Mitochondrial dysfunction: a hallmark of skin ageing

Mitochondria are the "powerhouses" or "lungs" of our cells and bioenergetic semi-autonomous organelles with their own genomes and genetic systems. [1] They are responsible for generating the energy that fuels a wide range of cellular processes in the skin, including cell signaling, pigmentation, wound healing, barrier integrity [2], metabolism and quality control.  [3] Mitochondria exist in each cell of the body and are generally inherited exclusively from the mother. Their primary role is cellular respiration; a process converting the energy in nutrients (like glucose) into a usable form of energy called ATP or Adenosine Triphosphate. Mitochondria are particularly abundant in the skin, reflecting the skin's high metabolic demand. When the functionality of mitochondria is impaired or declines, it impacts skin's vitality, health and beauty. Mitochondrial dysfunction is 1 of the 12 hallmarks of skin ageing. 

The skin is particularly susceptible to mitochondrial stress due to its constant exposure to environmental insults, such as UV radiation, pollution, and other oxidative stressors. These factors can damage mitochondrial DNA, leading to increased production of reactive oxygen species (ROS) and disrupting the delicate balance of cellular processes. [4] In aged post-mitotic cells, heavily lipofuscin-loaded lysosomes perform poorly, resulting in the enhanced accumulation of defective mitochondria, which in turn produce more reactive oxygen species causing additional damage (the mitochondrial-lysosomal axis theory). [5]

Optimal mitochondrial function is indispensable for sustaining the specialized functions of each cell type, like keratinocyte differentiation, fibroblast ECM production, melanocytes melanin production and distribution, immune cell surveillance, sebocytes and adipocytes. [6] Mitochondrial dysfunction is both directly and indirectly linked to chronological ageing and photo-ageing. [7] As mitochondrial function declines, the skin's ability to regenerate and repair itself is decreased. [2] This results in visible signs of aging, such as wrinkles, loss of elasticity, dryness, uneven pigmentation, melasma, age spots, lipomas, impaired wound healing. [2-4-5-8-9] Mitochondrial dysfunction also has been implicated in skin conditions like acne, eczema, lupus, psoriasis, vitiligo, atopic dermatitis and even skin cancer. [10]

Ageing is associated with changes in mitochondrial morphology, including [6] 
▌Hyperfusion or increased fragmentation
▌Loss of mitochondrial connectivity [11-7]
▌Decline in the efficiency of oxidative phosphorylation, leading to reduced ATP production
▌Decline mitochondrial membrane potential (ΔΨM)
▌Compromised cellular energy metabolism
▌Reduced mitochondrial turnover (downregulated biogenesis)
▌Impaired mitochondrial quality control such as mitophagy (removal of damaged mitochondria through autophagy) [6]

These alterations are related to the increased production of ROS exhibited by mitochondria during ageing, the accumulation of which causes oxidative damage to mitochondrial and cell components contributing to cellular senescence. [12] 

Good mitochondrial function or metabolism: [7]
▌Redox homeostasis: (the way of reducing oxidative stress) - mitochondrial respiration and ROS production are essential for keratinocyte differentiation
▌ATP production: Adenosine Triphosphate provides energy to drive and support many processes in living cells (and GTP)
▌Respiration: mitochondrial respiration is the most important generator of cellular energy
▌Biogenesis: allows cells to meet increased energy demands, to replace degraded mitochondria and is essential for the adaptation of cells to stress [6]
▌Calcium homeostasis
▌Cellular growth
▌Programmed cell death (apoptosis) reducing cell senescence [13]
▌Mitochondrial protein synthesis: mitochondria typically produce 13 proteins encoded by mitochondrial DNA (mtDNA)

Dysfunctional Mitochondria: [7]
▌Oxidative stress
▌Decreased ATP levels
▌Dysfunctional OXPHOS: Oxidative phosphorylation, a metabolic pathway in which enzymes oxidize nutrients to release stored chemical energy in the form of ATP
▌Altered mitochondrial biogenesis 
▌Calcium imbalance
▌Cell death

Mitochondrial proteins
Mitochondria contain >1,100 different proteins (MitoCoP) that often assemble into complexes and supercomplexes such as respiratory complexes and preprotein translocases. The chaperones Heat Shock Proteins HSP60-HSP10 are the most abundant mitochondrial proteins. [3] Small heat shock proteins form a chaperone system that operates in the mitochondrial intermembrane space. Depletion of small heat shock proteins leads to mitochondrial swelling and reduced respiration. [14]

Mitochondrial hyperpigmentation
Emerging research has shed light on the intricate relationship between mitochondrial dysfunction and the development of hyperpigmentation, a condition characterized by the overproduction and uneven distribution of melanin in the skin. One of the key mechanisms underlying this connection is the role of mitochondria in the regulation of melanogenesis, the process by which melanin is synthesized. Mitochondria are involved in the production of various cofactors and signaling molecules that are essential for the activity of tyrosinase, the rate-limiting enzyme in melanin synthesis. [15] When mitochondrial function is impaired, it can lead to an imbalance in the production and distribution of these cofactors and signaling molecules, ultimately resulting in the overproduction and uneven deposition of melanin in the skin. [15] This can manifest itself as age spots, melasma, and other forms of hyperpigmentation. The link between mitochondrial dysfunction and hyperpigmentation has been further supported by studies on genetic disorders that involve mitochondrial dysfunction, such as mitochondrial DNA depletion syndrome. In these conditions, patients often exhibit a range of pigmentary skin changes, including patchy hyper- and hypopigmentation, as well as reticular pigmentation. [16]

Mitochondrial crosstalk and exosomes
Mitochondria can crosstalk and move beyond cell boundaries. [17] Mitochondria-derived material might be transferred to neighboring cells in the form of cell-free mitochondria or included in extracellular vesicles [18-19]. This process supports cellular repair and contributes to vital mitochondrial functions. Besides restoring stressed cells and damaged tissues due to mitochondrial dysfunction, intercellular mitochondrial transfer also occurs under physiological and pathological conditions. [20] The transfer of active mitochondria from mesenchymal stem cells (MSCs) has been identified as a repair mechanism for rejuvenating damaged skin fibroblasts. [21] 

MITOCHONDRIAL SUPPORT
Move
According Martin Picard phD being physically active is a protective factor against almost everything health related. Exercise stimulates the production of mitochondria as more energy is required. 

Be hungry sometimes
If there is too much supply of energy acquired via food leads to mass shrinking of mitochondria or fragmentation. Don´t over-eat, be calorie neutral and sometimes being calorie deficient is good for mitochondria. Maintain a healthy weight, preferably with a mediterranean diet containing phenolic and polyphenolic compounds (increase mitochondrial function and number) nitrate rich vegetables, soybeans and cacao beans. 

​Mitohormesis
In model organisms, lifespan can be improved by compromising mitochondrial function, which induces a  hormetic response (“mitohormesis”), provided that this inhibition is partial and occurs early during development.

Feel good
Feeling good (positivity), especially at night, has a scientifically proven positive effect on mitochondrial health index, it is even a predictive factor. 

​Q10 or Coenzyme Q10 (CoQ10)
Q10 is part of the mitochondrial respiration chain and essential for cellular energy production. About 95% of our cellular energy is generated with support of Q10, which is produced by the human body itself. During skin ageing, both the cellular energy production and levels of Q10 are declined. Q10 is a powerful anti-oxidant [22], thus protecting cells from oxidative stress and damage and has proven to be able to "rescue" senescent cells by decreasing elevated senescent markers like p21 levels and β-Galactosidases positive cell numbers (in-vitro). Q10 is bio-active, increasing collagen type I and elastin production. [23] Q10 can be supplemented via nutrition, however also via topical application and is considered an evidence based active ingredient in skin care products.  Ubiquinol (reduced form) shows higher bioavailability compared to ubiquinone (oxidized form). [23] 

Pyrroloquinoline quinone (PQQ)
Q10 improves the energy in the mitochondria, however PQQ has shown to increase the number of mitochondria and a redox maestro. I´ve written a full post about this compound, which can be found as skincare ingredient and supplement. Read more about PQQ

Glutathione
Glutathione is formed in cell's cytoplasm from glutamic acid, cysteine and glycine. It is present in 2 forms: reduced (GSH) and oxidized (GSSG). Reduced GSH is an active anti-oxidant, while the presence of inactive GSSG is increased under oxidative stress. The ratio between GSH and GSSH is considered a measure of oxidative stress. Glutathione participates in redox reactions, acts as co-factor of many anti-oxidant enzymes and is the most important non-enzymatic anti-oxidant, essential for synthesis of proteins and DNA. Low Glutathione results in accelerated ageing and inflammatory skin diseases. Mitochondrial glutathione (mGSH) is the main line of defense for the maintenance of the appropriate mitochondrial redox environment to avoid or repair oxidative modifications leading to mitochondrial dysfunction and cell death. [24] Glutathione can be increased via supplementation via precursors cysteine or N-acetylcysteine (not recommended for pregnant women), a combination of Glycine and NAC (called GlyNAC) part of the popular "power of three" supplementation, or the reduced form of Glutathione itself, or increased via topical active ingredients like Licochalcone A. [25] 
I´ve written about GlyNAC in my post on autophagy.

Nicotinamide
NR nicotinamide ribosome which is the precursor of NMN nicotinamide mononucleotide which is the precursor of NAD+ nicotinamide adenine dinucleotide all could have a protective effect on mitochondria. Nicotinamide adenine dinucleotide is present in living organisms as ions NAD+ and NADP+ and in reduced forms NADH and NADPH. NADH is a cofactor of processes inside mitochondria:
▌ATP production
▌Activation of "youth proteins" sirtuins
▌Activation of PARP Poly (ADP-ribose) polymerase, a family of proteins involved in many cellular processes such as DNA repair, genomic stability and programmed cell death
▌Reduction of ROS (free radicals)
NAD levels as lowered during ageing. [26] One of the fans of NMN supplementation is Harvard Professor David Sinclair, best known for his work on understanding why we age and how to slow its effects and also featured in my article about hormesis. There are about 14 studies done to date with NMN supplementation in humans, one of which was done by Professor Sinclair. NMN supplementation does raise NAD levels, however there aren't substantial proven health benefits, unless you are unhealthy.

Resveratrol
Although systemically Resveratrol promotes mitochondrial biogenesis. [27] Other data shows that UVA (14 J/cm(2)) along with resveratrol causes massive oxidative stress in mitochondria. As a consequence of oxidative stress, the mitochondrial membrane potential decreases which results in opening of the mitochondrial pores ultimately leading to apoptosis in human keratinocytes. [28]

Magnesium
Magnesium supplementation has been shown to improve mitochondrial function by increasing ATP production, decreasing mitochondrial ROS and calcium overload, and repolarizing mitochondrial membrane potential. There are many forms of Magnesium, however Citrate, Malate and Orotate are particularly good for energy. 

L-Carnitine
Placebo-controlled trials have shown positive effects of L-Carnitine supplementation on both pre-frail subjects and elderly men. The effect is possibly mediated by counteracting age-related declining L-carnitine levels which may limit fatty acid oxidation by mitochondria. 

NEW Ergothioneine (EGT) 
Ergothioneine (EGT) is a sulfur-containing amino acid derivative known for its antioxidant properties, particularly in mitochondria. It is transported into cells and mitochondria via the OCTN1 transporter, where it helps reduce reactive oxygen species (ROS) and maintain cellular homeostasis [29]. EGT binds to and activates 3-mercaptopyruvate sulfurtransferase (MPST), enhancing mitochondrial respiration and exercise performance [30]. It also protects against oxidative stress and inflammation, potentially benefiting conditions like neurodegenerative diseases [31]. 

Melatonin
Not much talked about when it comes to mitochondria, however should not be ignored as mitochondria can benefit significantly from melatonin supplementation. 
1. Antioxidant protection: Melatonin acts as a powerful antioxidant within mitochondria, scavenging free radicals and reducing oxidative damage to mitochondrial DNA and proteins [32][34].
2. Regulation of mitochondrial homeostasis: Melatonin helps maintain electron flow, efficiency of oxidative phosphorylation, ATP production, and overall bioenergetic function of mitochondria [32][34].
3. Preservation of respiratory complex activities: Melatonin helps maintain the activities of mitochondrial respiratory complexes, which are crucial for energy production [32][34].
4. Modulation of calcium influx: Melatonin regulates calcium influx into mitochondria, helping prevent calcium overload which can be damaging [32][34].
5. Protection of mitochondrial permeability transition: Melatonin helps regulate the opening of the mitochondrial permeability transition pore, which is important for maintaining mitochondrial integrity [32][34].
6. Enhancement of mitochondrial fusion: Melatonin promotes mitochondrial fusion, which is part of the quality control process for maintaining healthy mitochondria [33].
7. Promotion of mitophagy: Melatonin enhances the removal of damaged mitochondria through mitophagy, helping maintain a healthy mitochondrial population [33].
8. Reduction of nitric oxide generation: Melatonin decreases nitric oxide production within mitochondria, which can be damaging in excess [32][34].
9. Selective uptake by mitochondria: Melatonin is selectively taken up by mitochondrial membranes, allowing it to exert its protective effects directly within these organelles [34].
10. Support of mitochondrial biogenesis: Some studies suggest melatonin may promote the formation of new mitochondria [33].

The key antioxidants used by mitochondria are Glutathione (GSH), Glutathione peroxidase (GPx), Coenzyme Q10 (CoQ10), Superoxide dismutase (SOD), Melatonin, Vitamin C (ascorbate) and Vitamin E (α-tocopherol).

​Red light therapy
By incorporating red light therapy into your skin care routine, you can help to counteract the damaging effects of mitochondrial dysfunction and support the skin's natural renewal processes.

As we continue to explore the 12 hallmarks of ageing, I am confident that we will gain even more valuable insights and develop breakthrough innovations that will improve skin quality, health, beauty and vitality. Always consult a qualified healthcare professional or dermatologist to determine what the most suitable approach is for your particular skin condition and rejuvenation goals. 

Take care!
Anne-Marie

References

1. Biological Sciences Why chloroplasts and mitochondria retain their own genomes and genetic systems: Colocation for redox regulation of gene expression John F. Allen et al. 2015
2. Experimental Dermatology Mitochondrial dysfunction: a neglected component of skin diseases René G. Feichtinger et al. 2014
3. Cell Metab. Quantitative high-confidence human mitochondrial proteome and its dynamics in cellular context Marcel Morgenstern et al. 2021
4. Br J Dermatol Oxidative stress and ageing M A Birch-Machin et al. 2016
5. Antioxid Redox Signal Oxidative stress, accumulation of biological 'garbage', and aging Alexei Terman et al. 2006
6. Front. Physiol., Mitochondrial dynamics and metabolism across skin cells: implications for skin homeostasis and aging
   Ines Martic et al. 2023
7. Cell Death Dis. Mitochondria in skin health, aging, and disease Annapoorna Sreedhar et al. 2020
8. Journal of Dermatological Treatment. The skin aging exposome Krutmann, J. et al. 2017 
9. Experimental Dermatology Regulation of melanogenesis--controversies and new concepts. Schallreuter, K. U. et al. 2008
10. Int J Mol Sci. Dermatologic Manifestations of Mitochondrial Dysfunction: A Review of the Literature Nicole Natarelli et al. 2024
11. Review Cell Metab Mitochondrial dynamics in the regulation of nutrient utilization and energy expenditure
    Marc Liesa et al. 2013
12. Stem Cell Reviews and Reports Telomeres and Mitochondrial Metabolism: Implications for Cellular Senescence and Age-related Diseases Xingyu Gao et al. 2022
13. Experimental & Molecular Medicine Mitochondria-associated programmed cell death as a therapeutic target for age-related disease
    Thanh T. Nguyen et al. 2023
14. Nature Cell Biology Small heat shock proteins operate as molecular chaperones in the mitochondrial intermembrane space
    Elias Adriaenssens et al. 2023
15. Review Exp Dermatol Regulation of melanogenesis--controversies and new concepts Karin U Schallreuter et al. 2008
16. Pigment Cell Melanoma Res. Mitochondrial DNA-depleter mouse as a model to study human pigmentary skin disorders Kyrene M. Villavicencio et al. 2021
17. J. Cell Biol. Mitochondria on the move: horizontal mitochondrial transfer in disease and health. Dong L.-F. 2023
18. Review Int J Mol Sci. Mitochondria Can Cross Cell Boundaries: An Overview of the Biological Relevance, Pathophysiological Implications and Therapeutic Perspectives of Intercellular Mitochondrial Transfer Daniela Valenti et al. 2021
19. Int J Mol Sci. Do Extracellular Vesicles Derived from Mesenchymal Stem Cells Contain Functional Mitochondria? Ljubava D. Zorova 2022
20. Review Signal Transduct Target Ther. Intercellular mitochondrial transfer as a means of tissue revitalization Delin Liu et al. 2021
21. Front. Physiol. Mesenchymal stem cells shift mitochondrial dynamics and enhance oxidative phosphorylation in recipient cells Newell C. et al. 2018
22. BioFactors Topical treatment with coenzyme Q10-containing formulas improves skin's Q10 level and provides antioxidative effects
    Anja Knott et al. 2015
23. Free Radical Biology and Medicine Anti-ageing effects of ubiquinone and ubiquinol in a senescence model of human dermal fibroblasts
    Fabio Marcheggiani et al. 2021
24. Antioxid Redox Signal. Mitochondrial Glutathione, a Key Survival Antioxidant Montserrat Marí et al. 2009
25. Exp Dermatol Licochalcone A activates Nrf2 in vitro and contributes to licorice extract-induced lowered cutaneous oxidative stress in vivo
    Jochen Kühnl et al. 2015
26. PLoS One Age-associated changes in oxidative stress and NAD+ metabolism in human tissue Hassina Massudi et al. 2012
27. Exerc Sport Sci Rev. Mitochondrial Protection by Resveratrol Zoltan Ungvari et al. 2011
28. J Photochem Photobiol B Resveratrol-sensitized UVA induced apoptosis in human keratinocytes through mitochondrial oxidative stress and pore opening Jean Z Boyer et al. 2012
29. Liu HM, Tang W, Wang XY, Jiang JJ, Zhang W, Wang W. Safe and Effective Antioxidant: The Biological Mechanism and Potential Pathways of Ergothioneine in the Skin. Molecules. 2023
30. Sprenger HG et al. Ergothioneine boosts mitochondrial respiration and exercise performance via direct activation of MPST. bioRxiv [Preprint]. 2024 
31. Leow, D.M.-K.; Cheah, I.K.-M.; Fong, Z.W.-J.; Halliwell, B.; Ong, W.-Y. Protective Effect of Ergothioneine against 7-Ketocholesterol-Induced Mitochondrial Damage in hCMEC/D3 Human Brain Endothelial Cells. Int. J. Mol. Sci. 2023, 24, 5498. 
32. Daniel P. Cardinali et al. Publicado en Hormones and Behavior, 2012, Melatonin and mitochondrial dysfunction in the Central Nervous System
33. Lei Xudan et al. The potential influence of melatonin on mitochondrial quality control: a review Frontiers in Pharmacology 2024
34. Srinivasan V. et al. Int. J. Alzheimers Dis. Melatonin in mitochondrial dysfunction and related disorders (2011)

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