This is a Validated Antibody Database (VAD) review about mouse Sdha, based on 109 published articles (read how Labome selects the articles), using Sdha antibody in all methods. It is aimed to help Labome visitors find the most suited Sdha antibody. Please note the number of articles fluctuates since newly identified citations are added and citations for discontinued catalog numbers are removed regularly.
Sdha synonym: 1500032O14Rik; 2310034D06Rik; 4921513A11; C81073; FP; SDH2; SDHF

Knockout validation
Cell Signaling Technology
domestic rabbit polyclonal
  • western blot knockout validation; human; fig 4i
Cell Signaling Technology Sdha antibody (CST, 5839) was used in western blot knockout validation on human samples (fig 4i). Nat Cell Biol (2021) ncbi
Abcam
mouse monoclonal (2E3GC12FB2AE2)
  • western blot; mouse; loading ...; fig 2d
Abcam Sdha antibody (Abcam, ab14715) was used in western blot on mouse samples (fig 2d). Hum Mol Genet (2021) ncbi
mouse monoclonal (2E3GC12FB2AE2)
  • western blot; human; 1:5000; fig s5d
Abcam Sdha antibody (Abcam, ab14715) was used in western blot on human samples at 1:5000 (fig s5d). Cell Rep (2021) ncbi
mouse monoclonal (2E3GC12FB2AE2)
  • western blot; human; fig 2b
Abcam Sdha antibody (Abcam, ab14715) was used in western blot on human samples (fig 2b). Front Endocrinol (Lausanne) (2021) ncbi
mouse monoclonal (2E3GC12FB2AE2)
  • western blot; human; 1:3000; fig e1d, e1e, e1f
Abcam Sdha antibody (Abcam, ab14715) was used in western blot on human samples at 1:3000 (fig e1d, e1e, e1f). Nat Metab (2021) ncbi
mouse monoclonal (2E3GC12FB2AE2)
  • western blot; mouse; 1:5000; loading ...; fig 4a
Abcam Sdha antibody (Abcam, ab14715) was used in western blot on mouse samples at 1:5000 (fig 4a). elife (2020) ncbi
mouse monoclonal (2E3GC12FB2AE2)
  • western blot; mouse; 1:10,000; loading ...; fig 2f
Abcam Sdha antibody (Abcam, ab14715) was used in western blot on mouse samples at 1:10,000 (fig 2f). elife (2020) ncbi
mouse monoclonal (2E3GC12FB2AE2)
  • western blot; human; 1:1000; loading ...; fig 2b
Abcam Sdha antibody (Abcam, ab14715) was used in western blot on human samples at 1:1000 (fig 2b). Front Genet (2020) ncbi
mouse monoclonal (2E3GC12FB2AE2)
  • western blot; mouse; 1:1000; loading ...; fig 2a, 2b
Abcam Sdha antibody (Abcam, ab14715) was used in western blot on mouse samples at 1:1000 (fig 2a, 2b). PLoS Genet (2020) ncbi
mouse monoclonal (2E3GC12FB2AE2)
  • immunohistochemistry - frozen section; mouse; loading ...; fig 8c
  • immunocytochemistry; mouse; loading ...; fig 8s3a
Abcam Sdha antibody (Abcam, ab14715) was used in immunohistochemistry - frozen section on mouse samples (fig 8c) and in immunocytochemistry on mouse samples (fig 8s3a). elife (2019) ncbi
mouse monoclonal (2E3GC12FB2AE2)
Abcam Sdha antibody (Abcam, ab14715) was used . Nature (2019) ncbi
mouse monoclonal (2E3GC12FB2AE2)
  • immunocytochemistry; mouse; 1:200; loading ...; fig 5d
  • western blot; mouse; 1:1000; loading ...; fig 5a
Abcam Sdha antibody (Abcam, ab14715) was used in immunocytochemistry on mouse samples at 1:200 (fig 5d) and in western blot on mouse samples at 1:1000 (fig 5a). Biochem J (2019) ncbi
mouse monoclonal (2E3GC12FB2AE2)
  • western blot; mouse; loading ...; fig s3d
Abcam Sdha antibody (Abcam, ab14715) was used in western blot on mouse samples (fig s3d). Sci Adv (2019) ncbi
mouse monoclonal (2E3GC12FB2AE2)
  • western blot; mouse; loading ...; fig 1b
  • western blot; human; loading ...; fig 1a
Abcam Sdha antibody (Abcam, ab14715) was used in western blot on mouse samples (fig 1b) and in western blot on human samples (fig 1a). Haematologica (2019) ncbi
mouse monoclonal (2E3GC12FB2AE2)
  • western blot; human; 1:10,000; loading ...; fig 1b, s1a, s2g
  • western blot; mouse; 1:10,000; loading ...; fig 1g
Abcam Sdha antibody (Abcam, ab14715) was used in western blot on human samples at 1:10,000 (fig 1b, s1a, s2g) and in western blot on mouse samples at 1:10,000 (fig 1g). Life Sci Alliance (2019) ncbi
mouse monoclonal (2E3GC12FB2AE2)
  • western blot; human; fig 3e
Abcam Sdha antibody (abcam, ab14715) was used in western blot on human samples (fig 3e). Nucleic Acids Res (2018) ncbi
mouse monoclonal (2E3GC12FB2AE2)
  • western blot; human; loading ...; fig 4c, e2c
Abcam Sdha antibody (Abcam, ab14715) was used in western blot on human samples (fig 4c, e2c). Nature (2018) ncbi
mouse monoclonal (2E3GC12FB2AE2)
  • western blot; human; fig 1a
Abcam Sdha antibody (Abcam, ab14715) was used in western blot on human samples (fig 1a). Hum Mol Genet (2018) ncbi
mouse monoclonal (2E3GC12FB2AE2)
  • western blot; mouse; fig 3d
Abcam Sdha antibody (Abcam, ab14715) was used in western blot on mouse samples (fig 3d). Science (2017) ncbi
mouse monoclonal (2E3GC12FB2AE2)
  • immunohistochemistry; mouse; 1:100; loading ...; fig 4s
In order to demonstrate that some mitochondrial enzymes associated with the tricarboxylic acid cycle are essential for epigenetic remodeling and transiently localize to the nucleus, Abcam Sdha antibody (Abcam, ab14715) was used in immunohistochemistry on mouse samples at 1:100 (fig 4s). Cell (2017) ncbi
mouse monoclonal (2E3GC12FB2AE2)
  • western blot; human; loading ...; tbl 2
Abcam Sdha antibody (Abcam, Ab14715) was used in western blot on human samples (tbl 2). EMBO Rep (2017) ncbi
mouse monoclonal (2E3GC12FB2AE2)
  • western blot; mouse; loading ...; fig 3b
Abcam Sdha antibody (Abcam, ab14715) was used in western blot on mouse samples (fig 3b). Mol Biol Cell (2017) ncbi
mouse monoclonal (2E3GC12FB2AE2)
  • western blot; human; fig 3
Abcam Sdha antibody (abcam, ab14715) was used in western blot on human samples (fig 3). Sci Rep (2016) ncbi
mouse monoclonal (2E3GC12FB2AE2)
  • western blot; human; loading ...; fig 1
In order to investigate the role of Complex I accessory subunits, Abcam Sdha antibody (Abcam, ab14715) was used in western blot on human samples (fig 1). Nature (2016) ncbi
mouse monoclonal (2E3GC12FB2AE2)
  • western blot; mouse; 1:500; fig 5a
In order to investigate how the interaction between desmin with the alpha beta crystallin contributes to cardiac health, Abcam Sdha antibody (abcam, ab14715) was used in western blot on mouse samples at 1:500 (fig 5a). J Cell Sci (2016) ncbi
mouse monoclonal (2E3GC12FB2AE2)
  • western blot; human; fig 1
Abcam Sdha antibody (Abcam, ab14715) was used in western blot on human samples (fig 1). elife (2016) ncbi
mouse monoclonal (2E3GC12FB2AE2)
  • western blot; mouse; loading ...; fig 1b
In order to show that syntaxin-17 is required for the delivery of stress-induced PINK1/parkin-dependent mitochondrial-derived vesicles to the late endosome/lysosome, Abcam Sdha antibody (Abcam, ab14715) was used in western blot on mouse samples (fig 1b). J Cell Biol (2016) ncbi
mouse monoclonal (2E3GC12FB2AE2)
  • western blot; human; loading ...; fig 6a
In order to test if electron transport chain disruption eliminates Her2-high disease, Abcam Sdha antibody (Abcam, ab14715) was used in western blot on human samples (fig 6a). Antioxid Redox Signal (2017) ncbi
mouse monoclonal (2E3GC12FB2AE2)
  • western blot; mouse; 1:1000; fig 2
Abcam Sdha antibody (Abcam, 14715) was used in western blot on mouse samples at 1:1000 (fig 2). Nat Commun (2016) ncbi
domestic rabbit polyclonal
  • western blot; fruit fly ; fig 3s1
Abcam Sdha antibody (Abcam, 137756) was used in western blot on fruit fly samples (fig 3s1). elife (2016) ncbi
mouse monoclonal (2E3GC12FB2AE2)
  • immunohistochemistry; human; 1:100; fig 4
In order to use CLARITY to study mechanisms of neurodegeneration that occur in mitochondrial disease, Abcam Sdha antibody (Abcam, ab14715) was used in immunohistochemistry on human samples at 1:100 (fig 4). Sci Rep (2016) ncbi
mouse monoclonal (2E3GC12FB2AE2)
  • western blot; rat; 1:3000; fig 2b
In order to characterize healthy and injured vocal fold fibroblasts, Abcam Sdha antibody (Abcam, ab14715) was used in western blot on rat samples at 1:3000 (fig 2b). Lab Invest (2016) ncbi
mouse monoclonal (2E3GC12FB2AE2)
  • immunohistochemistry; human; 1:500; loading ...; fig 2a
In order to determine if the isocitrate dehydrogenase R132H mutation is present in pituitary adenomas, Abcam Sdha antibody (Abcam, ab-14715) was used in immunohistochemistry on human samples at 1:500 (fig 2a). Pituitary (2016) ncbi
mouse monoclonal (2E3GC12FB2AE2)
  • immunocytochemistry; human; fig s8
  • western blot; human; 1:1000; fig 3
In order to study melanoma addiction to RNA SAMMSON long non-coding region, Abcam Sdha antibody (Abcam, AB14715) was used in immunocytochemistry on human samples (fig s8) and in western blot on human samples at 1:1000 (fig 3). Nature (2016) ncbi
mouse monoclonal (2E3GC12FB2AE2)
  • western blot; mouse; 1:2000; tbl 2
Abcam Sdha antibody (Abcam, Ab14715) was used in western blot on mouse samples at 1:2000 (tbl 2). EMBO J (2016) ncbi
mouse monoclonal (2E3GC12FB2AE2)
  • western blot; human; fig s4b
  • western blot; mouse; fig s4c
Abcam Sdha antibody (Abcam, ab14715) was used in western blot on human samples (fig s4b) and in western blot on mouse samples (fig s4c). Biochim Biophys Acta (2016) ncbi
mouse monoclonal (2E3GC12FB2AE2)
  • immunohistochemistry - paraffin section; human; loading ...; fig 1b
In order to study respiratory chain abnormalities and the contribution of mitochondrial DNA to the loss of respiratory chain complexes of idiopathic Parkinson disease patients at the single-neuron level, Abcam Sdha antibody (Abcam, ab14715) was used in immunohistochemistry - paraffin section on human samples (fig 1b). Ann Neurol (2016) ncbi
mouse monoclonal (2E3GC12FB2AE2)
  • western blot; mouse; 1:5000; fig 4
Abcam Sdha antibody (Abcam, ab14715) was used in western blot on mouse samples at 1:5000 (fig 4). Biochim Biophys Acta (2016) ncbi
mouse monoclonal (2E3GC12FB2AE2)
  • western blot; mouse; fig 2c
Abcam Sdha antibody (Abcam, Ab14715) was used in western blot on mouse samples (fig 2c). Oncotarget (2015) ncbi
mouse monoclonal (2E3GC12FB2AE2)
  • western blot; mouse; fig 3
Abcam Sdha antibody (Abcam, ab14715) was used in western blot on mouse samples (fig 3). PLoS ONE (2015) ncbi
mouse monoclonal (2E3GC12FB2AE2)
  • western blot; rat; 1:1000; fig 6
In order to elucidate ketamine-induced ulcerative cystitis and bladder apoptosis in association with oxidative stress mediated by mitochondria and the endoplasmic reticulum, Abcam Sdha antibody (Abcam, ab14715) was used in western blot on rat samples at 1:1000 (fig 6). Am J Physiol Renal Physiol (2015) ncbi
mouse monoclonal (2E3GC12FB2AE2)
  • western blot; human; 1:10,000; loading ...; fig 1a
Abcam Sdha antibody (Abcam, ab14715) was used in western blot on human samples at 1:10,000 (fig 1a). PLoS ONE (2015) ncbi
mouse monoclonal (2E3GC12FB2AE2)
  • western blot; human; 1:1000
In order to delineate the role of PYCR2 mutation in microcephaly and hypomyelination, Abcam Sdha antibody (Abcam, ab14715) was used in western blot on human samples at 1:1000. Am J Hum Genet (2015) ncbi
mouse monoclonal (2E3GC12FB2AE2)
  • western blot; human; 1:30,000
In order to discuss the known phenotypes related to AIFM1 mutations and further study a single patient, Abcam Sdha antibody (Abcam, ab14715) was used in western blot on human samples at 1:30,000. Mitochondrion (2015) ncbi
mouse monoclonal (2E3GC12FB2AE2)
  • western blot; mouse
In order to study the correlation between cardiac mitochondrial dysfunction and the high fat, high sucrose diet, Abcam Sdha antibody (Abcam, ab14715) was used in western blot on mouse samples . J Mol Cell Cardiol (2015) ncbi
mouse monoclonal (2E3GC12FB2AE2)
  • western blot; human
In order to explore the parkin-dependent regulation of apoptosis and the turnover of damaged mitochondria in various cell types, Abcam Sdha antibody (Abcam, ab14715) was used in western blot on human samples . Cell Death Dis (2014) ncbi
mouse monoclonal (2E3GC12FB2AE2)
  • western blot; chicken
Abcam Sdha antibody (Abcam, ab14715) was used in western blot on chicken samples . G3 (Bethesda) (2014) ncbi
mouse monoclonal (2E3GC12FB2AE2)
  • western blot; mouse; 1:10,000
Abcam Sdha antibody (Abcam, ab14715) was used in western blot on mouse samples at 1:10,000. PLoS ONE (2014) ncbi
mouse monoclonal (2E3GC12FB2AE2)
  • western blot; rat; 1:500
Abcam Sdha antibody (Abcam, ab14715) was used in western blot on rat samples at 1:500. J Neurochem (2014) ncbi
mouse monoclonal (2E3GC12FB2AE2)
  • immunohistochemistry - paraffin section; human; 1:1000
Abcam Sdha antibody (Abcam, ab14715) was used in immunohistochemistry - paraffin section on human samples at 1:1000. Endocr Pathol (2013) ncbi
mouse monoclonal (2E3GC12FB2AE2)
  • western blot; human
  • western blot; rat
  • western blot; mouse
Abcam Sdha antibody (Abcam, ab14715) was used in western blot on human samples , in western blot on rat samples and in western blot on mouse samples . PLoS ONE (2013) ncbi
mouse monoclonal (2E3GC12FB2AE2)
  • western blot; human
Abcam Sdha antibody (Abcam, ab14715) was used in western blot on human samples . Neurobiol Dis (2013) ncbi
mouse monoclonal (2E3GC12FB2AE2)
  • immunohistochemistry - paraffin section; human; 1:2500
  • western blot; human
Abcam Sdha antibody (Abcam, ab14715) was used in immunohistochemistry - paraffin section on human samples at 1:2500 and in western blot on human samples . Eur J Hum Genet (2014) ncbi
mouse monoclonal (2E3GC12FB2AE2)
  • immunocytochemistry; human; 1:50
Abcam Sdha antibody (Abcam, ab14715) was used in immunocytochemistry on human samples at 1:50. J Am Heart Assoc (2012) ncbi
mouse monoclonal (2E3GC12FB2AE2)
  • western blot; human; 1:1000
Abcam Sdha antibody (Abcam, AB14715) was used in western blot on human samples at 1:1000. Mitochondrion (2013) ncbi
mouse monoclonal (2E3GC12FB2AE2)
  • western blot; mouse; 1:200
Abcam Sdha antibody (Abcam, ab14715) was used in western blot on mouse samples at 1:200. Nat Med (2012) ncbi
Invitrogen
mouse monoclonal (2E3GC12FB2AE2)
  • western blot; mouse; loading ...; fig 1c
Invitrogen Sdha antibody (Invitrogen, 459200) was used in western blot on mouse samples (fig 1c). Cell Rep (2019) ncbi
mouse monoclonal (2E3GC12FB2AE2)
  • western blot; mouse; loading ...; fig 2a
Invitrogen Sdha antibody (Thermo Fisher Scientific, 459200) was used in western blot on mouse samples (fig 2a). Cell (2019) ncbi
mouse monoclonal (2E3GC12FB2AE2)
  • western blot; human; loading ...; fig 2a
Invitrogen Sdha antibody (Invitrogen, 459200) was used in western blot on human samples (fig 2a). J Cell Biol (2019) ncbi
mouse monoclonal (2E3GC12FB2AE2)
  • western blot; mouse; loading ...; fig 6b
In order to identify posttranscriptional mechanisms that regulate mitochondrial protein expression, Invitrogen Sdha antibody (Invitrogen, 459200) was used in western blot on mouse samples (fig 6b). J Cell Biol (2017) ncbi
mouse monoclonal (2E3GC12FB2AE2)
  • western blot; rat; 1:2000; loading ...; fig 1
In order to investigate the role of Ser25 phosphorylation in subcellular localization of Annexin A2 and its interaction with mRNP complexes, Invitrogen Sdha antibody (Invitrogen, 2E3GC12FB2AE2) was used in western blot on rat samples at 1:2000 (fig 1). FEBS Open Bio (2017) ncbi
mouse monoclonal (2E3GC12FB2AE2)
  • western blot; rat; 1:1000; loading ...; fig 6d
In order to evaluate the mitochondrial dynamics of the cerebral vasculature of 14-week-old Zucker diabetic fatty obese rats with early type 2 diabetes, Invitrogen Sdha antibody (Invitrogen, 459200) was used in western blot on rat samples at 1:1000 (fig 6d). J Vasc Res (2017) ncbi
mouse monoclonal (2E3GC12FB2AE2)
  • western blot; human; 1:500; loading ...; fig 2
In order to discover that protein oxidative and glycoxidative damage significantly increases during human brain aging, Invitrogen Sdha antibody (Invitrogen, 459200) was used in western blot on human samples at 1:500 (fig 2). Free Radic Biol Med (2017) ncbi
mouse monoclonal (2E3GC12FB2AE2)
  • western blot; human; fig 1j
In order to demonstrate that complex I function defines the metabolic differences between succinate dehydrogenase mutation associated tumors and neurodegenerative diseases, Invitrogen Sdha antibody (ThermoFisher Scientific, 459200) was used in western blot on human samples (fig 1j). Metab Eng (2017) ncbi
mouse monoclonal (2E3GC12FB2AE2)
  • immunoprecipitation; mouse; loading ...; fig s6c
  • western blot; mouse; 1:10,000; loading ...; fig s6c
In order to demonstrate that Fat1 cadherin represses mitochondrial respiration that regulates vascular smooth muscle cell proliferation after arterial injury, Invitrogen Sdha antibody (Invitrogen, 459200) was used in immunoprecipitation on mouse samples (fig s6c) and in western blot on mouse samples at 1:10,000 (fig s6c). Nature (2016) ncbi
mouse monoclonal (2E3GC12FB2AE2)
  • western blot; human; loading ...; fig 5a
In order to discover a mammalian translational plasticity pathway in mitochondria, Invitrogen Sdha antibody (Novex, 459200) was used in western blot on human samples (fig 5a). Cell (2016) ncbi
mouse monoclonal (2E3GC12FB2AE2)
  • immunohistochemistry - paraffin section; mouse; 1:1000; loading ...; fig 3a
In order to test if the severe neurodegeneration observed in mutUNG1-expressing mice is prevented by a ketogenic diet, Invitrogen Sdha antibody (Invitrogen, 459200) was used in immunohistochemistry - paraffin section on mouse samples at 1:1000 (fig 3a). Neurobiol Aging (2016) ncbi
mouse monoclonal (2E3GC12FB2AE2)
  • western blot; mouse; fig 1d
In order to identify a role for Ptcd3 in B-cell lymphoma, Invitrogen Sdha antibody (Invitrogen, 459200) was used in western blot on mouse samples (fig 1d). Oncotarget (2016) ncbi
mouse monoclonal (2E3GC12FB2AE2)
  • western blot; human; loading ...; fig 2b
In order to show direct interference of aggregation-prone Abeta peptides with mitochondrial protein biogenesis, Invitrogen Sdha antibody (Thermo Fisher, 459200) was used in western blot on human samples (fig 2b). Mol Biol Cell (2016) ncbi
mouse monoclonal (2E3GC12FB2AE2)
  • western blot; mouse; 1:1000; fig 4
In order to show that mutant desmin expression results in mitochondrial damage during early stages of desminopathies, Invitrogen Sdha antibody (Invitrogen, 459200) was used in western blot on mouse samples at 1:1000 (fig 4). Acta Neuropathol (2016) ncbi
mouse monoclonal (2E3GC12FB2AE2)
  • western blot; mouse; 1:5000; loading ...; fig 1b
In order to explore how bacterial infections alter the mitochondrial electron-transport chain in macrophages, Invitrogen Sdha antibody (Invitrogen, 459200) was used in western blot on mouse samples at 1:5000 (fig 1b). Nat Immunol (2016) ncbi
mouse monoclonal (2E3GC12FB2AE2)
  • western blot; mouse; fig 6
In order to study alleviation of impaired mitochondrial biogenesis by twinkle overexpression preventing cardiac rupture after myocardial infarction, Invitrogen Sdha antibody (Invitrogen, 459200) was used in western blot on mouse samples (fig 6). Am J Physiol Heart Circ Physiol (2016) ncbi
mouse monoclonal (2E3GC12FB2AE2)
  • western blot; mouse; 1:1000; fig 3
In order to study the alleviation of mitochondrial cardiomyopathy without affecting the mammalian UPRmt due to loss of CLPP, Invitrogen Sdha antibody (Invitrogen, 459200) was used in western blot on mouse samples at 1:1000 (fig 3). EMBO Rep (2016) ncbi
mouse monoclonal (2E3GC12FB2AE2)
  • western blot; human; fig 4
In order to study muscular dystrophy and the downstream effects of plectin mutations in epidermolysis bullosa simplex, Invitrogen Sdha antibody (Invitrogen, 459200) was used in western blot on human samples (fig 4). Acta Neuropathol Commun (2016) ncbi
mouse monoclonal (2E3GC12FB2AE2)
  • western blot; mouse; 1:5000; fig 5
In order to characterize a failing heart and mitochondrial protein hyperacetylation, Invitrogen Sdha antibody (Invitrogen, 459200) was used in western blot on mouse samples at 1:5000 (fig 5). JCI Insight (2016) ncbi
mouse monoclonal (2E3GC12FB2AE2)
  • western blot; human; 1:5000; fig s1
In order to elucidate how a reduction in mitochondrial iron during injury can alleviate cardiac damage, Invitrogen Sdha antibody (Life Technologies, 459200) was used in western blot on human samples at 1:5000 (fig s1). EMBO Mol Med (2016) ncbi
mouse monoclonal (2E3GC12FB2AE2)
  • western blot; rat; 1:1000; fig 6
In order to study cerebral vasculature mitochondrial function in insulin-resistant Zucker obese rats, Invitrogen Sdha antibody (Invitrogen, 459200) was used in western blot on rat samples at 1:1000 (fig 6). Am J Physiol Heart Circ Physiol (2016) ncbi
mouse monoclonal (2E3GC12FB2AE2)
  • western blot; mouse; fig s3a
In order to study how OMA1 links mitochondrial morphology and cardiac metabolism, Invitrogen Sdha antibody (Invitrogen, 459200) was used in western blot on mouse samples (fig s3a). Science (2015) ncbi
mouse monoclonal (2E3GC12FB2AE2)
  • western blot; mouse; fig s1
In order to analyze delay of neurodegeneration by preventing stress-induced OPA1 processing in mitochondria by loss of OMA1, Invitrogen Sdha antibody (Invitrogen, 459200) was used in western blot on mouse samples (fig s1). J Cell Biol (2016) ncbi
mouse monoclonal (2E3GC12FB2AE2)
  • western blot; rat; 1:1000
In order to test if mitochondrial energetics of large cerebral arteries are sex dependent, Invitrogen Sdha antibody (Invitrogen, 459200) was used in western blot on rat samples at 1:1000. Am J Physiol Heart Circ Physiol (2015) ncbi
mouse monoclonal (2E3GC12FB2AE2)
  • western blot; mouse
In order to test the requirement of AMP-activated protein kinase for exercise training-induced increases in skeletal muscle abundance of mitochondrial proteins, Invitrogen Sdha antibody (Invitrogen, #459200) was used in western blot on mouse samples . Front Physiol (2015) ncbi
mouse monoclonal (2E3GC12FB2AE2)
  • western blot; mouse
In order to assess the role of mtDNA copy number in heart failure, Invitrogen Sdha antibody (Invitrogen, 459200) was used in western blot on mouse samples . PLoS ONE (2015) ncbi
mouse monoclonal (2E3GC12FB2AE2)
  • western blot; human
In order to elucidate the molecular mechanisms by which mitochondrial respiratory chain dysfunction results in cell death, Invitrogen Sdha antibody (Invitrogen, 2E3GC12FB2AE2) was used in western blot on human samples . Cell Death Dis (2015) ncbi
mouse monoclonal (2E3GC12FB2AE2)
  • western blot; mouse; 1:1000; fig 5
In order to assess effects nuclear factor-erythroid 2-related factor 1 deficiency in beta-cells on beta-cell function and glucose homeostasis, Invitrogen Sdha antibody (Invitrogen, 459200) was used in western blot on mouse samples at 1:1000 (fig 5). Antioxid Redox Signal (2015) ncbi
mouse monoclonal (2E3GC12FB2AE2)
  • western blot; mouse; fig 2
In order to elucidate the mechanisms underlying cellular damage and senescence and accelerated aging in Hutchinson-Gilford progeria syndrome, Invitrogen Sdha antibody (Invitrogen, 459200) was used in western blot on mouse samples (fig 2). J Proteomics (2013) ncbi
mouse monoclonal (2E3GC12FB2AE2)
  • immunocytochemistry; mouse; fig 3
In order to determine if Irgm1 targets mycobacterial and listerial phagosomes, Invitrogen Sdha antibody (Invitrogen, 459200) was used in immunocytochemistry on mouse samples (fig 3). J Immunol (2013) ncbi
mouse monoclonal (2E3GC12FB2AE2)
  • western blot; rat; 1:10,000; fig 5
In order to investigate the mitochondrial dynamics in rat neurons following oxygen-glucose deprivation, Invitrogen Sdha antibody (Invitrogen, 459200) was used in western blot on rat samples at 1:10,000 (fig 5). PLoS ONE (2013) ncbi
mouse monoclonal (2E3GC12FB2AE2)
  • immunocytochemistry; human; 10 ug/ml; fig 8
In order to determine the enzymatic function of FAHD1, Invitrogen Sdha antibody (Invitrogen, 459200) was used in immunocytochemistry on human samples at 10 ug/ml (fig 8). J Biol Chem (2011) ncbi
mouse monoclonal (2E3GC12FB2AE2)
  • immunohistochemistry - paraffin section; mouse; 1:1000; fig 1
In order to investigate the effects of mitochondrial DNA damage on hippocampal neurons, Invitrogen Sdha antibody (Invitrogen, 459200) was used in immunohistochemistry - paraffin section on mouse samples at 1:1000 (fig 1). DNA Repair (Amst) (2011) ncbi
Santa Cruz Biotechnology
mouse monoclonal (D-4)
  • western blot; human; loading ...; fig 2c
Santa Cruz Biotechnology Sdha antibody (SantaCruz Biotechnology, sc-166947) was used in western blot on human samples (fig 2c). elife (2021) ncbi
mouse monoclonal (F-2)
  • western blot; human; 1:1000; loading ...
Santa Cruz Biotechnology Sdha antibody (Santa Cruz Biotechnology, sc-390381) was used in western blot on human samples at 1:1000. Nat Commun (2020) ncbi
mouse monoclonal (F-2)
  • western blot; mouse; 1:100; fig 3b
Santa Cruz Biotechnology Sdha antibody (Santa, SC390381) was used in western blot on mouse samples at 1:100 (fig 3b). Nature (2019) ncbi
Cell Signaling Technology
domestic rabbit polyclonal
  • immunohistochemistry; mouse; loading ...; fig s4
Cell Signaling Technology Sdha antibody (Cell Signaling, 5839) was used in immunohistochemistry on mouse samples (fig s4). iScience (2022) ncbi
domestic rabbit monoclonal (D6J9M)
  • western blot; mouse; loading ...; fig 5g
Cell Signaling Technology Sdha antibody (CST, 11998) was used in western blot on mouse samples (fig 5g). Cell Death Dis (2021) ncbi
domestic rabbit polyclonal
  • western blot; human; 1:1000
Cell Signaling Technology Sdha antibody (Cell Signaling, 5839) was used in western blot on human samples at 1:1000. Cell Rep (2021) ncbi
domestic rabbit polyclonal
  • western blot knockout validation; human; fig 4i
Cell Signaling Technology Sdha antibody (CST, 5839) was used in western blot knockout validation on human samples (fig 4i). Nat Cell Biol (2021) ncbi
domestic rabbit polyclonal
  • western blot; mouse; loading ...; fig 5a
Cell Signaling Technology Sdha antibody (Cell Signaling, 5839) was used in western blot on mouse samples (fig 5a). elife (2020) ncbi
domestic rabbit monoclonal (D6J9M)
  • western blot; human; 1:1000; loading ...; fig e3e
Cell Signaling Technology Sdha antibody (CST, 11998) was used in western blot on human samples at 1:1000 (fig e3e). Nature (2019) ncbi
domestic rabbit monoclonal (D6J9M)
  • flow cytometry; human; loading ...; fig 4b
Cell Signaling Technology Sdha antibody (Cell Signaling Technology, 11998) was used in flow cytometry on human samples (fig 4b). Physiol Rep (2019) ncbi
domestic rabbit monoclonal (D6J9M)
  • immunohistochemistry - paraffin section; human; loading ...; fig 5a
Cell Signaling Technology Sdha antibody (Cell Signaling, 11998) was used in immunohistochemistry - paraffin section on human samples (fig 5a). Cell (2019) ncbi
domestic rabbit polyclonal
  • other; human; loading ...; fig 2c
  • western blot; human; loading ...; fig 2a
Cell Signaling Technology Sdha antibody (Cell Signaling, 5839) was used in other on human samples (fig 2c) and in western blot on human samples (fig 2a). J Cell Biol (2019) ncbi
domestic rabbit monoclonal (D6J9M)
  • western blot; human; loading ...; fig 2h
Cell Signaling Technology Sdha antibody (Cell Signaling, 11998) was used in western blot on human samples (fig 2h). J Appl Physiol (1985) (2019) ncbi
domestic rabbit monoclonal (D6J9M)
  • other; human; loading ...; fig 4c
Cell Signaling Technology Sdha antibody (Cell Signaling, 11998) was used in other on human samples (fig 4c). Cancer Cell (2018) ncbi
domestic rabbit monoclonal (D6J9M)
  • western blot; human; loading ...; fig 5b
Cell Signaling Technology Sdha antibody (Cell Signaling, 11998) was used in western blot on human samples (fig 5b). Sci Rep (2017) ncbi
domestic rabbit monoclonal (D6J9M)
  • immunocytochemistry; human; 1:2000; loading ...; fig s8
  • western blot; human; 1:2000; loading ...; fig 4a
In order to research the role of mutations of the aminoacyl-tRNA-synthetases SARS and WARS2 in the pathogenesis of autosomal recessive intellectual disability, Cell Signaling Technology Sdha antibody (Cell Signaling, 11998) was used in immunocytochemistry on human samples at 1:2000 (fig s8) and in western blot on human samples at 1:2000 (fig 4a). Hum Mutat (2017) ncbi
domestic rabbit monoclonal (D6J9M)
  • immunohistochemistry - paraffin section; mouse; loading ...; fig 2C
  • western blot; mouse; fig 2B
Cell Signaling Technology Sdha antibody (Cell Signaling, 11998) was used in immunohistochemistry - paraffin section on mouse samples (fig 2C) and in western blot on mouse samples (fig 2B). Sci Rep (2017) ncbi
domestic rabbit polyclonal
  • western blot; mouse; loading ...; fig 4i
Cell Signaling Technology Sdha antibody (Cell Signaling Technology, 5839) was used in western blot on mouse samples (fig 4i). J Cell Biol (2017) ncbi
domestic rabbit monoclonal (D6J9M)
  • western blot; mouse; 1:1000; loading ...; fig 2c
In order to assess the effect of increased Parkin deletion mutagenesis in the absence of mitochondrial quality control, Cell Signaling Technology Sdha antibody (Cell Signaling, 11998) was used in western blot on mouse samples at 1:1000 (fig 2c). Neurobiol Dis (2017) ncbi
domestic rabbit monoclonal (D6J9M)
  • western blot; human; fig 7
In order to describe the effects of long- and short-term exposure to erythropoietin on white adipose tissue, Cell Signaling Technology Sdha antibody (Cell signaling, 11998) was used in western blot on human samples (fig 7). Lipids Health Dis (2016) ncbi
domestic rabbit polyclonal
  • western blot; mouse; fig 1
Cell Signaling Technology Sdha antibody (Cell Signaling Tech, 5839S) was used in western blot on mouse samples (fig 1). Eneuro (2016) ncbi
domestic rabbit polyclonal
  • western blot; mouse; fig 2
Cell Signaling Technology Sdha antibody (Cell Signaling, 5839) was used in western blot on mouse samples (fig 2). PLoS ONE (2016) ncbi
domestic rabbit monoclonal (D6J9M)
  • western blot; rat; 1:1000; fig 8
In order to investigate thyroid hormone-mediated autophagy in skeletal muscle, Cell Signaling Technology Sdha antibody (Cell Signaling Technology, 11998) was used in western blot on rat samples at 1:1000 (fig 8). Endocrinology (2016) ncbi
Articles Reviewed
  1. Wang X, Middleton F, Tawil R, Chen X. Cytosolic adaptation to mitochondria-induced proteostatic stress causes progressive muscle wasting. iScience. 2022;25:103715 pubmed publisher
  2. Zhang Y, Wen P, Luo J, Ding H, Cao H, He W, et al. Sirtuin 3 regulates mitochondrial protein acetylation and metabolism in tubular epithelial cells during renal fibrosis. Cell Death Dis. 2021;12:847 pubmed publisher
  3. Zhou X, Mikaeloff F, Curbo S, Zhao Q, Kuiper R, Vegvari A, et al. Coordinated pyruvate kinase activity is crucial for metabolic adaptation and cell survival during mitochondrial dysfunction. Hum Mol Genet. 2021;30:2012-2026 pubmed publisher
  4. Le Vasseur M, Friedman J, Jost M, Xu J, Yamada J, Kampmann M, et al. Genome-wide CRISPRi screening identifies OCIAD1 as a prohibitin client and regulatory determinant of mitochondrial Complex III assembly in human cells. elife. 2021;10: pubmed publisher
  5. Sighel D, Notarangelo M, Aibara S, Re A, Ricci G, Guida M, et al. Inhibition of mitochondrial translation suppresses glioblastoma stem cell growth. Cell Rep. 2021;35:109024 pubmed publisher
  6. Andrade J, Shi C, Costa A, Choi J, Kim J, Doddaballapur A, et al. Control of endothelial quiescence by FOXO-regulated metabolites. Nat Cell Biol. 2021;23:413-423 pubmed publisher
  7. Matlac D, Hadrava Vanova K, Bechmann N, Richter S, Folberth J, Ghayee H, et al. Succinate Mediates Tumorigenic Effects via Succinate Receptor 1: Potential for New Targeted Treatment Strategies in Succinate Dehydrogenase Deficient Paragangliomas. Front Endocrinol (Lausanne). 2021;12:589451 pubmed publisher
  8. Perry E, Bennett C, Luo C, Balsa E, Jedrychowski M, O Malley K, et al. Tetracyclines promote survival and fitness in mitochondrial disease models. Nat Metab. 2021;3:33-42 pubmed publisher
  9. Tao L, Lemoff A, Wang G, Zarek C, Lowe A, Yan N, et al. Reactive oxygen species oxidize STING and suppress interferon production. elife. 2020;9: pubmed publisher
  10. Nowinski S, Solmonson A, Rusin S, Maschek J, Bensard C, Fogarty S, et al. Mitochondrial fatty acid synthesis coordinates oxidative metabolism in mammalian mitochondria. elife. 2020;9: pubmed publisher
  11. Marmol P, Krapacher F, Ibanez C. Control of brown adipose tissue adaptation to nutrient stress by the activin receptor ALK7. elife. 2020;9: pubmed publisher
  12. Ng Y, Thompson K, Loher D, Hopton S, Falkous G, Hardy S, et al. Novel MT-ND Gene Variants Causing Adult-Onset Mitochondrial Disease and Isolated Complex I Deficiency. Front Genet. 2020;11:24 pubmed publisher
  13. Bajpai R, Sharma A, Achreja A, Edgar C, Wei C, Siddiqa A, et al. Electron transport chain activity is a predictor and target for venetoclax sensitivity in multiple myeloma. Nat Commun. 2020;11:1228 pubmed publisher
  14. Ferreira N, Andoniou C, Perks K, Ermer J, Rudler D, Rossetti G, et al. Murine cytomegalovirus infection exacerbates complex IV deficiency in a model of mitochondrial disease. PLoS Genet. 2020;16:e1008604 pubmed publisher
  15. Amendola C, Mahaffey J, Parker S, Ahearn I, Chen W, Zhou M, et al. KRAS4A directly regulates hexokinase 1. Nature. 2019;576:482-486 pubmed publisher
  16. Høgild M, Gudiksen A, Pilegaard H, Stødkilde Jørgensen H, Pedersen S, Møller N, et al. Redundancy in regulation of lipid accumulation in skeletal muscle during prolonged fasting in obese men. Physiol Rep. 2019;7:e14285 pubmed publisher
  17. Busch J, Cipullo M, Atanassov I, Bratic A, Silva Ramos E, Schondorf T, et al. MitoRibo-Tag Mice Provide a Tool for In Vivo Studies of Mitoribosome Composition. Cell Rep. 2019;29:1728-1738.e9 pubmed publisher
  18. Varuzhanyan G, Rojansky R, Sweredoski M, Graham R, Hess S, Ladinsky M, et al. Mitochondrial fusion is required for spermatogonial differentiation and meiosis. elife. 2019;8: pubmed publisher
  19. Morris J, Yashinskie J, Koche R, Chandwani R, Tian S, Chen C, et al. α-Ketoglutarate links p53 to cell fate during tumour suppression. Nature. 2019;573:595-599 pubmed publisher
  20. Harel M, Ortenberg R, Varanasi S, Mangalhara K, Mardamshina M, Markovits E, et al. Proteomics of Melanoma Response to Immunotherapy Reveals Mitochondrial Dependence. Cell. 2019;179:236-250.e18 pubmed publisher
  21. Martínez J, Tarallo D, Martinez Palma L, Victoria S, Bresque M, Rodriguez Bottero S, et al. Mitofusins modulate the increase in mitochondrial length, bioenergetics and secretory phenotype in therapy-induced senescent melanoma cells. Biochem J. 2019;476:2463-2486 pubmed publisher
  22. Hammerschmidt P, Ostkotte D, Nolte H, Gerl M, Jais A, Brunner H, et al. CerS6-Derived Sphingolipids Interact with Mff and Promote Mitochondrial Fragmentation in Obesity. Cell. 2019;177:1536-1552.e23 pubmed publisher
  23. Filograna R, Koolmeister C, Upadhyay M, Pajak A, Clemente P, Wibom R, et al. Modulation of mtDNA copy number ameliorates the pathological consequences of a heteroplasmic mtDNA mutation in the mouse. Sci Adv. 2019;5:eaav9824 pubmed publisher
  24. Shi Y, Lim S, Liang Q, Iyer S, Wang H, Wang Z, et al. Gboxin is an oxidative phosphorylation inhibitor that targets glioblastoma. Nature. 2019;567:341-346 pubmed publisher
  25. Maio N, Kim K, Holmes Hampton G, Singh A, Rouault T. Dimeric ferrochelatase bridges ABCB7 and ABCB10 homodimers in an architecturally defined molecular complex required for heme biosynthesis. Haematologica. 2019;: pubmed publisher
  26. Richter U, Ng K, Suomi F, Marttinen P, Turunen T, Jackson C, et al. Mitochondrial stress response triggered by defects in protein synthesis quality control. Life Sci Alliance. 2019;2: pubmed publisher
  27. Richter F, Dennerlein S, Nikolov M, Jans D, Naumenko N, Aich A, et al. ROMO1 is a constituent of the human presequence translocase required for YME1L protease import. J Cell Biol. 2019;218:598-614 pubmed publisher
  28. Riis S, Christensen B, Nellemann B, Møller A, Husted A, Pedersen S, et al. Molecular adaptations in human subcutaneous adipose tissue after ten weeks of endurance exercise training in healthy males. J Appl Physiol (1985). 2019;126:569-577 pubmed publisher
  29. Maiti P, Kim H, Tu Y, Barrientos A. Human GTPBP10 is required for mitoribosome maturation. Nucleic Acids Res. 2018;46:11423-11437 pubmed publisher
  30. Ng P, Li J, Jeong K, Shao S, Chen H, Tsang Y, et al. Systematic Functional Annotation of Somatic Mutations in Cancer. Cancer Cell. 2018;33:450-462.e10 pubmed publisher
  31. Morscher R, Ducker G, Li S, Mayer J, Gitai Z, Sperl W, et al. Mitochondrial translation requires folate-dependent tRNA methylation. Nature. 2018;554:128-132 pubmed publisher
  32. Straub I, Janer A, Weraarpachai W, Zinman L, Robertson J, Rogaeva E, et al. Loss of CHCHD10-CHCHD2 complexes required for respiration underlies the pathogenicity of a CHCHD10 mutation in ALS. Hum Mol Genet. 2018;27:178-189 pubmed publisher
  33. Wang Y, Kuang Z, Yu X, Ruhn K, Kubo M, Hooper L. The intestinal microbiota regulates body composition through NFIL3 and the circadian clock. Science. 2017;357:912-916 pubmed publisher
  34. Møller A, Kampmann U, Hedegaard J, Thorsen K, Nordentoft I, Vendelbo M, et al. Altered gene expression and repressed markers of autophagy in skeletal muscle of insulin resistant patients with type 2 diabetes. Sci Rep. 2017;7:43775 pubmed publisher
  35. Musante L, Püttmann L, Kahrizi K, Garshasbi M, Hu H, Stehr H, et al. Mutations of the aminoacyl-tRNA-synthetases SARS and WARS2 are implicated in the etiology of autosomal recessive intellectual disability. Hum Mutat. 2017;38:621-636 pubmed publisher
  36. Kemter E, Frohlich T, Arnold G, Wolf E, Wanke R. Mitochondrial Dysregulation Secondary to Endoplasmic Reticulum Stress in Autosomal Dominant Tubulointerstitial Kidney Disease - UMOD (ADTKD-UMOD). Sci Rep. 2017;7:42970 pubmed publisher
  37. Schatton D, Pla Martín D, Marx M, Hansen H, Mourier A, Nemazanyy I, et al. CLUH regulates mitochondrial metabolism by controlling translation and decay of target mRNAs. J Cell Biol. 2017;216:675-693 pubmed publisher
  38. Qiao A, Jin X, Pang J, Moskophidis D, Mivechi N. The transcriptional regulator of the chaperone response HSF1 controls hepatic bioenergetics and protein homeostasis. J Cell Biol. 2017;216:723-741 pubmed publisher
  39. Aukrust I, Rosenberg L, Ankerud M, Bertelsen V, Hollås H, Saraste J, et al. Post-translational modifications of Annexin A2 are linked to its association with perinuclear nonpolysomal mRNP complexes. FEBS Open Bio. 2017;7:160-173 pubmed publisher
  40. Merdzo I, Rutkai I, Sure V, McNulty C, Katakam P, Busija D. Impaired Mitochondrial Respiration in Large Cerebral Arteries of Rats with Type 2 Diabetes. J Vasc Res. 2017;54:1-12 pubmed publisher
  41. Nagaraj R, Sharpley M, Chi F, Braas D, Zhou Y, Kim R, et al. Nuclear Localization of Mitochondrial TCA Cycle Enzymes as a Critical Step in Mammalian Zygotic Genome Activation. Cell. 2017;168:210-223.e11 pubmed publisher
  42. Bourens M, Barrientos A. A CMC1-knockout reveals translation-independent control of human mitochondrial complex IV biogenesis. EMBO Rep. 2017;18:477-494 pubmed publisher
  43. Patrinostro X, O Rourke A, Chamberlain C, Moriarity B, Perrin B, Ervasti J. Relative importance of ?cyto- and ?cyto-actin in primary mouse embryonic fibroblasts. Mol Biol Cell. 2017;28:771-782 pubmed publisher
  44. Song L, McMackin M, Nguyen A, Cortopassi G. Parkin deficiency accelerates consequences of mitochondrial DNA deletions and Parkinsonism. Neurobiol Dis. 2017;100:30-38 pubmed publisher
  45. Cabre R, Naudi A, Dominguez Gonzalez M, Ayala V, Jove M, Mota Martorell N, et al. Sixty years old is the breakpoint of human frontal cortex aging. Free Radic Biol Med. 2017;103:14-22 pubmed publisher
  46. Lorendeau D, Rinaldi G, Boon R, Spincemaille P, Metzger K, Jäger C, et al. Dual loss of succinate dehydrogenase (SDH) and complex I activity is necessary to recapitulate the metabolic phenotype of SDH mutant tumors. Metab Eng. 2017;43:187-197 pubmed publisher
  47. Cao L, Riascos Bernal D, Chinnasamy P, Dunaway C, Hou R, Pujato M, et al. Control of mitochondrial function and cell growth by the atypical cadherin Fat1. Nature. 2016;539:575-578 pubmed publisher
  48. Zhang Y, Zhang Y, Zhong C, Xiao F. Cr(VI) induces premature senescence through ROS-mediated p53 pathway in L-02 hepatocytes. Sci Rep. 2016;6:34578 pubmed publisher
  49. Richter Dennerlein R, Oeljeklaus S, Lorenzi I, Ronsör C, Bareth B, Schendzielorz A, et al. Mitochondrial Protein Synthesis Adapts to Influx of Nuclear-Encoded Protein. Cell. 2016;167:471-483.e10 pubmed publisher
  50. Christensen B, Nellemann B, Jørgensen J, Pedersen S, Jessen N. Erythropoietin does not activate erythropoietin receptor signaling or lipolytic pathways in human subcutaneous white adipose tissue in vivo. Lipids Health Dis. 2016;15:160 pubmed publisher
  51. Lauritzen K, Hasan Olive M, Regnell C, Kleppa L, Scheibye Knudsen M, Gjedde A, et al. A ketogenic diet accelerates neurodegeneration in mice with induced mitochondrial DNA toxicity in the forebrain. Neurobiol Aging. 2016;48:34-47 pubmed publisher
  52. D Andrea A, Gritti I, Nicoli P, Giorgio M, Doni M, Conti A, et al. The mitochondrial translation machinery as a therapeutic target in Myc-driven lymphomas. Oncotarget. 2016;7:72415-72430 pubmed publisher
  53. Cenini G, Rüb C, Bruderek M, Voos W. Amyloid ?-peptides interfere with mitochondrial preprotein import competence by a coaggregation process. Mol Biol Cell. 2016;27:3257-3272 pubmed
  54. Stroud D, Surgenor E, Formosa L, Reljic B, Frazier A, Dibley M, et al. Accessory subunits are integral for assembly and function of human mitochondrial complex I. Nature. 2016;538:123-126 pubmed publisher
  55. Jiang H, Kang S, Zhang S, Karuppagounder S, Xu J, Lee Y, et al. Adult Conditional Knockout of PGC-1? Leads to Loss of Dopamine Neurons. Eneuro. 2016;3: pubmed publisher
  56. Diokmetzidou A, Soumaka E, Kloukina I, Tsikitis M, Makridakis M, Varela A, et al. Desmin and ?B-crystallin interplay in the maintenance of mitochondrial homeostasis and cardiomyocyte survival. J Cell Sci. 2016;129:3705-3720 pubmed
  57. Kang Y, Baker M, Liem M, Louber J, McKenzie M, Atukorala I, et al. Tim29 is a novel subunit of the human TIM22 translocase and is involved in complex assembly and stability. elife. 2016;5: pubmed publisher
  58. El Sikhry H, Alsaleh N, Dakarapu R, Falck J, Seubert J. Novel Roles of Epoxyeicosanoids in Regulating Cardiac Mitochondria. PLoS ONE. 2016;11:e0160380 pubmed publisher
  59. McLelland G, Lee S, McBride H, Fon E. Syntaxin-17 delivers PINK1/parkin-dependent mitochondrial vesicles to the endolysosomal system. J Cell Biol. 2016;214:275-91 pubmed publisher
  60. Winter L, Wittig I, Peeva V, Eggers B, Heidler J, Chevessier F, et al. Mutant desmin substantially perturbs mitochondrial morphology, function and maintenance in skeletal muscle tissue. Acta Neuropathol. 2016;132:453-73 pubmed publisher
  61. Rohlenova K, Sachaphibulkij K, Stursa J, Bezawork Geleta A, Blecha J, Endaya B, et al. Selective Disruption of Respiratory Supercomplexes as a New Strategy to Suppress Her2high Breast Cancer. Antioxid Redox Signal. 2017;26:84-103 pubmed publisher
  62. Garaude J, Acin Perez R, Martínez Cano S, Enamorado M, Ugolini M, Nistal Villán E, et al. Mitochondrial respiratory-chain adaptations in macrophages contribute to antibacterial host defense. Nat Immunol. 2016;17:1037-1045 pubmed publisher
  63. Inoue T, Ikeda M, Ide T, Fujino T, Matsuo Y, Arai S, et al. Twinkle overexpression prevents cardiac rupture after myocardial infarction by alleviating impaired mitochondrial biogenesis. Am J Physiol Heart Circ Physiol. 2016;311:H509-19 pubmed publisher
  64. Richman T, Spahr H, Ermer J, Davies S, Viola H, Bates K, et al. Loss of the RNA-binding protein TACO1 causes late-onset mitochondrial dysfunction in mice. Nat Commun. 2016;7:11884 pubmed publisher
  65. Barry W, Thummel C. The Drosophila HNF4 nuclear receptor promotes glucose-stimulated insulin secretion and mitochondrial function in adults. elife. 2016;5: pubmed publisher
  66. Phillips J, Laude A, Lightowlers R, Morris C, Turnbull D, Lax N. Development of passive CLARITY and immunofluorescent labelling of multiple proteins in human cerebellum: understanding mechanisms of neurodegeneration in mitochondrial disease. Sci Rep. 2016;6:26013 pubmed publisher
  67. Seiferling D, Szczepanowska K, Becker C, Senft K, Hermans S, Maiti P, et al. Loss of CLPP alleviates mitochondrial cardiomyopathy without affecting the mammalian UPRmt. EMBO Rep. 2016;17:953-64 pubmed publisher
  68. Winter L, Türk M, Harter P, Mittelbronn M, Kornblum C, Norwood F, et al. Downstream effects of plectin mutations in epidermolysis bullosa simplex with muscular dystrophy. Acta Neuropathol Commun. 2016;4:44 pubmed publisher
  69. Kishimoto Y, Kishimoto A, Ye S, Kendziorski C, Welham N. Modeling fibrosis using fibroblasts isolated from scarred rat vocal folds. Lab Invest. 2016;96:807-16 pubmed publisher
  70. Casar Borota O, Øystese K, Sundstrom M, Melchior L, Popovic V. A high-throughput analysis of the IDH1(R132H) protein expression in pituitary adenomas. Pituitary. 2016;19:407-14 pubmed publisher
  71. Leucci E, Vendramin R, Spinazzi M, Laurette P, Fiers M, Wouters J, et al. Melanoma addiction to the long non-coding RNA SAMMSON. Nature. 2016;531:518-22 pubmed publisher
  72. Horton J, Martin O, Lai L, Riley N, Richards A, Vega R, et al. Mitochondrial protein hyperacetylation in the failing heart. JCI Insight. 2016;2: pubmed
  73. Carbognin E, Betto R, Soriano M, Smith A, Martello G. Stat3 promotes mitochondrial transcription and oxidative respiration during maintenance and induction of naive pluripotency. EMBO J. 2016;35:618-34 pubmed publisher
  74. Chang H, Wu R, Shang M, Sato T, Chen C, Shapiro J, et al. Reduction in mitochondrial iron alleviates cardiac damage during injury. EMBO Mol Med. 2016;8:247-67 pubmed publisher
  75. Merdzo I, Rutkai I, Tokés T, Sure V, Katakam P, Busija D. The mitochondrial function of the cerebral vasculature in insulin-resistant Zucker obese rats. Am J Physiol Heart Circ Physiol. 2016;310:H830-8 pubmed publisher
  76. Kovarova N, Pecina P, Nůsková H, Vrbacky M, Zeviani M, Mracek T, et al. Tissue- and species-specific differences in cytochrome c oxidase assembly induced by SURF1 defects. Biochim Biophys Acta. 2016;1862:705-715 pubmed publisher
  77. Wai T, García Prieto J, Baker M, Merkwirth C, Benit P, Rustin P, et al. Imbalanced OPA1 processing and mitochondrial fragmentation cause heart failure in mice. Science. 2015;350:aad0116 pubmed publisher
  78. Korwitz A, Merkwirth C, Richter Dennerlein R, Tröder S, Sprenger H, Quirós P, et al. Loss of OMA1 delays neurodegeneration by preventing stress-induced OPA1 processing in mitochondria. J Cell Biol. 2016;212:157-66 pubmed publisher
  79. Grünewald A, Rygiel K, Hepplewhite P, Morris C, Picard M, Turnbull D. Mitochondrial DNA Depletion in Respiratory Chain-Deficient Parkinson Disease Neurons. Ann Neurol. 2016;79:366-78 pubmed publisher
  80. Lesmana R, Sinha R, Singh B, Zhou J, Ohba K, Wu Y, et al. Thyroid Hormone Stimulation of Autophagy Is Essential for Mitochondrial Biogenesis and Activity in Skeletal Muscle. Endocrinology. 2016;157:23-38 pubmed publisher
  81. Hilse K, Kalinovich A, Rupprecht A, Smorodchenko A, Zeitz U, Staniek K, et al. The expression of UCP3 directly correlates to UCP1 abundance in brown adipose tissue. Biochim Biophys Acta. 2016;1857:72-78 pubmed publisher
  82. Loriot C, Domingues M, Berger A, Menara M, Ruel M, Morin A, et al. Deciphering the molecular basis of invasiveness in Sdhb-deficient cells. Oncotarget. 2015;6:32955-65 pubmed publisher
  83. Lee S, Kim J, Hong S, Lee A, Park E, Seo H, et al. High Inorganic Phosphate Intake Promotes Tumorigenesis at Early Stages in a Mouse Model of Lung Cancer. PLoS ONE. 2015;10:e0135582 pubmed publisher
  84. Rutkai I, Dutta S, Katakam P, Busija D. Dynamics of enhanced mitochondrial respiration in female compared with male rat cerebral arteries. Am J Physiol Heart Circ Physiol. 2015;309:H1490-500 pubmed publisher
  85. Liu K, Chuang S, Long C, Lee Y, Wang C, Lu M, et al. Ketamine-induced ulcerative cystitis and bladder apoptosis involve oxidative stress mediated by mitochondria and the endoplasmic reticulum. Am J Physiol Renal Physiol. 2015;309:F318-31 pubmed publisher
  86. Her Y, Nelson Holte M, MAHER L. Oxygen concentration controls epigenetic effects in models of familial paraganglioma. PLoS ONE. 2015;10:e0127471 pubmed publisher
  87. Nakayama T, Al Maawali A, El Quessny M, Rajab A, Khalil S, Stoler J, et al. Mutations in PYCR2, Encoding Pyrroline-5-Carboxylate Reductase 2, Cause Microcephaly and Hypomyelination. Am J Hum Genet. 2015;96:709-19 pubmed publisher
  88. Brandauer J, Andersen M, Kellezi H, Risis S, Frøsig C, Vienberg S, et al. AMP-activated protein kinase controls exercise training- and AICAR-induced increases in SIRT3 and MnSOD. Front Physiol. 2015;6:85 pubmed publisher
  89. Ikeda M, Ide T, Fujino T, Arai S, Saku K, Kakino T, et al. Overexpression of TFAM or twinkle increases mtDNA copy number and facilitates cardioprotection associated with limited mitochondrial oxidative stress. PLoS ONE. 2015;10:e0119687 pubmed publisher
  90. Schüll S, Günther S, Brodesser S, Seeger J, Tosetti B, Wiegmann K, et al. Cytochrome c oxidase deficiency accelerates mitochondrial apoptosis by activating ceramide synthase 6. Cell Death Dis. 2015;6:e1691 pubmed publisher
  91. Kettwig M, Schubach M, Zimmermann F, Klinge L, Mayr J, Biskup S, et al. From ventriculomegaly to severe muscular atrophy: expansion of the clinical spectrum related to mutations in AIFM1. Mitochondrion. 2015;21:12-8 pubmed publisher
  92. Zheng H, Fu J, Xue P, Zhao R, Dong J, Liu D, et al. CNC-bZIP protein Nrf1-dependent regulation of glucose-stimulated insulin secretion. Antioxid Redox Signal. 2015;22:819-31 pubmed publisher
  93. Sverdlov A, Elezaby A, Behring J, Bachschmid M, Luptak I, Tu V, et al. High fat, high sucrose diet causes cardiac mitochondrial dysfunction due in part to oxidative post-translational modification of mitochondrial complex II. J Mol Cell Cardiol. 2015;78:165-73 pubmed publisher
  94. Charan R, Johnson B, Zaganelli S, Nardozzi J, LaVoie M. Inhibition of apoptotic Bax translocation to the mitochondria is a central function of parkin. Cell Death Dis. 2014;5:e1313 pubmed publisher
  95. Chauss D, Basu S, Rajakaruna S, Ma Z, Gau V, Anastas S, et al. Differentiation state-specific mitochondrial dynamic regulatory networks are revealed by global transcriptional analysis of the developing chicken lens. G3 (Bethesda). 2014;4:1515-27 pubmed publisher
  96. Rupprecht A, Sittner D, Smorodchenko A, Hilse K, Goyn J, Moldzio R, et al. Uncoupling protein 2 and 4 expression pattern during stem cell differentiation provides new insight into their putative function. PLoS ONE. 2014;9:e88474 pubmed publisher
  97. Killinger B, Shah M, Moszczynska A. Co-administration of betulinic acid and methamphetamine causes toxicity to dopaminergic and serotonergic nerve terminals in the striatum of late adolescent rats. J Neurochem. 2014;128:764-75 pubmed publisher
  98. Castelblanco E, Santacana M, Valls J, De Cubas A, Cascon A, Robledo M, et al. Usefulness of negative and weak-diffuse pattern of SDHB immunostaining in assessment of SDH mutations in paragangliomas and pheochromocytomas. Endocr Pathol. 2013;24:199-205 pubmed publisher
  99. Rivera Torres J, Acin Perez R, Cabezas Sánchez P, Osorio F, Gonzalez Gomez C, Megias D, et al. Identification of mitochondrial dysfunction in Hutchinson-Gilford progeria syndrome through use of stable isotope labeling with amino acids in cell culture. J Proteomics. 2013;91:466-77 pubmed publisher
  100. Kovarova N, Mracek T, Nůsková H, Holzerová E, Vrbacky M, Pecina P, et al. High molecular weight forms of mammalian respiratory chain complex II. PLoS ONE. 2013;8:e71869 pubmed publisher
  101. Springer H, Schramm M, Taylor G, Howard J. Irgm1 (LRG-47), a regulator of cell-autonomous immunity, does not localize to mycobacterial or listerial phagosomes in IFN-?-induced mouse cells. J Immunol. 2013;191:1765-74 pubmed publisher
  102. Schlehe J, Journel M, Taylor K, Amodeo K, LaVoie M. The mitochondrial disease associated protein Ndufaf2 is dispensable for Complex-1 assembly but critical for the regulation of oxidative stress. Neurobiol Dis. 2013;58:57-67 pubmed publisher
  103. Wappler E, Institoris A, Dutta S, Katakam P, Busija D. Mitochondrial dynamics associated with oxygen-glucose deprivation in rat primary neuronal cultures. PLoS ONE. 2013;8:e63206 pubmed publisher
  104. Pantaleo M, Astolfi A, Urbini M, Nannini M, Paterini P, Indio V, et al. Analysis of all subunits, SDHA, SDHB, SDHC, SDHD, of the succinate dehydrogenase complex in KIT/PDGFRA wild-type GIST. Eur J Hum Genet. 2014;22:32-9 pubmed publisher
  105. Wan X, Gupta S, Zago M, Davidson M, Dousset P, Amoroso A, et al. Defects of mtDNA replication impaired mitochondrial biogenesis during Trypanosoma cruzi infection in human cardiomyocytes and chagasic patients: the role of Nrf1/2 and antioxidant response. J Am Heart Assoc. 2012;1:e003855 pubmed publisher
  106. Murad N, Cullen J, McKenzie M, Ryan M, Thorburn D, Gueven N, et al. Mitochondrial dysfunction in a novel form of autosomal recessive ataxia. Mitochondrion. 2013;13:235-45 pubmed publisher
  107. Zhang S, Liu X, Bawa Khalfe T, Lu L, Lyu Y, Liu L, et al. Identification of the molecular basis of doxorubicin-induced cardiotoxicity. Nat Med. 2012;18:1639-42 pubmed publisher
  108. Pircher H, Straganz G, Ehehalt D, Morrow G, Tanguay R, Jansen Durr P. Identification of human fumarylacetoacetate hydrolase domain-containing protein 1 (FAHD1) as a novel mitochondrial acylpyruvase. J Biol Chem. 2011;286:36500-8 pubmed publisher
  109. Lauritzen K, Cheng C, Wiksen H, Bergersen L, Klungland A. Mitochondrial DNA toxicity compromises mitochondrial dynamics and induces hippocampal antioxidant defenses. DNA Repair (Amst). 2011;10:639-53 pubmed publisher