Identification of compound heterozygous mutations (G188E/W382X) of lipoprotein lipase gene in a Japanese infant with hyperchylomicronemia: the G188E mutation was newly identified in Japanese.

We herein report a case of a 5-month-old Japanese female (patient AN) with fasting hyperchylomicronemia due to a primary lipoprotein lipase (LPL) deficiency. Patient AN was compound heterozygous for a missense mutation (GG818G-->GAG/Gly188-->Glu; G188E) in exon 5 and a nonsense mutation (TGG1401-->TGA/Trp382-->Stop; W382X) in exon 8 of the LPL gene. This resulted in less than 10% of the control levels for both the LPL activity and immunoreactive LPL mass in the postheparin plasma. A G188E mutation was thus identified for the first time in a Japanese, and the haplotype of this G188E allele was different from that of the G188E alleles identified in other ethnic groups. This additional mutation might be useful for early diagnosis of LPL gene aberrations in Japanese patients with fasting hyperchylomicronemia.     

A 60-y-old chylomicronemia patient homozygous for missense mutation (G188E) in the lipoprotein lipase gene showed no accelerated atherosclerosis

BACKGROUND: Familial lipoprotein lipase (LPL) deficiency is a rare autosomal recessive disorder caused by mutations in the LPL gene. Patients with LPL deficiency have chylomicronemia; however, whether they develop accelerated atherosclerosis remains unclear. METHODS: We investigated clinical and mutational characteristics of a 60-y-old Japanese patient with chylomicronemia. RESULTS: The patient's fasting plasma triglyceride levels were >9.0 mmol/l. In postheparin plasma, one fifth of the normal LPL protein mass was present; however, LPL activity was undetectable. Molecular analysis of the LPL gene showed the patient to be a homozygote of missense mutation replacing glycine with glutamine at codon 188 (G188E), which had been known to produce mutant LPL protein lacking lipolytic activity. Ultrasonographic examination of the patient's carotid and femoral arteries showed no accelerated atherosclerosis. Moreover, 64-slice mechanical multidetector-row computer tomography (MDCT) angiography did not detect any accelerated atherosclerotic lesions in the patient's coronary arteries. The patient had none of the risk factors such as smoking, hypertension, and diabetes. CONCLUSIONS: Our case suggests that accelerated atherosclerosis may not develop in patients with LPL deficiency, when they have no risk factors.     

Missense mutation W86R in exon 3 of the lipoprotein lipase gene in a boy with chylomicronemia

BACKGROUND: Familial LPL deficiency is a rare inborn error of metabolism caused by mutational change within the LPL gene, which leads to massive hypertriglyceridemia. METHODS: The underlying molecular defect in a boy of Croatian descent was studied by SSCP analysis, DNA sequencing and finally confirmed by RFLP. RESULTS: DNA analysis showed the child to be a homozygote and his parents heterozygotes for TGG-->CGG change in codon 86 of the LPL gene, which leads to W86R amino acid substitution. DNA sequence analysis also showed a silent mutation in the third exon of father's DNA, V108V. Determination of some LPL gene polymorphisms showed the child and his parents to have HindIII/H+H+ and both S447 wild-type alleles, whereas for PvuII the parents had P(+)P- and the child P(+)P+ genotype. CONCLUSIONS: In this case, W86R mutation was the reason for the production of nonfunctional enzyme and consequently triacylglycerol (TG) exceeding 15 mmol/l. This implies the risk of frequent episodes of acute pancreatitis. Decreased LPL activity leads to elevated triacylglycerol levels and reduced HDL-cholesterol, both risk factors for the development of coronary artery disease. LPL genotyping especially of young patients with hypertriglyceridemia is therefore necessary and justifiable.     

高HDL-C个体CETP基因15外显子错义突变(442D∶G)的检测及临床意义

目的证实胆固醇酯转移蛋白(CETP)基因15外显子错义突变(442D∶G)是导致高α脂蛋白血症的重要因素之一.方法建立检测CETP基因15外显子错义突变(442D∶G)的聚合酶链反应-限制性内切酶酶切片断长度多态性分析(PCR-RFLP)方法,检测50例高α脂蛋白血症(HDL-C≥1.7 mmol/L)个体CETP基因15外显子442D∶G错义突变的阳性率.结果 50例高α脂蛋白血症患者中,发现杂合子15例,纯合子1例;对照组70例,仅1例杂合子,差异有显著性(u<0.05).结论 CETP基因15外显子错义突变是导致高密度脂蛋白胆固醇(HDL-C)的重要因素之一.     

Familial chylomicronemia (type I hyperlipoproteinemia) due to a single missense mutation in the lipoprotein lipase gene.

Complete deficiency of lipoprotein lipase (LPL) causes the chylomicronemia syndrome. To understand the molecular basis of LPL deficiency, two siblings with drastically reduced postheparin plasma lipolytic activities were selected for analysis of their LPL gene. We used the polymerase chain reaction to examine the nine coding LPL exons in the two affected siblings and three relatives. DNA sequence analysis revealed a single nucleotide change compared with the normal LPL cDNA: a G----A substitution at nucleotide position 680. This transition caused a replacement of glutamic acid for glycine at amino acid residue 142 of the mature LPL protein. Amino acid sequence comparisons of the region surrounding glycine-142 indicated that it is highly conserved among lipases from different species, suggesting a crucial role of this domain for the LPL structure. Expression studies of the mutant LPL cDNA in COS-7 cells produced normal amounts of enzyme mass. However, the mutated LPL was not catalytically active, nor was it efficiently secreted from the cells. This established that the Gly----Glu substitution at amino acid 142 is sufficient to abolish enzymatic activity and to result in the chylomicronemia syndrome observed in these patients.     

A novel missense mutation C127R (FH Zagreb) in the LDL-receptor gene.

We employed the analysis of single-strand conformation polymorphisms to identify mutations in exon 4 of the low density lipoprotein receptor gene causing familial hypercholesterolemia. Three familial hypercholesterolemia heterozygotes had abnormal single-strand conformation polymorphism patterns. DNA sequencing revealed that the abnormal pattern of exon 4A was due to heterozygosity (T/C) at nucleotide 442. Nucleotide 442 is the first base of codon 127, and the T-->C mutation (C127R) changes this codon from CysTGT to ArgCGT. Abnormal patterns of exon 4B were due to heterozygosity (A/G) at nucleotide 662: nucleotide 662 is the second base of codon 200, and the A-->G mutation (D200G) changes this codon from AspGAC to GlyGGC. Mutation D200G was previously described as FH Padova, but mutation C127R (FH Zagreb) has not been reported previously. This novel mutation was confirmed by restriction endonuclease analysis with Dsa I. The screening of 420 familial hypercholesterolemia heterozygotes suggests that C127R and D200G account for about 0.7% of mutations causing familial hypercholesterolemia in Croatia.     

A novel frameshift mutation in exon 6 (the site of Asn 291) of the lipoprotein lipase gene in type I hyperlipidemia.

A new heterozygous lipoprotein lipase gene defect has been identified in a type I hyperlipidemic patient at the position of notable amino acid Asn 291. The patient is a 33-year-old male. His body mass index (BMI) was 18.5 kg/m2. The total cholesterol (TC), triglycerides (TG) and high density lipoprotein-cholesterol (HDL-C) concentration from his fasting plasma were 4.8, 11.9 and 0.4 mmol/l, respectively. The lipoprotein lipase (LPL) activity and mass in the postheparin plasma (PHP) from the patient were 0.58 mmol/ml/h (normal range: 7.7+/-2.6) and 244 ng/ml (normal range: 192+/-30), respectively. The hepatic lipase activity of the PHP from the patient was 10.6 mmol/ml/h (normal range: 9.9+/-3.6). DNA analysis of the LPL gene revealed that this patient had a heterozygous one nucleotide deletion of A coding Asn 291, resulting in a premature termination of the LPL protein at amino acid residue 303. The other abnormality in the LPL gene of the proband was an amino acid residue 194 defect (Ile194-->Thr), which is known to cause a defective enzyme. A medium-chain triglyceride (MCT) loading test was conducted to find how this triglyceride affects plasma lipoprotein metabolism in this patient in a short term (Fig. 3). The plasma total cholesterol (TC) or high density lipoprotein (HDL)-C levels did not change significantly after oral administration of a fatty meal containing long chain triglycerides (LCT) or MCT. The plasma TG level, on the other hand, increased from 11.9 to 19.2 mmol/l (+61%) at 6 h after loading a fatty meal containing LCT, whereas the plasma TG levels tended to even decrease at 6 h after oral administration of an MCT, tricaprin (from 11.6 to 10.5 mmol/l (-9.4%)). These results suggest that MCT, as opposed to LCT, is useful for treatment of type I hyperlipidemia with a novel mutation at the notable amino acid Asn 291 of the LPL gene.     

A novel missense mutation (Asn5→Ile) in lecithin: cholesterol acyltransferase (LCAT) gene in a Japanese patient with LCAT deficiency

We identified a novel missense mutation in the lecithin: cholesterol acyltransferase gene in a new case of lecithin:cholesterol acyltransferase (LCAT) deficiency. The patient was a 64-year-old diabetic Japanese male who showed an extremely low level of serum high-density lipoprotein-cholesterol, corneal opacities, anemia, and proteinuria. Both the patient's LCAT activity and mass were markedly low. DNA sequence analysis of the LCAT gene showed an A-to-T transition at base 97 in exon 1, and predicted a change in asparagine to isoleucine at the 5th amino acid of the protein. Restriction analysis of polymerase chain reaction-amplified DNA usingAse I showed that the patient was homozygous for this mutation. Our results suggested that asparagine 5 was an important amino acid and substitution with isoleucine caused marked reduction of LCAT activity and mass, resulting in LCAT deficiency.     

A novel mutation of the DHCR7 gene in a sicilian compound heterozygote with Smith-Lemli-Opitz Syndrome.

INTRODUCTION: Smith-Lemli-Opitz syndrome (SLOS) is an autosomal recessive disorder of cholesterol biosynthesis, resulting from deficient 7-dehydrocholesterol reductase (3beta-hydroxysterol Delta7-reductase) activity, the enzyme responsible for conversion of 7-dehydrocholesterol to cholesterol. SLOS is most common among people of European descent, with a reported incidence of 1 per 20,000-60,000 newborns, depending on the diagnostic criteria and the reference population. More than 80 different mutations have been identified in several hundred patients. In Italy, SLOS appears to be a rare condition, probably because of underdiagnosis. METHOD: We analyzed by direct sequencing the 7-dehydrocholesterol reductase gene (DHCR7) in a Sicilian patient with Smith-Lemli-Opitz syndrome and his parents in order to characterize the molecular defect. RESULTS: The molecular analysis of the coding exons and the intron-exon boundaries of the DHCR7 gene demonstrated the presence of two missense mutations: a novel mutation (I251N) and a known mutation (E288K) responsible in a compound heterozygous state for a severe form of SLOS. CONCLUSION: The present study describes a Sicilian patient, a carrier of a novel mutation of the DHCR7 gene (I251N), which is responsible in a compound heterozygous state for a severe form of SLOS.     

A missense mutation at codon 188 of the human lipoprotein lipase gene is a frequent cause of lipoprotein lipase deficiency in persons of different ancestries.

Lipoprotein lipase (LPL) plays a crucial role in the regulation of lipoprotein metabolism by hydrolysing the core triglycerides of circulating chylomicrons and VLDL. Human, bovine, mouse, and guinea pig complementary DNA clones have recently been isolated and the organization of the human LPL gene is now known to comprise 10 exons spanning approximately 30 kb. Here we report a similar mutation on 21 alleles from 13 unrelated affected probands with LPL deficiency of French Canadian, English, Polish, German, Dutch, and East Indian ancestry. We show that an identical missense mutation within exon 5, resulting in an amino acid substitution of glutamic acid for glycine at position 188, is responsible for LPL deficiency in 21 of 88 LPL alleles assessed. This mutation alters an Ava II restriction site in exon 5 and will allow a rapid screening test for this mutation in patients with LPL deficiency. This mutation has occurred on the same haplotype in all the unrelated affected persons suggesting a common origin. The amino acid substitution lies within the longest segment of homology for LPL in different species and results in a protein that is catalytically defective.     

Two novel alpha-galactosidase A mutations causing Fabry disease: A missense mutation M11V in a heterozygote woman and a nonsense mutation R190X in a hemizygote man

ObjectivesTo evaluate the nature of the molecular lesions in the alpha-galactosidase A gene of two patients having Fabry disease.MethodsEnzyme analyses were done using 4-methylumbellyferyl alpha-galactoside as substrate. Single stranded conformational polymorphism analysis and DNA sequencing were performed following PCR amplification of seven exons of alpha-galactosidase A gene.ResultsTwo new mutations, M11V and R190X, were identified. The female patient with M11V mutation had rheumatologic symptoms, microalbuminuria. The male patient with R190X mutation had a classical phenotype. M11V mutation is in the signal sequence of the peptide and may affect the targeting of the ribosomes to ER. R190X mutation causes premature termination, and probably leads to degradation of the protein.ConclusionThis is the first study in our country investigating the molecular aspects of Fabry disease. It provides the molecular basis for understanding the underlying mechanism of Fabry disease, allows prenatal diagnosis and provides genotype/phenotype correlations.     

Amino acid substitution (Ile194----Thr) in exon 5 of the lipoprotein lipase gene causes lipoprotein lipase deficiency in three unrelated probands. Support for a multicentric origin.

Studies on the molecular biology of lipoprotein lipase (LPL) deficiency have been facilitated by the availability of LPL gene probes and the recent characterization of gene mutations underlying human LPL deficiency. Typically, missense mutations have predominated and show a preferential localization to exons 4 and 5. This distribution supports earlier studies attributing functional significance to residues encoded by these exons. We now report a further missense mutation within exon 5 of the LPL gene in three unrelated patients. Amplification of individual exons by the polymerase chain reaction and direct sequencing revealed a T----C transition at codon 194 of the LPL cDNA which results in a substitution of threonine for isoleucine at this residue. The catalytic abnormality induced by this mutation was confirmed through in vitro mutagenesis studies in COS-1 cells. Transfection with a LPL cDNA containing the codon 194 transition resulted in the synthesis and secretion of a catalytically defective protein. The Thr194 substitution was associated with two different DNA haplotypes, consistent with a multicentric origin for this mutation.     

胆固醇酯转运蛋白基因15外显子D442G突变的检测

应用聚合酶链反应-限制性片段长度多态性分析(PCR-RFLP) 的方法检测110例脑动脉粥样硬化患者胆固醇酯转运蛋白(CETP)基因15外显子D442G错义突变.首先用聚合酶链反应特异性扩增包含人CETP基因15外显子第1506位碱基的基因序列,扩增产物用限制性内切酶MspⅠ酶切,聚丙烯酰胺凝胶电泳后分析结果.110例脑动脉粥样硬化患者中发现4例杂合突变,突变率3.6%,与对照组4%比较无明显差异.该方法简单、快速、准确,适合于一般实验室开展及大规模人群调查.     

A novel mutation in exon 5 of the ALAS2 gene results in X-linked sideroblastic anemia

BACKGROUND: Mutations in the erythroid-specific 5-aminolevulinate-synthase gene (ALAS2) have been identified in many cases of X-linked sideroblastic anemia (XLSA). METHODS: A polymerase chain reaction-mediated restriction fragment length polymorphism (RFLP) assay was used. RESULTS: A G527T point mutation was identified. This resulted in a substitution of tyrosine for asparagine at residue 159 (D159Y). This mutation was also identified in the mother of the two probands. Mutations in all three individuals were confirmed by DNA sequencing analysis. CONCLUSIONS: We identified a missense mutation in exon 5 of the ALAS2 gene in two brothers of a consanguineous marriage, who were clinically pyridoxine-responsive.     

CETP gene mutation (D442G) increases low-density lipoprotein particle size in patients with coronary heart disease

BACKGROUND: Small, dense low-density lipoprotein (LDL) in subjects with the atherogenic pattern B has been established as a risk factor of atherosclerosis. Cholesteryl ester transfer protein (CETP) plays an important role in the transfer and exchange of cholesteryl esters and triglycerides between the lipoprotein classes of human plasma. It has been shown that CETP can also change the particle size of high-density lipoprotein (HDL) and LDL subfractions in vitro. Previous clinical studies about CETP gene mutations mainly focused on abnormalities in HDL, few involved those in LDL. OBJECTIVES: To investigate the effect of the D442G mutation in the CETP gene on major peak size of LDL particles in patients with coronary heart diseases (CHD). METHODS: D442G mutation in the CETP gene was detected using the PCR-RFLP. LDL particles sizes were analyzed by 2-16% nondenaturing polyacrylamide gradient gels in CHD patients with D442G mutation in the CETP gene. RESULTS: Six heterozygotes and one homozygote were found to have the D442G mutation among 200 CHD patients. The frequency of this mutation was 3.5%. The major peak size of LDL in patients with gene mutation (n=7) was significantly larger than that in patients without the mutation (n=40) (26.92 +/- 0.79 nm vs. 25.71 +/- 0.66 nm, respectively; P<0.01). All the patients with the gene mutation expressed pattern A, whereas only about half of the patients without the mutation expressed this pattern. The patients with gene mutation had decreased plasma CETP concentration, while increased concentration of HDL-C and apolipoprotein A-I compared with controls. CONCLUSIONS: CETP gene mutation (D442G) increases LDL particle size. This suggests that CETP play an antiatherogenic role.     

A novel mutation of the ceruloplasmin gene in a patient with heteroallelic ceruloplasmin gene mutation (HypoCPGM)

We found a novel missense mutation in the ceruloplasmin (Cp) gene in a patient with the heteroallelic Cp gene mutation (HypoCPGM). The patient was a 72-year-old woman who came to our hospital with a 1-year history of postural tremor of the hands. The diagnosis was made based on serum Cp and copper readings which were about half the normal levels, as well as MRI tests of her brain which showed characteristics for hereditary ceruloplasmin deficiency (HCD), known to be caused by the homoallelic Cp gene mutation. Polymerase chain reaction (PCR)-direct sequencing analysis of the Cp gene of the patient revealed a novel point mutation, A to T, at nucleotide position 82 in Exon 1. This mutation changes the Ile28 codon (ATT) to a Phe codon (TTT) (missense mutation). PCR-restriction analysis with restriction enzyme Tsp EI for the mutation revealed that both the patient and her son were heterozygotes for the mutation.