Michael E. Ash BSc DO ND, Robert Settenari M.S and Prof. Garth L. Nicolson Ph.D explain the relationship between energy deficit, mitochondrial membrane quality, the immune system, inflammation and how to recover from persistent fatigue using validated natural medicine.
At some point we all experience fatigue, but it usually resolves on its own and is easily explained. Sometimes it has a straight-forward organic explanation, sometimes not. For many however, such organic explanations fail to present a validated route to satisfactory resolution. As research into persistent fatigue has progressed, most clinicians comprehend that all explanatory models of the causes and mechanisms of fatigue and exhaustion proceed from the assumption that they are complex, multifactorial processes. For example, fatigue has been proposed to have biochemical, immunological, emotional, behavioural and cognitive components, to name a few that contribute to overall fatigue.
Fatigue is usually understood as a loss of overall energy and inability to perform even simple tasks without exertion. At the cellular level, fatigue is related to adversely altered cellular energy systems found primarily in the cellular mitochondria.
At the biochemical level fatigue is related to the metabolic energy available to tissues and cells, mainly through mitochondrial electron transport. Electron transport is directly linked to functional, intact inner mitochondrial membranes. Thus the integrity of mitochondrial membranes is critical to cell function and energy metabolism.
Fatigue is the most common complaint of patients seeking general medical care; between 7% and 45% of primary care consultations involve fatigue as a major complaint. It appears that some degree of fatigue may be identified in nearly all of the population, indicating that fatigue is not simply an individual problem; it is also a public health problem. Fatigue can progress to the point that it causes disability comparable to that found in chronic medical patients.,
The successful management or resolution of fatigue is also important in various physical activities of relatively healthy men and women, such as work and sports performance.
Many who experience fatigue do not initially seek primary care intervention but self-treat with stimulants such as central nervous system agonists that include caffeine, herbs and sugars. Although these provide short term increases in energy and perception of reduced fatigue, they have potential long term adverse health effects.,
Fatigue: Successful Intervention
Recent clinical trials using patients with chronic fatigue have shown the benefit of an oral, non- central nervous system agonist; Lipid Replacement Therapy (LRT®). Using naturally occurring glycophospholipids, cofactor nutrients and probiotics, mitochondrial electron transport function can been restored. The result is that moderate to severe chronic fatigue can be significantly reduced in the process.,
Additional studies have also identified significant improvements in energy, mood, affect and function in a healthy population following ingestion of the glycophospholipids and cofactor nutrients in a drink., These additional natural agents (principally antioxidants and bacterial mediators of immune tolerance) have also shown benefits from a molecular perspective in the inhibition of immune mediated inflammation and associated fatigue.,,,
LRT® is a dietary approach to replace damaged cellular lipids with undamaged (unoxidised) lipids to ensure proper function of cellular structures, such as cellular and organelle (mitochondrial) membranes. LRT® can result in the cellular delivery of unoxidised, undamaged membrane glycophospholipids in order to replace damaged lipids and restore function to cellular membranes. LRT® has proven to be an effective method to prevent ROS/RNS-associated changes in function and for use in the treatment of various clinical conditions.
In recent studies using LRT and co factor nutrients for 6 months or more has also reduced the blood levels of the amino acid homocysteine, which are related to increased risk for cardiovascular disease, stroke, cognitive loss, depression and immune dysfunction.
The role of glycophospholipids and other food-derived agents are attractive as safe and effective interventions in the treatment of persistent and transient fatigue. Studies have been conducted on various populations from those with normal health and function to those undergoing complex treatments for cancer and those with persistent fatigue. These groups have shown between 30-40% improvement in fatigue perception and function utilising the internationally recognised Piper Fatigue Scale.,12
Mechanisms of Fatigue and its Resolution (click image to enlarge)
Mitochondria are responsible for many metabolic circuits and signalling pathways. Just a few examples of these include: oxidative phosphorylation, the mechanism our cells use to generate most intracellular ATP (cellular fuel); biosynthesis of key molecules including haeme and certain steroids as well as in many catabolic energy relevant pathways such as the β-oxidation of fatty acids; and regulation of calcium homeostasis. Importantly, mitochondria are responsible for production of most of our cell’s reactive oxygen species (ROS) and some reactive nitrogen species (RNS). Significant oxidative damage to mitochondrial membranes also represents the point of no return of programmed cell death pathways that culminate in apoptosis or regulated necrosis.
Of clinical interest from an immunological perspective, recent studies suggest that mitochondria are significant players in the orchestration of innate immune responses via activation of a multiprotein complex called the inflammasome which results in the production and release of the pro-inflammatory cytokines IL-1β and IL-18.,
These, in turn, contribute to defensive and coordinated management of the bacterial organisms that reside in our digestive tract. The digestive tract is home to trillions of bacteria and this represents the site of greatest density of innate immune receptors in the body. These receptors are key mediators in the management and maintenance of immune response and tolerance. Their inappropriate activation and expression by IL-1β and IL-18 leads to altered innate immune hyper-responsiveness and may contribute to immune mediated inflammatory diseases as well as fatigue through the subsequent development of persistent molecular inflammation.
Damage to mitochondrial components, especially the delicate inner mitochondrial membrane, leads to the cytosolic release of toxic proteins (caspases and non-caspases) that are normally confined in the mitochondria. These released proteins then bind to specialised innate immune inflammasome activating receptors called nucleotide-binding-and-oligomerisation domains (NOD’s).
These NOD receptors not only recognise intracellular pathogen-associated molecular patterns (PAMPs), but also self-generated signals known as ‘damage-associated molecular patterns’ (DAMPs). Examples are extracellular ATP, uric acid and heat shock proteins that accumulate with stress and trigger inflammasome activity. New evidence has placed inflammasomes at the centre stage of complex diseases (metabolic syndrome and carcinogenesis) and physiological processes (regulation of intestinal microbial ecology) and energy management.,,,,,,
Increased toxic metabolites and trans-membrane ion leakage suppresses the core ability of the mitochondria to produce ATP and alter nutrient uptake resulting in overall reductions in energy and persistent fatigue.
Damage to mitochondrial membranes is typically due to ROS, RNS, environmental stressors, cellular aging and mitochondropathies. All of these factors also inhibit mitophagy – a natural process that normally limits ROS-related damage by safely removing damaged and inflammation-promoting mitochondria and mitochondrial components. This results in an inflammatory driven feed forward cycle, in which membrane damage continues to produce ROS and RNS and DAMPs contributing to numerous diseases and functional loss of cellular energy.
The innate immune receptors, known as pattern recognition receptors (PRRs), are stimulated by these DAMPs to induce the production of inflammatory cytokines, sustaining and promoting inflammation. These components, in turn, orchestrate the assembly of a supramolecular platform (the inflammasome), which then activates pro-inflammatory immune cytokines such as IL-1β, IL-18 and Nuclear Factor Kappa B (NFκβ).
This process is the defining link between innate immune responses and mitochondrial functionality. Once activated, additional innate immune effects include the induction of hyper-responsive actions that occur with with bacterial triggers from the gastrointestinal tract. The consequences include local inflammation, loss of mucosal barrier integrity and fatigue.,
The molecular mechanisms utilised by bacteria in our gut to maintain immune homeostasis and tolerance through macrophage and dendritic cell activation can be manipulated to favour the promotion of anti-inflammatory cytokines such as IL-10 and TGFβ.
The ingestion of probiotics and prebiotics can be used to mediate immune responsiveness via the promotion of regulatory Tcells, dendritic cells and low counter activation of either T helper-mediated: Th1 and Th2 driven inflammatory responses., The field of immune intervention via consumption of bacteria is over 100 years old, but has recently experienced a significant increase in interest, as the role of the bacteria in our gut is now understood to influence local and systemic illness.
This sequence of events places mitochondria at the cross roads of bioenergetics metabolism, cell death signaling and the innate and adaptive immune system.
Healthy mitochondrial function (and death) determines appropriate management of energy production, fatigue control and innate immune driven inflammation responsiveness. Using LRT® administered as a nutritional supplement with antioxidants assures that mitochondrial membrane permeability is maintained in the optimal range, preventing oxidative membrane damage, and reducing the number of mitochondrial DNA deletions. Thus LRT® can be used to restore mitochondrial and other cellular membrane functions via delivery of undamaged replacement lipids to cellular organelles.
LRT is not just the dietary substitution of certain lipids with proposed health benefits; it is the actual replacement of damaged cellular lipids with undamaged lipids to ensure proper structure and function of cellular structures, mainly cellular and organelle membranes.12
Inflammation is an essential immune response that enables survival during infection or injury and maintains tissue homeostasis under a variety of noxious conditions. Inflammation comes at the cost of a transient decline in local tissue function, which can in turn contribute to the pathogenesis of diseases and loss of function related to altered homeostasis. Inflammation has been described as the ‘common soil’ of altered health and function.
Inflammation driven fatigue is a recognised consequence of host defence, and raising immune responsiveness is an energy dependent process that is a component of post viral and bacterial infection as well as a more recently proposed response to altered microbial composition (dysbiosis) in the human gut due to environmental driven factors and mitochondrial damage.,
This suggests that alterations to the microbial balance in the digestive tract may induce loss of tolerance and subsequent increase in receptor stimulation, which in turn is amplified via mitochondrial membrane permeability, DAMP production and inflammasome stimulation. This may then lead to ‘inflammasome-induced dysbiosis’, which whilst a relatively new area of research may provide some interesting pathophysiological connections. (click image to enlarge)
Resolution of Chronic Conditions
People with fatiguing conditions often exhibit “sickness” signs and symptoms for a variety of reasons. One of these may be an increase in peripheral pro-inflammatory signalling. This notion is based on overwhelming evidence that pro-inflammatory cytokines are capable of inducing all the cardinal symptoms of CFS in humans.,
The use of selected immune modulating probiotics along with LRT provides the cytokine milieu the opportunity to be beneficially altered through the management of mitochondrial membrane repair, DAMP reduction and PRR induced tolerance via changes in bacterial ratios in the gut towards ones that favour symbiosis. The activation of PRRs induces host-defense signaling pathways that culminate in the production of proinflammatory and antimicrobial molecules as well as anti-inflammatory molecules. Resolution of inflammasome-induced dysbiosis makes a considerable contribution towards improving mitochondrial fitness, just as mitochondrial fitness contributes to the healthy management of gut-mediated immune reactivity.
A central question in immunology, is how the immune system discriminates between commensal and pathogenic bacteria. This problem is particularly important in the intestine, where trillions of commensal microorganisms continually challenge the immune system without eliciting a proinflammatory response, and where probiotics, when carefully selected by species and strain, can amplify either desired outcome.
The results – recovery from fatigue derived from LRT and associated pro and pre-biotics, along with antioxidants are likely due to reduced pro-inflammatory cytokines and reduced innate immune receptor hyper-sensitivity.
In addition to fatigue, mitochondrial dysfunction and the accumulation of damaged mitochondrial components have also been linked to a wide variety of chronic, metabolic and degenerative diseases, aging and cancer.
LRT has been successfully used in clinical studies to reduce fatigue, increase mitochondrial function and protect cellular and mitochondrial membranes from oxidative damage.10 In multiple clinical studies fatigue was reduced 35-43% by oral administration of LRT and key nutrients. Even in severely fatigued patients with chronic fatigue syndrome or fibromyalgia syndrome, LRT reduced fatigue by 43.1%.
In the study by Agadjadyan et al. LRT (supplied as NT Factor®) reduced fatigue 35.5% in aging adults and significantly improved mitochondrial function to a level that was similar to that found in young, healthy adults.
This health altering intersection of immunity, oxidative stress and dysbiosis, can be found in the membranes of the mitochondria residing in our cells – not only of the gastrointestinal tract but all other tissues as well. The clinical use of LRT has the potential to decrease the effects of aging on mitochondria and improve mitochondrial function in chronic diseases, diminish fatigue and improve altered states of mucosal immunity through the participatory resolution of inflammasome mediated dysbiosis. The improvement in terms of restitution of mucosal and immunological tolerance has potential health benefits that extend systemically.
 Nelson E, Kirk J, McHugo G, Douglass R, Ohler J, Wasson J, Zubkoff M. Chief complaint fatigue: a longitudinal study from the patient’s perspective. Fam Pract Res J. 1987 Summer;6(4):175-88. View Abstract
 Arria AM, Caldeira KM, Kasperski SJ, Vincent KB, Griffiths RR, O’Grady KE. Energy drink consumption and increased risk for alcohol dependence. Alcohol Clin Exp Res. 2011 Feb;35(2):365-75. doi: 10.1111/j.1530-0277.2010.01352.x. Epub 2010 Nov 12. View Abstract
 Avellaneda Fernández A, Pérez Martín A, Izquierdo Martínez M, Arruti Bustillo M, Barbado Hernández FJ, de la Cruz Labrado J, Díaz-Delgado Peñas R, Gutiérrez Rivas E, Palacín Delgado C, Rivera Redondo J, Ramón Giménez JR. Chronic fatigue syndrome: aetiology, diagnosis and treatment. BMC Psychiatry. 2009 Oct 23;9 Suppl 1:S1. Review. View Abstract
 Nicolson, G.L. and Ellithrope, R. Lipid replacement and antioxidant nutritional therapy for restoring mitochondrial function and reducing fatigue in chronic fatigue syndrome and other fatiguing illnesses. J. Chronic Fatigue Syndr. 13(1): 57-68 (2006). View Full Paper
 Nicolson, G.L. and Settineri, R. Lipid Replacement Therapy: a functional food approach with new formulations for reducing cellular oxidative damage, cancer-associated fatigue and the adverse effects of cancer therapy. Funct. Food Health Dis. 4: 135-160 (2011). View Full Paper
 Ellithorpe, R.A., Settineri, R., Mitchell, C.A., Jacques, B., Ellithorpe, E. and Nicolson, G.L. Lipid replacement therapy drink containing a glycophospholipid formulation rapidly and significantly reduces fatigue while improving energy and mental clarity. Funct. Food Health Dis. 8: 245-254 (2011). View Full Paper
 Nicolson GL, Ellithorpe RR, Ayson-Mitchell C, Jacques B, Settineri R. Lipid Replacement Therapy with a Glycophospholipid-Antioxidant-Vitamin Formulation Significantly Reduces Fatigue Within One Week. JANA Vol 13 No1 2010: 10-14 View Full Paper
 Ströhle A, Wolters M, Hahn A. Micronutrients at the interface between inflammation and infection–ascorbic acid and calciferol: part 1, general overview with a focus on ascorbic acid. Inflamm Allergy Drug Targets. 2011 Feb;10(1):54-63. Review. View Abstract
 Ströhle A, Wolters M, Hahn A.Micronutrients at the interface between inflammation and infection–ascorbic acid and calciferol. Part 2: calciferol and the significance of nutrient supplements. Inflamm Allergy Drug Targets. 2011 Feb;10(1):64-74. Review. View Abstract
 Walsh NP, Gleeson M, Shephard RJ, Gleeson M, Woods JA, Bishop NC, Fleshner M, Green C, Pedersen BK, Hoffman-Goetz L, Rogers CJ, Northoff H, Abbasi A, Simon P. Position statement. Part one: Immune function and exercise. Exerc Immunol Rev. 2011;17:6-63. Review. View Abstract
 Walsh NP, Gleeson M, Pyne DB, Nieman DC, Dhabhar FS, Shephard RJ, Oliver SJ, Bermon S, Kajeniene A. Position statement. Part two: Maintaining immune health. Exerc Immunol Rev. 2011;17:64-103. Review. View Abstract
 Nicolson GL, Ellithorpe R and Settineri R. Blood homocysteine levels are significantly reduced with a glycophospholipid formulation (NTFactor® plus vitamin B-complex): a retrospective study in older subjects. Paper in Preparation.
 Piper BF, Dibble SL, Dodd MJ, Weiss MC, Slaughter RE, Paul SM. The revised Piper Fatigue Scale: psychometric evaluation in women with breast cancer. Oncol Nurs Forum. 1998 May;25(4):677-84. View Abstract
 Nakahira K, Haspel JA, Rathinam VA, Lee SJ, Dolinay T, Lam HC, Englert JA, Rabinovitch M, Cernadas M, Kim HP, Fitzgerald KA, Ryter SW, Choi AM. Autophagy proteins regulate innate immune responses by inhibiting the release of mitochondrial DNA mediated by the NALP3 inflammasome. Nat Immunol. 2011 Mar;12(3):222-30. Epub 2010 Dec 12. View Abstract
 Stienstra R, van Diepen JA, Tack CJ, Zaki MH, van de Veerdonk FL, Perera D, Neale GA, Hooiveld GJ, Hijmans A, Vroegrijk I, van den Berg S, Romijn J, Rensen PC, Joosten LA, Netea MG, Kanneganti TD.Inflammasome is a central player in the induction of obesity and insulin resistance. Proc Natl Acad Sci U S A. 2011 Sep 13;108(37):15324-9. Epub 2011 Aug 29. View Abstract
 Bansal AS, Bradley AS, Bishop KN, Kiani-Alikhan S, Ford B. Chronic fatigue syndrome, the immune system and viral infection. Brain Behav Immun. 2012 Jan;26(1):24-31. Epub 2011 Jul 2. Review. View Abstract
 Maes M, Twisk FN, Kubera M, Ringel K. Evidence for inflammation and activation of cell-mediated immunity in Myalgic Encephalomyelitis/Chronic Fatigue Syndrome (ME/CFS): increased interleukin-1, tumor necrosis factor-α, PMN-elastase, lysozyme and neopterin. J Affect Disord. 2012 Feb;136(3):933-9. Epub 2011 Oct 4. View Abstract
 Henao-Mejia J, Elinav E, Jin C, Hao L, Mehal WZ, Strowig T, Thaiss CA, Kau AL, Eisenbarth SC, Jurczak MJ, Camporez JP, Shulman GI, Gordon JI, Hoffman HM, Flavell RA. Inflammasome-mediated dysbiosis regulates progression of NAFLD and obesity. Nature. 2012 Feb 1;482(7384):179-85. doi: 10.1038/nature10809. View Abstract
 Maes M. Inflammatory and oxidative and nitrosative stress pathways underpinning chronic fatigue, somatization and psychosomatic symptoms. Curr Opin Psychiatry. 2009 Jan;22(1):75-83. Review. View Abstract
 Habil N, Al-Murrani W, Beal J, Foey AD. Probiotic bacterial strains differentially modulate macrophage cytokine production in a strain-dependent and cell subset-specific manner. Benef Microbes. 2011 Dec 1;2(4):283-93. View Abstract
 Gómez-Llorente C, Muñoz S, Gil A. Role of Toll-like receptors in the development of immunotolerance mediated by probiotics. Proc Nutr Soc. 2010 Aug;69(3):381-9. Epub 2010 Apr 23. Review. View Abstract
 Ellithorpe RR, Settineri R, Nicolson GL. Pilot study: reduction of fatigue by use of a dietary supplement containing glycophospholipids. J Am Nutraceut Assoc. 2003; 6(1): 23-28. View Full Paper
 Hirota SA, Ng J, Lueng A, Khajah M, Parhar K, Li Y, Lam V, Potentier MS, Ng K, Bawa M, McCafferty DM, Rioux KP, Ghosh S, Xavier RJ, Colgan SP, Tschopp J, Muruve D, MacDonald JA, Beck PL. NLRP3 inflammasome plays a key role in the regulation of intestinal homeostasis. Inflamm Bowel Dis. 2011 Jun;17(6):1359-72. doi: 10.1002/ibd.21478. Epub 2010 Sep 24. View Abstract
 Lebeer, S., Vanderleyden, J. & De Keersmaecker, S.C. Host interactions of probiotic bacterial surface molecules: comparison with commensals and pathogens. Nat. Rev. Microbiol. 8, 171–184 (2010). View Abstract
 Agadjanyan M, Vasilevko V, Ghochikyan A, Berns P, Kesslak P, Settineri R, Nicolson GL. Nutritional supplement (NTFactor) restores mitochondrial function and reduces moderately severe fatigue in aged subjects. J Chronic Fatigue Syndr 2003; 11(3): 23-26. View Full Paper
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