A novel molecular mechanism to explain biotin-unresponsive holocarboxylase synthetase deficiency

Biotin (vitamins H and B7) is an important micronutrient as defects in its availability, metabolism or adsorption can cause serious illnesses, especially in the young. A key molecule in the biotin cycle is holocarboxylase synthetase (HLCS), which attaches biotin onto the biotin-dependent enzymes. Patients with congenital HLCS deficiency are prescribed oral biotin supplements that, in most cases, reverse the clinical symptoms. However, some patients respond poorly to biotin therapy and have an extremely poor long-term prognosis. Whilst a small number of mutations in the HLCS gene have been implicated, the molecular mechanisms that lead to the biotin-unresponsive phenotype are not understood. To improve our understanding of HLCS, limited proteolysis was performed together with yeast two-hybrid analysis. A structured domain within the N-terminal region that contained two missense mutations was identified in patients who were refractory to biotin therapy, namely p.L216R and p.L237P. Genetic studies demonstrated that the interaction between the enzyme and the protein substrate was disrupted by mutation. Further dissection of the binding mechanism using surface plasmon resonance demonstrated that the mutations reduced affinity for the substrate through a >15-fold increase in dissociation rate. Together, these data provide the first molecular explanation for HLCS-deficient patients that do not respond to biotin therapy.     

Reduced half-life of holocarboxylase synthetase from patients with severe multiple carboxylase deficiency

Multiple carboxylase deficiency is a clinical condition caused by defects in the enzymes involved in biotin metabolism, holocarboxylase synthetase (HLCS) or biotinidase. HLCS deficiency is a potentially fatal condition if left untreated, although the majority of patients respond to oral supplementation of 10-20 mg/day of biotin. Patients who display incomplete responsiveness to this therapy have a poor long-term prognosis. Here we investigated cell lines from two such HLCS-deficient patients homozygous for the c.647T>G p.L216R allele. Growth of the patients' fibroblasts was compromised compared with normal fibroblasts. Also the patient cells were not sensitive to biotin-depletion from the media, and growth rates could not be restored by re-administration of biotin. The molecular basis for the HLCS deficiency was further investigated by characterisation of the p.L216R protein. The HLCS mRNA was detected in MCD and normal cell lines. However, protein and enzyme activity could not be detected in the patients' cells. In vitro kinetic analysis revealed that enzyme activity was severely compromised for recombinantly expressed p.L216R and could not be increased by additional biotin. Furthermore, the turn-over rate for the mutant protein was double that of wildtype HLCS. These results help provide a molecular explanation for the incomplete biotin-responsiveness of this p.L216R form of HLCS.     

Effects of single-nucleotide polymorphisms in the human holocarboxylase synthetase gene on enzyme catalysis

Holocarboxylase synthetase (HLCS) is a biotin protein ligase, which has a pivotal role in biotin-dependent metabolic pathways and epigenetic phenomena in humans. Knockdown of HLCS produces phenotypes such as heat susceptibility and decreased life span in Drosophila melanogaster, whereas knockout of HLCS appears to be embryonic lethal. HLCS comprises 726 amino acids in four domains. More than 2500 single-nucleotide polymorphisms (SNPs) have been identified in human HLCS. Here, we tested the hypotheses that HLCS SNPs impair enzyme activity, and that biotin supplementation restores the activities of HLCS variants to wild-type levels. We used an in silico approach to identify five SNPs that alter the amino acid sequence in the N-terminal, central, and C-terminal domains in human HLCS. Recombinant HLCS was used for enzyme kinetics analyses of HLCS variants, wild-type HLCS, and the L216R mutant, which has a biotin ligase activity near zero. The biotin affinity of variant Q699R is lower than that of the wild-type control, but the maximal activity was restored to that of wild-type HLCS when assay mixtures were supplemented with biotin. In contrast, the biotin affinities of HLCS variants V96F and G510R are not significantly different from the wild-type control, but their maximal activities remained moderately lower than that of wild-type HLCS even when assay mixtures were supplemented with biotin. The V96 L SNP did not alter enzyme kinetics. Our findings suggest that individuals with HLCS SNPs may benefit from supplemental biotin, yet to different extents depending on the genotype.     

Mutations in the holocarboxylase synthetase gene HLCS

Holocarboxylase synthetase (HLCS) deficiency is an autosomal recessive disorder. HLCS is an enzyme that catalyzes biotin incorporation into carboxylases and histones. Since the first report of the cDNA sequence, 30 mutations in the HLCS gene have been reported. Mutations occur throughout the entire coding region except exons 6 and 10. The types of mutations are one single amino acid deletion, five single nucleotide insertions/deletions, 22 missense mutations, and two nonsense mutations. The only intronic mutation identified thus far is c.1519+5G>A (also designated IVS10+5G>A), which causes a splice error. Several lines of evidence suggest that c.1519+5G>A is a founder mutation in Scandinavian patients. Prevalence of this mutation is about 10 times higher in the Faroe Islands than in the rest of the world. The mutations p.L237P and c.780delG are predominant only in Japanese patients. These are probably founder mutations in this population. Mutations p.R508W and p.V550M are identified in several ethic groups and accompanied with various haplotypes, suggesting that these are recurrent mutations. There is a good relationship between clinical biotin responsiveness and the residual activity of HLCS. A combination of a null mutation and a point mutation that shows less than a few percent of the normal activity results in neonatal onset. Patients who have mutant HLCS with higher residual activity develop symptom after the neonatal period and show a good clinical response to biotin therapy.     

Holocarboxylase synthetase deficiency: novel clinical and molecular findings

Tammachote R, Janklat S, Tongkobpetch S, Suphapeetiporn K and Shotelersuk V. Holocarboxylase synthetase deficiency: novel clinical and molecular findings. Multiple carboxylase deficiency (MCD) is an autosomal recessive metabolic disorder caused by defective activity of biotinidase or holocarboxylase synthetase (HLCS) in the biotin cycle. Clinical symptoms include skin lesions and severe metabolic acidosis. Here, we reported four unrelated Thai patients with MCD, diagnosed by urine organic acid analysis. Unlike Caucasians, which biotinidase deficiency has been found to be more common, all of our four Thai patients were affected by HLCS deficiency. Instead of the generally recommended high dose of biotin, our patients were given biotin at 1.2 mg/day. This low‐dose biotin significantly improved their clinical symptoms and stabilized the metabolic state on long‐term follow‐up. Mutation analysis by polymerase chain reaction‐sequencing of the entire coding region of the HLCS gene revealed the c.1522C>T (p.R508W) mutation in six of the eight mutant alleles. This suggests it as the most common mutation in the Thai population, which paves the way for a rapid and unsophisticated diagnostic method for the ethnic Thai. Haplotype analysis revealed that the c.1522C>T was on three different haplotypes suggesting that it was recurrent, not caused by a founder effect. In addition, a novel mutation, c.1513G>C (p.G505R), was identified, expanding the mutational spectrum of this gene.     

Clustering of mutations in the biotin-binding region of holocarboxylase synthetase in biotin-responsive multiple carboxylase deficiency

Holocarboxylase synthetase (HCS) catalyses the biotinylation of the four biotin-dependent carboxylases found in humans. A deficiency in HCS results in biotin-responsive multiple carboxylase deficiency (MCD). We have identified six different point mutations in the HCS gene in nine patients with MCD. Two of the mutations are frequent among the MCD patients analyzed. Four of the mutations cluster in the putative biotin- binding domain as deduced from the corresponding Escherichia coli enzyme and consistent with an explanation for biotin-responsiveness based on altered affinity for biotin. The two others may define an additional domain involved in biotin-binding or biotin-mediated stabilization of the protein.      

12例多种羧化酶缺乏症的基因突变分析

目的 旨在从基因水平证实多种羧化酶缺乏症(multiple carboxylase deficiency,MCD)的诊断,探讨我国MCD患儿的基因突变情况.方法 12例MCD患儿接受基因诊断.采用PCR及直接测序法分别对4例生物素酶(biotinidase,BT)缺乏症和8例全羧化酶合成酶(holocarboxylase synthetas,HLCS)缺乏症进行BT基因和HLCS基因突变分析,对基因新突变通过限制性片段长度多态性分析及患儿父母和50名正常对照者基因检测以证实.结果 12例患儿基因突变检出率100%.4例BT缺乏症中发现BT基因突变6种:c.98-104del7ins3,c.1369G>A(V457M),c.1157G>A(W386X),c.1284C>A(Y428X),c.1384delA,c.1493_1494insT,后4种为新突变.8例HLCS缺乏症中发现HLCS基因突变4种:c.126G>T(E42D),c.1994G>C(R665P),c.1088T>A(V363D),c.1522C>T(R508W),后两种为热点突变[75%(12/16)],c.1994G>C为新突变.结论 本研究从基因水平上证实了12例MCD的诊断.共发现了6种BT基因突变,4种HLCS基因突变,其中5种为新突变;得出2种HLCS基因的热点突变.     

Characterization of six novel mutations in the methylenetetrahydrofolate reductase (MTHFR) gene in patients with homocystinuria

Severe deficiency of methylenetetrahydrofolate reductase (MTHFR) is the most common inborn error of folate metabolism. Patients are characterized by severe hyperhomocysteinemia, homocystinuria and a variety of neurological and vascular problems. Eighteen rare mutations have been reported in this group of patients. Two polymorphisms which cause mild enzyme deficiencies have been described (677C-->T and 1298A-->C). The first sequence change encodes a thermolabile enzyme and is associated with mild hyperhomocysteinemia. Six novel point mutations are described in patients with severe deficiency of MTHFR, along with their associated polymorphisms and clinical phenotypes. Of the two nonsense mutations (1762A-->T, 1134C-->G) and four missense mutations (1727C-->T, 1172G-->A, 1768G-->A, and 358G-->A), one was identified in the N-terminal catalytic domain, while the others were located in the regulatory C-terminal region. All four residues affected by missense mutations are conserved in one or more MTHFRs of other species. This report brings the total to 24 mutations identified in severe MTHFR deficiency, with two mutations identified in each of 22 patients.     

Mechanism of biotin responsiveness in biotin-responsive multiple carboxylase deficiency

Holocarboxylase synthetase (HCS) catalyses the biotinylation of the four biotin-dependent carboxylases found in humans. A deficiency in HCS results in biotin-responsive multiple carboxylase deficiency. We have evaluated the biotin responsiveness associated with six missense mutations previously identified in affected patients by expression of plasmids containing the mutated HCS in an Escherichia coli strain mutated in the corresponding BirA gene. We demonstrate that the mutations identified in the MCD patients are indeed responsible for their reduced HCS activity. Four of the mutations, clustering in the putative biotin binding domain as deduced from the structure of the E. coli enzyme, are consistent with an explanation for biotin responsiveness based on altered affinity for biotin. The remaining mutations, located outside the biotin binding region, were associated with a more limited biotin responsiveness that may be explained by the degree of residual enzyme activity present. The data suggest that the concentration of circulating biotin is as low as 100 times below the Km of the enzyme, so that any increase in biotin concentration through dietary supplementation would result in saturation of the available mutant enzyme. We suggest that these alternative explanations are sufficient to account for the apparent universality of biotin responsiveness in biotin responsive multiple carboxylase deficiency.     

Identification of two novel and four uncommon missense mutations among Chinese Gaucher disease patients

Gaucher disease is the most prevalent lysosomal storage disease. It is panethnic and results from an inherited deficiency of glucocerebrosidase. Most mutations to date have been identified among Jewish and non-Jewish Caucasian patients; mutations in Chinese patients are largely unknown. We have performed nucleotide sequence analysis of PCR-amplified glucocerebrosidase genomic DNA from five unrelated Chinese patients affected with type 1 (non-neuropathic) Gaucher disease. A novel heterozygous C → T mutation at cDNA nucleotide position 475 (R120W) was detected in a patient who is also heterozygous for a C → T transition at cDNA nucleotide position 259 (R48W). In a second patient, a novel, heterozygous T → G transversion at cDNA 226 (F37V) was detected. Mutation 1448 (L444P), the most prevalent mutation among non-Jewish Caucasian Gaucher patients, was found in the heterozygous form in four patients. The mutations in the second Gaucher allele in the other three patients are mutations 254 (G46E), 680 (N188S), and 754 (F213I), which were recently reported in Korean, Arab, and Chinese (Taiwanese) patients. We have developed screening methods that utilize PCR amplification of glucocerebrosidase genomic DNA and Eco571, Nci1, Hinc11, BsaJ1, and Bsr1 restriction endonuclease analyses for the detection of each of these mutations. The population genetics of some of these Gaucher alleles and their implications in genotype/phenotype correlation are discussed. Am. J. Med. Genet. 71:172–178, 1997. © 1997 Wiley-Liss, Inc.     

Six novel β‐galactosidase gene mutations in Brazilian patients with GM1‐gangliosidosis

GM1‐gangliosidosis is a lysosomal storage disease caused by a deficiency of acid β‐galactosidase. Three clinical forms are recognized—infantile, juvenile, and adult—based on age of onset and severity of the symptoms. We have performed molecular analysis of a large cohort of GM1 patients (19 Brazilian and one Uruguayan), using nonradioactive single‐strand conformation polymorphism (SSCP) and restriction enzyme analysis of genomic DNA. Six novel mutations (R121S, V240M, D491N, 638–641insT, 895–896insC, 1622–1627insG) and two previously described point mutations (R59H, R208C) were identified. Together they accounted for 90% of the disease alleles of the patients. Two mutations, 1622–1627insG and R59H, were present in 18 of 20 patients. In addition, four polymorphisms (L10P, L12L, R521C, S532G) were identified. All cases reported are infantile GM1 gangliosidosis. This report constitutes the most comprehensive molecular study to date of this disorder in infantile patients. Since GM1‐gangliosidosis is the most common lysosomal storage disorder in Southern Brazil, molecular diagnosis will be important for genetic counseling, carrier detection and prenatal diagnosis in index families. Hum Mutat 13:401–409, 1999. © 1999 Wiley‐Liss, Inc.     

Clinical features,BTD gene mutations,and their functional studies of eight symptomatic patients with biotinidase deficiency from Southern China

Biotinidase (BTD) deficiency is a rare autosomal recessive metabolic disease, which develops neurological and cutaneous symptoms because of the impaired biotin recycling. Pathogenic mutations on BTD gene cause BTD deficiency. Clinical features and mutation analysis of Chinese children with BTD deficiency were rarely described. Herein, for the first time, we reported the clinical features, BTD gene mutations and their functional studies of eight symptomatic children with BTD deficiency from southern China. Fatigue, hypotonia, proximal muscular weakness, hearing deficits, rash and respiratory problems are common clinical phenotype of our patients. Seizures are observed only in patients with profound BTD deficiency. Five novel mutations were detected, among which c.637delC (H213TfsTer51) was found in 50% of our patients and might be considered as a common mutation. In vitro studies confirmed three mild mutations c.1368A>C (Q456H), c.1613G>A (R538H), and c.644T>A (L215H) which retained 10–30% of wild type enzyme activity, and six severe mutations c.235C>T (R79C), c.1271G>C (C424S), c.1412G>A (C471Y), c.637delC (H213TfsTer51), c.395T>G (M132W), c.464T>C (L155P), and c.1493dupT (L498FfsTer13) which retained <10% of wild type enzyme activity. c.1330G>C (D444H) decreased the protein expression but not activity of BTD enzyme, and H213TfsTer51 was structurally damaging while L498FfsTer13 was functionally damaging. These results will be helpful in establishing the definitive diagnosis of BTD deficiency at the gene level, offering appropriate genetic counseling, and providing clues to structure/function relationships of the enzyme.

     

Heterogeneous mutations in the glucose-6-phosphatase gene in Japanese patients with glycogen storage disease type Ia

Glycogen storage disease type Ia (GSD-Ia) is an autosomal recessive disorder of glycogen metabolism caused by glucose-6-phosphatase (G6Pase) deficiency. It is characterized by short stature, hepatomegaly, hypoglycemia, hyperuricemia, and lactic acidemia. Various mutations have been reported in the G6Pase gene (G6PC). However, in Japanese patients, a g727t substitution was found to be the major cause of GSD-Ia, accounting for 20 of 22 mutant alleles [Kajihara et al., 1995], and no other mutations have been found in this population. We analyzed four Japanese GSD-Ia patients and identified three other mutations in addition to the g727t. They included two missense mutations (R83H and P257L) and one nonsense mutation (R170X). Each of the three mutations exhibited markedly decreased G6Pase activity when expressed in COS7 cells. A patient homozygous for R170X showed multiple episodes of profound hypoglycemia associated with convulsions, while P257L was associated with a mild clinical phenotype. The presence of R170X in three unrelated families may implicate that it is another important mutation in the etiology of GSD-Ia in Japanese patients. Thus, the detection of non-g727t mutations is also important in establishing the DNA-based diagnosis of GSD-Ia in this population.     

Metachromatic leukodystrophy: Identification of the first deletion in exon 1 and nine novel point mutations in the arylsulfatase A gene

Metachromatic leukodystrophy (MLD), a lysosomal storage disease caused by the deficiency of arylsulfatase A (ASA), is inherited as an autosomal recessive trait, and its frequency is estimated to be 1 in 40,000 live births. Genomic DNA from 21 MLD patients (14 late-infantile and 7 juvenile cases) was amplified in four overlapping PCR fragments and tested by allele-specific oligonucleotide (ASO) for the two common mutations 459+1G→A and P426L. These mutations were found in only 28.6% of the alleles studied. The remaining alleles were analyzed by chemical mismatch cleavage (CMC) and automatic sequencing. In addition to five previously reported mutations (459+1G→a, A212V, R244C, R390W, P426L), 10 novel mutations were identified: 9 missense mutations (S95N, G119R, D152Y, R244H, S250Y, A314T, R384C, R496H, K367N) and one 8 bp deletion in exon 1, the first mutation reported in this exon. These methods allowed us to identify 76% of the alleles tested. Genotype-phenotype correlations could be established for some of these mutations. These results confirm the heterogeneity of mutations causing MLD and suggest that CMC is a reliable and informative screening method for point mutation detection in the arylsulfatase A gene. Hum Mutat 9:234–242, 1997. © 1997 Wiley-Liss, Inc.     

Molecular characterisation of 34 patients with biotinidase deficiency ascertained by newborn screening and family investigation

This study characterises the spectrum of biotinidase mutations in 21 patients (17 families) with profound biotinidase deficiency (BD) and 13 unrelated patients with partial BD using a denaturing gradient gel electrophoretic mutation screening and selective sequencing approach. In 29 from 30 unrelated families we found biallelic mutations including four common mutations, D444H (frequency 23.3%), G98:d7i3(20.0%), Q456H(20.0%), T532M (15.0%) and nine rare mutations (V62M, R157H, A171T+D444H, C423W, D543H, L279W, N172S, V109G, 12236G-A) with frequencies less than 5.0%. Only three profound BD patients with G98:d7i3/G98:d7i3 and Q456H/Q456H genotypes and residual biotinidase activities of 0.0%, and 0.9% of normal activity developed clinical symptoms before biotin supplementation at 8 weeks of age. All other patients remained asymptomatic within the first months of life or even longer without treatment. Two patients homozygous for the frameshift mutation G98:d7i3 had no measurable residual enzyme activity. Twelve patients with partial BD had the D444H mutation in at least one allele. We conclude that, based on mutation analysis and biochemical examinations of the enzyme, it is currently not clearly predictable whether an untreated patient will develop symptoms or not, although it seems that patients with activities lower than 1% are at a high risk for developing symptoms of the disease early in life.     

Role of distal zinc finger of nucleocapsid protein in genomic RNA dimerization of human immunodeficiency virus type 1; no role for the palindrome crowning the R-U5 hairpin

Genomic RNA isolated from HIV-1 variously mutated in nucleocapsid protein (NC) was characterized by nondenaturing gel electrophoresis. Mutations in the C-terminal, the N-terminal, and the linker regions had no effect on genomic RNA dimerization [they are R7R10K11S, P31L, R32G, S3(32-34), and K59L], while a C36S/C39S mutation in the distal zinc knuckle (Cys-His box or zinc finger) inhibited genome dimerization as much as disrupting the kissing-loop domain. The four mutations which inhibited tRNA(Lys3) genomic placement (i.e., the in vivo placement of tRNA(Lys3) on the primer binding site) had no effect on genome dimerization. Among five mutations which inhibited genome packaging, four had no effect on genome dimerization. Thus the N-terminal and linker regions of NC control genome packaging/tRNA(Lys3) placement (two processes which do not require mature NC) but have little influence on genome dimerization and 2-base extension of tRNA(Lys3) (two processes which are likely to require mature NC). It has been suggested, based on electron microscopy, that the AAGCUU82 palindrome crowning the R-U5 hairpin stimulates genomic RNA dimerization. To test this hypothesis, we deleted AGCU81 from wild-type viruses and from viruses bearing a disrupted kissing-loop hairpin or kissing-loop domain; in another mutant, we duplicated AGCU81. The loss of AGCU81 reduced dimerization by 2.5 +/- 4%; its duplication increased it by 3 +/- 6%. Dissociation temperature was left unchanged. We reach two conclusions. First, the palindrome crowning the R-U5 hairpin has no impact on HIV-1 genome dimerization. Second, genomic RNA dimerization is differentially influenced by NC sequence: it is Zn finger dependent but independent of the basic nature of the N-terminal and linker subdomains. We propose that the NC regions implicated in 2-base extension of tRNA(Lys3) are required for a second (maturation) step of tRNA placement. Genome dimerization and mature tRNA placement would then become two RNA-RNA interactions sharing similar NC sequence requirements.     

Functional assessment of TSC1 missense variants identified in individuals with tuberous sclerosis complex

Tuberous sclerosis complex (TSC) is an autosomal dominant disorder caused by mutations in the TSC1 or TSC2 genes. The TSC1 and TSC2 gene products, TSC1 and TSC2, form a complex that inhibits the mammalian target of rapamycin (mTOR) complex 1 (TORC1). Previously, we demonstrated that pathogenic amino acid substitutions in the N-terminal domain of TSC1 (amino acids 50-224) are destabilizing. Here we investigate an additional 21 unclassified TSC1 variants. Our functional assessment identified four substitutions (p.L61R, p.G132D, p.F158S, and p.R204P) between amino acids 50 and 224 that reduced TSC1 stability and prevented the TSC1-TSC2-dependent inhibition of TORC1. In four cases (20%), our functional assessment did not agree with the predictions of the SIFT amino acid substitution analysis software. Our new data confirm our previous finding that the N-terminal region of TSC1 is essential for TSC1 function.     

Genomic screening for beta-sarcoglycan gene mutations: missense mutations may cause severe limb-girdle muscular dystrophy type 2E (LGMD 2E)

Autosomal recessive limb-girdle muscular dystrophies (LGMDs) are genetically heterogeneous. A subgroup of these disorders is caused by mutations in the dystrophin-associated sarcoglycan complex. Truncating mutations in the 43 kDa beta-sarcoglycan gene (LGMD 2E) were originally identified in a sporadic case of Duchenne-like muscular dystrophy, and a common missense mutation (T151R) was identified independently in Indiana Amish pedigrees with a milder form of LGMD. To facilitate mutational analysis of larger numbers of patients directly from genomic DNA, as opposed to reverse transcribed RNA from muscle biopsies, we have determined the genomic structure of the beta-sarcoglycan gene. The open reading frame of the beta-sarcoglycan coding region extends over six exons. Primers were designed for PCR amplification of single exons from genomic DNA and subsequent single strand conformation polymorphism (SSCP) analysis. We screened 15 patients from the Brazilian LGMD patient population, 13 of whom followed a severe course. Most of the patients had been assessed previously for deficiency of alpha- sarcoglycan immunofluorescence on muscle biopsy sections as a marker for disease of the sarcoglycan complex. Novel mutations in two familial and two sporadic cases of severe childhood-onset LGMD were identified. Only one of these patients carried a truncating mutation (homozygous 2 bp deletion, FS164TER), while the other three carried missense mutations (homozygous R91P, homozygous M100K, heterozygous recessive L108R; only one allele could be identified in this family). All three missense mutations occurred in exon 3, coding for the immediate extracellular domain. Complete absence for all three of the known sarcoglycans was noted by immunohistochemistry on muscle biopsy sections of the patients.      

Reciprocal effect of Waardenburg syndrome mutations on DNA binding by the Pax-3 paired domain and homeodomain

The Pax-3 protein contains two DNA-binding domains, a paired domain and a homeodomain. Mutations in Pax-3 cause Waardenburg syndrome (WS) in humans and the mouse Splotch (Sp) phenotype. In the Sp-delayed mouse, a mutation in the Pax-3 paired domain (G9R) abrogates the DNA-binding activity of both the paired domain and the homeodomain, suggesting that they may functionally interact. To investigate this possibility further, we have analyzed the DNA-binding properties of additional point mutants in the Pax-3 paired domain and homeodomain that occur in WS patients (F12L, N14H, G15S, P17L, R23L, G48A, S51F and G66D in the paired domain, V47F and R53G in the homeodomain), the Pax-1 un mutation (G15A) and a substitution associated with Peters' anomaly in the PAX-6 gene (R23G). Within the paired domain, seven of 10 mutations were found to abrogate DNA-binding by the paired domain. Remarkably, these seven mutations also affected DNA binding by the homeodomain, causing either a complete loss (P17L and G66D), a reduction (R23G, R23L, G15S and G15A) or an increase in DNA-binding activity (N14H). In addition, the effect of paired domain mutations occurred at the level of monomer formation by the homeodomain, while the dimerization potential of this domain seemed unaffected in mutants where it could be analyzed. Furthermore, while both homeodomain mutations were found to abolish DNA binding by this domain, the R53G mutation also abrogated DNA binding by the paired domain. The important observation that independent mutations in either domain can affect DNA binding by the other in the intact Pax- 3 protein strongly suggests that the two domains are not functionally independent but bind DNA through cooperative interactions. Modeling the deleterlous mutations on the three-dimensional structure of the paired domain of Drosophila Prd shows that these mutations cluster at the DNA interface, thus suggesting that a series of DNA contacts are essential for DNA binding by both the paired domain and the homeodomain of Pax-3.      

Differences in methylation patterns in the methylation boundary region of IDS gene in Hunter syndrome patients: implications for CpG hot spot mutations

Hunter syndrome, an X-linked disorder, results from deficiency of iduronate-2-sulfatase (IDS). Around 40% of independent point mutations at IDS were found at CpG sites as transitional events. The 15 CpG sites in the coding sequences of exons 1 and 2, which are normally hypomethylated, account for very few of transitional mutations. By contrast, the CpG sites in the coding sequences of exon 3, though also normally hypomethylated, account for much higher fraction of transitional mutations. To better understand relationship between methylation status and CpG transitional mutations in this region, the methylation patterns of 11 Hunter patients with transitional mutations at CpG sites were investigated using bisulfite genomic sequencing. The patient cohort mutation spectrum is composed of one mutation in exon 1 (one patient) and three different mutations in exon 3 (10 patients). We confirmed that in normal males, cytosines at the CpG sites from the promoter region to a portion of intron 3 were hypomethylated. However, specific CpG sites in this area were more highly methylated in patients. The patients with p.R8X (exon 1), p.P86L (exon 3), and p.R88H (exon 3) mutations had a hypermethylated condition in exon 2 to intron 3 but retained hypomethylation in exon 1. The same trend was found in four patients with p.A85T (exon 3), although the degree of hypermethylation was less. These findings suggest methylation patterns in the beginning of IDS genomic region are polymorphic in humans and that hypermethylation in this region in some individuals predisposes them to CpG mutations resulting in Hunter syndrome.