A novel small molecule approach for the treatment of propionic and methylmalonic acidemias

Propionic Acidemia (PA) and Methylmalonic Acidemia (MMA) are inborn errors of metabolism affecting the catabolism of valine, isoleucine, methionine, threonine and odd-chain fatty acids. These are multi-organ disorders caused by the enzymatic deficiency of propionyl-CoA carboxylase (PCC) or methylmalonyl-CoA mutase (MUT), resulting in the accumulation of propionyl-coenzyme A (P-CoA) and methylmalonyl-CoA (M-CoA in MMA only). Primary metabolites of these CoA esters include 2-methylcitric acid (MCA), propionyl-carnitine (C3), and 3-hydroxypropionic acid, which are detectable in both PA and MMA, and methylmalonic acid, which is detectable in MMA patients only (Chapman et al., 2012). We deployed liver cell-based models that utilized PA and MMA patient-derived primary hepatocytes to validate a small molecule therapy for PA and MMA patients. The small molecule, HST5040, resulted in a dose-dependent reduction in the levels of P-CoA, M-CoA (in MMA) and the disease-relevant biomarkers C3, MCA, and methylmalonic acid (in MMA). A putative working model of how HST5040 reduces the P-CoA and its derived metabolites involves the conversion of HST5040 to HST5040-CoA driving the redistribution of free and conjugated CoA pools, resulting in the differential reduction of the aberrantly high P-CoA and M-CoA. The reduction of P-CoA and M-CoA, either by slowing production (due to increased demands on the free CoA (CoASH) pool) or enhancing clearance (to replenish the CoASH pool), results in a net decrease in the CoA-derived metabolites (C3, MCA and MMA (MMA only)). A Phase 2 study in PA and MMA patients will be initiated in the United States.

Delineating the clinical spectrum of isolated methylmalonic acidurias: cblA and mut

INTRODUCTION

Long-term outcome is postulated to be different in isolated methylmalonic aciduria caused by mutations in the MMAA gene (cblA type) compared with methylmalonyl-CoA mutase deficiency (mut), but case definition was previously difficult.

METHOD

Cross-sectional analysis of data from the European Registry and Network for Intoxication type Metabolic Diseases (Chafea no. December 1, 2010).

RESULTS

Data from 28 cblA and 95 mut patients in most cases confirmed by mutation analysis (including 4 new mutations for cblA and 19 new mutations for mut). Metabolic crisis is the predominant symptom leading to diagnosis in both groups. Biochemical disturbances during the first crisis were similar in both groups, as well as the age at diagnosis. Z scores of body height and body weight were similar in both groups at birth, but were significantly lower in the mut group at the time of last visit. Glomerular filtration rate was significantly higher in cblA; and as a consequence, chronic renal failure and related complications were significantly less frequent and renal function could be preserved even in older patients. Neurological complications were predominantly found in the mut subgroup. Methylmalonic acidemia (MMA) levels in urine and plasma were significantly lower in cblA. 27/28 cblA patients were reported to be responsive to cobalamin, only 86% of cblA patients were treated with i.m. hydroxocobalamin. In total, 73% of cblA and 98% of mut patients followed a calculated diet with amino acid supplements in 27% (cblA) and 69% (mut). During the study interval, six patients from the mut group died, while all cblA patients survived.

CONCLUSION

Although similar at first, cblA patients respond to hydroxocobalamin treatment, subsequently show significantly lower levels of MMA and a milder course than mut patients.

Biochemical and anaplerotic applications of in vitro models of propionic acidemia and methylmalonic acidemia using patient-derived primary hepatocytes

Propionic acidemia (PA) and methylmalonic acidemia (MMA) are autosomal recessive disorders of propionyl-CoA (P-CoA) catabolism, which are caused by a deficiency in the enzyme propionyl-CoA carboxylase or the enzyme methylmalonyl-CoA (MM-CoA) mutase, respectively. The functional consequence of PA or MMA is the inability to catabolize P-CoA to MM-CoA or MM-CoA to succinyl-CoA, resulting in the accumulation of P-CoA and other metabolic intermediates, such as propionylcarnitine (C3), 3-hydroxypropionic acid, methylcitric acid (MCA), and methylmalonic acid (only in MMA). P-CoA and its metabolic intermediates, at high concentrations found in PA and MMA, inhibit enzymes in the first steps of the urea cycle as well as enzymes in the tricarboxylic acid (TCA) cycle, causing a reduction in mitochondrial energy production. We previously showed that metabolic defects of PA could be recapitulated using PA patient-derived primary hepatocytes in a novel organotypic system. Here, we sought to investigate whether treatment of normal human primary hepatocytes with propionate would recapitulate some of the biochemical features of PA and MMA in the same platform. We found that high levels of propionate resulted in high levels of intracellular P-CoA in normal hepatocytes. Analysis of TCA cycle intermediates by GC-MS/MS indicated that propionate may inhibit enzymes of the TCA cycle as shown in PA, but is also incorporated in the TCA cycle, which does not occur in PA. To better recapitulate the disease phenotype, we obtained hepatocytes derived from livers of PA and MMA patients. We characterized the PA and MMA donors by measuring key proximal biomarkers, including P-CoA, MM-CoA, as well as clinical biomarkers propionylcarnitine-to-acetylcarnitine ratios (C3/C2), MCA, and methylmalonic acid. Additionally, we used isotopically-labeled amino acids to investigate the contribution of relevant amino acids to production of P-CoA in models of metabolic stability or acute metabolic crisis. As observed clinically, we demonstrated that the isoleucine and valine catabolism pathways are the greatest sources of P-CoA in PA and MMA donor cells and that each donor showed differential sensitivity to isoleucine and valine. We also studied the effects of disodium citrate, an anaplerotic therapy, which resulted in a significant increase in the absolute concentration of TCA cycle intermediates, which is in agreement with the benefit observed clinically. Our human cell-based PA and MMA disease models can inform preclinical drug discovery and development where mouse models of these diseases are inaccurate, particularly in well-described species differences in branched-chain amino acid catabolism.

Impaired mitophagy links mitochondrial disease to epithelial stress in methylmalonyl-CoA mutase deficiency

Deregulation of mitochondrial network in terminally differentiated cells contributes to a broad spectrum of disorders. Methylmalonic acidemia (MMA) is one of the most common inherited metabolic disorders, due to deficiency of the mitochondrial methylmalonyl-coenzyme A mutase (MMUT). How MMUT deficiency triggers cell damage remains unknown, preventing the development of disease-modifying therapies. Here we combine genetic and pharmacological approaches to demonstrate that MMUT deficiency induces metabolic and mitochondrial alterations that are exacerbated by anomalies in PINK1/Parkin-mediated mitophagy, causing the accumulation of dysfunctional mitochondria that trigger epithelial stress and ultimately cell damage. Using drug-disease network perturbation modelling, we predict targetable pathways, whose modulation repairs mitochondrial dysfunctions in patient-derived cells and alleviate phenotype changes in mmut-deficient zebrafish. These results suggest a link between primary MMUT deficiency, diseased mitochondria, mitophagy dysfunction and epithelial stress, and provide potential therapeutic perspectives for MMA.

Gene Therapy for Methylmalonic Acidemia: Past, Present, and Future

Methylmalonic acidemia (MMA) is a severe, and sometimes lethal, monogenic metabolic disorder in need of improved treatments. A number of new genomic therapies, which include canonical adeno-associated virus gene addition, genome editing, and systemic mRNA therapy, have shown great promise in murine models of MMA. Each approach has unique advantages and disadvantages for treating genetic disorders like MMA. This article reviews traditional viral gene therapy experiments that have provided enabling proof of concept studies in animal models, and newer approaches that may emerge as effective treatments for MMA and related disorders of organic acid metabolism.

Liver neoplasms in methylmalonic aciduria: An emerging complication

Methylmalonic aciduria (MMA) is an inherited metabolic disease caused by methylmalonyl-CoA mutase deficiency. Early-onset disease usually presents with a neonatal acute metabolic acidosis, rapidly causing lethargy, coma, and death if untreated. Late-onset patients have a better prognosis but develop common long-term complications, including neurological deterioration, chronic kidney disease, pancreatitis, optic neuropathy, and chronic liver disease. Of note, oncogenesis has been reported anecdotally in organic acidurias. Here, we present three novel and two previously published cases of MMA patients who developed malignant liver neoplasms. All five patients were affected by a severe, early-onset form of isolated MMA (4 mut⁰ , 1 cblB subtype). Different types of liver neoplasms, that is, hepatoblastoma and hepatocellular carcinoma, were diagnosed at ages ranging from infancy to adulthood. We discuss pathophysiological hypotheses involved in MMA-related oncogenesis such as mitochondrial dysfunction, impairment of tricarboxylic acid cycle, oxidative stress, and effects of oncometabolites. Based on the intriguing occurrence of liver abnormalities, including neoplasms, we recommend close biochemical and imaging monitoring of liver disease in routine follow-up of MMA patients.

Genetic diagnosis of one family with incomplete clinical data

A 6-day-old female patient suddenly died of congestive heart failure, hepatomegaly and hypoglycemic encephalopathy. Tandem mass spectrometry (MS) analysis revealed a possibility of carnitine deficiency. However, many of the clinical symptoms had not yet occurred at that time, and the clinical data was incomplete. We aim to derive a systematic procedure of identifying pathogenic mutations for similar patients. Physicians could save patients' lives with effective treatment at a much earlier stage. Direct sequencing of the exons and exon-intron boundaries of GAA, SLC25A5, CPT1, CPT2, SLC25A20 and MUT genes were performed on the parents of the patient. DNA from the blood spots of the patient was analyzed for the MUT gene. The results revealed that the patient was a compound heterozygote with MUT. c. 729_730insTT and c. 1677-1G>A. cDNA sequence demonstrated MUT c. 1677-1G>A resulting in the deletion of eight nucleotides and the introduction of 13 novel amino acids before premature termination.

Pseudoexon exclusion by antisense therapy in methylmalonic aciduria (MMAuria)

Development of pseudoexon exclusion therapies by antisense modification of pre-mRNA splicing represents a type of personalized genetic medicine. Here we present the cellular antisense therapy and the cell-based splicing assays to investigate the effect of two novel deep intronic changes c.1957-898A>G and c.1957-920C>A identified in the methylmalonyl-coenzyme A (CoA) mutase (MUT) gene. The results show that the nucleotide change c.1957-898A>G is a pathological mutation activating pseudoexon insertion and that antisense morpholino oligonucleotide (AMO) treatment in patient fibroblasts leads to recovery of MUT activity to levels 25 to 100% of control range. On the contrary, the change c.1957-920C>A, identified in two fibroblasts cell lines in cis with c.1885A>G (p.R629G) or c.458T>A (p.D153V), appears to be a rare variant of uncertain clinical significance. The functional analysis of c.1885A>G and c.458T>A indicate that they are the disease-causing mutations in these two patients. The results presented here highlight the necessity of scanning the described intronic region for mutations in MUT-affected patients, followed by functional analyses to demonstrate the pathogenicity of the identified changes, and extend previous work of the applicability of the antisense approach in methylmalonic aciduria (MMAuria) for a novel intronic mutation.

Prediction of outcome in isolated methylmalonic acidurias: combined use of clinical and biochemical parameters

Objectives Isolated methylmalonic acidurias (MMAurias) are caused by deficiency of methylmalonyl-CoA mutase or by defects in the synthesis of its cofactor 5'-deoxyadenosylcobalamin. The aim of this study was to evaluate which parameters best predicted the long-term outcome. Methods Standardized questionnaires were sent to 20 European metabolic centres asking for age at diagnosis, birth decade, diagnostic work-up, cobalamin responsiveness, enzymatic subgroup (mut(0), mut(-), cblA, cblB) and different aspects of long-term outcome. Results 273 patients were included. Neonatal onset of the disease was associated with increased mortality rate, high frequency of developmental delay, and severe handicap. Cobalamin non-responsive patients with neonatal onset born in the 1970s and 1980s had a particularly poor outcome. A more favourable outcome was found in patients with late onset of symptoms, especially when cobalamin responsive or classified as mut(-). Prevention of neonatal crises in pre-symptomatically diagnosed newborns was identified as a protective factor concerning handicap. Chronic renal failure manifested earlier in mut(0) patients than in other enzymatic subgroups. Conclusion Outcome in MMAurias is best predicted by the enzymatic subgroup, cobalamin responsiveness, age at onset and birth decade. The prognosis is still unfavourable in patients with neonatal metabolic crises and non-responsiveness to cobalamin, in particular mut(0) patients.

Renal transplant in methylmalonic acidemia: could it be the best option? Report on a case at 10 years and review of the literature

Methylmalonic acidemia (MMA) is an inborn error of organic acid metabolism. Patients with severe disease develop many complications despite treatment; often, the disease progresses to severe damage of the central nervous system or to end-stage renal disease (ESRD). When medical treatment is ineffective, liver, kidney, or combined liver and kidney transplantation is advocated. At present, there are no definite guidelines as for the organ to be transplanted, and results are inconsistent. We report on a 27-year-old woman with MMA MUT0. The clinical symptoms developed at age 4 months. She progressed to ESRD and received a kidney transplant in November 1996 at age 17 years. One hundred and twenty months after transplant, renal function is normal; although urinary levels of methylmalonic acid are above normal limits, no episodes of metabolic decompensation have been observed after transplantation. Although liver is the major site of methylmalonyl-CoA mutase activity, this case and similar ones in the literature suggest that the smaller mutase activity present in the transplanted kidney may be sufficient to ensure partial correction of the metabolism of organic acids sufficient to prevent the onset of episodes of metabolic decompensation. It is worth investigating whether kidney transplant can be a safer and more satisfactory alternative to liver transplantation in cases of MMA unresponsive to medical treatment although urine MMA excretion remains significantly elevated.

Adenoviral-mediated correction of methylmalonyl-CoA mutase deficiency in murine fibroblasts and human hepatocytes

BACKGROUND

Methylmalonic acidemia (MMA), a common organic aciduria, is caused by deficiency of the mitochondrial localized, 5'deoxyadenosylcobalamin dependent enzyme, methylmalonyl-CoA mutase (MUT). Liver transplantation in the absence of gross hepatic dysfunction provides supportive therapy and metabolic stability in severely affected patients, which invites the concept of using cell and gene delivery as future treatments for this condition.

METHODS

To assess the effectiveness of gene delivery to restore the defective metabolism in this disorder, adenoviral correction experiments were performed using murine Mut embryonic fibroblasts and primary human methylmalonyl-CoA mutase deficient hepatocytes derived from a patient who harbored two early truncating mutations, E224X and R228X, in the MUT gene. Enzymatic and expression studies were used to assess the extent of functional correction.

RESULTS

Primary hepatocytes, isolated from the native liver after removal subsequent to a combined liver-kidney transplantation procedure, or Mut murine fibroblasts were infected with a second generation recombinant adenoviral vector that expressed the murine methylmalonyl-CoA mutase as well as eGFP from distinct promoters. After transduction, [1-14C] propionate macromolecular incorporation studies and Western analysis demonstrated complete correction of the enzymatic defect in both cell types. Viral reconstitution of enzymatic expression in the human methylmalonyl-CoA mutase deficient hepatocytes exceeded that seen in fibroblasts or control hepatocytes.

CONCLUSION

These experiments provide proof of principle for viral correction in methylmalonic acidemia and suggest that hepatocyte-directed gene delivery will be an effective therapeutic treatment strategy in both murine models and in human patients. Primary hepatocytes from a liver that was unsuitable for transplantation provided an important resource for these studies.

[Diagnosis and treatment of methylmalonic aciduria: a case report]

The methylmalonic aciduria is an organic acidemia, inherited as autosomic recessive trait, caused by a deficiency of the methylmalonyl-CoA mutase, or by defects in the biosynthesis of the cofactor adenosylcobalamin. Regarding the enzymatic defect, there are two forms: mut(o) with no detectable enzymatic activity and mut(-) with reduced activity. Its clinical presentation may vary from a severe neonatal form with acidosis and death, up to a progressive chronic form. Here we describe the case of a four year-old boy, with diagnosis of methylmalonyl-CoA mutase deficiency type mut(-) with an acute presentation. Molecular analysis of MUT gene identified two mutations c.607G>A (G203R) and c.2080C>T (R694W), later confirmed in the parents. The aim of this report is to highlight the importance of including the organic acid analysis in urine among the first line exams in acutely and severely ill children with undefined etiology. The definitive diagnosis is important because it may allow a specific treatment and a favorable evolution to prevent the secuelae.

Mutation and biochemical analysis of 19 probands with mut0 and 13 with mut- methylmalonic aciduria: identification of seven novel mutations

Isolated methylmalonic acidurias (MMA-urias) comprise a group of rare autosomal recessively inherited disorders characterised by accumulation of MMA in urine and other body fluids, resulting from deficient activity of the mitochondrial enzyme methylmalonyl-CoA mutase (MCM). Isolated MMA-uria results from either MCM apoenzyme defects (mut(0) and mut(-)) or defects in synthesis of its cofactor 5-deoxyadenosylcobalamin, i.e. cblA, cblB and cblD-variant 2. To date various studies have identified 171 disease-causing mutations in the MCM gene (MUT). We report mutation analysis in 32 probands with mut MMA-uria including 13 probands with a mut(-) defect. Sixty two of 64 possible mutant alleles were identified, seven of which were novel missense alleles. We found three novel mutations (c.427C>T/p.H143Y; c.862T>C/p.S288P; c.1361G>A/p.G454E) among 19 probands with a mut(0) defect and four novel mutations (c.299A>G/p.Y100C; c.1031C>T/p.S344F; c.1097A>G/p.N366S; c.2081G>T/p.R694L) among 13 probands with a mut(-) defect. Our study provides evidence that the p.Y100C, p.R108H, p.N366S, p.V633G, p.R694W, p.R694L and p.M700K mutations are associated with a mut(-) phenotype.

Clinical and biochemical studies on Chinese patients with methylmalonic aciduria

Methylmalonic aciduria is a common organic aciduria disease. Recently, gas chromatography-mass spectrometry has been used to diagnose methylmalonic aciduria in China. Often, however, the diagnosis of methylmalonic aciduria is delayed because of a lack of technical expertise and the limited experience of general clinicians in China. In this study, the natural history, clinical features, and outcome of 77 Chinese patients with methylmalonic aciduria were investigated. Of the 77 patients, 31 (40.3%) had isolated methylmalonic aciduria and 46 (59.7%) had methylmalonic aciduria combined with homocystinemia. Thus, we observed a higher rate of the combined disease than studies conducted in other countries, suggesting that it might be more common in China. Total plasma homocysteine measurement might enable differential diagnoses of methylmalonic aciduria to be distinguished. The clinical spectrum of these 77 patients with methylmalonic aciduria ranged from neonatal death and severe symptoms to benign asymptomatic organic aciduria. Neonatal and infantile onset, which was a characteristic of the majority of cases, was associated with a greater severity relative to later-onset cases. Among the 17 cases who had onset after 3 years of age, only 1 patient had isolated methylmalonic aciduria and 16 had combined methylmalonic aciduria and homocystinemia. Nine of the patients with combined methylmalonic aciduria and homocystinemia completely recovered and exhibited normal intelligence, whereas seven improved, with a mild handicap.

Mutation and haplotype analyses of the MUT gene in Japanese patients with methylmalonic acidemia

Methylmalonic acidemia (MMA) is caused by a deficiency in the activity of L: -methylmalonyl-CoA mutase (MCM), a vitamin B12 (or cobalamin, Cbl)-dependent enzyme. Apoenzyme-deficient MMA (mut MMA) results from mutations in the nuclear gene MUT. Most of the MUT mutations are thought to be private or restricted to only a few pedigrees. Our group elucidated the spectrum of mutations of Japanese mut MMA patients by performing mutation and haplotype analyses in 29 patients with mut MMA. A sequence analysis identified mutations in 95% (55/58) of the disease alleles. Five mutations were relatively frequent (p.E117X, c.385 + 5G > A, p.R369H, p.L494X, and p.R727X) and four were novel (p.M1V, c.753_753 + 5delGGTATA, c.1560G > C, and c.2098_2099delAT). Haplotype analysis suggested that all of the frequent mutations, with the exception of p.R369H, were spread by the founder effect. Among 46 Japanese patients investigated in the present and previous studies, 76% (70/92) of the mutations were located in exons 2, 6, 8, and 13. This finding - that a limited number of mutations account for most of the mutations in Japanese mut MMA patients - is in contrast with results of a previous study in Caucasian patients.

Liver transplantation is not curative for methylmalonic acidopathy caused by methylmalonyl-CoA mutase deficiency

Methylmalonic acidopathy resulting from severe methylmalonyl-CoA mutase deficiency causes acute, potentially lethal ketoacidotic episodes, renal failure, and acute and chronic neurologic disease. As dietary and alkali therapy is suboptimal, liver transplantation during infancy has been touted as a potential cure. However, reports in liver transplant recipients about new onset neurologic disease, in the absence of ketoacidosis, and progressive renal insufficiency have cast doubt about its effectiveness. We report the long-term (9 years) outcome for the first patient with severe methylmalonic acidopathy transplanted in the USA and provide new biochemical data that indicate why transplanted patients are still susceptible to "metabolic strokes". In our 10-year-old male patient, there is clear evidence that the de novo synthesis of propionyl-CoA within the CNS leads to brain methylmalonate (MMA) accumulation that is largely unaffected by transplantation. Liver replacement is not a cure for methylmalonic acidopathy.

Three novel and six common mutations in 11 patients with methylmalonic acidemia

BACKGROUND

Patients with a defect in methylmalonyl-coenzyme A mutase (MCM) are classified as having methylmalonic acidemia, which is divided into two subclasses: mut(0) and mut(-). Fifty-five disease-causing mutations have been identified. Although most are private mutations, only three (E117X, G717V, and N219Y) are reportedly common in Japanese, Black, and Caucasian populations, respectively. Here we identified mutations in 11 Japanese patients with MCM deficiency.

METHODS

Mutational analysis was performed in 11 unrelated Japanese patients with MCM deficiency using polymerase chain reaction and direct sequencing.

RESULTS

Three novel (L494X, R727X, and 449_461del) and six previously reported (R93H, E117X, N219Y, R369H, G648D and IVS2 + 5G>A) mutations were identified. The L494X mutation was found in three unrelated patients, and the R93H, E117X, R369H, G648D, and IVS2 + 5G>A mutations occurred more than once. Two of the patients were classified as mut(-) phenotype because of residual [(14)C]-propionate incorporation in the presence of a high concentration of hydroxocobalamin. The two mut(-) patients were heterozygous for the G648D mutation and presented with lethargy and metabolic acidosis after 2 years of life. Their psychomotor development has been documented as normal. The patients with the R727X or c.374_385del [corrected] mutations clinically exhibited mut(0) phenotype. Two patients with mut(0) phenotype died in infancy. One presented early in the neonatal period; the other was symptomatic in the late infantile period.

CONCLUSIONS

The L494X, R93H, E117X, R369H, G648D, and IVS2 + 5G>A mutations are found in more than two unrelated families in the Japanese population. The short-term outcome was generally poor in patients with mut(0), and therefore alternative treatments should be considered.

Impaired energy metabolism and abnormal muscle histology in mut- methylmalonic aciduria

The authors report a 27-year-old man with B12-responsive mut- methylmalonic aciduria associated with pure muscle symptoms. Two mutations were found in the methylmalonyl-CoA mutase gene. An exercise test showed a reduced maximal workload and reduced oxygen uptake, and a muscle biopsy showed subsarcolemmal accumulation of mitochondria and normal respiratory chain enzyme activities. These findings may be caused by inhibition of mitochondrial energy metabolism by methylmalonate or its metabolites.

Molecular basis of methylmalonyl‐CoA mutase apoenzyme defect in 40 European patients affected by mut ° and mut – forms of methylmalonic acidemia: Identification of 29 novel mutations in the MUT gene

Methylmalonyl-CoA mutase (MCM) apoenzyme deficiency is a rare metabolic disease that may result in distinct biochemical phenotypes of methylmalonic acidemia (MMA), namely mut(o) and mut-. We analyzed a cohort of 40 MCM-deficient patients with MMA affected by either the mut(o) or the mut- form of the disease. By direct sequencing of cDNA and gDNA of the MUT gene, we detected 42 mutations, 29 of which were novel mutations. These included five frameshift mutations (insertion, deletion, or duplication of a single nucleotide), five sequence modifications in consensus splice sites, six nonsense and 12 missense mutations, and a large genomic deletion including exon 12. We explored how the 12 novel missense mutations might cause the observed phenotype by mapping them onto a three-dimensional model of the human MCM generated by homology with the P. shermanii enzyme. In this work we update the spectrum of MCM mutations (n=84), and then discuss their prevalence and distribution throughout the coding sequence in relation to the enzyme structure.

Mutational spectrum in ten Italian patients affected by methylmalonyl-CoA mutase deficiency

We report seven novel mutations, including three amino acids substitutions (p.Glu286Lys, p.Cys560Tyr, p.Pro615Leu), two nonsense mutations (p.Arg31X, p.Glu 451X), one splicing defect (c.2125-1G >A), one small deletion (c.1758-1759delA) and nine previously described mutations identified in 10 unrelated Italian patients affected by mut MMA.

Methylmalonic aciduria: follow-up and enzymology on the original case after 36 years

A 36-year follow-up on the original patient described with methylmalonic aciduria has shown that she has methylmalonyl-CoA apomutase deficiency. The main clinical problem associated with her methylmalonic aciduria is progressive renal impairment requiring commencement of haemodialysis at 42 years of age.

Breastfeeding experience in inborn errors of metabolism other than phenylketonuria

Breastfeeding has been recommended for the dietary treatment of infants with phenylketonuria, but studies documenting clinical experience in other inborn errors of metabolism are very few. Seven infants diagnosed with methylmalonyl-CoA mutase deficiency (n=2), ornithine carbamoyltransferase deficiency (n=1), propionic acidaemia (n=1), isovaleric acidaemia (n=1), maple syrup urine disease (n=1) and glutaric acidemia type I (n=1) were tried with breastfeeding over two years. After the control of acute metabolic problems, an initial feeding period with a measured volume of expressed breast milk plus a special essential amino acid mixture was continued with breastfeeding on demand and with the addition of a special essential amino acid mixture. Two patients with methylmalonic acidaemia and one patient with glutaric acidaemia type I tolerated breastfeeding on demand very well, with good growth and metabolic control for periods of 18, 8 and 5 months, respectively. In the patient with propionic acidaemia, on-demand breastfeeding continued for 3 months but was terminated after two acute metabolic episodes. The patient with isovaleric acidaemia had insufficiency of breast milk and formula supplementation ended with breast milk cessation. In the patient with severe ornithine carbamoyltransferase deficiency, breastfeeding was stopped owing to poor metabolic control. The patient with maple syrup urine disease also experienced problems, both in metabolic control and in insufficiency of breast milk, resulting in termination of breastfeeding. Breastfeeding of infants with inborn errors of protein catabolism is feasible, but it needs close monitoring with attention to such clinical parameters as growth, development and biochemistry, including amino acids, organic acids and ammonia.

Mutation analysis of the MMAA and MMAB genes in Japanese patients with vitamin B(12)-responsive methylmalonic acidemia: identification of a prevalent MMAA mutation

Methylmalonic acidemia (MMA) is caused by the deficient activity of l-methylmalonyl-CoA mutase, which is a vitamin B(12) (or cobalamin, Cbl)-dependent enzyme. MMA due to the effect of insufficient Cbl metabolism is classified into three forms (cblA, cblB, and cblH). Recently, the genes responsible for cblA and cblB were identified as MMAA and MMAB, respectively. The MMAA protein likely transports Cbl into the mitochondria for adenosylcobalamin synthesis, while the MMAB protein appears to be an adenosyltransferase. We performed a mutation analysis of 10 unrelated Japanese patients with vitamin B(12)-responsive MMA. Seven patients had mutations in MMAA, whereas the other three patients showed no disease-causing substitutions in either MMAA or MMAB. Five novel mutations were identified in MMAA (R22X, R145X, L217X, R359G, and 503delC). The 503delC mutation was observed in five of the seven MMAA patients, suggesting that the mutation is prevalent in Japanese patients. This finding may facilitate the DNA diagnosis of vitamin B(12)-responsive MMA within the Japanese population.

Growth hormone deficiency associated with methylmalonic acidemia

Poor growth is a common finding in patients with organic acidemias. Growth hormone (GH) therapy has been considered in the management of these disorders as a mode to enhance anabolism and lower the high levels of methylmalonic acid. We report two patients with methylmalonic acidemia (mut(o)) and GH deficiency. Both patients had persistently elevated serum concentrations of methylmalonic acid, which failed to respond to conventional therapy. In anticipation of using GH therapy to reduce high methylmalonic acid concentrations, the first patient underwent GH testing utilizing a provocative glucagon stimulation test and was found to be deficient. He was subsequently treated with GH and demonstrated improved growth, but his methylmalonic acid concentrations remain elevated. The second patient was also found to be GH deficient. These findings suggest that GH deficiency may be an etiologic factor in the poor growth seen in patients with organic acidemia.

Novel mutations in a Thai patient with methylmalonic acidemia

A Thai patient with methylmalonic acidemia (MMA) and no methylmalonyl-CoA mutase (MCM, EC 5.4.99.2) activity in leukocytes in the presence of deoxyadenosyl cobalamin (mut(0)) was found to be heterozygous for two novel mutations: 1048delT and 1706_1707delGGinsTA (G544X), inherited from her mother and father, respectively. The proband was also heterozygous for the polymorphism, A499T, which did not affect the activity of recombinant MCM.

Identification of the human and bovine ATP:Cob(I)alamin adenosyltransferase cDNAs based on complementation of a bacterial mutant

In humans, deficiencies in coenzyme B12-dependent methylmalonyl-CoA mutase (MCM) lead to methylmalonyl aciduria, a rare disease that is often fatal in newborns. Such deficiencies can result from inborn errors in the MCM structural gene or from mutations that impair the assimilation of dietary cobalamins into coenzyme B12 (Ado-B12), the required cofactor for MCM. ATP:cob(I)alamin adenosyltransferase (ATR) catalyzes the terminal step in the conversion of cobalamins into Ado-B12. Substantial evidence indicates that inherited defects in this enzyme lead to methylmalonyl aciduria, but the corresponding ATR gene has not been identified. Here we report the identification of the bovine and human ATR cDNAs as well as the corresponding human gene. A bovine liver cDNA expression library was screened for clones that complemented an ATR-deficient bacterial strain for color formation on aldehyde indicator medium, and four positive clones were isolated. The DNA sequences of two clones were determined and found to be identical. Sequence similarity searching was then used to identify a homologous human cDNA (89% identity) and its corresponding gene that is located on chromosome XII. The bovine and human cDNAs were independently cloned and expressed in Escherichia coli. Enzyme assays showed that expression strains produced 87 and 98 nmol/min/mg ATR activity, respectively. These specific activities are in line with values reported previously for bacterial ATR enzymes. Subsequent studies showed that the human cDNA clone complemented an ATR-deficient bacterial mutant for Ado-B12-dependent growth on 1,2-propanediol. This demonstrated that the human ATR is active under physiological conditions albeit in a heterologous host. In addition, Western blots were used to show that ATR expression is altered in cell lines derived from cblB methylmalonyl aciduria patients compared with cell lines from normal individuals. We propose that inborn errors in the human ATR gene identified here result in methylmalonyl aciduria. The identification of genes involved in this disorder will allow improvements in the diagnosis and treatment of this serious disease.

Molecular studies in mutase-deficient (MUT) methylmalonic aciduria: identification of five novel mutations

Mutase-deficient (MUT) methylmalonic aciduria (MMA) is an autosomal recessive inborn error of organic acid metabolism, resulting from a functional defect in the nuclear encoded mitochondrial enzyme methylmalonyl-CoA mutase (MCM) (EC.5.4.99.2). The enzyme requires 5'-deoxyadenosylcobalamin as a cofactor. Isolated MMA results from either apoenzyme or cofactor defects, and is classified into several genotypic classes and complementation groups. These are designated mut(-) or mut(0) (together termed mut), depending on minimal or no apoenzyme activity respectively and cobalamin A or B (cbl A/B) for cofactor defects. To date various studies have identified over 53 disease-causing mutations from patients with mut(0/-) MMA. These are predominantly missense/nonsense nucleotide substitutions. In this study, we report the genotype analysis on 7 patients diagnosed with mut MMA. Five novel mutations were identified (R403stop, 497delG, P615T, 208delG and R467stop) and one novel polymorphism (c712A->G). The previously reported R228Q mutation was found in one patient, who is a compound heterozygote for this mutation and the R467stop mutation. A recently reported N219Y mutation was found in one patient. The 497delG mutation was detected as a homozygous deletion. The remaining mutations were observed in compound heterozygotes, with the second mutation yet to be identified. Many of the unidentified mutations may occur within the promotor or intronic regions.

Progressive neurologic disability in methylmalonic acidemia despite transplantation of the liver

Methylmalonic acidemia unresponsive to cobalamin is often fatal in infancy. Patients have been considered candidates for hepatic transplantation and experience has been that the procedure eliminates the life-threatening episodes of ketoacidosis that characterize this disease.

CONCLUSION

experience with a 24-year-old patient treated with hepatic transplantation indicates that this procedure does not prevent progressive renal failure and neurologic dysfunction.

Cobalamin (Cbl) C/D deficiency: clinical, neurophysiological and neuroradiologic findings in 14 cases

The early onset type of cobalamin (Cbl) C/D deficiency is characterised by feeding difficulties, failure to thrive, hypotonia, seizures, microcephaly and developmental delay. It has an unfavourable outcome, often with early death and significant neurological impairment in survivors. While clinical and biochemical features of Cbl C/D deficiency are well known, only a few isolated case reports are available concerning neurophysiological and neuroimaging findings. We carried out clinical, biochemical, neurophysiological and neuroradiologic investigations in 14 cases with early-onset of the Cbl CID defect. Mental retardation was identified in most of the cases. A variable degree of supratentorial white matter atrophy was detected in 11 cases by MR imaging and tetraventricular hydrocephalus was present in the remaining 3 patients. Waking EEG showed a clear prevalence of epileptiform abnormalities, possibly related to the high incidence of seizures in these cases. Increased latency of evoked responses and/or prolongation of central conduction time were the most significant neurophysiological abnormalities. The selective white matter involvement, shown both by neuroradiologic and neurophysiological studies, seems to be the most consistent finding of Cbl C/D deficiency and may be related to a reduced supply of methyl groups, possibly caused by the dysfunction in the methyl-transfer pathway.

Seven novel mutations in mut methylmalonic aciduria

Methylmalonic aciduria (MMA) is an autosomal recessive inborn error of metabolism that results from functional defects in methylmalonyl CoA mutase (MCM), a nuclear-encoded, mitochondrial enzyme that uses the vitamin B12 derivative, adenosylcobalamin (AdoCbl) as a cofactor. To date, 23 mutations have been identified at the MUT locus on the short arm of chromosome 6, causing the mut forms of MMA (mut complementation group; mut MMA, McKusick #251000). We now report seven novel mutations. Three were found inmut0 patients: R228Q (c759G-->A) was found as a heterozygous change; G312V (c1011G-->T) and 346delL (c1112delCTT) were both found as homozygous changes. Four mutations were found in mut patients: A191E (c648C-->A) and V633G (c1974T-->G) were found in the same patient; 684insL (c2128insCTC) and L685R (c2130T-->G) were both found as homozygous changes. The recent modelling of the human methylmalonyl CoA mutase allowed for an interpretation of the identified mutations.

Liver transplantation for methylmalonic acidaemia

The outcome for children with severe forms of methylmalonic acidaemia remains poor. Patients have recurrent episodes of metabolic decompensation; many have neurodevelopmental complications and the mortality is high. Long-term survivors develop chronic renal failure. Because of the poor prognosis, transplantation has been considered. In young patients with early onset disease, liver transplantation might prevent complications and, for those in end-stage renal failure, kidney transplantation could be combined with that of the liver. The results of liver transplantation in the early onset patients have generally been disappointing. In particular there appears to be a high risk of neurological complications. The optimal management of those in end-stage renal failure has not yet been determined although combined liver and kidney transplantation has been successful.

CONCLUSION

The role of transplantation in methylmalonic acidaemia has yet to be established and follow up of all patients who are considered for transplantation is essential.

Towards metabolic sink therapy for mut methylmalonic acidaemia: correction of methylmalonyl-CoA mutase deficiency in T lymphocytes from a mut methylmalonic acidaemia child by retroviral-mediated gene transfer

The pathology associated with mut methylmalonic acidaemia (MMA) is caused by systemic accumulation of methylmalonate. Therefore, removal of methylmalonate from the circulation of affected individuals by an engineered metabolic system is proposed as a potential treatment. The haematopoietic cell is a potential site for such a metabolic system because of its direct contact with the accumulated metabolite and the demonstrated safety and ease in utilizing this cell. In this study, we assessed the feasibility of developing a haematopoietic cell-based methylmalonate sink by analysing propionate/methylmalonate metabolism in a variety of haematopoietic cells. The results show that propionate metabolism and methylmalonyl-CoA mutase (MCM) activity are intact in primary T cells, EBV-B cells, and CD34+ haematopoietic stem cell-derived granulocytes, whereas they are defective in those from a mut MMA child. Moreover, normal T and EBV-B cells clear methylmalonate from the medium at a significant rate. Transduction of MCM-deficient T cells with a recombinant retrovirus encoding the human MCM cDNA results in correction of propionate metabolism. These results establish the basis for developing haematopoietic cell-based metabolic sink therapy for mut MMA by T lymphocyte/haematopoietic stem cell-directed gene transfer.

Successful pregnancy in severe methylmalonic acidaemia

Methylmalonic acidaemia is an inborn error of metabolism characterized by recurrent episodes of life-threatening ketoacidosis. With improved and intensive treatment, these patients are living into adulthood, but many experience late-onset disease complications such as chronic renal failure, chronic pancreatitis and osteopenia. We report the successful delivery of a healthy baby to a 20-year-old woman with vitamin B12-unresponsive methylmalonic acidaemia who has these late-onset manifestations of the disease and had plasma methylmalonic acid concentrations of 1900 mumol/L during the first trimester of pregnancy.

Molecular analysis of methylmalonyl-CoA mutase deficiency: identification of three missense mutations in mut0 patients

Genetic defects in the methylmalonyl-CoA mutase (MCM) gene cause methylmalonic acidemia (MMA). Only three mutations have been reported among Oriental patients to date. We studied fibroblast cell lines established from three Japanese patients with MCM deficiency. Enzymatic study showed that these patients had the muttype of MMA. Nucleotide sequencing of MCM cDNAs identified three missense mutations: a T to A change at nucleotide position 2082, which results in an amino acid substitution of Glu669 for valine (V669E); a T to A change at position 1179 with the corresponding amino acid substitution of Asp368 for valine (V368D); and a G to A change at position 1182 with the corresponding amino acid substitution of His369 for arginine (R369H). Each of the three missense mutations abolished MCM activity according to a transient expression study. Alignment of these mutations with a recently reported homology model of human MCM allowed us to speculate on the effect of these nonconservative amino acid substitutions on MCM activity: V368D and R369H affected residues in the beta/alpha-(TIM-) barrel domain, on one of the two alpha-helices that form the dimer interface, while V669E altered a residue in the adenosylcobalamin-binding domain in the C terminus.

Renal transplantation in a patient with methylmalonic acidaemia

Renal insufficiency is frequently reported in mutase-deficient methylmalonic acidaemia. We present a case report of a patient with mut- methylmalonic acidaemia who developed chronic tubulointerstitial nephropathy during adolescence. At 24 years of age, she developed end-stage renal failure and underwent renal transplantation. Both plasma and urine methylmalonic acid levels decreased significantly with improved renal function following transplantation. Complications included cyclosporin toxicity and development of diabetes. Renal, metabolic, and clinical status remained improved at 3 years after the kidney transplant.

Methylmalonic acidaemia with bilateral globus pallidus involvement: a neuropathological study

A 16-month-old boy was hospitalized because of a 1-day history of severe ketoacidosis with lethargy, hypotonia, vomiting, and important dyspnoea. Organic acid assay by gas chromatography-mass spectrometry confirmed the diagnosis of methylmalonic acidaemia (MMA). On the sixteenth day, he developed an acute extrapyramidal disorder. The CT scan of the brain disclosed bilaterally symmetric lucency of basal ganglia. He died at 17 months of age. Post-mortem neuropathological examination, showed severe necrosis with spongiosis, cystic cavitation and numerous lipid-laden macrophages of the globi pallidi, and mild spongiosis of subthalamic nuclei, mammillary bodies, portion of internal capsule adjacent to globus pallidus, superior cerebellar peduncles and tegmentum of brainstem. Pallidal infarction, a focal ischaemic lesion, demonstrates that ischaemia/energy depletion may be important in the etiology of the neuropathology of MMA.

Combined liver-kidney transplantation in methylmalonic acidemia

A 13-year-old boy with non-B12-responsive methylmalonic acidemia (MMA) had chronic renal failure. Hemodialysis led to symptomatic and biochemical improvement. He subsequently received a combined liver-kidney transplant. After 16 months of follow-up he has a normal lifestyle and a marked reduction in plasma and urine methylmalonate.

Neurological dysfunction in methylmalonic acidaemia is probably related to the inhibitory effect of methylmalonate on brain energy production

Methylmalonic acidaemia is an inherited metabolic disorder caused by a severe deficiency of the activity of the enzyme L-methylmalonyl-CoA mutase or its cofactor 5'-deoxyadenosylcobalamin, resulting in tissue accumulation of large quantities of methylmalonic acid. Among the various clinical features, neurological symptoms are frequently observed. Patients may present cerebral atrophy and basal ganglia abnormalities are common. In the present report, we update the current knowledge on the influence of methylmalonic acid on brain metabolism in the hope of better understanding the neurological dysfunction characteristic of methylmalonic acidaemia. We present evidence showing that the metabolite inhibits brain energy production by various mechanisms and propose that a fall in cellular ATP generation leading to excitotoxicity is crucial for the occurrence of the neurological damage observed in these patients.

Use of human somatotrophin in the treatment of a patient with methylmalonic aciduria

Growth hormone (GH) insufficiency was demonstrated in a patient with methylmalonic aciduria. GH administration at 14-21 U/m2 per week accelerated linear growth, stimulated lipolysis, and produced clinical improvement and reduced urinary methylmalonate excretion. The clinical and metabolic benefits were lost as the dose of GH was increased to 28 U/m2 per week. CONCLUSION. The use of GH in other patients with methylmalonic aciduria (and other disorders of intermediary metabolism demonstrating similar clinical and metabolic features) warrants further study.

Methylmalonic acidemia: brain lesions in a case of vitamin B12 non-responsive (mut0) type

Neuropathological findings were described in a 9-day-old female infant who died of the vitamin B12 non-responsive (mut0) type of methylmalonic acidemia (MMA). Widespread karyorhectic fragments of varying size and shape were noted throughout the brain, in particular densely accumulated in the cerebellar granular layers and the layer IV of the striate cortex. Bilateral or symmetrical necrotic foci were observed in various regions of the grey matter: Sommer's sector of the hippocampus, basal ganglia, thalamus, hypothalamus and brainstem. In the cerebral cortex small spongy necrotic foci were scattered mainly in the depths of gyri. Alzheimer type II astrocytes appeared in the preserved zone of the caudate nucleus. Myelinated nerve fibers in the brainstem were spongy or vacuolated, whereas peripheral myelin sheaths of cranial nerves were intact. Multiple hemorrhagic foci were noted in the cerebellum, predominantly the granular layers. The lymphoid tissue in the spleen and the thymus was hypoplastic. It may be difficult to explain exactly the mechanisms of the pathological changes observed here on routine light microscopy; the outcome of systemic ischemia/hypoxia before death cannot be completely ignored. But, it is suggested that widespread karyorhexis may occur selectively in specific cells (or cell groups), including immature neurons and other cellular components (glial and/or mesenchymal cells) among the patients with the mut0 type of MMA.

[Molecular diagnosis of a kindred with novel mutation of methylmalonyl-CoA mutase gene using non-RI SSCP]

A deficiency of methylmalonyl-CoA mutase (MCM) results in methylmalonic acidemia, which is inherited as an autosomal recessive disease and is characterized by accumulation of precursors and abnormal derivatives of methylmalonyl-CoA in body fluids. Abnormal splicing with 13 base pairs (bp) insertion at MCM exons 2 and 3 junction in MCM transcripts and a homozygous point mutation, g to a transition, on 5 bp downstream exon 2 were detected in a proband with methylmalonic acidemia. The parents in the kindred were heterozygous carriers of the g to a transition in MCM intron 2. Non-RI single strand conformation polymorphisms (SSCP) was conducted to devise for analysis of this MCM mutation. This non-RI SSCP is considered to be useful diagnostic means with high potential for extended clinical application.

Metabolic persistence of fetal hemoglobin

Hereditary persistence of fetal hemoglobin (HPFH) has typically been ascribed to mutations in the beta-globin gene cluster. Pharmacologic agents, including the short-chain fatty acid butyrate, have been shown to upregulate fetal and embryonic globin gene expression. In this report we investigate the possibility that metabolic derangements characterized by an inability to metabolize another short-chain fatty acid, propionate, could be associated with a persistence of fetal hemoglobin unrelated to alterations in the beta-globin cluster. Embryonic globin gene upregulation in a murine adult erythroid cell culture was shown by RNase protection after induction with three short-chain fatty acids (C2-C5). Chart reviews and measurement of fetal hemoglobin in five patients with abnormalities in propionate (C3) metabolism were undertaken; SSCP/dideoxy fingerprint analysis of the gamma-globin gene promoters was done in three of these five patients. Twelve patients with other metabolic derangements served as controls. Only the four patients with clinically severe abnormalities in propionate metabolism (ages 2 to 11), but without anemia, showed a sustained elevation in fetal hemoglobin (3% to 10%). The level of elevation of fetal hemoglobin in these patients, who lack erythropoietic stress, suggests that propionic acid and/or its metabolites are potent stimulators of fetal hemoglobin expression. Study of this group of patients should allow unique insights into the long-term effects of sustained exposure to elevations of short-chain fatty acid levels.

Identification of two novel mutations in the methylmalonyl-CoA mutase gene with decreased levels of mutant mRNA in methylmalonic acidemia

Genetic defects in the methylmalonyl-CoA mutase (MCM) gene result in methylmalonic acidemia which is inherited as an autosomal recessive disease. We investigated fibroblast cultures obtained from two Japanese patients with MCM deficiency. MCM mRNA was not detected by Northern blot analysis, suggesting that MCM mRNA was markedly decreased. Reverse transcription/polymerase chain reaction (RT-PCR) of MCM mRNA followed by analysis on a fluorescent fragment analyzer indicated that the level of MCM mRNA in these fibroblasts was less than 1% of normal controls. This minute amount of MCM mRNA was successfully amplified by nested RT-PCR and subjected to primary structure analysis. Sequence analysis revealed two novel mutations: a G-to-T substitution at nucleotide position 425 and a 2 bp deletion at nucleotide positions 769 and 770. The first mutation (G425T) resulted in the substitution of a termination codon for glutamic acid at amino acid position 117. The second mutation (769 delta CA) resulted in a frame shift which created a premature termination codon 508 amino acid upstream of the C-terminus of the protein. Patient 1 was homozygous for G425T and patient 2 was a compound heterozygote for G425T and 769 delta CA. Our report is the first to identify MCM mutations that affect the stability of MCM mRNA. An analysis of 16 Japanese patients revealed the presence of G425T in six patients, suggesting a relatively high incidence of the mutation among Japanese patients. This is in sharp contrast to a previous report describing diverse heterogeneity of MCM mutations among Caucasians.

Congenital absence of insulin cells in a neonate with diabetes mellitus and mutase-deficient methylmalonic acidaemia

We report on a female neonate with diabetes mellitus and methylmalonic acidaemia, who died at age 16 days. Using immunocytochemistry, electron microscopy and in situ hybridisation, we were unable to demonstrate any insulin cells in the pancreatic islets. Methylmalonic acidaemia was caused by a methylmalonyl coenzyme A mutase apoenzyme defect. The metabolic crisis of the methylmalonic acidaemia aggravated the diabetes and may explain the failure of insulin therapy. Our results suggest that the infant suffered from a congenital absence of beta cells associated with a genetically transmitted mutase apoenzyme defect.

Propionate metabolism in cultured human cells after overexpression of recombinant methylmalonyl CoA mutase: implications for somatic gene therapy

Strategies for somatic gene therapy must consider the metabolic consequences of expressing the recombinant gene product in addition to methods for gene transfer and expression. We describe studies of propionate metabolism in cultured cells transfected with methylmalonyl CoA mutase (MCM), the enzyme deficient in mut methylmalonic acidemia. Transfection of MCM into mut fibroblasts restores propionate metabolism to normal levels in a dose-dependent manner. Overexpression of MCM, or the addition of excess propionate, carnitine, or cobalamin, does not increase propionate metabolism in normal human fibroblasts, lymphoblasts, or hepatoma cells, although hepatic cells exhibit > 10-fold higher levels of propionate metabolism. Significantly, the restoration of propionate metabolism in mut fibroblasts is disproportionately greater than the efficiency of transfection, suggesting the presence of a cooperative phenomenon between cells. Intercellular participation in propionate metabolism is evident in cocultures of MCM-deficient and propionyl CoA carboxylase-deficient cells. We conclude that the liver is the preferred target for gene therapy of MCM deficiency because of its greater capacity for propionate metabolism and that cooperation between cells could enhance the biological effect of a subpopulation of cells transformed with recombinant MCM.