An expanding spectrum of complications in isolated methylmalonic aciduria

Isolated methylmalonic aciduria (MMA) is a group of autosomal recessive disorders caused by mutations in the genes MMUT, MMAA, MMAB and MMADHC. Depending on the causative gene and – in case of MMUT – residual methylmalonyl-CoA mutase (MMUT; EC 5.4.99.2) enzyme activity, the MMA subtypes are called mut⁰, mut^-, cblA, cblB, cblD-variant 2 (1). MMUT is the enzyme responsible for the conversion of L-methylmalonyl-CoA to succinyl-CoA in mitochondria. The vitamin B12 (cobalamin) cofactor in the form of adenosylcobalamin is required to facilitate this isomerisation reaction (2). The substrate of MMUT is derived from propionyl-CoA, which is formed by the catabolism of protein, more specifically of the amino acids isoleucine, valine, threonine and methionine, and the breakdown of the side chain of cholesterol and odd-chain fatty acids. The product of the MMUT reaction, succinyl-CoA, enters the tricarboxylic acid (TCA) cycle, also located in the mitochondria. The TCA cycle is a sequence of vital biochemical reactions serving the purpose of providing molecules, which are utilised for energy production by the respiratory chain.

The vital biochemical function of the MMUT enzyme in mitochondrial metabolism is reflected by the devastating clinical consequences it causes in case of a deficiency. Onset of the disease varies. MMA patients might present early after birth following an initial symptom-free period of a few hours to days (3). Patients may show symptoms such as poor feeding, vomiting, increasing lethargy, imitating a septic-like clinical picture, which could lead to coma and death (4). Proposed guidelines for the diagnosis and management have been published to guide physicians (5).

Methylmalonic aciduria was first recognised as an inborn error of metabolism in the 1960s (6). Raised awareness of early presenting inborn errors of metabolism, enhanced diagnostic testing and advances in clinical care over the years has improved the survival of MMA patients through the initial acute phase of the disease. In addition, there are milder MMA phenotypes which present later (late-onset, i.e. after the neonatal period), e.g. during an acute illness (7). The increased life expectancy has led to an expansion of the so far known natural history of MMA, which shows a variety of long-term complications affecting different organ systems. In addition to the well-known complications, such as neurological problems and chronic kidney disease, it is becoming more evident, that the disease course of MMA also includes some so far less anticipated complications. The occurrence of an even broader variety of complications leads to the hypothesis that almost all organ systems can be affected by MMA, depending on their susceptibility. Many of the complications can be devastating and significantly affect the quality of life of patients. Hence, this review attempts to summarise the most common as well as the emerging long-term complications of MMA disease, allowing clinicians to monitor the respective organ systems and thus aiding patient management.

Various aspects of neurological complications have been described in MMA. One of the most devastating complications from a neurological perspective is related to the phenomenon of metabolic stroke during which patients experience an acute onset of neurological symptoms related to stroke-like lesions in the area of the basal ganglia. It is estimated that up to one third of MMA patients experience an episode of a metabolic stroke which subsequently often results in a movement disorder (29). An acute metabolic decompensation can not only trigger a metabolic stroke, but can also lead to epilepsy. Epilepsy can manifest as part of an acute metabolic decompensation or can be triggered by brain lesions which occurred during a metabolic decompensation (9). In addition, a majority of MMA patients show impaired cognitive function, which is associated with early-onset disease and the presence of hyperammonaemia at diagnosis as well as epilepsy (30, 31, 32). Also sensory organs are involved and MMA patients show ophthalmological complications in the form of optic atrophy (8, 33) as well as sensorineural hearing loss (8, 9).

Cytopenia of several cell lineages (mainly erythrocytes, neutrophils and thrombocytes) is commonly observed in MMA (8). It can occur during an acute metabolic crisis or chronically. Increased susceptibility to infections in the context of neutropenia has not been demonstrated in MMA patients so far. While the exact pathomechanisms causing these complications are unclear, anaemia might at least be exacerbated if renal failure is present due to insufficient synthesis of erythropoietin.

As this review illustrates, a variety of organ systems are affected by MMA disease. Some are not discussed in detail here, such as hypermobility of the joints or muscular hypotonia, further demonstrating the ubiquitous efects of MMUT deficiency on many tissues. The exact biological mechanisms underlying tissue damage and/or malfunction are yet to be determined (9). This lack of knowledge poses problems in the development of novel therapies, which are urgently required. Available disease models (15, 43, 44) can be used to further unravel yet unknown possible disease manifestations and their pathomechanisms and to assess the efficacy of novel treatment modalities.

In the meantime, this review suggests monitoring the full range of potential long-term complications, as only their early detection allows timely symptomatic treatment.