Tuj 1, Neuron-specific class III beta-tubulin or Tubulin beta 4 Antibody

Product Details

Catalog Number: MO15013

Applications: ICC, WB, IHC, IF

Type: Mouse IgG

Immunogen: Microtubules derived from rat brain

Storage: Store at 4°C short term. Aliquot and store at -20°C long term. Avoid freeze-thaw cycles.

Shipping: Frozen (Polar Packs)

Format A: Protein G Purified

Format B: liquid

Species Reactivity: Human

Entrez: 10381

UniProt: Q13509

Downloads: Datasheet (pdf)

Product Sizes

Size	List Price	Price	Cart
100 ug		$289.00	Add to Cart

Human β-Tubulin 3 is a 50,432 dalton structural protein (450 amino acid) expressed in neurons of the PNS and CNS. It contributes to microtubule stability in neuronal cell bodies and axons, and plays a role in axonal transport.

Product Reviews
Excellent product, quick shipping! Product Name: Tuj1, Mouse – (Cat# MO15013) https://www.neuromics.com/MO15013 Organization: University of Stanford
Alexa - Jan 31, 2018 - Rating: 5.0
First order from neuromics and everything went without any issue. Product Name: Tuj 1, Mouse – (Cat# MO15013) http://bit.ly/1Qx4ASc Organization: Stanford University
Tian TianW - May 01, 2016 - Rating: 5.0
Staining (Tuj1) worked well on human neural progenitor cells. Product Name: Tuj 1, Mouse – (Cat# MO15013-100) http://bit.ly/1Qx4ASc Organization: UCONN
Stephen Crocker - Nov 19, 2015 - Rating: 5.0
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Product Publications

Cristina Martínez‐Ramos, Laura Rodríguez Doblado, Eric López Mocholi, Ana Alastrue‐Agudo, Marina Sánchez Petidier, Esther Giraldo, Manuel Monleón Pradas, Victoria Moreno‐Manzano (2019). Biohybrids for spinal cord injury repair. Journal of Tissue Engineering and Regenerative Medicine. https://doi.org/10.1002/term.2816
Ana Artero Castro, Kathleen Long, Andrew Bassett, Candela Machuca Arellano, Marian León, Almudena Ávila-Fernandeze , Marta Cortón, Toni Vidal-Puig, Carmen Ayuso, Dunja Lukovic, Slaven Erceg. (2018). Generation of gene-corrected human induced pluripotent stem cell lines derived from retinitis pigmentosa patient with Ser331Cysfs*5 mutation in MERTK. Stem Cell Research. https://doi.org/10.1016/j.scr.2018.11.003
Patrick Lüningschrör, Beyenech Binotti, Benjamin Dombert, Peter Heimann, Angel Perez-Lara, Carsten Slotta, Nadine Thau-Habermann, Cora R. von Collenberg, Franziska Karl, Markus Damme, Arie Horowitz, Isabelle Maystadt8, Annette Füchtbauer, Ernst-Martin Füchtbauer, Sibylle Jablonka, Robert Blum, Nurcan Üçeyler, Susanne Petri, Barbara Kaltschmidt, Reinhard Jahn, Christian Kaltschmidt2 & Michael Sendtner. (2018). Plekhg5-regulated autophagy of synaptic vesicles reveals a pathogenic mechanism in motoneuron disease. Nature Communications. DOI: 10.1038/s41467-017-00689-z
C. Machuca Arellano, A. Vilches, E. Clemente, S.I. Pascual-Pascual, A. Bolinches-Amoros, A. Artera Castro, C. Espinos, M.L. Rodriguez, P. Jendelova, S. Erceg. (2018). Generation of a Human iPSC Line From a Patient With Autosomal Recessive Spastic Ataxia of Charlevoix-Saguenay (ARSACS) Caused By Mutation in SACSIN Gene. Stem Cell Research. Doi: 10/1016/j.scr.2018.07.012
Qianqian Yang, Gaoying Sun, Haiyan Yin, Hongrui Li, Zhixin Cao, Jinghan Wang, Jeijuan Zhou, Haibo Wang, Jianfeng Li. (2018) PINK1 Protects Auditory Hair Cells and Spiral Ganglion Neurons from Cisplatin-induced Ototoxicity via Inducing Autophagy and Inhibiting JNK Signaling Pathway. Free Radical Biology and Medicine. https://doi.org/10.1016/j.freeradbiomed.2018.02.025
Jackelien van Scheppingen, James D. Mills, Till S. Zimmer, Diede W.M. Broekaart, Valentina Iori, Anika Bongaarts, Jasper J. Anink, Anand M. Iyer, Anatoly Korotkov, Floor E. Jansen, Wim van Hecke, Wim G. Spliet, Peter C. van Rijen,
Johannes C. Baayen, Annamaria Vezzani, Erwin A. van Vliet, Eleonora Aronica. (2018). miR147b: A novel key regulator of interleukin 1 beta-mediated inflammation in human astrocytes. Glia. 2018;00:1–16. https://doi.org/10.1002/glia.23302
Jintao Du, Xianren Wang, Xiaobo Zhang, Xuemei Zhang, and Hongyan Jiang. DNER modulates the length, polarity and synaptogenesis of spiral ganglion neurons via the Notch signaling pathway. Molecular Medicine Reports. DOI: 10.3892/mmr.2017.8115
Ola Awad, Leelamma M. Panicker, Rania M. Deranieh, Manasa P. Srikanth, Robert A. Brown, Antanina Voit, Tejasvi Peesay, Tea Soon Park, Elias T. Zambidis, and Ricardo A. Feldman. (2017). Altered Differentiation Potential of Gaucher’s Disease iPSC Neuronal Progenitors due to Wnt/b-Catenin Downregulation. Stem Cell Reports doi: 10.1016/j.stemcr.2017.10.029
D. Soscia, A. Belle, N. Fischer, H. Enright, A. Sales, J. Osburn, W. Benett, E. Mukerjee, K. Kulp, S. Pannu, and E. Wheeler. (2017). Controlled placement of multiple CNS cell populations to create complex neuronal cultures. PLoS ONE 12 (11): 0188146. https://doi.org/10.1371/journal.pone.0188146
Patrick Lüningschrör, Beyenech Binotti, Benjamin Dombert, Peter Heimann, Angel Perez-Lara, Carsten Slotta, Nadine Thau-Habermann, Cora R. von Collenberg, Franziska Karl, Markus Damme, Arie Horowitz, Isabelle Maystadt, Annette Füchtbauer, Ernst-Martin Füchtbauer, Sibylle Jablonka, Robert Blum, Nurcan Üçeyler, Susanne Petri, Barbara Kaltschmidt, Reinhard Jahn, Christian Kaltschmidt & Michael Sendtner. (2017) Plekhg5-regulated autophagy of synaptic vesicles reveals a pathogenic mechanism in motoneuron disease. Nature Communications. doi:10.1038/s41467-017-00689-z
Jintao Du Xuemei Zhang, Hui Cao, Di Jiang, Xianren Wang, Wei Zhou, Kaitian Chen, Jiao Zhou, Hongyan Jiang, Luo Ba. (2017). MiR-194 is involved in morphogenesis of spiral ganglion neurons in inner ear by rearranging actin cytoskeleton via targeting RhoB. International Journal of Developmental Neuroscience. doi: 10.1016/j.ijdevneu.2017.09.004
Di Jiang, Jintao Du, Xuemei Zhang, Wei Zhou, Lin Zong, Chang Dong, Kaitian Chen, Yu Chen, Xihui Chen, and Hongyan Jiang. (2016). miR-124 promotes the neuronal differentiation of mouse inner ear neural stem cells. International Journal of Molecular Medicine, Volume 38 Issue 5. doi: 10.3892/ijmm.2016.2751
Thomas V. Johnson; Ericka N. Oglesby; Matthew R. Steinhart; Elizabeth Cone-Kimball; Joan Jefferys; Harry A. Quigley. (2016). Time-Lapse Retinal Ganglion Cell Dendritic Field Degeneration Imaged in Organotypic Retinal Explant Culture. Investigative Ophthalmology & Visual Science, Vol.57, 253-264. doi: 10.1167/iovs.15-17769
Loïc Binan, Charlène Tendey, Gregory De Crescenzo, Rouwayda El Ayoubi, Abdellah Ajji, Mario Jolicoeur. (2013). Differentiation of neuronal stem cells into motor neurons using electrospun poly-l-lactic acid/gelatin scaffold Biomaterials. Biomaterials, doi: 10.1016/j.biomaterials.2013.09.097
Dirk Puehringer, Nadiya Orel, Patrick Lüningschrör, Narayan Subramanian, Thomas Herrmann, Moses V Chao & Michael Sendtner. (2013). EGF transactivation of Trk receptors regulates the migration of newborn cortical neurons. Nature Neuroscience 16, 407–415 (2013) doi: 10.1038/nn.3333
Leanne M. Ramer, A. Peter van Stolk, Jessica A. Inskip, Matt S. Ramer and Andrei V. Krassioukov. (2012). Plasticity of TRPV1-expressing sensory neurons mediating autonomic dysreflexia following spinal cord injury. Front. Physiol., doi: 10.3389/fphys.2012.00257
A. Young, D.W. Machacek, S.K. Dhara, P.R. MacLeish, M. Benveniste, M.C. Dodla, C.D. Sturkie and S.L. Stice. (2011). Ion channels and ionotrophic receptors in a human embryonic stem cell derived neural progenitors. Neuroscience, doi: 10.1016/j.neuroscience.2011.04.039
C. Bettina Portmann-Lanz PhD, Andreina Schoeberlein PhD, Reto Portmann PhD, Stefan Mohr MD, Pierre Rollini PhD, Ruth Sager and Daniel V. Surbek MD. (2010). Turning placenta into brain: placental mesenchymal stem cells differentiate into neurons and oligodendrocytes. American Journal of Obstetrics and Gynecology, doi: 10.1016/j.ajog.2009.10.893
Alonso M. Higuero, Lucía Sánchez-Ruiloba, Laura E. Doglio, Francisco Portillo, José Abad- Rodríguez, Carlos G. Dotti and Teresa Iglesias. (2009). Kidins220/ARMS modulates the activity of microtubule-regulating proteins and controls neuronal polarity and development. Journal of Biological Chemistry, doi: 10.1074/jbc.M109.024703
Vidya Murthy, Stéphane F. Maison, Julián Taranda, Nadeem Haque, Chris T. Bond, A. Belén Elgoyhen, John P. Adelman, M. Charles Liberman, Douglas E. Vetter. (2009). SK2 channels are required for function and long-term survival of efferent synapses on mammalian outer hair cells. Molecular and Cellular Neuroscience, 40, 39–49. doi: 10.1016/j.mcn.2008.08.011
Sujoy K. Dhara, Kowser Hasneen, David W. Machacek, Nolan L. Boyd, Raj R. Rao, Steven L. Stice. (2008). Human neural progenitor cells derived from embryonic stem cells in feeder-free cultures. Differentiation, 76 (5), 454–464. doi: 10.1111/j.1432-0436.2007.00256.x

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A2B5	MO15016	100 ug
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AP-2 Alpha	RA18023	100 ul
ATPase Na+/K+ transporting alpha 1	MO25023	50 ul
Brg1	GT15244	100 ug
CD4	MO20025	100 ul
Doublecortin/DCX	MO22113	100 ul
Frizzled 4/CD344	GT15217	100 ug
GAP43	MO22118	100 ul
GAP43	MO22170	100 µl
GAP43	RA25086	100 ul
GAP43 (IgG)	MO22171	100 µl
Jagged1	GT15171	100 ug
Laminin	RA25038	100 ul
Laminin 111	RA22121	100 ul
Mash1	GT15216	100 ug
Mash1	MO15048	100 ug
MSX1/HOX7	GT41015	100 ug
Musashi-1	GT15116	100 ug
Musashi-1	MO15049	100 ug
Musashi-1	RA14128	50 ul
Nestin	CH23001	100 ul
Nestin	GT15114	100 ug
Nestin	MO15012	100 ug
Nestin	MO15056	100 ug
Nestin	MO22183	100 ug
Nestin	RA22125	100 ul
Netrin-1	CH23002	100 ul
Netrin-4	GT15164	100 ug
Neuritin	GT15022	100 ug
NeuroD1	GT15231	100 ug
Neurofilament alpha-internexin/NF66	CH22101	100 ul
Neurofilament alpha-internexin/NF66	MO25017	500 ul
Neurofilament alpha-internexin/NF66	RA22102	100 ul
Notch1	RA19069	100 ul
Notch2	GT15124	100 ug
Notch3	RA19070	100 ug
Nucleostemin	GT15050	100 ug
Otx2	GT15095	100 ug
Otx2	MO15039	100 ug
PAX3	GT41025	100 ug
S100B	GT15160	100 ug
Semaphorin 3C	GT15077	100 ug
Semaphorin 6a	GT15056	100 ug
Semaphorin 6a	MO15023	100 ug
Semaphorin 6a	MO15023	50 ug
Semaphorin 6a	MO15023	500 ug
Semaphorin 6B	GT15165	100 ug
Semaphorin 7A	GT15076	50 ug
Semaphorin 7A	MO15041	100 ug
Semaphorin 7A	MO15041	50 ug
Semaphorin 7A	MO15041	500 ug
SOX2	GT15098	100 ug.
SOX2	MO15040	100 ug
SOX2	RA25021	100 ul
TROY/TNFRSF19	GT15223	100 ug
TROY/TNFRSF19, Biotinylated	GT15332B	50 ug
Tuj 1 (Neuron-specific class III beta-tubulin)	CH23005	100 ul
Vimentin	CH22108	100 ul
Vimentin	CH23010	100 ul
Vimentin	GT22103	100 ul

Images

Tuj-1 staining of Neuron-specific class III β-tubulin in differentiated human neural progenitor cells. Cells were stained using goat anti-mouse Alexa Fluor 488 (green) secondary antibody (Molecular Probe, A-11001) and counterstained with PI (red).

Neural progenitors were labeled with anti-rat Nestin polyclonal antibody (Cat#:GT15114) and stained with conjugated donkey anti-goat secondary anti-body (green). Differentiated neurons were labeled with neuron-specific mouse anti-β-III tubulin/ Tuj1-(Cat#MO15013 monoclonal antibody (red). Nuclei were stained with DAPI (blue)

Neural progenitors were labeled with anti-rat Nestin polyclonal antibody (Cat#:GT15114) and Differentiated neurons were labeled with neuron-specific mouse anti-β-III tubulin/ Tuj1-(Cat#MO15013 monoclonal antibody (red)

Immunostaining of hNP1 Progenitors before and after differentiation. The culture was highly homogenous with neural rosettes. Differentiation (2007) DOI: 10.1111/j.1432-0436.2007.00256.x...Dilutions: NES (1:100, Neuromics, Edina, MN), MSI1 (1:100, Neuromics), Tuj1 (1:500, Neuromics)...

Immunostaining of hNP1 Progenitors before and after differentiation. The culture was highly homogenous with neural rosettes.

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