An isolated complex v inefficiency and dysregulated mitochondrial function in immortalized lymphocytes from ME/CFS patients
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Missailidis, Daniel
Annesley, Sarah
Allan, Claire Y.
Sanislav, Oana
Lidbury, Brett
Lewis, Donald P.
Fisher, Paul
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MDPI Publishing
Abstract
Myalgic encephalomyelitis/chronic fatigue syndrome (ME/CFS) is an enigmatic condition
characterized by exacerbation of symptoms after exertion (post-exertional malaise or “PEM”), and by
fatigue whose severity and associated requirement for rest are excessive and disproportionate to the
fatigue-inducing activity. There is no definitive molecular marker or known underlying pathological
mechanism for the condition. Increasing evidence for aberrant energy metabolism suggests a role for
mitochondrial dysfunction in ME/CFS. Our objective was therefore to measure mitochondrial function
and cellular stress sensing in actively metabolizing patient blood cells. We immortalized lymphoblasts
isolated from 51 ME/CFS patients diagnosed according to the Canadian Consensus Criteria and an
age- and gender-matched control group. Parameters of mitochondrial function and energy stress
sensing were assessed by Seahorse extracellular flux analysis, proteomics, and an array of additional
biochemical assays. As a proportion of the basal oxygen consumption rate (OCR), the rate of ATP
synthesis by Complex V was significantly reduced in ME/CFS lymphoblasts, while significant elevations
were observed in Complex I OCR, maximum OCR, spare respiratory capacity, nonmitochondrial
OCR and “proton leak” as a proportion of the basal OCR. This was accompanied by a reduction of
mitochondrial membrane potential, chronically hyperactivated TOR Complex I stress signaling and
upregulated expression of mitochondrial respiratory complexes, fatty acid transporters, and enzymes
of the β-oxidation and TCA cycles. By contrast, mitochondrial mass and genome copy number, as well
as glycolytic rates and steady state ATP levels were unchanged. Our results suggest a model in which
ME/CFS lymphoblasts have a Complex V defect accompanied by compensatory upregulation of their
respiratory capacity that includes the mitochondrial respiratory complexes, membrane transporters
and enzymes involved in fatty acid β-oxidation. This homeostatically returns ATP synthesis and steady
state levels to “normal” in the resting cells, but may leave them unable to adequately respond to acute
increases in energy demand as the relevant homeostatic pathways are already activated.
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International Journal of Molecular Sciences
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