This is a Validated Antibody Database (VAD) review about human MITF, based on 49 published articles (read how Labome selects the articles), using MITF antibody in all methods. It is aimed to help Labome visitors find the most suited MITF antibody. Please note the number of articles fluctuates since newly identified citations are added and citations for discontinued catalog numbers are removed regularly.
MITF synonym: CMM8; COMMAD; MI; WS2; WS2A; bHLHe32

Knockout validation
Abcam
mouse monoclonal (C5)
  • western blot knockout validation; human; 1:2000; loading ...; fig s1-1a
Abcam MITF antibody (Abcam, ab12039) was used in western blot knockout validation on human samples at 1:2000 (fig s1-1a). elife (2021) ncbi
Invitrogen
mouse monoclonal (D5)
  • western blot knockout validation; human; loading ...; fig 2b
Invitrogen MITF antibody (Thermo Fisher, MA5-14154) was used in western blot knockout validation on human samples (fig 2b). Oncogene (2021) ncbi
Abcam
mouse monoclonal (C5)
  • western blot; human; loading ...; fig 6a
Abcam MITF antibody (Abcam, ab12039) was used in western blot on human samples (fig 6a). Nat Commun (2021) ncbi
mouse monoclonal (D5)
  • immunohistochemistry; human; loading ...; fig 2a
Abcam MITF antibody (abcam, ab3201) was used in immunohistochemistry on human samples (fig 2a). Cell Stem Cell (2021) ncbi
domestic rabbit polyclonal
  • immunohistochemistry; rat; 1:100; loading ...; fig 4a
Abcam MITF antibody (Abcam, AB122982) was used in immunohistochemistry on rat samples at 1:100 (fig 4a). Exp Mol Med (2021) ncbi
mouse monoclonal (C5)
  • western blot knockout validation; human; 1:2000; loading ...; fig s1-1a
Abcam MITF antibody (Abcam, ab12039) was used in western blot knockout validation on human samples at 1:2000 (fig s1-1a). elife (2021) ncbi
mouse monoclonal (C5)
  • other; human; loading ...; fig 4c
Abcam MITF antibody (Abcam, ab12039) was used in other on human samples (fig 4c). PLoS ONE (2020) ncbi
domestic rabbit polyclonal
  • immunocytochemistry; mouse; 1:50; loading ...; fig 2f
Abcam MITF antibody (Santa, ab20663) was used in immunocytochemistry on mouse samples at 1:50 (fig 2f). EBioMedicine (2020) ncbi
mouse monoclonal (C5)
  • immunohistochemistry; mouse; 1:400; loading ...; fig s1e
Abcam MITF antibody (Abcam, ab12039) was used in immunohistochemistry on mouse samples at 1:400 (fig s1e). Nature (2020) ncbi
domestic rabbit polyclonal
  • western blot; human; loading ...; fig 4h
Abcam MITF antibody (Abcam, ab20663) was used in western blot on human samples (fig 4h). Aging (Albany NY) (2019) ncbi
domestic rabbit polyclonal
  • western blot; mouse; 1:1000; loading ...; fig 3b
Abcam MITF antibody (Abcam, ab20663) was used in western blot on mouse samples at 1:1000 (fig 3b). Mol Med Rep (2019) ncbi
domestic rabbit monoclonal (EPR9731)
  • western blot; human; 1:200; loading ...; fig 1a
Abcam MITF antibody (Abcam, ab140606) was used in western blot on human samples at 1:200 (fig 1a). Cell Mol Biol Lett (2019) ncbi
domestic rabbit polyclonal
  • immunocytochemistry; human; fig 3e
In order to characterize the differentiation of RPE cells, Abcam MITF antibody (Abcam, ab20663) was used in immunocytochemistry on human samples (fig 3e). Stem Cell Res Ther (2017) ncbi
mouse monoclonal (C5)
  • western blot; mouse; 1:1000; loading ...; fig sf10d
Abcam MITF antibody (Abcam, Ab12039) was used in western blot on mouse samples at 1:1000 (fig sf10d). J Clin Invest (2017) ncbi
domestic rabbit polyclonal
  • immunohistochemistry; human; 1:500; fig 2A
In order to establish an application to generate retinal pigmented epithelium from induced pluripotent stem cells, Abcam MITF antibody (Abcam, ab122982) was used in immunohistochemistry on human samples at 1:500 (fig 2A). PLoS ONE (2017) ncbi
domestic rabbit polyclonal
  • immunocytochemistry; mouse; 1:50; fig 4h
In order to develop a novel method for obtaining perivascular-resident macrophage-like melanocytes, pericytes, and endothelial cells primary cells to study the vestibular blood-labyrinth barrier, Abcam MITF antibody (Abcam, Ab20663) was used in immunocytochemistry on mouse samples at 1:50 (fig 4h). Hear Res (2017) ncbi
mouse monoclonal (C5)
  • western blot; human; fig 2a
In order to develop a patient-derived xenograft platform and use it to identify genes that contribute the cancer resistance of melanoma patients treated with BRAF inhibitors, Abcam MITF antibody (Abcam, ab12039) was used in western blot on human samples (fig 2a). Cell Rep (2016) ncbi
mouse monoclonal (D5)
  • immunohistochemistry; human; loading ...; fig 3c
In order to investigate metastatic melanoma through single-cell RNA-seq, Abcam MITF antibody (Abcam, ab3201) was used in immunohistochemistry on human samples (fig 3c). Science (2016) ncbi
mouse monoclonal (C5)
  • western blot; human; fig 2
In order to investigate regulation of the visual cycle genes Rdh5 and Rlbp1 in the retinal pigment epithelium by microphthalmia-associated transcription factor, Abcam MITF antibody (Abcam, 12039) was used in western blot on human samples (fig 2). Sci Rep (2016) ncbi
mouse monoclonal (C5)
  • western blot; pigs ; 1:1000; fig 5d
Abcam MITF antibody (Abcam, ab12039) was used in western blot on pigs samples at 1:1000 (fig 5d). Sci Rep (2015) ncbi
mouse monoclonal (C5)
  • western blot; mouse; 1:1000; fig 6
Abcam MITF antibody (Abcam, Ab12039) was used in western blot on mouse samples at 1:1000 (fig 6). PLoS ONE (2015) ncbi
mouse monoclonal (C5)
  • ChIP-Seq; human; fig 4
  • western blot; human; 1:1000; fig s7
Abcam MITF antibody (Abcam, ab12039) was used in ChIP-Seq on human samples (fig 4) and in western blot on human samples at 1:1000 (fig s7). Nat Commun (2015) ncbi
mouse monoclonal (C5)
  • western blot; human
In order to study the promotion of c-Myc degradation by BLM helicase and its effect on tumor initiation, Abcam MITF antibody (Abcam, ab12039) was used in western blot on human samples . J Cell Sci (2013) ncbi
Invitrogen
mouse monoclonal (D5)
  • western blot knockout validation; human; loading ...; fig 2b
Invitrogen MITF antibody (Thermo Fisher, MA5-14154) was used in western blot knockout validation on human samples (fig 2b). Oncogene (2021) ncbi
mouse monoclonal (D5)
  • western blot; mouse; 1:1000; loading ...; fig s1b
  • western blot; human; 1:1000; loading ...; fig s3a, s3b
Invitrogen MITF antibody (ThermoFisher Scientific, D5) was used in western blot on mouse samples at 1:1000 (fig s1b) and in western blot on human samples at 1:1000 (fig s3a, s3b). Transl Oncol (2019) ncbi
mouse monoclonal (D5)
  • immunocytochemistry; human; loading ...; fig 2a
In order to propose a method for deriving homogeneous retinal pigment epithelium populations using an adherent, monolayer system and defined xeno-free media and matrices, Invitrogen MITF antibody (Thermo Fisher, MS-772-PABX) was used in immunocytochemistry on human samples (fig 2a). Stem Cells Transl Med (2017) ncbi
mouse monoclonal (D5)
  • immunohistochemistry - paraffin section; human; loading ...; fig s8
In order to find that exposure of tumor cells to RAF/MEK inhibitors elicits a heterogeneous response in which some cells die, some arrest, and the remainder adapt to drug, Invitrogen MITF antibody (Thermo Scientific, MA5-14154) was used in immunohistochemistry - paraffin section on human samples (fig s8). Mol Syst Biol (2017) ncbi
mouse monoclonal (D5)
  • immunohistochemistry - paraffin section; human; 1:50
In order to describe an unusual case of a recurrent dural neoplasm, Invitrogen MITF antibody (Labvision, D5) was used in immunohistochemistry - paraffin section on human samples at 1:50. Hum Pathol (2015) ncbi
mouse monoclonal (D5)
  • western blot; human
In order to study the increased immunohistochemical expression of PRMT5 in malignant and metastatic melanoma and the pathological significance, Invitrogen MITF antibody (Thermo-Scientific, MS-772-PO) was used in western blot on human samples . PLoS ONE (2013) ncbi
mouse monoclonal (D5)
  • immunocytochemistry; mouse
  • western blot; mouse
In order to study the role of MITF in counteracting B-RAF-stimulated melanocyte and melanoma cell proliferation, Invitrogen MITF antibody (Neomarkers, D5) was used in immunocytochemistry on mouse samples and in western blot on mouse samples . J Cell Biol (2005) ncbi
Santa Cruz Biotechnology
mouse monoclonal (C5)
  • immunocytochemistry; human; loading ...; fig 1a
Santa Cruz Biotechnology MITF antibody (Santa Cruz Biotechnology, sc-56725) was used in immunocytochemistry on human samples (fig 1a). Mol Ther Methods Clin Dev (2021) ncbi
mouse monoclonal (C5)
  • chromatin immunoprecipitation; human; loading ...; fig 5e
  • immunocytochemistry; human; loading ...; fig 4g
  • western blot; human; loading ...; fig 4e
Santa Cruz Biotechnology MITF antibody (Santa Cruz, sc-56725) was used in chromatin immunoprecipitation on human samples (fig 5e), in immunocytochemistry on human samples (fig 4g) and in western blot on human samples (fig 4e). Mol Carcinog (2016) ncbi
mouse monoclonal (C5)
  • immunocytochemistry; mouse; 1:100; fig s1
In order to elucidate the relationship between MITF and c-Jun in melanoma, Santa Cruz Biotechnology MITF antibody (Santa Cruz, sc-56725) was used in immunocytochemistry on mouse samples at 1:100 (fig s1). Nat Commun (2015) ncbi
mouse monoclonal (4H205)
  • chromatin immunoprecipitation; human
  • immunocytochemistry; human; fig 2a
  • western blot; human; fig 2c
Santa Cruz Biotechnology MITF antibody (santa cruz, sc-71587) was used in chromatin immunoprecipitation on human samples , in immunocytochemistry on human samples (fig 2a) and in western blot on human samples (fig 2c). Nature (2015) ncbi
R&D Systems
domestic goat polyclonal
  • immunohistochemistry; mouse; 1:100; loading ...; fig 3a
R&D Systems MITF antibody (R&D Systems, AF5769) was used in immunohistochemistry on mouse samples at 1:100 (fig 3a). Cell Mol Life Sci (2021) ncbi
Cell Signaling Technology
domestic rabbit monoclonal (D5G7V)
  • western blot; mouse; 1:1000; loading ...; fig 5
Cell Signaling Technology MITF antibody (Cell Signaling, 12590) was used in western blot on mouse samples at 1:1000 (fig 5). J Immunother Cancer (2021) ncbi
domestic rabbit monoclonal (D5G7V)
  • western blot; mouse; 1:5000; loading ...; fig 1e
Cell Signaling Technology MITF antibody (Cell Signaling, 12590) was used in western blot on mouse samples at 1:5000 (fig 1e). Cancers (Basel) (2020) ncbi
domestic rabbit monoclonal (D5G7V)
  • western blot; mouse; loading ...; fig 3d
Cell Signaling Technology MITF antibody (Cell Signaling, 12590) was used in western blot on mouse samples (fig 3d). Science (2019) ncbi
domestic rabbit monoclonal (D5G7V)
  • western blot; human; 1:1000; loading ...; fig 2
Cell Signaling Technology MITF antibody (Cell Signaling Technology, 12590) was used in western blot on human samples at 1:1000 (fig 2). Oncotarget (2016) ncbi
domestic rabbit monoclonal (D5G7V)
  • western blot; human; 1:1000; fig 5
Cell Signaling Technology MITF antibody (Cell Signaling, 12590) was used in western blot on human samples at 1:1000 (fig 5). PLoS ONE (2016) ncbi
domestic rabbit monoclonal (D5G7V)
  • western blot; human; 1:1000; loading ...; fig 2d
Cell Signaling Technology MITF antibody (Cell Signaling, 12590) was used in western blot on human samples at 1:1000 (fig 2d). elife (2016) ncbi
domestic rabbit monoclonal (D5G7V)
  • western blot; human; fig 3e
Cell Signaling Technology MITF antibody (Cell Signaling, 12590) was used in western blot on human samples (fig 3e). Nat Genet (2016) ncbi
domestic rabbit monoclonal (D5G7V)
  • western blot; human; 1:2000; fig 4
Cell Signaling Technology MITF antibody (Cell Signaling, 12590) was used in western blot on human samples at 1:2000 (fig 4). Oncotarget (2016) ncbi
domestic rabbit monoclonal (D5G7V)
  • western blot; human; 1:1000; fig 3c
Cell Signaling Technology MITF antibody (Cell Signaling, 12590) was used in western blot on human samples at 1:1000 (fig 3c). PLoS ONE (2015) ncbi
Dako
mouse monoclonal (D5)
  • immunohistochemistry - frozen section; human; 1:100; loading ...; fig s4f
Dako MITF antibody (DAKO, M3621) was used in immunohistochemistry - frozen section on human samples at 1:100 (fig s4f). Int J Mol Sci (2020) ncbi
mouse monoclonal (D5)
  • immunohistochemistry; human; 1:100; loading ...; fig 3b
In order to present the Cell and Tissue Display (CTD) method for embedding 16 or more different tissue samples in multi-compartment agarose blocks, Dako MITF antibody (Dako, M362129-2) was used in immunohistochemistry on human samples at 1:100 (fig 3b). J Histochem Cytochem (2016) ncbi
mouse monoclonal (D5)
  • immunohistochemistry - paraffin section; human; fig st1
  • western blot; human; fig 3
Dako MITF antibody (Dako, M3621) was used in immunohistochemistry - paraffin section on human samples (fig st1) and in western blot on human samples (fig 3). Nature (2016) ncbi
mouse monoclonal (D5)
  • western blot; human
In order to investigate the role of CITED1 in melanoma, Dako MITF antibody (Dako, M3621) was used in western blot on human samples . Peerj (2015) ncbi
mouse monoclonal (D5)
  • immunohistochemistry - paraffin section; human; 1:100
Dako MITF antibody (Dako, M3621) was used in immunohistochemistry - paraffin section on human samples at 1:100. Dev Neurobiol (2015) ncbi
Exalpha Biologicals
monoclonal (C5)
  • immunohistochemistry; human; 1:500; loading ...; fig 4a
Exalpha Biologicals MITF antibody (Exalpha Biologicals, X1405M) was used in immunohistochemistry on human samples at 1:500 (fig 4a). elife (2019) ncbi
Cell Marque
monoclonal (C5/D5)
  • immunohistochemistry - paraffin section; human; loading ...; fig 5a
Cell Marque MITF antibody (Cell Marque, 284M-96) was used in immunohistochemistry - paraffin section on human samples (fig 5a). Cell (2019) ncbi
Articles Reviewed
  1. Kaucka M, Szarowska B, Kavkova M, Kastriti M, Kameneva P, Schmidt I, et al. Nerve-associated Schwann cell precursors contribute extracutaneous melanocytes to the heart, inner ear, supraorbital locations and brain meninges. Cell Mol Life Sci. 2021;78:6033-6049 pubmed publisher
  2. Hamm M, Sohier P, Petit V, Raymond J, Delmas V, Le Coz M, et al. BRN2 is a non-canonical melanoma tumor-suppressor. Nat Commun. 2021;12:3707 pubmed publisher
  3. Eriksen A, Møller R, Makovoz B, Uhl S, tenOever B, Blenkinsop T. SARS-CoV-2 infects human adult donor eyes and hESC-derived ocular epithelium. Cell Stem Cell. 2021;28:1205-1220.e7 pubmed publisher
  4. Yang J, Chung S, Yun K, Kim B, So S, Kang S, et al. Long-term effects of human induced pluripotent stem cell-derived retinal cell transplantation in Pde6b knockout rats. Exp Mol Med. 2021;53:631-642 pubmed publisher
  5. Salas A, Duarri A, Fontrodona L, Ram xed rez D, Badia A, Isla Magran xe9 H, et al. Cell therapy with hiPSC-derived RPE cells and RPCs prevents visual function loss in a rat model of retinal degeneration. Mol Ther Methods Clin Dev. 2021;20:688-702 pubmed publisher
  6. Can xe8 S, Van Snick J, Uyttenhove C, Pilotte L, van den Eynde B. TGFβ1 neutralization displays therapeutic efficacy through both an immunomodulatory and a non-immune tumor-intrinsic mechanism. J Immunother Cancer. 2021;9: pubmed publisher
  7. Dilshat R, Fock V, Kenny C, Gerritsen I, Lasseur R, Travnickova J, et al. MITF reprograms the extracellular matrix and focal adhesion in melanoma. elife. 2021;10: pubmed publisher
  8. Zarei M, Giannikou K, Du H, Liu H, Duarte M, Johnson S, et al. MITF is a driver oncogene and potential therapeutic target in kidney angiomyolipoma tumors through transcriptional regulation of CYR61. Oncogene. 2021;40:112-126 pubmed publisher
  9. Martínez Vicente I, Abrisqueta M, Herraiz C, Sires Campos J, Castejón Griñán M, Bennett D, et al. Mahogunin Ring Finger 1 Is Required for Genomic Stability and Modulates the Malignant Phenotype of Melanoma Cells. Cancers (Basel). 2020;12: pubmed publisher
  10. Ballesteros Álvarez J, Dilshat R, Fock V, Möller K, Karl L, Larue L, et al. MITF and TFEB cross-regulation in melanoma cells. PLoS ONE. 2020;15:e0238546 pubmed publisher
  11. Garita Hernandez M, Routet F, Guibbal L, Khabou H, Toualbi L, Riancho L, et al. AAV-Mediated Gene Delivery to 3D Retinal Organoids Derived from Human Induced Pluripotent Stem Cells. Int J Mol Sci. 2020;21: pubmed publisher
  12. Chen F, Liu X, Chen Y, Liu J, Lu H, Wang W, et al. Sphere-induced reprogramming of RPE cells into dual-potential RPE stem-like cells. EBioMedicine. 2020;52:102618 pubmed publisher
  13. Zhang B, Ma S, Rachmin I, He M, Baral P, Choi S, et al. Hyperactivation of sympathetic nerves drives depletion of melanocyte stem cells. Nature. 2020;577:676-681 pubmed publisher
  14. Tang L, Li J, Fu W, Wu W, Xu J. Suppression of FADS1 induces ROS generation, cell cycle arrest, and apoptosis in melanocytes: implications for vitiligo. Aging (Albany NY). 2019;11:11829-11843 pubmed publisher
  15. 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
  16. Achberger K, Probst C, Haderspeck J, Bolz S, Rogal J, Chuchuy J, et al. Merging organoid and organ-on-a-chip technology to generate complex multi-layer tissue models in a human retina-on-a-chip platform. elife. 2019;8: pubmed publisher
  17. Qi S, Liu B, Zhang J, Liu X, Dong C, Fan R. Knockdown of microRNA‑143‑5p by STTM technology affects eumelanin and pheomelanin production in melanocytes. Mol Med Rep. 2019;20:2649-2656 pubmed publisher
  18. Pan H, Alamri A, Valapala M. Nutrient deprivation and lysosomal stress induce activation of TFEB in retinal pigment epithelial cells. Cell Mol Biol Lett. 2019;24:33 pubmed publisher
  19. He M, Chaurushiya M, Webster J, Kummerfeld S, Reja R, Chaudhuri S, et al. Intrinsic apoptosis shapes the tumor spectrum linked to inactivation of the deubiquitinase BAP1. Science. 2019;364:283-285 pubmed publisher
  20. Wiedemann G, Aithal C, Kraechan A, Heise C, Cadilha B, Zhang J, et al. Microphthalmia-Associated Transcription Factor (MITF) Regulates Immune Cell Migration into Melanoma. Transl Oncol. 2019;12:350-360 pubmed publisher
  21. Hazim R, Karumbayaram S, Jiang M, Dimashkie A, Lopes V, Li D, et al. Differentiation of RPE cells from integration-free iPS cells and their cell biological characterization. Stem Cell Res Ther. 2017;8:217 pubmed publisher
  22. Olvedy M, Tisserand J, Luciani F, Boeckx B, Wouters J, Lopez S, et al. Comparative oncogenomics identifies tyrosine kinase FES as a tumor suppressor in melanoma. J Clin Invest. 2017;127:2310-2325 pubmed publisher
  23. Geng Z, Walsh P, Truong V, Hill C, Ebeling M, Kapphahn R, et al. Generation of retinal pigmented epithelium from iPSCs derived from the conjunctiva of donors with and without age related macular degeneration. PLoS ONE. 2017;12:e0173575 pubmed publisher
  24. Choudhary P, Booth H, Gutteridge A, Surmacz B, Louca I, Steer J, et al. Directing Differentiation of Pluripotent Stem Cells Toward Retinal Pigment Epithelium Lineage. Stem Cells Transl Med. 2017;6:490-501 pubmed publisher
  25. Zhang J, Chen S, Cai J, Hou Z, Wang X, Kachelmeier A, et al. Culture media-based selection of endothelial cells, pericytes, and perivascular-resident macrophage-like melanocytes from the young mouse vestibular system. Hear Res. 2017;345:10-22 pubmed publisher
  26. Fallahi Sichani M, Becker V, Izar B, Baker G, Lin J, Boswell S, et al. Adaptive resistance of melanoma cells to RAF inhibition via reversible induction of a slowly dividing de-differentiated state. Mol Syst Biol. 2017;13:905 pubmed publisher
  27. Alver T, Lavelle T, Longva A, Øy G, Hovig E, Bøe S. MITF depletion elevates expression levels of ERBB3 receptor and its cognate ligand NRG1-beta in melanoma. Oncotarget. 2016;7:55128-55140 pubmed publisher
  28. Talar B, Gajos Michniewicz A, Talar M, Chouaib S, Czyz M. Pentoxifylline Inhibits WNT Signalling in ?-Cateninhigh Patient-Derived Melanoma Cell Populations. PLoS ONE. 2016;11:e0158275 pubmed publisher
  29. Kemper K, Krijgsman O, Kong X, Cornelissen Steijger P, Shahrabi A, Weeber F, et al. BRAF(V600E) Kinase Domain Duplication Identified in Therapy-Refractory Melanoma Patient-Derived Xenografts. Cell Rep. 2016;16:263-277 pubmed publisher
  30. Theodosakis N, Micevic G, Bosenberg M, Rodic N. Cell and Tissue Display: An Alternative Multipurpose Tool for Microscopy. J Histochem Cytochem. 2016;64:403-11 pubmed publisher
  31. Tirosh I, Izar B, Prakadan S, Wadsworth M, Treacy D, Trombetta J, et al. Dissecting the multicellular ecosystem of metastatic melanoma by single-cell RNA-seq. Science. 2016;352:189-96 pubmed publisher
  32. Natale C, Duperret E, Zhang J, Sadeghi R, Dahal A, O Brien K, et al. Sex steroids regulate skin pigmentation through nonclassical membrane-bound receptors. elife. 2016;5: pubmed publisher
  33. Moore A, Ceraudo E, Sher J, Guan Y, Shoushtari A, Chang M, et al. Recurrent activating mutations of G-protein-coupled receptor CYSLTR2 in uveal melanoma. Nat Genet. 2016;48:675-80 pubmed publisher
  34. Kaur A, Webster M, Marchbank K, Behera R, Ndoye A, Kugel C, et al. sFRP2 in the aged microenvironment drives melanoma metastasis and therapy resistance. Nature. 2016;532:250-4 pubmed publisher
  35. Seip K, Fleten K, Barkovskaya A, Nygaard V, Haugen M, Engesæter B, et al. Fibroblast-induced switching to the mesenchymal-like phenotype and PI3K/mTOR signaling protects melanoma cells from BRAF inhibitors. Oncotarget. 2016;7:19997-20015 pubmed publisher
  36. Wen B, Li S, Li H, Chen Y, Ma X, Wang J, et al. Microphthalmia-associated transcription factor regulates the visual cycle genes Rlbp1 and Rdh5 in the retinal pigment epithelium. Sci Rep. 2016;6:21208 pubmed publisher
  37. De Luca T, Pelosi A, Trisciuoglio D, D Aguanno S, Desideri M, Farini V, et al. miR-211 and MITF modulation by Bcl-2 protein in melanoma cells. Mol Carcinog. 2016;55:2304-2312 pubmed publisher
  38. Riesenberg S, Groetchen A, Siddaway R, Bald T, Reinhardt J, Smorra D, et al. MITF and c-Jun antagonism interconnects melanoma dedifferentiation with pro-inflammatory cytokine responsiveness and myeloid cell recruitment. Nat Commun. 2015;6:8755 pubmed publisher
  39. Wang X, Zhou J, Cao C, Huang J, Hai T, Wang Y, et al. Efficient CRISPR/Cas9-mediated biallelic gene disruption and site-specific knockin after rapid selection of highly active sgRNAs in pigs. Sci Rep. 2015;5:13348 pubmed publisher
  40. Perera R, Stoykova S, Nicolay B, Ross K, Fitamant J, Boukhali M, et al. Transcriptional control of autophagy-lysosome function drives pancreatic cancer metabolism. Nature. 2015;524:361-5 pubmed publisher
  41. Miracco C, Toscano M, Butorano M, Baldino G, Tacchini D, Barone A, et al. Unusual clear cell, lymphoplasmacyte-rich, dural-based tumor with divergent differentiation: a tricky case mimicking a meningioma. Hum Pathol. 2015;46:1050-6 pubmed publisher
  42. Stemig M, Astelford K, Emery A, Cho J, Allen B, Huang T, et al. Deletion of histone deacetylase 7 in osteoclasts decreases bone mass in mice by interactions with MITF. PLoS ONE. 2015;10:e0123843 pubmed publisher
  43. Verfaillie A, Imrichová H, Atak Z, Dewaele M, Rambow F, Hulselmans G, et al. Decoding the regulatory landscape of melanoma reveals TEADS as regulators of the invasive cell state. Nat Commun. 2015;6:6683 pubmed publisher
  44. Arts N, Cané S, Hennequart M, Lamy J, Bommer G, Van den Eynde B, et al. microRNA-155, induced by interleukin-1ß, represses the expression of microphthalmia-associated transcription factor (MITF-M) in melanoma cells. PLoS ONE. 2015;10:e0122517 pubmed publisher
  45. Howlin J, Cirenajwis H, Lettiero B, Staaf J, Lauss M, Saal L, et al. Loss of CITED1, an MITF regulator, drives a phenotype switch in vitro and can predict clinical outcome in primary melanoma tumours. Peerj. 2015;3:e788 pubmed publisher
  46. Locher H, de Groot J, van Iperen L, Huisman M, Frijns J, Chuva de Sousa Lopes S. Development of the stria vascularis and potassium regulation in the human fetal cochlea: Insights into hereditary sensorineural hearing loss. Dev Neurobiol. 2015;75:1219-40 pubmed publisher
  47. Nicholas C, Yang J, Peters S, Bill M, Baiocchi R, Yan F, et al. PRMT5 is upregulated in malignant and metastatic melanoma and regulates expression of MITF and p27(Kip1.). PLoS ONE. 2013;8:e74710 pubmed publisher
  48. Chandra S, Priyadarshini R, Madhavan V, Tikoo S, Hussain M, Mudgal R, et al. Enhancement of c-Myc degradation by BLM helicase leads to delayed tumor initiation. J Cell Sci. 2013;126:3782-95 pubmed publisher
  49. Wellbrock C, Marais R. Elevated expression of MITF counteracts B-RAF-stimulated melanocyte and melanoma cell proliferation. J Cell Biol. 2005;170:703-8 pubmed