion at cDNA nt 661 that resulted in a (Pro182-->Thr), and a G-->A transition at cDNA nt 721 (Gly202-->Arg). Two missense mutations were found in exon 7: a G-->A transition at cDNA nt 887 (Arg257-->Gln) and a C-->T at cDNA nt 970 (Arg285-->Cys). Two missense mutations were found in exon 9: a T-->G at cDNA nt 1249 (Trp378-->Gly) and a G-->A at cDNA nt 1255 (Asp380-->Asn). In addition to these disease-producing mutations, a silent C-->G transversion at cDNA nt 1431, occurring in a gene that already contained the 1226G mutation, was found in one family. CONCLUSIONS: The mutations described here and previously known can be classified as mild, severe, or lethal, on the basis of their effect on enzyme production and on clinical phenotype, and as polymorphic or sporadic, on the basis of the haplotype in which they are found. Rare mutations such as the new ones described here are sporadic in nature.     

Overexpression of MerT, the mercuric ion transport protein of transposon Tn501, and genetic selection of mercury hypersensitivity mutations

The small (116 amino acids) inner membrane protein MerT encoded by the transposon Tn501 has been overexpressed under the control of the bacteriophage T7 expression system. Random mutants of MerT were made and screened for loss of mercuric ion hypersensitivity. Several mutant merT genes were selected and sequenced: Cys24Arg and Cys25Tyr mutations abolish mercury resistance, as do charge-substitution mutations in the first predicted transmembrane helix (Gly14Arg, Gly15Arg, Gly27Arg, Ala18Asp), and the termination mutations Trp66Ter and Cys82Ter.     

Promoting collaboration in community health nursing

Malignant hyperthermia (MH) is a pharmacogenetic disorder. Susceptibility to MH (MHS) is presumed to be inherited in an autosomal dominant way. MH crises are triggered by halogenated inhalational anaesthetics and suxamethonium, and may be lethal if not treated early and adequately. Until now, eight mutations in the RYR1 gene have been described as causes of MHS phenotype in various MH families. The mutation RYR1 G1021A (Gly341Arg) has been reported to account for approximately 10% of Caucasian MHS cases. However, in our study this mutation was discovered in only 1 out of 89 Scandinavian families, indicating that this mutation may be the cause of MHS in only about 1% of MHS families in those populations. The mutation may have been brought to Scandinavia by an immigrant.     

Factor V Arg306-->Thr (factor V Cambridge) and factor V Arg306-->Gly mutations in venous thrombotic disease

We investigated the prevalence of two reported mutations of the factor V gene (factor V Arg306-->Thr, or factor V Cambridge, and factor V Arg306-->Gly) in 104 relatively young patients with verified venous thrombosis and in 208 age-, sex- and race-matched controls, in order to establish whether the two mutations are associated with increased predisposition for venous thrombosis. PCR amplification followed by BstNI and MspI digestion was employed to determine the genotypes, and each mutation was confirmed by DNA sequencing. Among the controls, one individual was found to be heterozygous for the factor V Arg306-->Thr mutation and one heterozygous for the factor VArg306-->Gly mutation; none of the patients carried either mutation. Our findings do not support factor V Cambridge and factor V Arg306-->Gly as risk factors for venous thrombosis.     

Molecular diagnosis of salt wasting congenital adrenal hyperplasia, caused by deficit of 21-hydroxylase, in the Chilean population

BACKGROUND: The most frequent cause of congenital adrenal hyperplasia, manifested as virilization and salt wasting, is the deficit of 21-hydroxylase. This disease is originated by mutations of the gene CYP21 that codifies this enzyme, mostly recombination between this gene and its inactive pseudogene called CYP21P. AIM: To study the molecular origin of this enzyme deficiency in Chilean patients. PATIENTS AND METHODS: Twenty five patients with salt wasting congenital adrenal hyperplasia, that had 17-hydroxyprogesterone levels above 30 ng/ml, were studied. In all patients, a polymerase chain reaction (PCR) with selective primers was done with extracted genomic DNA, to amplify the active gene and specific primers for normal or mutated alleles (Allele-specific PCR). RESULTS: The affected allele was identified in 39 (78%) of the 50 chromosomes of the 25 patients. The higher frequency affected the ASIn2 in 26% of cases, followed by mutations Arg357Trp in 22% of cases and Gln319Stop in 12% and deletion in 12%. The identification of two affected alleles in a same patient was achieved in 17 cases (68%). The most frequent genotypes were homozygosity for ASIn2 (16%), homozygosity for Arg357Trp (12%) and the homozygote deletion of the gene in 12%. CONCLUSION: The most frequent mechanisms of genetic damage in this population of patients with salt wasting congenital adrenal hyperplasia due to deficiency of 21-hydroxylase were the mutations ASIn2 and Arg357Trp. This type of studies allows prenatal diagnosis and genetic counseling.     

Identification of two novel mutations in the ventricular regulatory myosin light chain gene (MYL2) associated with familial and classical forms of hypertrophic cardiomyopathy

Five disease genes encoding sarcomeric proteins and associated with familial and classical forms of hypertrophic cardiomyopathy have been determined since 1989. In 1996 two other genes encoding ventricular regulatory and essential myosin light chains were shown to be associated with a particular phenotype of the disease characterized by mid left ventricular obstruction. The aim of the present study was to search for mutations in the ventricular regulatory myosin light chain gene (MYL2), located on chromosome 12q23q24.3, in a panel of 42 probands presenting a classical phenotype of familial hypertrophic cardiomyopathy. Single-strand conformation polymorphism analysis was used to search for mutations in the coding segments of the MYL2 gene, and the abnormal products were sequenced. Two novel missense mutations, Phe18Leu in exon 2 and Arg58Gln in exon 4 were identified in three unrelated families. None of the affected patients had hypertrophy localized only at the level of the papillary muscle with mid left ventricular obstruction. By analysis of genetic recombinations, one of these mutations identified in a large family allowed us to refine the localization of the MYL2 gene on the genetic map, in an interval of 6 cM containing six informative microsatellite markers. In conclusion, we show that mutations in the MYL2 gene may be involved in familial and classical forms of hypertrophic cardiomyopathy, and we provide new tools for the genetic analysis of patients with familial hypertrophic cardiomyopathy.     

Oligomerization properties of ERp29, an endoplasmic reticulum stress protein

Leber's congenital amaurosis (LCA) is the earliest and most severe of all inherited retinal dystrophies. Recently, we mapped an LCA gene to chromosome 17p13.1 (LCA1) and ascribed the disease to mutations of the retinal guanylate cyclase (ret GC) gene in a subset of families of North African ancestry. Owing to the genetic heterogeneity of LCA and considering that LCA1 results from an impaired production of cGMP in the retina (with permanent closure of cGMP-gated cation channels), we hypothesized that the activation of the cGMP phosphodiesterase (PDE) could trigger the disease by lowering the intracellular cGMP level in the retina. The rod and cone cGMP-PDE inhibitory subunits were regarded therefore as candidate genes in LCA. Here, we report the exclusion of five rod and cone cGMP-PDE subunits in LCA families unlinked to chromosome 17p13.     

His1069Gln and six novel Wilson disease mutations: analysis of relevance for early diagnosis and phenotype

In the present study we examined 33 German and 10 Cuban unrelated Wilson disease (WND) index patients and their relatives. The common His1069Gln mutation accounted for 42% of all WND chromosomes in the German series and the haplotype C was found to be highly predictive for this mutation. Six WND gene mutations have not been described previously and involved a splice site at intron 18 (3903 + del1G), a termination codon in the copper-binding region of exon 2 (Cys271X), and missense mutations in transmembrane region 2 (Gly710Ala), in transmembrane region 3 (Tyr741Cys), in the DKTGT motif (Thr1031Ile) and in the ATP loop region (Gly1176Arg). In 15 German WND index patients and three sibs both WND mutations could be determined and a genotype-phenotype correlation was attempted. Patients homozygous for the His1069Gln mutation showed almost the complete range of clinical presentations, and thus in our study this mutation is not associated with a late, neurological presentation.     

Role of the beta 3-adrenergic receptor locus in obesity and noninsulin-dependent diabetes among members of Caucasian families with a diabetic sibling pair

Obesity and insulin resistance are important risk factors for the development of noninsulin-dependent diabetes (NIDDM) and are prevalent among predisposed first degree relatives of diabetic individuals. Recent molecular screening and analysis of a common missense mutation of the beta 3-adrenergic receptor gene suggested this locus as a strong candidate for increased obesity, earlier age of diabetes onset, and insulin resistance. To test the hypothesis that the beta 3-adrenergic receptor locus affects diabetes susceptibility, obesity as measured by body mass index, and components of the insulin resistance syndrome, we examined the role of this region in families ascertained for two or more NIDDM siblings. Linkage analysis was conducted using both parametric and nonparametric analyses, including multipoint sibling pair analysis. We found no evidence for linkage to NIDDM as a dichotomous trait and no evidence for linkage to body mass index, waist/hip ratio, insulin levels, or glucose levels as quantitative traits or to reported age of onset among NIDDM individuals. The Trp64 Arg missense mutation was present in 11% of the population. The mutation was not associated with NIDDM, and Arg64 carriers did not have earlier NIDDM onset, higher body mass index, or higher waist/hip ratio than Trp64 homozygotes. Among relatives, Arg64 carriers had significantly lower fasting glucose levels and lower waist/hip ratios than Trp64 homozygotes, but no characteristics of the insulin resistance syndrome. We conclude that the beta 3-adrenergic receptor locus does not play an important role in NIDDM susceptibility or in the insulin resistance syndrome among members of families with a strong predisposition to NIDDM.     

Mutations in a novel gene, VMD2, encoding a protein of unknown properties cause juvenile-onset vitelliform macular dystrophy (Best's disease)

Vitelliform macular dystrophy (Best's disease) is an autosomal dominant, early-onset form of macular degeneration in which the primary defect is thought to occur at the level of the retinal pigment epithelium. Genetic linkage has mapped the disease locus to chromosome 11q12-q13.1 within a 980 kb interval flanked by markers at loci D11S4076 and uteroglobin. To identify the disease gene, we systematically characterized genes from within the critical region and analysed the coding regions for mutations in 12 patients from large multigeneration Best's disease families. Following this approach, we identified a novel gene of unknown function carrying heterozygous mutations in all 12 probands. Of these, 10 result in distinct missense mutations of amino acids that are highly conserved throughout evolution, spanning a phylogenetic distance from Caenorhabditis elegans to human, and include V9M, A10T, W24C, R25Q, R218Q, Y227N, Y227C, V235M, P297A and F305S. One deletion mutation, DeltaI295, was found in two families and segregates with the disease in both cases. Northern blot analysis reveals tissue-specific expression for this gene, exclusively in the retinal pigment epithelium. In conclusion, our data provide strong evidence that mutations in the gene that we have identified cause Best's disease.     

Wiskott-Aldrich syndrome/X-linked thrombocytopenia: WASP gene mutations, protein expression, and phenotype

Wiskott-Aldrich syndrome (WAS) and X-linked thrombocytopenia (XLT), caused by mutations of the WAS protein (WASP) gene, represent different phenotypes of the same disease. To demonstrate a phenotype/genotype correlation, we determined WASP gene mutations in 48 unrelated WAS families. Mutations included missense (20 families) and nonsense (eight) mutations located mostly in exons 1 to 4, and splice-site mutations (seven) and deletions and insertions (13) located preferentially in exons 7 to 11. Both genomic DNA and cDNA were sequenced and WASP expression was measured in cell lysates using peptide-specific rabbit anti-WASP antibodies. WASP was expressed in hematopoietic cell lines including bone marrow-derived CD34+ cells. Missense mutations located in exons 1 to 3 caused mild disease in all but one family and permitted WASP expression, although frequently at decreased concentration. Missense mutations affecting exon 4 were associated with classic WAS and, with one exception, barely detectable WASP. Nonsense mutations caused classic WAS and lack of protein. Insertions, deletions, and splice-site mutations resulted in classic WAS and absent, unstable, truncated, or multiply spliced protein. Using affinity precipitation, WASP was found to bind to Src SH3-containing proteins Fyn, Lck, PLC-gamma, and Grb2, and mutated WASP, if expressed, was able to bind to Fyn-glutathione S-transferase (GST) fusion protein. We conclude that missense mutations affecting the PH domain (exons 1 to 3) of WASP inhibit less important functions of the protein and result in a mild phenotype, and that missense mutations affecting exon 4 and complex mutations affecting the 3' portion of WASP interfere with crucial functions of the protein and cause classic WAS.     

KVLQT1 C-terminal missense mutation causes a forme fruste long-QT syndrome

BACKGROUND: KVLQT1, the gene encoding the alpha-subunit of a cardiac potassium channel, is the most common cause of the dominant form of long-QT syndrome (LQT1-type), the Romano-Ward syndrome (RWS). The overall phenotype of RWS is characterized by a prolonged QT interval on the ECG and cardiac ventricular arrhythmias leading to recurrent syncopes and sudden death. However, there is considerable variability in the clinical presentation, and potential severity is often difficult to evaluate. To analyze the relationship between phenotypes and underlying defects in KVLQT1, we investigated mutations in this gene in 20 RWS families originating from France. METHODS AND RESULTS: By PCR-SSCP analysis, 16 missense mutations were identified in KVLQT1, 11 of them being novel. Fifteen mutations, localized in the transmembrane domains S2-S3, S4-S5, P, and S6, were associated with a high percentage of symptomatic carriers (55 of 95, or 58%) and sudden deaths (23 of 95, or 24%). In contrast, a missense mutation, Arg555Cys, identified in the C-terminal domain in 3 families, was associated with a significantly less pronounced QT prolongation (459+/-33 ms, n=41, versus 480+/-32 ms, n=70, P=.0012), and significantly lower percentages of symptomatic carriers (7 of 44, or 16%, P<.001) and sudden deaths (2 of 44, or 5%, P<.01). Most of the cardiac events occurring in these 3 families were triggered by drugs known to affect ventricular repolarization. CONCLUSIONS: Our data show a wide KVLQT1 allelic heterogeneity among 20 families in which KVLQT1 causes RWS. We describe the first missense mutation in the C-terminal domain of KVLQT1, which is clearly associated with a fruste phenotype, which could be a favoring factor of acquired LQT syndrome.     

Inhibition of insulin release by intraduodenally infused enterostatin-VPDPR in rats

BACKGROUND: Retinopathy of prematurity (ROP) is a retinal vascular disease occurring in infants with short gestational age and low birth weight and can lead to retinal detachment (ROP stages 4 and 5). X-linked familial exudative vitreoretinopathy is phenotypically similar to ROP and has been associated with mutations in the Norrie disease (ND) gene in some cases. OBJECTIVE: To determine if similar mutations in the ND gene may play a role in the development of advanced ROP. METHODS: Clinical examination and molecular genetic analysis were performed on 16 children, including 2 dizygotic and 1 monozygotic twin pairs, and their parents from 13 families. RESULTS: Sequencing of the amplified products revealed missense mutations (R121W and L108P) in the third exon of the ND gene in 4 patients. These mutations were not present in an unaffected premature twin, 2 children with regressed stage 3 ROP, the parents, or in 50 unrelated healthy control subjects. CONCLUSION: These findings suggest that mutations in the ND gene may play a role in the development of severe ROP in premature infants.     

No association between the Gly971Arg variant of the insulin receptor substrate 1 gene and NIDDM in the Taiwanese population

OBJECTIVE: To study the role of the Gly971Arg variant of the insulin receptor substrate 1 (IRS-1) gene in the development of NIDDM in the Chinese population living in Taiwan. RESEARCH DESIGN AND METHODS: A total of 82 unrelated normal control subjects, 89 subjects with NIDDM, and 23 multiplex families were recruited in Taiwan. All of them were Han Chinese. Pedigree members without a history of diabetes were studies by the standard 75-g oral glucose tolerance test. Detection of the Gly971Arg variant of the IRS-1 gene was performed by polymerase chain reaction and restriction fragment-length polymorphism analysis. RESULTS: The frequency of Gly971Arg variant of the IRS-1 gene in the normal population was 1.2% which was lower than frequencies reported in white populations. The prevalence of the Gly971Arg variant was not significantly increased in both the nonselected NIDDM population (1.1%) and the probands of the multiplex families (4.3%). More importantly, the Gly971Arg variant of the IRS-1 gene did not cosegregate with BMI and NIDDM in these families, CONCLUSIONS: The Gly971Arg variant of the IRS-1 gene is an infrequent normal allele among Taiwanese. This variant is neither associated nor cosegregated with NIDDM in the Taiwanese population and families. Gly971Arg of IRS-1 gene does not play an important role in the development of NIDDM in this population.     

Duplication of the proteolipid protein gene is the major cause of Pelizaeus-Merzbacher disease

BACKGROUND/OBJECTIVE: Pelizaeus-Merzbacher disease (PMD), an X-linked recessive dysmyelination disorder, is caused by mutations in the proteolipid protein (PLP) gene. However, missense mutations were only found in a fraction of PMD patients, even in families that showed linkage with the PLP locus on Xq22. Here we describe the use of an extended protocol that includes screening for both missense mutations and duplications. METHOD: Two groups of patients were analyzed, one group with 10 independent PMD families and one group with 24 sporadic patients suspected of PMD. Missense mutations in the PLP gene were identified by sequencing. PLP gene duplications were detected by quantitative polymerase chain reaction and/or Southern blot analysis. RESULTS: Sequencing of the PLP gene revealed four mutations in group 1 and one mutation in group 2. However, inclusion of duplication analysis in the screening protocol raised the amount of mutations found in group 1 from 40 to 90%, and in group 2 from 4 to 25%. CONCLUSIONS: These results demonstrate that duplications of the PLP gene are the major cause of PMD. Furthermore, it appears that the phenotype resulting from PLP duplications is relatively mild, and that many probands are nontypical PMD patients.