Mutations In Cystathionine Beta-synthase Gene Research Articles

Identification of three novel pathogenic mutations in cystathionine beta-synthase gene of Pakistani intellectually disabled patients.

Classical homocystinuria (HCU) is an autosomal recessive inborn error of metabolism, which is caused by the cystathionine-β-synthase (CBS: encoded by CBS) deficiency. Symptoms of untreated classical HCU patients include intellectual disability (ID), ectopia lentis and long limbs, along with elevated plasma methionine, and homocysteine. A total of 429 ID patients (age range: 1.6-23 years) were sampled from Northern areas of Punjab, Pakistan. Biochemical and genetic analyses were performed to find classical HCU disease in ID patients. Biochemically, nine patients from seven unrelated families were identified with high levels of plasma methionine and homocysteine. Targeted exonic analysis of CBS confirmed seven causative homozygous mutations; of which three were novel missense mutations (c.451G>T; p.Gly151Trp, c.975G>C; p.Lys325Asn and c.1039+1G>T splicing), and four were recurrent variants (c.451+1G>A; IVS4+1 splicing, c.770C>T; p.Thr257Met, c.808_810del GAG; p.Glu270del and c.752T>C; p.Leu251Pro). Treatment of patients was initiated without further delay with pyridoxine, folic acid, cobalamin, and betaine as well as dietary protein restriction. The immediate impact was noticed in behavioral improvement, decreased irritability, improved black hair color, and socialization. Overall, health outcomes in this disorder depend on the age and symptomatology at the time of treatment initiation. With personalized treatment and care, such patients can reach their full potential of living as healthy a life as possible. This screening study is one of the pioneering initiatives in Pakistan which would help to minimize the burden of such treatable inborn errors of metabolism in the intellectually disabled patients.

Small aminothiol compounds improve the function of Arg to Cys variant proteins: effect on the human cystathionine β-synthase p.R336C.

The key regulatory point of L-methionine (Met) and L-homocysteine (Hcy) degradation is catalyzed by cystathionine beta-synthase (CBS). CBS deficiency is caused by mutations in CBS gene, often resulting in protein misfolding. The prevalence of CBS deficiency in Qatar is 1/1800, ∼200-fold higher than the worldwide prevalence of 1/344 000. Almost all patients bear the CBS p.R336C variant. More than 20 years ago, it was shown in vitro that two unrelated protein variants with a substitution of an arginine (Arg) residue by cysteine (Cys) could be rescued by cysteamine (mercaptoethylamine), likely via formation of a disulfide between Cys and cysteamine, functionally mimicking the wild-type (WT) Arg side-chain. Based on these findings, we aimed to study whether cysteamine was able to improve the function of p.R336C CBS variant. Additionally, we tested the effect of mercaptoethylguanidine (MEG), a compound with a guanidino and a thiol function that may resemble Arg structure better than cysteamine. Three purified recombinant CBS proteins (p.R336C, p.R336H and WT) were pre-incubated with cysteamine, MEG or Cys (as negative control), and CBS activity and stability were measured. Pre-incubation with cysteamine and MEG increased the enzymatic activity of the p.R336C protein, which was absent upon pre-incubation with Cys. The WT and the p.R336H variant enzyme activity presented no increase with any of the tested compounds. Our results show that cysteamine and MEG are able to specifically improve the function of the CBS p.R336C variant, suggesting that any Arg-to-Cys substitution accessible to these small molecules may be converted back to a moiety resembling Arg.

A case of homocystinuria due to CBS gene mutations revealed by cerebral venous thrombosis

BackgroundHomocystinuria caused by cystathionine beta synthase (CBS) deficiency is most often diagnosed in childhood and has a variable expressivity. The most frequent abnormalities include intellectual disability, ectopia lentis, myopia, skeletal abnormalities or thromboembolism. ObjectiveTo report a case of homocystinuria unraveled by cerebral venous thrombosis (CVT). ObservationA 17 year old female was admitted in our department of neurology for subacute headache and presented seizures in the emergency room. Cerebral imaging revealed CVT. Severe hyperhomocysteinemia was found and led to the diagnosis of homocystinuria due to composite heterozygous mutations in the CBS gene. Further investigations disclosed lens subluxation in association with myopia, mild scoliosis and osteopenia. The patient was treated by heparin followed by warfarin, vitamin therapy and dietary methionine restriction. Total homocysteine and methionine levels became normal in a few weeks and the patient had a complete recovery. ConclusionIn patients with CVT, plasma total homocysteine measurement as part of the etiologic work up may reveal severe hyperhomocysteinemia due to CBS or remethylation defects that require specific treatment and management including perhaps protein-restricted diet and/or vitamin therapy for life.

Reduced response of Cystathionine Beta‐Synthase (CBS) to S‐Adenosylmethionine (SAM): Identification and functional analysis of CBS gene mutations in Homocystinuria patients

A reduced response of cystathionine beta-synthase (CBS) to its allosteric activator S-adenosylmethionine (SAM) has been reported to be a cause of CBS dysfunction in homocystinuria patients. In this work we performed a retrospective analysis of fibroblast data from 62 homocystinuria patients and found that 13 of them presented a disturbed SAM activation. Their genotypic background was identified and the corresponding CBS mutant proteins were produced in E. coli. Nine distinct mutations were detected in 22 independent alleles: the novel mutations p.K269del, p.P427L, p.S500L and p.L540Q; and the previously described mutations p.P49L, p.C165Rfs*2, p.I278T, p.R336H and p.D444N. Expression levels and residual enzyme activities, determined in the soluble fraction of E. coli lysates, strongly correlated with the localization of the affected amino acid residue. C-terminal mutations lead to activities in the range of the wild-type CBS and to oligomeric forms migrating faster than tetramers, suggesting an abnormal conformation that might be responsible for the lack of SAM activation. Mutations in the catalytic core were associated with low protein expression levels, decreased enzyme activities and a higher content of high molecular mass forms. Furthermore, the absence of SAM activation found in the patients' fibroblasts was confirmed for all but one of the characterized recombinant proteins (p.P49L). Our study experimentally supports a deficient regulation of CBS by SAM as a frequently found mechanism in CBS deficiency, which should be considered not only as a valuable diagnostic tool but also as a potential target for the development of new therapeutic approaches in classical homocystinuria.

Clinical and molecular findings of 13 families from Saudi Arabia and a family from Sudan with homocystinuria

Homocystinuria due to cystathionine beta synthase (CBS) deficiency results in elevated plasma homocysteine and methionine levels, which are associated with multiple organ pathologies, including vascular, respiratory, musculoskeletal, nervous, and ocular tissues. This autosomal recessive disorder is caused by homozygous or compound heterozygous mutations in the CBS gene encoding for the CBS. Although homocystinuria is observed in Arab and North African patients, their clinical presentations have not been described and molecular causes remained largely uninvestigated. In this study, we describe the clinical presentations of 22 homocystinuria patients from 13 Saudi Arabian families and 1 North African Sudanese family. Cardinal biochemical features of homocystinuria manifested in all patients, but heterogeneity of expression was observed for other associated phenotypes. One patient developed Legg-Calvé-Perthes disease that has not been previously described in homocystinuria. In the Saudi families, a novel nonsense mutation, p.Trp323X, and recurrent p.Arg336Cys and p.Gly153Arg mutations were identified in the CBS gene. The p.Trp323X mutation was found in 10 of the 13 unrelated Saudi families. In the Sudanese family, the p.Thr257Met mutation in the CBS gene, previously described in Italian and Spanish patients, was found. This study shows that the spectrum of CBS gene mutations in Saudi homocystinuria patients is quite different than the Arab patients from Qatar and Israel. This study is the only detailed phenotypic and genetic depiction of homocystinuria patients from Saudi Arabia and Sudan. The data are useful for diagnosis and management of Saudi patients.

Characterisation of a human liver cystathionine beta synthase mRNA sequence corresponding to the c.[833T>C;844_845ins68] mutation in CBS gene

Cystathionine beta synthase (CBS) is the only reaction that removes homocysteine from methionine cycle and redirects it to the transsulfuration pathway. The c.[833T>C;844_845ins68] mutation in the CBS gene has been reported initially as corresponding to classic homocystinuria. Studies showing that the insertion is associated with very smalls amounts of the transcript in the nucleus; others suggest that the heterozygous and homozygous subjects are protected against hyperhomocysteinemia and that the insertion tends to rescue the protein function. The liver is the major organ which metabolizes the circulating homocysteine to cystathionine. We have determined the sequence of the liver mRNA corresponding to the CBS c.[833T>C;844_845ins68] gene. We have shown that a novel splicing event could account for the modification in protein and possibly in enzyme activity.

Two Novel Mutations in the Cystathionine beta-synthase Gene of Homocystinuric Patients.

Background: The continued identfication of new mutations in the cystathionine beta-synthase (CBS) gene is important in correlating the genotype/phenotype of patients with classic homocystinuria and in assessing whether heterozygosity of CBS deficiency is an important cause of mild hyperhomocysteinemia, an independent risk factor for occlusive vascular diseases. Methods and Results: Single-strand polymorphism and direct nucleotide sequencing were used to detect two novel mutations in the CBS gene of three homocystinuric patients from two unrelated families. The first mutation, a G-to-A transistion at nucleotide 1316 in exon 12, results in an amino acid substitution of arginine by glutamine at codon 439. The second mutation is a G-to-A transition at nucleotide 1109 in exon 10 and results in an amino acid substitution of cysteine by tyrosine at codon 370. All three patients are apparently compound heterozygotes, with one of the two novel mutations on one allele and the T(833)C mutation on the other allele. Conclusions: The absence of the G(1316)A and G(1109)A in 216 control alleles demonstrates that these two novel mutations do not represent common polymorphisms, but rather are responsible for the defective CBS enzyme activities encoded by one of the two alleles of the CBS gene in each of the two families.