Mitochondrial Diseases Clinical Trial
Official title:
A Feasibility Study of Bezafibrate in Mitochondrial Myopathy
The purpose of this study is to gather preliminary data on whether bezafibrate can improve
cellular energy production in mitochondrial disease.
Mitochondrial diseases are rare inherited disorders that arise due to deficient energy
production within the cells of the body. Consequently, the typical clinical features arise in
organs with high energy requirements. Mitochondrial disorders exhibit highly variable
clinical effects, both between individuals and within families. Characteristic symptoms
include muscle weakness (myopathy), hearing loss, migraine, epilepsy and stroke like episodes
in addition to diabetes and heart problems. Mitochondrial disorders can therefore impact
considerably on both quality of life and life expectancy. Despite this, no proven disease
modifying treatments are available.
Pre-clinical studies have identified that several existing medications improve mitochondrial
function. Of these, bezafibrate has the best supportive data and, because it is already
licensed as a treatment for high blood fats, has a well characterised side effect profile.
The investigators will therefore conduct a feasibility study of bezafibrate in people with
mitochondrial myopathy. Ten affected participants will be recruited and will receive a
titrating course of bezafibrate three times daily for 12 weeks.
Mitochondrial disorders are genetically determined metabolic diseases affecting approximately
1 in 5000 people. Current strategies for treating mitochondrial disorders are limited, and
restricted to alleviating symptoms. A recently published Cochrane review did not identify any
disease modifying treatments of proven benefit. There is therefore an urgent and currently
unmet need for treatments that modify the underlying biochemical deficit and disease
trajectory.
Improving deficient oxidative phosphorylation (OXPHOS) pathways through induction of
mitochondrial biogenesis is a potential approach to the treatment of mitochondrial disorders.
This involves stimulating transcription factors for both nuclear and mitochondrial genomes
simultaneously in order to up-regulate respiratory chain (RC) gene expression. This role is
fulfilled by peroxisome proliferator activated receptor (PPAR)-γ coactivator-1α (PGC-1α); a
pivotal transcriptional co-factor widely considered the master regulator of mitochondrial
biogenesis.
PGC-1α interacts with a number of transcription factors. These include α, β/δ and γ isoforms
of the peroxisomal proliferator activated receptors (PPARs). This group of ubiquitously
expressed nuclear receptors is activated by binding of fatty acids. Subsequently,
transcription of genes involved in mitochondrial fatty acid oxidation is induced, thereby
enabling cellular metabolic shift from glycolysis. Additionally, PGC-1α co-activates estrogen
related receptor alpha (ERRα); nuclear respiratory factors (NRF) 1 and 2 (transcription
factors bound to promoter regions of target nuclear genes involved in the respiratory chain);
and TFAM (transcription factor A mitochondrial), which modulates mitochondrial DNA
transcription and replication.
PGC-1α expression is induced through cold exposure, starvation and exercise. The PPARs,
AMP-protein activated kinase (AMPK) and sirtuin 1 (Sirt1) also increase PGC-1α activity and
provide a means through which this pathway can be pharmacologically manipulated. Indeed,
several compounds have been identified that exert their effect in this way including:
bezafibrate and the glitazones (PPAR agonists); metformin and AICAR (AMPK); and resveratrol
(Sirt1). Of these, bezafibrate, glitazones and metformin have established relevance in
diabetes and hyperlipidaemia. Their mechanism of action also provides a rationale for their
use in other metabolic disorders such as obesity and mitochondrial disease.
Indeed,bezafibrate has shown promise as a disease modifying pharmaceutical agent in
pre-clinical studies using both cellular and animal models of mitochondrial myopathy.
Cellular models of mitochondrial disease have demonstrated improvements in a variety of
measures of mitochondrial function when grown in a bezafibrate enriched medium. This has
included a cell line comparable to the specific patient group we propose to review in this
feasibility study. Furthermore, a mouse model of mitochondrial myopathy has demonstrated
improvement in clinically relevant outcomes including time to disease manifestation and life
span.
This phase II, open label, non-randomised feasibility study aims to build on the work
obtained in pre-clinical studies and provide proof of principle data in humans affected with
the most common form of mitochondrial muscle disease. This study is not designed to provide
proof of efficacy. However, should bezafibrate exert a demonstrable molecular effect here,
the investigators anticipate the need for larger, randomised trials of bezafibrate in the
future. An additional aim of this feasibility study, is therefore obtaining the relevant data
to determine how many patients the investigators would need in a larger trial; and what
biochemical and clinical measurements the investigators would use to determine drug effect in
such a trial.
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