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True, but irrelevant: this does not permanently affect the expression or production of mitochondrial proteins
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{{more citations needed|date=February 2014}}
{{more citations needed|date=February 2014}}
{{Infobox medical condition (new)
{{Infobox medical condition (new)
| name = Mitochondrial disease
| name = Mitochondrial disease
| synonyms =
| synonyms = Mitochondrial cytopathy; mitochondriopathy (MCP)
| image = Ragged_red_fibres_-_gtc_-_very_high_mag.jpg
| image = Ragged_red_fibres_-_gtc_-_very_high_mag.jpg
| caption = [[Micrograph]] showing ragged red fibers, a finding seen in various types of mitochondrial diseases. [[Muscle biopsy]]. [[Gomori trichrome stain]].
| caption = [[Micrograph]] showing ragged red fibers, a finding seen in various types of mitochondrial diseases. [[Muscle biopsy]]. [[Gomori trichrome stain]].
| pronounce =
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| field = [[Medical genetics]]
| field = [[Medical genetics]]
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'''Mitochondrial disease''' is a group of disorders caused by '''mitochondrial dysfunction'''. [[Mitochondria]] are the [[organelle]]s that generate energy for the cell and are found in every cell of the human body except [[red blood cells]]. They convert the energy of food molecules into the [[adenosine triphosphate|ATP]] that powers most cell functions.
'''Mitochondrial disease''' is a group of disorders caused by '''mitochondrial dysfunction'''. [[Mitochondria]] are the [[organelle]]s that generate energy for the cell and are found in every cell of the human body except [[red blood cells]]. They convert the energy of food molecules into the [[adenosine triphosphate|ATP]] that powers most cell functions.


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== Types ==
== Types ==
{{Unreferenced section|date=January 2021}}
{{Refimprove|date=November 2023}}
Mitochondrial disease can manifest in many different ways<ref>{{Cite web |title=Mitochondrial Diseases |url=https://medlineplus.gov/mitochondrialdiseases.html |access-date=2023-03-15 |website=medlineplus.gov}}</ref> whether in children<ref name=Rahman2020>{{cite journal |vauthors=Rahman S |title=Mitochondrial disease in children |journal=Journal of Internal Medicine |volume=287 |issue=6 |pages=609–633 |date=2020 |pmid=32176382 |doi=10.1111/joim.13054 |url=|doi-access=free }}</ref> or adults.<ref name=LaMorgia2020>{{cite journal |vauthors=La Morgia C, Maresca A, Caporali L, Valentino ML, Carelli V |title=Mitochondrial diseases in adults |journal=Journal of Internal Medicine |volume=287 |issue=6 |pages=592–608 |date=2020 |pmid=32463135 |doi=10.1111/joim.13064 |url=|doi-access=free }}</ref> Examples of mitochondrial diseases include:
Examples of mitochondrial diseases include:
* [[Mitochondrial myopathy]]
* [[Mitochondrial myopathy]]<ref name=Rahman2020/><ref name=LaMorgia2020/>
* Maternally inherited [[diabetes mellitus and deafness]] (MIDD)<ref name=Tsang2018>{{cite book |vauthors=Tsang SH, Aycinena AR, Sharma T |title=Atlas of Inherited Retinal Diseases |chapter=Mitochondrial disorder: maternally inherited diabetes and deafness |series=Advances in Experimental Medicine and Biology |volume=1085 |pages=163–165 |date=2018 |pmid=30578504 |doi=10.1007/978-3-319-95046-4_31 |isbn=978-3-319-95045-7 |chapter-url=}}</ref>
* [[Diabetes mellitus and deafness]] (DAD)
** this combination at an early age can be due to mitochondrial disease
** While [[diabetes mellitus]] and [[deafness]] can be found together for other reasons, at an early age this combination can be due to mitochondrial disease, as may occur in [[Kearns–Sayre syndrome]] and [[Pearson syndrome]]<ref name=Rahman2020/>
* [[Leber's hereditary optic neuropathy]] (LHON)<ref name=LaMorgia2020/>
** [[Diabetes mellitus]] and [[deafness]] can be found together for other reasons
**LHON is an eye disorder characterized by progressive loss of central vision due to degeneration of the optic nerves and retina (apparently affecting between 1 in 30,000 and 1 in 50,000 people<ref name=Shamsnajafabadi2023>{{cite journal |vauthors=Shamsnajafabadi H, MacLaren RE, Cehajic-Kapetanovic J |title=Current and future landscape in genetic therapies for Leber hereditary optic neuropathy |journal=Cells |volume=12 |issue=15 |date=2023 |page=2013 |pmid=37566092 |pmc=10416882 |doi=10.3390/cells12152013 |doi-access=free }}</ref>); visual loss typically begins in young adulthood<ref name=Rahman2020/>
* [[Leber's hereditary optic neuropathy]] (LHON)
* [[Leigh syndrome]], subacute necrotizing encephalomyelopathy<ref name=Rahman2020a>{{cite book |vauthors=Rahman S |title=Mitochondrial Diseases |chapter=Leigh syndrome |series=Handbook of Clinical Neurology |volume=194 |pages=43–63 |date=2023 |pmid=36813320 |doi=10.1016/B978-0-12-821751-1.00015-4 |isbn=9780128217511 |chapter-url=}}</ref>
** visual loss beginning in young adulthood
** eye disorder characterized by progressive loss of central vision due to degeneration of the optic nerves and retina
** affects 1 in 50,000 people in Finland
* [[Leigh syndrome]], subacute necrotizing encephalomyelopathy{{citation needed|reason=Can anyone attest to this term being in use?|date=February 2022}}
** after normal development the disease usually begins late in the first year of life, although onset may occur in adulthood
** after normal development the disease usually begins late in the first year of life, although onset may occur in adulthood
** a rapid decline in function occurs and is marked by seizures, altered states of consciousness, dementia, ventilatory failure
** a rapid decline in function occurs and is marked by seizures, altered states of consciousness, dementia, ventilatory failure
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** lactic acidosis
** lactic acidosis
** exercise intolerance
** exercise intolerance
* [[MELAS syndrome]]
* [[MELAS syndrome]], mitochondrial encephalopathy, lactic acidosis, and stroke-like episodes
* [[Mitochondrial DNA depletion syndrome]]
* [[Mitochondrial DNA depletion syndrome]]


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* [[Alzheimer's disease]],<ref>{{cite journal |doi=10.1080/14789450.2021.1918550 |pmid=33874826 |title=Mitochondrial dysfunction in Alzheimer's disease - a proteomics perspective |journal=Expert Review of Proteomics |volume=18 |issue=4 |pages=295–304 |year=2021 |last1=Abyadeh |first1=Morteza |last2=Gupta |first2=Vivek|last3=Chitranshi|first3=Nitin|last4=Gupta|first4=Veer|last5=Wu|first5=Yunqi|last6=Saks|first6=Danit|last7=WanderWall|first7=Roshana|last8=Fitzhenry|first8=Matthew J|last9=Basavarajappa|first9=Devaraj |last10=You|first10=Yuyi|last11=H Hosseini|first11=Ghasem|last12=A Haynes|first12=Paul|last13= L Graham |first13=Stuart|last14=Mirzaei|first14=Mehdi |s2cid=233310698 }}</ref>
* [[Alzheimer's disease]],<ref>{{cite journal |doi=10.1080/14789450.2021.1918550 |pmid=33874826 |title=Mitochondrial dysfunction in Alzheimer's disease - a proteomics perspective |journal=Expert Review of Proteomics |volume=18 |issue=4 |pages=295–304 |year=2021 |last1=Abyadeh |first1=Morteza |last2=Gupta |first2=Vivek|last3=Chitranshi|first3=Nitin|last4=Gupta|first4=Veer|last5=Wu|first5=Yunqi|last6=Saks|first6=Danit|last7=WanderWall|first7=Roshana|last8=Fitzhenry|first8=Matthew J|last9=Basavarajappa|first9=Devaraj |last10=You|first10=Yuyi|last11=H Hosseini|first11=Ghasem|last12=A Haynes|first12=Paul|last13= L Graham |first13=Stuart|last14=Mirzaei|first14=Mehdi |s2cid=233310698 }}</ref>
* [[Parkinson's disease]]
* [[Parkinson's disease]]
* [[bipolar disorder]],<ref>{{cite journal |doi=10.1038/sj.mp.4001711 |pmid=16027739 |title=Mitochondrial dysfunction in bipolar disorder: Evidence from magnetic resonance spectroscopy research |journal=Molecular Psychiatry |volume=10 |issue=10 |pages=900–19 |year=2005 |last1=Stork |first1=C |last2=Renshaw |first2=P F |doi-access=free }}</ref><ref name="ReferenceA">{{cite journal |doi=10.1016/j.yexmp.2006.09.008 |pmid=17239370 |title=Mitochondrial dysfunction and molecular pathways of disease |journal=Experimental and Molecular Pathology |volume=83 |issue=1 |pages=84–92 |year=2007 |last1=Pieczenik |first1=Steve R |last2=Neustadt |first2=John }}</ref><ref>{{cite journal |doi=10.1177/0004867412449303 |pmid=22711881 |title=Mitochondrial modulators for bipolar disorder: A pathophysiologically informed paradigm for new drug development |journal=Australian & New Zealand Journal of Psychiatry |volume=47 |issue=1 |pages=26–42 |year=2012 |last1=Nierenberg |first1=Andrew A |last2=Kansky |first2=Christine |last3=Brennan |first3=Brian P |last4=Shelton |first4=Richard C |last5=Perlis |first5=Roy |last6=Iosifescu |first6=Dan V |s2cid=22983555 }}</ref> [[schizophrenia]], aging and senescence, anxiety disorders<ref>{{cite journal|last1=Misiewicz|first1=Zuzanna|last2=Iurato|first2=Stella|last3=Kulesskaya|first3=Natalia|last4=Salminen|first4=Laura|last5=Rodrigues|first5=Luis|last6=Maccarrone|first6=Giuseppina|last7=Martins|first7=Jade|last8=Czamara|first8=Darina|last9=Laine|first9=Mikaela A.|last10=Sokolowska|first10=Ewa|last11=Trontti|first11=Kalevi|last12=Rewerts|first12=Christiane|last13= Novak |first13=Bozidar|last14=Volk|first14=Naama|last15=Park|first15=Dong Ik|last16=Jokitalo|first16=Eija|last17=Paulin|first17=Lars|last18=Auvinen|first18=Petri|last19=Voikar|first19=Vootele|last20=Chen|first20=Alon|last21=Erhardt|first21=Angelika|last22=Turck|first22=Christoph W.|last23=Hovatta|first23=Iiris|date=2019-09-26|title=Multi-omics analysis identifies mitochondrial pathways associated with anxiety-related behavior|journal=PLOS Genetics|language=en|volume=15|issue=9|pages=e1008358|doi=10.1371/journal.pgen.1008358|pmid=31557158|pmc=6762065|issn=1553-7404}}</ref>
* [[bipolar disorder]],<ref>{{cite journal |doi=10.1038/sj.mp.4001711 |pmid=16027739 |title=Mitochondrial dysfunction in bipolar disorder: Evidence from magnetic resonance spectroscopy research |journal=Molecular Psychiatry |volume=10 |issue=10 |pages=900–19 |year=2005 |last1=Stork |first1=C |last2=Renshaw |first2=P F |doi-access=free }}</ref><ref name="ReferenceA">{{cite journal |doi=10.1016/j.yexmp.2006.09.008 |pmid=17239370 |title=Mitochondrial dysfunction and molecular pathways of disease |journal=Experimental and Molecular Pathology |volume=83 |issue=1 |pages=84–92 |year=2007 |last1=Pieczenik |first1=Steve R |last2=Neustadt |first2=John }}</ref><ref>{{cite journal |doi=10.1177/0004867412449303 |pmid=22711881 |title=Mitochondrial modulators for bipolar disorder: A pathophysiologically informed paradigm for new drug development |journal=Australian & New Zealand Journal of Psychiatry |volume=47 |issue=1 |pages=26–42 |year=2012 |last1=Nierenberg |first1=Andrew A |last2=Kansky |first2=Christine |last3=Brennan |first3=Brian P |last4=Shelton |first4=Richard C |last5=Perlis |first5=Roy |last6=Iosifescu |first6=Dan V |s2cid=22983555 }}</ref> [[schizophrenia]], aging and senescence,<ref>{{cite journal | doi=10.1016/j.ebiom.2022.103815 |pmid=35085849 |title=Comprehensive summary of mitochondrial DNA alterations in the postmortem human brain: A systematic review|journal=eBioMedicine|volume=76|issue=103815|year=2022|last1=Valiente-Pallejà|first1=A|last2=Tortajada |first2=J |last3=Bulduk|first3=BK|page=103815 |pmc=8790490 |doi-access=free}}</ref> anxiety disorders<ref>{{cite journal |last1=Misiewicz |first1=Zuzanna |last2=Iurato |first2=Stella |last3=Kulesskaya |first3=Natalia |last4=Salminen |first4=Laura |last5=Rodrigues |first5=Luis |last6=Maccarrone |first6=Giuseppina |last7=Martins |first7=Jade |last8=Czamara |first8=Darina |last9=Laine |first9=Mikaela A. |last10=Sokolowska |first10=Ewa |last11=Trontti |first11=Kalevi |last12=Rewerts |first12=Christiane |last13=Novak |first13=Bozidar |last14=Volk |first14=Naama |last15=Park |first15=Dong Ik |last16=Jokitalo |first16=Eija |last17=Paulin |first17=Lars |last18=Auvinen |first18=Petri |last19=Voikar |first19=Vootele |last20=Chen |first20=Alon |last21=Erhardt |first21=Angelika |last22=Turck |first22=Christoph W. |last23=Hovatta |first23=Iiris |title=Multi-omics analysis identifies mitochondrial pathways associated with anxiety-related behavior |journal=PLOS Genetics |date=26 September 2019 |volume=15 |issue=9 |pages=e1008358 |doi=10.1371/journal.pgen.1008358 |pmid=31557158 |pmc=6762065 |doi-access=free }}</ref>
* [[cardiovascular disease]]
* [[cardiovascular disease]]
* [[sarcopenia]]
* [[sarcopenia]]
* [[chronic fatigue syndrome]]<ref name="ReferenceA"/>
* [[chronic fatigue syndrome]]<ref name="ReferenceA"/>
* [[ALS]]<ref>{{cite journal |last1=Muyderman |first1=H |last2=Chen |first2=T |title=Mitochondrial dysfunction in amyotrophic lateral sclerosis – a valid pharmacological target? |journal=British Journal of Pharmacology |date=April 2014 |volume=171 |issue=8 |pages=2191–2205 |doi=10.1111/bph.12476 |pmid=24148000 |pmc=3976630 }}</ref>


The body, and each mutation, is modulated by other genome variants; the mutation that in one individual may cause liver disease might in another person cause a brain disorder. The severity of the specific defect may also be great or small. Some defects include [[exercise intolerance]]. Defects often affect the operation of the mitochondria and multiple tissues more severely, leading to multi-system diseases.<ref name="pmid22424226">{{cite journal |vauthors = Nunnari J, Suomalainen A |title = Mitochondria: in sickness and in health |journal = Cell |volume = 148 |issue = 6 |pages = 1145–59 |year = 2012 |pmid = 22424226 |pmc = 5381524 |doi = 10.1016/j.cell.2012.02.035 }}</ref>
The body, and each mutation, is modulated by other genome variants; the mutation that in one individual may cause liver disease might in another person cause a brain disorder. The severity of the specific defect may also be great or small. Some defects include [[exercise intolerance]]. Defects often affect the operation of the mitochondria and multiple tissues more severely, leading to multi-system diseases.<ref name="pmid22424226">{{cite journal |vauthors = Nunnari J, Suomalainen A |title = Mitochondria: in sickness and in health |journal = Cell |volume = 148 |issue = 6 |pages = 1145–59 |year = 2012 |pmid = 22424226 |pmc = 5381524 |doi = 10.1016/j.cell.2012.02.035 }}</ref>


It has also been reported that drug tolerant cancer cells have an increased number and size of mitochondria, which suggested an increase in mitochondrial biogenesis.<ref name="pmid31431543">{{cite journal | vauthors = Goldman A, Khiste S, Freinkman E, Dhawan A, Majumder B, Mondal J, Pinkerton AB, Eton E, Medhi R, Chandrasekar V, Rahman MM, Ichimura T, Gopinath KS, Majumder P, Kohandel M, Sengupta S | display-authors = 6 | title = Targeting tumor phenotypic plasticity and metabolic remodeling in adaptive cross-drug tolerance | journal = Science Signaling | volume = 12 | issue = 595 | date = August 2019 | pmid = 31431543 | doi = 10.1126/scisignal.aas8779 | pmc = 7261372 }}</ref> Interestingly, a recent study in ''Nature Nanotechnology'' has reported that cancer cells can hijack the mitochondria from immune cells via physical tunneling nanotubes.<ref>{{cite journal | vauthors = Saha T, Dash C, Jayabalan R, etal | title = Intercellular nanotubes mediate mitochondrial trafficking between cancer and immune cells. | journal = Nat. Nanotechnol. | date = 2021 | volume = 17 | issue = 1 | pages = 98–106 | doi = 10.1038/s41565-021-01000-4 | pmid = 34795441 | s2cid = 244349825 }}</ref>
It has also been reported that drug tolerant cancer cells have an increased number and size of mitochondria, which suggested an increase in mitochondrial biogenesis.<ref name="pmid31431543">{{cite journal | vauthors = Goldman A, Khiste S, Freinkman E, Dhawan A, Majumder B, Mondal J, Pinkerton AB, Eton E, Medhi R, Chandrasekar V, Rahman MM, Ichimura T, Gopinath KS, Majumder P, Kohandel M, Sengupta S | display-authors = 6 | title = Targeting tumor phenotypic plasticity and metabolic remodeling in adaptive cross-drug tolerance | journal = Science Signaling | volume = 12 | issue = 595 | date = August 2019 | pmid = 31431543 | doi = 10.1126/scisignal.aas8779 | pmc = 7261372 }}</ref> Interestingly, a recent study in ''Nature Nanotechnology'' has reported that cancer cells can hijack the mitochondria from immune cells via physical tunneling nanotubes.<ref>{{cite journal | vauthors = Saha T, Dash C, Jayabalan R, etal | title = Intercellular nanotubes mediate mitochondrial trafficking between cancer and immune cells. | journal = Nat. Nanotechnol. | date = 2021 | volume = 17 | issue = 1 | pages = 98–106 | doi = 10.1038/s41565-021-01000-4 | pmid = 34795441 | s2cid = 244349825 | pmc = 10071558 }}</ref>


As a rule, mitochondrial diseases are worse when the defective mitochondria are present in the [[muscle]]s, [[cerebrum]], or [[nerve]]s,<ref name=pmid17637511>{{cite journal |doi=10.1159/000105676 |pmid=17637511 |title=Hematological Manifestations of Primary Mitochondrial Disorders |journal=Acta Haematologica |volume=118 |issue=2 |pages=88–98 |year=2007 |last1=Finsterer |first1=Josef |s2cid=24222021 }}</ref> because these cells use more energy than most other cells in the body.
As a rule, mitochondrial diseases are worse when the defective mitochondria are present in the [[muscle]]s, [[cerebrum]], or [[nerve]]s,<ref name=pmid17637511>{{cite journal |doi=10.1159/000105676 |pmid=17637511 |title=Hematological Manifestations of Primary Mitochondrial Disorders |journal=Acta Haematologica |volume=118 |issue=2 |pages=88–98 |year=2007 |last1=Finsterer |first1=Josef |s2cid=24222021 }}</ref> because these cells use more energy than most other cells in the body.
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==Causes==
==Causes==
Mitochondrial disorders may be caused by [[mutations]] (acquired or inherited), in [[mitochondrial DNA]] (mtDNA), or in [[nuclear gene]]s that code for mitochondrial components. They may also be the result of acquired mitochondrial dysfunction due to adverse effects of [[drugs]], [[infections]], or other environmental causes.<ref>{{Cite web|url=https://meshb.nlm.nih.gov/record/ui?ui=D028361|title=Mitochondrial diseases|website=MeSH|access-date=2 August 2019}}</ref> [[Oxalate]] may enter cells where it is known to cause mitochondrial dysfunction.<ref>{{Cite journal|last1=Patel|first1=Mikita|last2=Yarlagadda|first2=Vidhush|last3=Adedoyin|first3=Oreoluwa|last4=Saini|first4=Vikram|last5=Assimos|first5=Dean G.|last6=Holmes|first6=Ross P.|last7=Mitchell|first7=Tanecia|date=May 2018|title=Oxalate induces mitochondrial dysfunction and disrupts redox homeostasis in a human monocyte derived cell line|journal=Redox Biology|volume=15|pages=207–215|doi=10.1016/j.redox.2017.12.003|pmid=29272854|pmc=5975227}}</ref>
Mitochondrial disorders may be caused by [[mutations]] (acquired or inherited), in [[mitochondrial DNA]] (mtDNA), or in [[nuclear gene]]s that code for mitochondrial components. They may also be the result of acquired mitochondrial dysfunction due to adverse effects of [[drugs]], [[infections]], or other environmental causes.<ref>{{Cite web|url=https://meshb.nlm.nih.gov/record/ui?ui=D028361|title=Mitochondrial diseases|website=MeSH|access-date=2 August 2019}}</ref>


[[File:Maternal Inheritance - mitochondrial DNA.png|thumb|Example of a pedigree for a genetic trait inherited by mitochondrial DNA in animals and humans. Offspring of the males with the trait don't inherit the trait. Offspring of the females with the trait always inherit the trait (independently from their own gender).]]
[[File:Maternal Inheritance - mitochondrial DNA.png|thumb|Example of a pedigree for a genetic trait inherited by mitochondrial DNA in animals and humans. Offspring of the males with the trait don't inherit the trait. Offspring of the females with the trait always inherit the trait (independently from their own gender).]]
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Mitochondria possess many of the same DNA repair pathways as nuclei do—but not all of them;<ref>{{cite journal | vauthors = Alexeyev M, Shokolenko I, Wilson G, LeDoux S | title = The maintenance of mitochondrial DNA integrity--critical analysis and update | journal = Cold Spring Harbor Perspectives in Biology | volume = 5 | issue = 5 | pages = a012641 | date = May 2013 | pmid = 23637283 | pmc = 3632056 | doi = 10.1101/cshperspect.a012641 }}</ref> therefore, mutations occur more frequently in mitochondrial DNA than in nuclear DNA (see [[Mutation rate]]). This means that mitochondrial DNA disorders may occur spontaneously and relatively often. Defects in enzymes that control mitochondrial [[DNA replication]] (all of which are encoded for by genes in the nuclear DNA) may also cause mitochondrial DNA mutations.
Mitochondria possess many of the same DNA repair pathways as nuclei do—but not all of them;<ref>{{cite journal | vauthors = Alexeyev M, Shokolenko I, Wilson G, LeDoux S | title = The maintenance of mitochondrial DNA integrity--critical analysis and update | journal = Cold Spring Harbor Perspectives in Biology | volume = 5 | issue = 5 | pages = a012641 | date = May 2013 | pmid = 23637283 | pmc = 3632056 | doi = 10.1101/cshperspect.a012641 }}</ref> therefore, mutations occur more frequently in mitochondrial DNA than in nuclear DNA (see [[Mutation rate]]). This means that mitochondrial DNA disorders may occur spontaneously and relatively often. Defects in enzymes that control mitochondrial [[DNA replication]] (all of which are encoded for by genes in the nuclear DNA) may also cause mitochondrial DNA mutations.


Most mitochondrial function and biogenesis is controlled by [[nuclear DNA]]. Human mitochondrial DNA encodes 13 proteins of the [[respiratory chain]], while most of the estimated 1,500 proteins and components targeted to mitochondria are nuclear-encoded. Defects in nuclear-encoded mitochondrial genes are associated with hundreds of clinical disease phenotypes including [[anemia]], [[dementia]], [[hypertension]], [[lymphoma]], [[retinopathy]], [[seizures]], and [[neurodevelopmental disorders]].<ref>{{cite journal |author2-link=Helen H. Lu |vauthors = Scharfe C, Lu HH, Neuenburg JK, Allen EA, Li GC, Klopstock T, Cowan TM, Enns GM, Davis RW |title = Mapping gene associations in human mitochondria using clinical disease phenotypes |journal = PLOS Comput Biol |year = 2009 |pmid = 19390613 |volume = 5 |issue = 4 |pages = e1000374 |doi = 10.1371/journal.pcbi.1000374 |pmc = 2668170 |veditors = Rzhetsky A|bibcode = 2009PLSCB...5E0374S }}</ref>
Most mitochondrial function and biogenesis is controlled by [[nuclear DNA]]. Human mitochondrial DNA encodes 13 proteins of the [[respiratory chain]], while most of the estimated 1,500 proteins and components targeted to mitochondria are nuclear-encoded. Defects in nuclear-encoded mitochondrial genes are associated with hundreds of clinical disease phenotypes including [[anemia]], [[dementia]], [[hypertension]], [[lymphoma]], [[retinopathy]], [[seizures]], and [[neurodevelopmental disorders]].<ref>{{cite journal |author2-link=Helen H. Lu |vauthors = Scharfe C, Lu HH, Neuenburg JK, Allen EA, Li GC, Klopstock T, Cowan TM, Enns GM, Davis RW |title = Mapping gene associations in human mitochondria using clinical disease phenotypes |journal = PLOS Comput Biol |year = 2009 |pmid = 19390613 |volume = 5 |issue = 4 |pages = e1000374 |doi = 10.1371/journal.pcbi.1000374 |pmc = 2668170 |veditors = Rzhetsky A|bibcode = 2009PLSCB...5E0374S |doi-access = free }}</ref>


A study by Yale University researchers (published in the February 12, 2004, issue of the ''[[New England Journal of Medicine]]'') explored the role of mitochondria in insulin resistance among the offspring of patients with type 2 diabetes.<ref name="Petersen et al.">{{cite journal|last1=Petersen|first1=Kitt Falk|last2=Dufour|first2=Sylvie|last3=Befroy|first3=Douglas|last4=Garcia|first4=Rina|last5=Shulman|first5=Gerald I.|title=Impaired Mitochondrial Activity in the Insulin-Resistant Offspring of Patients with Type 2 Diabetes|journal=New England Journal of Medicine|volume=350|issue=7|year=2004|pages=664–671|issn=0028-4793|doi=10.1056/NEJMoa031314|pmid=14960743|pmc=2995502}}</ref>
A study by Yale University researchers (published in the February 12, 2004, issue of the ''[[New England Journal of Medicine]]'') explored the role of mitochondria in insulin resistance among the offspring of patients with type 2 diabetes.<ref name="Petersen et al.">{{cite journal |last1=Petersen |first1=Kitt Falk |last2=Dufour |first2=Sylvie |last3=Befroy |first3=Douglas |last4=Garcia |first4=Rina |last5=Shulman |first5=Gerald I. |title=Impaired Mitochondrial Activity in the Insulin-Resistant Offspring of Patients with Type 2 Diabetes |journal=New England Journal of Medicine |date=12 February 2004 |volume=350 |issue=7 |pages=664–671 |doi=10.1056/NEJMoa031314 |pmid=14960743 |pmc=2995502 }}</ref>
Other studies have shown that the mechanism may involve the interruption of the mitochondrial signaling process in body cells ([[intramyocellular lipids]]). A study conducted at the Pennington Biomedical Research Center in Baton Rouge, Louisiana<ref>''Diabetes'' 54, 2005 1926-33</ref> showed that this, in turn, partially disables the genes that produce mitochondria.
Other studies have shown that the mechanism may involve the interruption of the mitochondrial signaling process in body cells ([[intramyocellular lipids]]). A study conducted at the Pennington Biomedical Research Center in Baton Rouge, Louisiana<ref>{{cite journal |last1=Sparks |first1=Lauren M. |last2=Xie |first2=Hui |last3=Koza |first3=Robert A. |last4=Mynatt |first4=Randall |last5=Hulver |first5=Matthew W. |last6=Bray |first6=George A. |last7=Smith |first7=Steven R. |title=A High-Fat Diet Coordinately Downregulates Genes Required for Mitochondrial Oxidative Phosphorylation in Skeletal Muscle |journal=Diabetes |date=July 2005 |volume=54 |issue=7 |pages=1926–1933 |id={{Gale|A134380159}} {{ProQuest|216493144}} |doi=10.2337/diabetes.54.7.1926 |pmid=15983191 }}</ref> showed that this, in turn, partially disables the genes that produce mitochondria.


==Mechanisms==
==Mechanisms==
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The effective overall energy unit for the available body energy is referred to as the daily [[glycogen]] generation capacity,<ref name=Chemiosomosis >{{cite web|last=Mitchell|first=Peter|title=David Keilin's respiratory chain concept and its chemiosmotic consequences|url=https://www.nobelprize.org/nobel_prizes/chemistry/laureates/1978/mitchell-lecture.pdf|publisher=Nobel institute}}</ref><ref name=Dichloroacetate >{{cite journal|last=Michelakis|first=Evangelos|title=A Mitochondria-K+ Channel Axis Is Suppressed in Cancer and Its Normalization Promotes Apoptosis and Inhibits Cancer Growth|journal=University of Alberta|publisher=University of Alberta, 2007|doi=10.1016/j.ccr.2006.10.020|volume=11|issue=1|pages=37–51|pmid=17222789|date=January 2007|doi-access=free}}</ref><ref name="Lorini & Ciman" >{{cite journal|last=Lorini & Ciman|first=M, & M|title=Hypoglycaemic action of Diisopropylammonium salts in experimental diabetes|journal=Institute of Biochemistry, University of Padua, September 1962|publisher=Biochemical Pharmacology|doi=10.1016/0006-2952(62)90177-6|volume=11|issue=9|pages=823–827|year=1962|pmid=14466716}}</ref> and is used to compare the mitochondrial output of affected or chronically glycogen-depleted individuals to healthy individuals. This value is slow to change in a given individual, as it takes between 18 and 24 months to complete a full cycle.<ref name=Dichloroacetate/>
The effective overall energy unit for the available body energy is referred to as the daily [[glycogen]] generation capacity,<ref name=Chemiosomosis >{{cite web|last=Mitchell|first=Peter|title=David Keilin's respiratory chain concept and its chemiosmotic consequences|url=https://www.nobelprize.org/nobel_prizes/chemistry/laureates/1978/mitchell-lecture.pdf|publisher=Nobel institute}}</ref><ref name=Dichloroacetate >{{cite journal|last=Michelakis|first=Evangelos|title=A Mitochondria-K+ Channel Axis Is Suppressed in Cancer and Its Normalization Promotes Apoptosis and Inhibits Cancer Growth|journal=University of Alberta|publisher=University of Alberta, 2007|doi=10.1016/j.ccr.2006.10.020|volume=11|issue=1|pages=37–51|pmid=17222789|date=January 2007|doi-access=free}}</ref><ref name="Lorini & Ciman" >{{cite journal|last=Lorini & Ciman|first=M, & M|title=Hypoglycaemic action of Diisopropylammonium salts in experimental diabetes|journal=Institute of Biochemistry, University of Padua, September 1962|publisher=Biochemical Pharmacology|doi=10.1016/0006-2952(62)90177-6|volume=11|issue=9|pages=823–827|year=1962|pmid=14466716}}</ref> and is used to compare the mitochondrial output of affected or chronically glycogen-depleted individuals to healthy individuals. This value is slow to change in a given individual, as it takes between 18 and 24 months to complete a full cycle.<ref name=Dichloroacetate/>


The glycogen generation capacity is entirely dependent on, and determined by, the operating levels of the [[mitochondria]] in all of the [[Cell (biology)|cells]] of the [[human body]];<ref name="Dichloroacetate pharmacology" >{{cite journal |vauthors = Stacpoole PW, Henderson GN, Yan Z, James MO |title = Clinical pharmacology and toxicology of dichloroacetate |journal = Environ. Health Perspect. |volume = 106 Suppl 4 |pages = 989–94 |year = 1998 |pmid = 9703483 |pmc = 1533324 |doi=10.1289/ehp.98106s4989}}</ref> however, the relation between the [[energy]] generated by the mitochondria and the glycogen capacity is very loose and is mediated by many [[biochemical pathways]].<ref name=Chemiosomosis /> The energy output of full healthy mitochondrial function can be predicted exactly by a complicated theoretical argument, but this argument is not straightforward, as most energy is consumed by the brain and is not easily measurable.
The glycogen generation capacity is entirely dependent on, and determined by, the operating levels of the [[mitochondria]] in all of the [[Cell (biology)|cells]] of the [[human body]];<ref name="Dichloroacetate pharmacology" >{{cite journal |vauthors = Stacpoole PW, Henderson GN, Yan Z, James MO |title = Clinical pharmacology and toxicology of dichloroacetate |journal = Environ. Health Perspect. |volume = 106 |pages = 989–94 |year = 1998 |issue = Suppl 4 |pmid = 9703483 |pmc = 1533324 |doi=10.1289/ehp.98106s4989}}</ref> however, the relation between the [[energy]] generated by the mitochondria and the glycogen capacity is very loose and is mediated by many [[biochemical pathways]].<ref name=Chemiosomosis /> The energy output of full healthy mitochondrial function can be predicted exactly by a complicated theoretical argument, but this argument is not straightforward, as most energy is consumed by the brain and is not easily measurable.


== Diagnosis ==
== Diagnosis ==
Mitochondrial diseases are usually detected by analysing muscle samples, where the presence of these organelles is higher. The most common tests for the detection of these diseases are:
Mitochondrial diseases are usually detected by analysing muscle samples, where the presence of these organelles is higher. The most common tests for the detection of these diseases are:
# [[Southern blot]] to detect big deletions or duplications
# [[Southern blot]] to detect large deletions or duplications
# [[Polymerase chain reaction]] and specific [[mutation testing]]<ref>{{Cite journal |last1=Bulduk |first1=Bengisu Kevser |last2=Kiliç |first2=Hasan Basri |last3=Bekircan-Kurt |first3=Can Ebru |last4=Haliloğlu |first4=Göknur |last5=Erdem Özdamar |first5=Sevim |last6=Topaloğlu |first6=Haluk |last7=Kocaefe |first7=Y. Çetin |date=2020-03-01 |title=A Novel Amplification-Refractory Mutation System-PCR Strategy to Screen MT-TL1 Pathogenic Variants in Patient Repositories |url=http://dx.doi.org/10.1089/gtmb.2019.0079 |journal=Genetic Testing and Molecular Biomarkers |volume=24 |issue=3 |pages=165–170 |doi=10.1089/gtmb.2019.0079 |pmid=32167396 |s2cid=212693790 |issn=1945-0265}}</ref>
# [[Polymerase chain reaction]] and specific [[mutation testing]]<ref>{{cite journal |last1=Bulduk |first1=Bengisu Kevser |last2=Kiliç |first2=Hasan Basri |last3=Bekircan-Kurt |first3=Can Ebru |last4=Haliloğlu |first4=Göknur |last5=Erdem Özdamar |first5=Sevim |last6=Topaloğlu |first6=Haluk |last7=Kocaefe |first7=Y. Çetin |title=A Novel Amplification-Refractory Mutation System-PCR Strategy to Screen MT-TL1 Pathogenic Variants in Patient Repositories |journal=Genetic Testing and Molecular Biomarkers |date=March 2020 |volume=24 |issue=3 |pages=165–170 |doi=10.1089/gtmb.2019.0079 |pmid=32167396 |s2cid=212693790 }}</ref>
# [[Sequencing]]
# [[Sequencing]]


==Treatments==
==Treatments==
Although research is ongoing, treatment options are currently limited; [[vitamin]]s are frequently prescribed, though the evidence for their effectiveness is limited.<ref>{{cite journal |vauthors=Marriage B, Clandinin MT, Glerum DM |title=Nutritional cofactor treatment in mitochondrial disorders |journal=J Am Diet Assoc |volume=103 |issue=8 |pages=1029–38 |year=2003 |pmid=12891154 |doi=10.1016/S0002-8223(03)00476-0}}</ref>
Although research is ongoing, treatment options are currently limited; [[vitamin]]s are frequently prescribed, though the evidence for their effectiveness is limited.<ref>{{cite journal |vauthors=Marriage B, Clandinin MT, Glerum DM |title=Nutritional cofactor treatment in mitochondrial disorders |journal=J Am Diet Assoc |volume=103 |issue=8 |pages=1029–38 |year=2003 |pmid=12891154 |doi=10.1016/S0002-8223(03)00476-0}}</ref>
[[Pyruvate]] has been proposed in 2007 as a treatment option.<ref>{{cite journal |vauthors=Tanaka M, Nishigaki Y, Fuku N, Ibi T, Sahashi K, Koga Y |title=Therapeutic potential of pyruvate therapy for mitochondrial diseases |journal=Mitochondrion |volume=7 |issue=6 |pages=399–401 |year=2007 |pmid= 17881297 |doi=10.1016/j.mito.2007.07.002}}</ref> [[N-acetyl cysteine]] reverses many models of mitochondrial dysfunction.<ref>{{cite journal | author = Frantz MC, Wipf P | date = Jun 2010 | title = Mitochondria as a target in treatment | journal = Environ Mol Mutagen | volume = 51 | issue = 5| pages = 462–75 | doi = 10.1002/em.20554 | pmid = 20175113 | pmc = 2920596 }}</ref> In the case of mood disorders, specifically [[bipolar disorder]], it is hypothesized that N-acetyl-cysteine (NAC), acetyl-L-carnitine (ALCAR), S-adenosylmethionine (SAMe), coenzyme Q10 (CoQ10), alpha-lipoic acid (ALA), creatine monohydrate (CM), and melatonin could be potential treatment options.<ref>{{cite journal |vauthors=Nierenberg, Andrew A, Kansky, Christine, Brennan, Brian P, Shelton, Richard C, Perlis, Roy, Iosifescu, Dan V |title=Mitochondrial modulators for bipolar disorder: A pathophysiologically informed paradigm for new drug development |journal=Australian & New Zealand Journal of Psychiatry |volume=47 |issue=1 |pages=26–42 |year=2012 |doi=10.1177/0004867412449303|pmid=22711881 |s2cid=22983555 }}</ref>
[[Pyruvate]] has been proposed in 2007 as a treatment option.<ref>{{cite journal |vauthors=Tanaka M, Nishigaki Y, Fuku N, Ibi T, Sahashi K, Koga Y |title=Therapeutic potential of pyruvate therapy for mitochondrial diseases |journal=Mitochondrion |volume=7 |issue=6 |pages=399–401 |year=2007 |pmid= 17881297 |doi=10.1016/j.mito.2007.07.002}}</ref> [[N-acetyl cysteine]] reverses many models of mitochondrial dysfunction.<ref>{{cite journal | author = Frantz MC, Wipf P | date = Jun 2010 | title = Mitochondria as a target in treatment | journal = Environ Mol Mutagen | volume = 51 | issue = 5| pages = 462–75 | doi = 10.1002/em.20554 | pmid = 20175113 | pmc = 2920596 | bibcode = 2010EnvMM..51..462F }}</ref> In the case of mood disorders, specifically [[bipolar disorder]], it is hypothesized that N-acetyl-cysteine (NAC), acetyl-L-carnitine (ALCAR), S-adenosylmethionine (SAMe), coenzyme Q10 (CoQ10), alpha-lipoic acid (ALA), creatine monohydrate (CM), and melatonin could be potential treatment options.<ref>{{cite journal |vauthors=Nierenberg, Andrew A, Kansky, Christine, Brennan, Brian P, Shelton, Richard C, Perlis, Roy, Iosifescu, Dan V |title=Mitochondrial modulators for bipolar disorder: A pathophysiologically informed paradigm for new drug development |journal=Australian & New Zealand Journal of Psychiatry |volume=47 |issue=1 |pages=26–42 |year=2012 |doi=10.1177/0004867412449303|pmid=22711881 |s2cid=22983555 }}</ref>


===Gene therapy prior to conception===
===Gene therapy prior to conception===
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About 1 in 4,000 children in the United States will develop mitochondrial disease by the age of 10 years. Up to 4,000 children per year in the US are born with a type of mitochondrial disease.<ref>[http://biochemgen.ucsd.edu/mmdc/brochure.htm The Mitochondrial and Metabolic Disease Center<!-- Bot generated title -->]</ref> Because mitochondrial disorders contain many variations and subsets, some particular mitochondrial disorders are very rare.
About 1 in 4,000 children in the United States will develop mitochondrial disease by the age of 10 years. Up to 4,000 children per year in the US are born with a type of mitochondrial disease.<ref>[http://biochemgen.ucsd.edu/mmdc/brochure.htm The Mitochondrial and Metabolic Disease Center<!-- Bot generated title -->]</ref> Because mitochondrial disorders contain many variations and subsets, some particular mitochondrial disorders are very rare.


The average number of births per year among women at risk for transmitting mtDNA disease is estimated to approximately 150 in the [[United Kingdom]] and 800 in the [[United States]].<ref name="GormanGrady2015">{{cite journal|last1=Gorman|first1=Gráinne S.|last2=Grady|first2=John P.|last3=Ng|first3=Yi|last4=Schaefer|first4=Andrew M.|last5=McNally|first5=Richard J.|last6=Chinnery|first6=Patrick F.|last7=Yu-Wai-Man|first7=Patrick|last8=Herbert|first8=Mary|last9=Taylor|first9=Robert W.|last10=McFarland|first10=Robert|last11=Turnbull|first11=Doug M.|author-link11=Douglass Turnbull|title=Mitochondrial Donation — How Many Women Could Benefit?|journal=New England Journal of Medicine|year=2015|pages=885–887|issn=0028-4793|doi=10.1056/NEJMc1500960|pmid=25629662|volume=372|issue=9|pmc=4481295}}</ref>
The average number of births per year among women at risk for transmitting mtDNA disease is estimated to approximately 150 in the [[United Kingdom]] and 800 in the [[United States]].<ref name="GormanGrady2015">{{cite journal |last1=Gorman |first1=Gráinne S. |last2=Grady |first2=John P. |last3=Ng |first3=Yi |last4=Schaefer |first4=Andrew M. |last5=McNally |first5=Richard J. |last6=Chinnery |first6=Patrick F. |last7=Yu-Wai-Man |first7=Patrick |last8=Herbert |first8=Mary |last9=Taylor |first9=Robert W. |last10=McFarland |first10=Robert |last11=Turnbull |first11=Doug M. |title=Mitochondrial Donation — How Many Women Could Benefit? |journal=New England Journal of Medicine |date=26 February 2015 |volume=372 |issue=9 |pages=885–887 |doi=10.1056/NEJMc1500960 |pmid=25629662 |pmc=4481295 }}</ref>


==History==
==History==
The first pathogenic mutation in mitochondrial DNA was identified in 1988; from that time to 2016, around 275 other disease-causing mutations were identified.<ref name=NAS2016ethics>{{cite book|last1=Committee on the Ethical and Social Policy Considerations of Novel Techniques for Prevention of Maternal Transmission of Mitochondrial DNA Diseases|last2=Board on Health Sciences Policy|last3=Institute of Medicine|editor1-last=Claiborne|editor1-first=Anne|editor2-last=English|editor2-first=Rebecca|editor3-last=Kahn|editor3-first=Jeffrey|title=Mitochondrial Replacement Techniques: Ethical, Social, and Policy Considerations|date=2016|publisher=National Academies Press|isbn=978-0-309-38870-2|url=https://www.nap.edu/read/21871/chapter/1}} [http://nationalacademies.org/hmd/reports/2016/Mitochondrial-Replacement-Techniques Index page] with links to summaries including [http://www.nationalacademies.org/hmd/~/media/Files/Report%20Files/2016/Mitochondrial%20Replacement%20Techniques/mito%20ethics%20infographic_FINAL.pdf one page summary flyer].</ref>{{rp|37}}
The first pathogenic mutation in mitochondrial DNA was identified in 1988; from that time to 2016, around 275 other disease-causing mutations were identified.<ref name=NAS2016ethics>{{cite book |doi=10.17226/21871 |title=Mitochondrial Replacement Techniques |date=2016 |pmid=27054230 |isbn=978-0-309-38870-2 |editor-last1=Claiborne |editor-last2=English |editor-last3=Kahn |editor-first1=Anne |editor-first2=Rebecca |editor-first3=Jeffrey |page=37 |chapter=Etiology, Clinical Manifestation, and Diagnosis |last1=Claiborne |first1=A. |last2=English |first2=R. |last3=Kahn |first3=J. }}</ref>


==Notable cases==
==Notable cases==
Notable people with mitochondrial disease include:
Notable people with mitochondrial disease include:
* [[Mattie Stepanek]], a poet, peace advocate, and motivational speaker who had dysautonomic mitochondrial myopathy, and who died at age 13. <ref>{{cite web|url=https://www.spokesman.com/stories/2004/jun/23/young-poet-peace-advocate-mattie-dies/}}</ref>
* [[Mattie Stepanek]], a poet, peace advocate, and motivational speaker who had dysautonomic mitochondrial myopathy, and who died at age 13.<ref>{{cite web|url=https://www.spokesman.com/stories/2004/jun/23/young-poet-peace-advocate-mattie-dies/|title=Young poet, peace advocate Mattie dies &#124; the Spokesman-Review }}</ref>
* [[Rocco Baldelli]], a coach and former center fielder in [[Major League Baseball]] who had to retire from active play at age 29 due to mitochondrial channelopathy.
* [[Rocco Baldelli]], a coach and former center fielder in [[Major League Baseball]] who had to retire from active play at age 29 due to mitochondrial channelopathy.
* [[Charlie Gard case|Charlie Gard]], a British boy who had [[mitochondrial DNA depletion syndrome]]; decisions about his care were taken to various law courts.
* [[Charlie Gard case|Charlie Gard]], a British boy who had [[mitochondrial DNA depletion syndrome]]; decisions about his care were taken to various law courts.
* [[Charles Darwin]], a nineteenth century naturalist who suffered from a disabling illness, is speculated to have [[MELAS syndrome]].<ref>{{cite journal |last1=Hayman |first1=John |title=Charles Darwin's Mitochondria |journal=Genetics |date=May 2013 |volume=194 |issue=1 |pages=21–25 |doi=10.1534/genetics.113.151241 |pmid=23633139 |pmc=3632469 }}</ref>


==References==
==References==
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== External links ==
== External links ==
{{Commons category|Mitochondrial diseases}}
{{Mitochondrial diseases}}
* {{Curlie|Health/Conditions_and_Diseases/Neurological_Disorders/Brain_Diseases/Metabolic/Mitochondrial/}}
* [http://www.mitopatients.org International Mito Patients (IMP)]
{{Medical resources
{{Medical resources
| DiseasesDB = 28840
| DiseasesDB = 28840
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| SNOMED CT = 240096000
| SNOMED CT = 240096000
}}
}}
{{Authority control}}
{{Commons category|Mitochondrial diseases}}
* {{Curlie|Health/Conditions_and_Diseases/Neurological_Disorders/Brain_Diseases/Metabolic/Mitochondrial/}}
* [http://www.mitopatients.org International Mito Patients (IMP)]


[[Category:Mitochondrial diseases| ]]
[[Category:Mitochondrial diseases| ]]

Revision as of 17:47, 20 March 2024

Mitochondrial disease
Other namesMitochondrial cytopathy; mitochondriopathy (MCP)
Micrograph showing ragged red fibers, a finding seen in various types of mitochondrial diseases. Muscle biopsy. Gomori trichrome stain.
SpecialtyMedical genetics

Mitochondrial disease is a group of disorders caused by mitochondrial dysfunction. Mitochondria are the organelles that generate energy for the cell and are found in every cell of the human body except red blood cells. They convert the energy of food molecules into the ATP that powers most cell functions.

Mitochondrial diseases take on unique characteristics both because of the way the diseases are often inherited and because mitochondria are so critical to cell function. A subclass of these diseases that have neuromuscular symptoms are known as mitochondrial myopathies.

Types

Mitochondrial disease can manifest in many different ways[1] whether in children[2] or adults.[3] Examples of mitochondrial diseases include:

Conditions such as Friedreich's ataxia can affect the mitochondria but are not associated with mitochondrial proteins.

Presentation

Associated conditions

Acquired conditions in which mitochondrial dysfunction has been involved are:

The body, and each mutation, is modulated by other genome variants; the mutation that in one individual may cause liver disease might in another person cause a brain disorder. The severity of the specific defect may also be great or small. Some defects include exercise intolerance. Defects often affect the operation of the mitochondria and multiple tissues more severely, leading to multi-system diseases.[14]

It has also been reported that drug tolerant cancer cells have an increased number and size of mitochondria, which suggested an increase in mitochondrial biogenesis.[15] Interestingly, a recent study in Nature Nanotechnology has reported that cancer cells can hijack the mitochondria from immune cells via physical tunneling nanotubes.[16]

As a rule, mitochondrial diseases are worse when the defective mitochondria are present in the muscles, cerebrum, or nerves,[17] because these cells use more energy than most other cells in the body.

Although mitochondrial diseases vary greatly in presentation from person to person, several major clinical categories of these conditions have been defined, based on the most common phenotypic features, symptoms, and signs associated with the particular mutations that tend to cause them.[citation needed]

An outstanding question and area of research is whether ATP depletion or reactive oxygen species are in fact responsible for the observed phenotypic consequences.[citation needed]

Cerebellar atrophy or hypoplasia has sometimes been reported to be associated.[18]

Causes

Mitochondrial disorders may be caused by mutations (acquired or inherited), in mitochondrial DNA (mtDNA), or in nuclear genes that code for mitochondrial components. They may also be the result of acquired mitochondrial dysfunction due to adverse effects of drugs, infections, or other environmental causes.[19]

Example of a pedigree for a genetic trait inherited by mitochondrial DNA in animals and humans. Offspring of the males with the trait don't inherit the trait. Offspring of the females with the trait always inherit the trait (independently from their own gender).

Nuclear DNA has two copies per cell (except for sperm and egg cells), one copy being inherited from the father and the other from the mother. Mitochondrial DNA, however, is inherited from the mother only (with some exceptions) and each mitochondrion typically contains between 2 and 10 mtDNA copies. During cell division the mitochondria segregate randomly between the two new cells. Those mitochondria make more copies, normally reaching 500 mitochondria per cell. As mtDNA is copied when mitochondria proliferate, they can accumulate random mutations, a phenomenon called heteroplasmy. If only a few of the mtDNA copies inherited from the mother are defective, mitochondrial division may cause most of the defective copies to end up in just one of the new mitochondria (for more detailed inheritance patterns, see human mitochondrial genetics). Mitochondrial disease may become clinically apparent once the number of affected mitochondria reaches a certain level; this phenomenon is called "threshold expression".

Mitochondria possess many of the same DNA repair pathways as nuclei do—but not all of them;[20] therefore, mutations occur more frequently in mitochondrial DNA than in nuclear DNA (see Mutation rate). This means that mitochondrial DNA disorders may occur spontaneously and relatively often. Defects in enzymes that control mitochondrial DNA replication (all of which are encoded for by genes in the nuclear DNA) may also cause mitochondrial DNA mutations.

Most mitochondrial function and biogenesis is controlled by nuclear DNA. Human mitochondrial DNA encodes 13 proteins of the respiratory chain, while most of the estimated 1,500 proteins and components targeted to mitochondria are nuclear-encoded. Defects in nuclear-encoded mitochondrial genes are associated with hundreds of clinical disease phenotypes including anemia, dementia, hypertension, lymphoma, retinopathy, seizures, and neurodevelopmental disorders.[21]

A study by Yale University researchers (published in the February 12, 2004, issue of the New England Journal of Medicine) explored the role of mitochondria in insulin resistance among the offspring of patients with type 2 diabetes.[22] Other studies have shown that the mechanism may involve the interruption of the mitochondrial signaling process in body cells (intramyocellular lipids). A study conducted at the Pennington Biomedical Research Center in Baton Rouge, Louisiana[23] showed that this, in turn, partially disables the genes that produce mitochondria.

Mechanisms

The effective overall energy unit for the available body energy is referred to as the daily glycogen generation capacity,[24][25][26] and is used to compare the mitochondrial output of affected or chronically glycogen-depleted individuals to healthy individuals. This value is slow to change in a given individual, as it takes between 18 and 24 months to complete a full cycle.[25]

The glycogen generation capacity is entirely dependent on, and determined by, the operating levels of the mitochondria in all of the cells of the human body;[27] however, the relation between the energy generated by the mitochondria and the glycogen capacity is very loose and is mediated by many biochemical pathways.[24] The energy output of full healthy mitochondrial function can be predicted exactly by a complicated theoretical argument, but this argument is not straightforward, as most energy is consumed by the brain and is not easily measurable.

Diagnosis

Mitochondrial diseases are usually detected by analysing muscle samples, where the presence of these organelles is higher. The most common tests for the detection of these diseases are:

  1. Southern blot to detect large deletions or duplications
  2. Polymerase chain reaction and specific mutation testing[28]
  3. Sequencing

Treatments

Although research is ongoing, treatment options are currently limited; vitamins are frequently prescribed, though the evidence for their effectiveness is limited.[29] Pyruvate has been proposed in 2007 as a treatment option.[30] N-acetyl cysteine reverses many models of mitochondrial dysfunction.[31] In the case of mood disorders, specifically bipolar disorder, it is hypothesized that N-acetyl-cysteine (NAC), acetyl-L-carnitine (ALCAR), S-adenosylmethionine (SAMe), coenzyme Q10 (CoQ10), alpha-lipoic acid (ALA), creatine monohydrate (CM), and melatonin could be potential treatment options.[32]

Gene therapy prior to conception

Mitochondrial replacement therapy (MRT), where the nuclear DNA is transferred to another healthy egg cell leaving the defective mitochondrial DNA behind, is an IVF treatment procedure.[33] Using a similar pronuclear transfer technique, researchers at Newcastle University led by Douglass Turnbull successfully transplanted healthy DNA in human eggs from women with mitochondrial disease into the eggs of women donors who were unaffected.[34][35] In such cases, ethical questions have been raised regarding biological motherhood, since the child receives genes and gene regulatory molecules from two different women. Using genetic engineering in attempts to produce babies free of mitochondrial disease is controversial in some circles and raises important ethical issues.[36][37] A male baby was born in Mexico in 2016 from a mother with Leigh syndrome using MRT.[38]

In September 2012 a public consultation was launched in the UK to explore the ethical issues involved.[39] Human genetic engineering was used on a small scale to allow infertile women with genetic defects in their mitochondria to have children.[40] In June 2013, the United Kingdom government agreed to develop legislation that would legalize the 'three-person IVF' procedure as a treatment to fix or eliminate mitochondrial diseases that are passed on from mother to child. The procedure could be offered from 29 October 2015 once regulations had been established.[41][42][43] Embryonic mitochondrial transplant and protofection have been proposed as a possible treatment for inherited mitochondrial disease, and allotopic expression of mitochondrial proteins as a radical treatment for mtDNA mutation load.

In June 2018 Australian Senate's Senate Community Affairs References Committee recommended a move towards legalising Mitochondrial replacement therapy (MRT). Research and clinical applications of MRT were overseen by laws made by federal and state governments. State laws were, for the most part, consistent with federal law. In all states, legislation prohibited the use of MRT techniques in the clinic, and except for Western Australia, research on a limited range of MRT was permissible up to day 14 of embryo development, subject to a license being granted. In 2010, the Hon. Mark Butler MP, then Federal Minister for Mental Health and Ageing, had appointed an independent committee to review the two relevant acts: the Prohibition of Human Cloning for Reproduction Act 2002 and the Research Involving Human Embryos Act 2002. The committee's report, released in July 2011, recommended the existing legislation remain unchanged

Currently, human clinical trials are underway at GenSight Biologics (ClinicalTrials.gov # NCT02064569) and the University of Miami (ClinicalTrials.gov # NCT02161380) to examine the safety and efficacy of mitochondrial gene therapy in Leber's hereditary optic neuropathy.

Epidemiology

About 1 in 4,000 children in the United States will develop mitochondrial disease by the age of 10 years. Up to 4,000 children per year in the US are born with a type of mitochondrial disease.[44] Because mitochondrial disorders contain many variations and subsets, some particular mitochondrial disorders are very rare.

The average number of births per year among women at risk for transmitting mtDNA disease is estimated to approximately 150 in the United Kingdom and 800 in the United States.[45]

History

The first pathogenic mutation in mitochondrial DNA was identified in 1988; from that time to 2016, around 275 other disease-causing mutations were identified.[46]

Notable cases

Notable people with mitochondrial disease include:

References

  1. ^ "Mitochondrial Diseases". medlineplus.gov. Retrieved 2023-03-15.
  2. ^ a b c d Rahman S (2020). "Mitochondrial disease in children". Journal of Internal Medicine. 287 (6): 609–633. doi:10.1111/joim.13054. PMID 32176382.
  3. ^ a b c La Morgia C, Maresca A, Caporali L, Valentino ML, Carelli V (2020). "Mitochondrial diseases in adults". Journal of Internal Medicine. 287 (6): 592–608. doi:10.1111/joim.13064. PMID 32463135.
  4. ^ Tsang SH, Aycinena AR, Sharma T (2018). "Mitochondrial disorder: maternally inherited diabetes and deafness". Atlas of Inherited Retinal Diseases. Advances in Experimental Medicine and Biology. Vol. 1085. pp. 163–165. doi:10.1007/978-3-319-95046-4_31. ISBN 978-3-319-95045-7. PMID 30578504.
  5. ^ Shamsnajafabadi H, MacLaren RE, Cehajic-Kapetanovic J (2023). "Current and future landscape in genetic therapies for Leber hereditary optic neuropathy". Cells. 12 (15): 2013. doi:10.3390/cells12152013. PMC 10416882. PMID 37566092.
  6. ^ Rahman S (2023). "Leigh syndrome". Mitochondrial Diseases. Handbook of Clinical Neurology. Vol. 194. pp. 43–63. doi:10.1016/B978-0-12-821751-1.00015-4. ISBN 9780128217511. PMID 36813320.
  7. ^ Abyadeh, Morteza; Gupta, Vivek; Chitranshi, Nitin; Gupta, Veer; Wu, Yunqi; Saks, Danit; WanderWall, Roshana; Fitzhenry, Matthew J; Basavarajappa, Devaraj; You, Yuyi; H Hosseini, Ghasem; A Haynes, Paul; L Graham, Stuart; Mirzaei, Mehdi (2021). "Mitochondrial dysfunction in Alzheimer's disease - a proteomics perspective". Expert Review of Proteomics. 18 (4): 295–304. doi:10.1080/14789450.2021.1918550. PMID 33874826. S2CID 233310698.
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