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Homocystinuria caused by cystathionine β-synthase (CβS, EC no. 4.2.1.22) deficiency is an inborn error of sulfur amino acid metabolism. Worldwide, estimates of the incidence of CβS deficiency range from 1/20,500 in Denmark1 to 1/800,000 in Japan.2 CβS, the first enzyme in the transsulfuration pathway, catalyzes the condensation of homocysteine and serine to produce cystathionine, and ultimately, cysteine (Fig. 1). CβS uses pyridoxal phosphate (B6) and heme as its cofactors.3,4

Fig. 1
figure 1

Metabolism of homocysteine. Transsulfuration proceeds by first condensing homocysteine with serine, producing cystathionine. Hydrolysis of cystathionine by cystathionase yields cysteine and α-ketobutyrate. Remethylation of homocysteine by betaine-homocysteine methyl transferase-catalyzed transfer of an N-methyl group from betaine to homocysteine, yielding methionine and N, N-dimethylglycine.

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Total plasma homocysteine (tHcy) is markedly elevated in CβS deficiency and is a sensitive in vivo marker for therapeutic intervention.2 Even mild to moderate elevation of tHcy is a risk-factor for premature vascular disease (PVD), much like cholesterol.7 However, a portion of patients with CβS deficiency, even during optimal dietary compliance, can not lower tHcy to the normal range (personal observations and Table 2).

Table 2 Human CβS activity determined in total yeast extracts
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Therapeutically, patients with CβS deficiency can be divided into two groups, based upon the effects of pharmacological pyridoxine therapy on their metabolic status and clinical outcome. Patients experiencing significant decreases in both plasma methionine and free plasma homocystine (fHcys) while receiving pharmacological amounts of pyridoxine without diet manipulation are considered “B6-responsive.” Patients showing no significant decreases in methionine or fHys while receiving up to 1.0 g/day of pyroxidine following pyroxidine are classified as “B6-nonresponsive.”2,811 Such individuals demonstrate minimal or absent residual CβS activity in cultured fibroblasts.2,811

Betaine (N, N, N-trimethylglycine) is a natural product of choline catabolism and serves as a methyl-donor for homocysteine to synthesize methionine by betaine-homocysteine S-methyltransferase (BHMT, EC 2.1.1.5) (Fig. 1). This enzyme, present primarily in the liver and kidney, is induced by betaine and can remethylate up to 25% of total homocysteine flux.12

Betaine improved biochemical control in previous studies of patients with B6-nonresponsive CβS deficiency.13 Subsequent studies confirmed their observations that betaine treatment decreased total plasma homocysteine, in both plasma and cerebrospinal fluid.9,14,15 However, because standardized dietary management did not precede the use of betaine in these studies, the additive effect of betaine to “dietary control” remained unknown. In this study, our patients achieved their optimal dietary control, based upon their nutritional history and metabolic measures of plasma methionine and tHcy. We then assessed the additive effect of betaine on tHcy and plasma methionine. We determined their molecular genotypes for CβS deficiency and correlated them with ethnicity and clinical B6 nonresponsivity.

MATERIALS AND METHODS

Patient recruitment

Five patients with biochemically confirmed cystathionine β-synthase deficiency cared for by the Division of Medical Genetics at Emory University were recruited for this study. The study and its informed consent were approved by Emory University's Human Investigations Committee. Diagnoses were established by elevated methionine, free homocystine, and decreased free cystine for patients diagnosed before 1996. Total plasma homocysteine quantitation began in 1996. Molecular genotyping of CβS confirmed these biochemical diagnoses in all patients. Three of the five patients were identified by positive newborn screening for hypermethioninemia, and two were identified later in life after the discovery of ectopia lentis. All patients required methionine restriction to < 30 mg/kg per day, to decrease their free homocystine and total plasma homocysteine concentrations. Methionine-restricted diets were implemented concurrently with pyridoxine supplementation at doses up to 20 mg/kg per day. We selected for this study five patients classified as B6-nonresponsive. All were treated with methionine restriction and pharmacological supplementation of pyridoxine, but could not maintain plasma methionine below 50 μmol/L or free homocystine below 5 μmol/L. The treatment of B6-nonresponsive CβS deficiency patients with “methionine restriction” was accomplished in part by the simultaneous dietary restriction of natural protein, and supplementation with medical foods free of methionine. These methionine-free medical foods were supplemented with conditionally-essential l-cysteine, in the form of l-cystine.

Study design

Patients were first treated with natural protein restriction, supplementation with methionine-depleted, l-cystine–fortified medical foods, and 5 to 20 mg/kg per day of pyridoxine.16 Upon attaining the lowest plasma methionine and total plasma homocysteine, we began betaine at prescribed doses of 20–50 mg/kg per day. Dosages were increased to 120–150 mg/kg per day and provided as three divided doses until stabilization of tHcy to lowest concentrations for the individual. Biochemical measurements were obtained every one to three months, until the tHcy reached a nadir. Three-day diet histories were analyzed and compared for methionine content, and other essential nutrients throughout the studies.

Statistical analyses

The Student's t test was used for comparisons of each metabolic parameter in each patient before and during betaine therapy. Significance was reported for P ≤ 0.05.

Biochemical measurements

Total plasma homocysteine and total plasma cysteine concentrations were determined after chemical reduction, derivitization with a fluorophore, and subsequent HPLC separation as previously described.17 Plasma amino acid concentrations (including methionine and free homocystine) were determined by traditional methods of ion-exchange chromatography.18

Molecular analyses of the CβS gene

Nucleic Acids were isolated from 75 mL of cells using the Purescript RNA Isolation kit (Gentra Systems, Minneapolis, MN). The fifteen coding exons of CβS were amplified using the primer pairs described in19 After PCR the products were isolated by gel purification using the QIAEXII Gel Extraction Kit (Qiagen, Valencia, CA) and sequenced at the Fox Chase Cancer Center. Mutant alleles were tested individually in a yeast functional assay as previously described.20,21 All 6 mutant alleles identified in these 5 patients failed to augment cysteine auxotrophy consistent with these mutations affecting enzyme function, as shown in Table 2.

RESULTS

Genotypes of patients studied

The molecular bases for the five patients studied with clinical B6-nonresponsive CβS deficiency are shown in24 Two American Black patients (patients 5 and 1) possessed a T353M allele.25,26 One (Patient 5) was homozygous for this mutation, and the other (Patient 1) was compound heterozygous for this mutation and a novel Q526K mutation. All patients were classified as B6-nonresponsive by clinical criteria.

Effect of betaine on plasma methionine

Table 3 shows the plasma methionine concentrations obtained immediately before the initiation of betaine but after optimum B6 and dietary therapy. The listed plasma methionine concentrations (μmol/L) reflect the effect of betaine therapy. Plasma methionine concentrations increased about 2-fold in patients 2, 3, and 5, and 4-fold in patient 1. None of these patients reported a change in methionine dietary intake (data not shown). Plasma methionine concentration decreased about 16% in patient 4, who reported a decrease in methionine intake, increased compliance with the metabolic formula, and inconsistent compliance with the prescribed betaine dosing regimen (discussed later).

Table 3 Metabolite quantitations in five B6-nonresponsive patients
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Effect of betaine on total plasma homocysteine

Total plasma homocysteine concentrations obtained before initiation of betaine therapy, and after maximal therapy, are shown in Table 2. All patients experienced significant reductions in tHcy, regardless of genotype or plasma methionine concentrations. Patients 1, 2, and 3 normalized their total plasma homocysteine concentrations on betaine therapy, despite elevated concentrations before the initiation of betaine. Even patients 4 and 5, who are adolescents with variable compliance to diet, demonstrated decreased tHcy concentrations.

Effect of betaine on total plasma cysteine

Total plasma cysteine concentrations did not significantly change before and during betaine therapy in the group as a whole (Table 3). Although Patient 4 experienced a doubling of total plasma cysteine concentrations during betaine therapy, he also reported increased intake of cystine-fortified medical food.

Effect of betaine on the ratio of methionine/total plasma homocysteine

Because betaine decreases homocysteine and increases methionine by providing an additional pathway for homocysteine transmethylation to methionine, a ratio of this substrate and product were good biochemical parameters of response to betaine (Table 3). During betaine addition, all patients experienced an increase in the ratio of plasma methionine/tHcy, regardless of estimated methionine intakes, compliance with methionine restriction or betaine. As seen by comparing the methionine/tHcy ratios in Table 2, even Patient 4 had an approximately 4-fold increase in this ratio when betaine was added to his therapeutic regimen.

DISCUSSION

Several previous publications reported the effective use of betaine in CβS deficiency. Most groups noted improvement in metabolic control.29 first demonstrated the clinical efficacy of betaine, and a later study by Wilcken et al.13 found that betaine decreased estimated tHcy and increased estimated tCys, which were determined from free homocystine and free homocysteine-cysteine mixed disulfide concentrations. This study also found variable effects of betaine on plasma methionine concentrations. In subsequent studies, when tHcy was measured in patients with CβS deficiency, betaine decreased total plasma homocysteine concentrations in both plasma and cerebrospinal fluid.9,14 These more recent studies showed the efficacy of betaine and supported its approval by the FDA as an “orphan drug” for the treatment of homocystinuria.

We observed significant and clinically relevant “net” metabolic effects of betaine in patients with B6-nonresponsive CβS deficiency. The response to betaine was greatest among patients 1 and 2 who had mutations previously described as B6-nonresponsive (NR)25,24,30 compared to patients who were heterozygous for mutant alleles previously defined as B6-responsive.3133 The dramatic falls in total plasma homocysteine in all 5 patients were reflected in the mean decrease of over 47.4 μmol/L. Although we observed 4/5 patients with a near doubling of their plasma methionine during maximal betaine therapy, the mean plasma methionine in our betaine treatment group did not change. This was because of the decrease in the plasma methionine of patient 4, for which we found two contributing explanations. First, this patient reported improved compliance with both methionine restriction and consumption of the methionine-depleted, cystine-enriched medical food. Objective evidence supporting improved compliance by Patient 4 was the doubling of his total plasma cysteine and the decrease in plasma methionine during betaine treatment, which was only observed in this subject. This patient also reported being partially compliant with his betaine dosing regimen, only taking one fourth of the prescribed dose, resulting in an intake of approximately 20 to 30 mg/kg per day. Therefore, with both decreased methionine intake and suboptimal betaine dosing, it is not surprising that his plasma methionine decreased compared to baseline when all other patients' plasma methionines increased after betaine therapy. Of interest was that his ratio of met/tHcy increased as in other patients indicating, that remethylation of methionine from homocysteine was enhanced by betaine.

At least two different biochemical mechanisms may account for the rise in met/tHcy. First, the direct effect of dietary methionine restriction in CβS deficiency is a decrease in the “available pool of methionine” and a secondary decrease in production of homocysteine.16 Second, increasing the alternate pathway for remethylation of homocysteine is expected to increase methionine by remethylating homocysteine. The mean ratio of methionine to total plasma homocysteine increased almost an order of magnitude (0.65 to 6.1) and provided metabolic evidence supporting the “rerouting” as a major metabolic fate of homocysteine. Without flux studies, we cannot determine whether this rise in met/tHcy was partially due to the reduction in the overall “available methionine pool” and the secondary drop in homocysteine. However, because in Patient 4 methionine was lower on betaine, than off betaine, yet his met/tHcy increased, it is unlikely that reduced methionine pools played a major role in his response.

Molecular analysis of the CβS gene confirmed the clinical assessment of B6 response in CβS deficiency by identifying specific gene mutations (genotypes) and enabled genotype/phenotype correlation. The interpretation of the CβS genotype-phenotype relationship includes prediction of an individual's response to treatment with B6 (pyridoxine), betaine, and/or a methionine-restricted, cystine supplemented diet. For example, responsiveness to B6 (pyridoxine) supplementation was reported for I278T homozyotes.11 However, there is residual enzyme activity with minimal growth in yeast functional assays31 for homozygotes, but not for compound heterozygotes with other mutant alleles. In our study when the I278T mutation was present with either D376N or L101P, the patient was B6-nonresponsive. Interpretation of genotype-phenotype correlation is complex and must include both the environment (i.e., methionine intake) and undefined epigenetic metabolism. For example, T262M and L101P are classified as mixed response because the same genotype was found in both B6-responsive and B6-nonresponsive phenotypes.11 and responded more efficiently to betaine treatment when compared to the three patients associated with the B6 responsive or mixed response genotype categories. In functional yeast assays, the V320A mutation enabled growth in these cysteine auxotrophs in response to B6 supplementation.31 This data suggests that defining genotypes will assist in predicting response to betaine therapy. Studies of more patients with B6 nonresponsive mutations will assist in further understanding the genotype-phenotype relationship. Because phenotypes associated with CβS genotypes are still unclear, the complexity of genotype/phenotype correlations will require further knowledge of alternate homocysteine metabolism (epigenes) as well as nutritional exposure (environment) using multivariate analysis.

Despite varying compliance and unknown variables in this prospective study, the use of betaine by patients with homocystinuria, classified clinically as B6-nonresponsive, improved metabolic control. This improvement was achieved in 3 to 6 months, without either side-effect or adverse reactions, consistent with previous reports.34; however, this is the first report of the efficacy of betaine treatment when administered in conjunction with dietary methionine restriction to reduce tHcy in persons with B6-nonresponsive CβS deficiency.

Table 1 Oligonucleotide primer sequences used to sequence the sixteen exons of the cystathionine β-synthase gene
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