This is a Validated Antibody Database (VAD) review about cow TUBB3, based on 168 published articles (read how Labome selects the articles), using TUBB3 antibody in all methods. It is aimed to help Labome visitors find the most suited TUBB3 antibody. Please note the number of articles fluctuates since newly identified citations are added and citations for discontinued catalog numbers are removed regularly.
TUBB3 synonym: TUBB4; tubulin beta-3 chain; tubulin, beta, 3; tubulin, beta, 4

Abcam
mouse monoclonal (2G10)
  • immunocytochemistry; human; fig s5b
Abcam TUBB3 antibody (Abcam, ab78078) was used in immunocytochemistry on human samples (fig s5b). Cell (2018) ncbi
mouse monoclonal (TU-20)
  • immunocytochemistry; rat; 1:100; loading ...; tbl 1
In order to compare the efficiency of fascaplysin with other drugs used to treat glial tumors, Abcam TUBB3 antibody (Abcam, ab7751) was used in immunocytochemistry on rat samples at 1:100 (tbl 1). Oncol Lett (2017) ncbi
mouse monoclonal (2G10)
  • immunocytochemistry; mouse; 1:400; loading ...; fig 7a
In order to analyze the effects of dopamine related metabolite concentrations in M1 and M2 microglia phenotypes, Abcam TUBB3 antibody (Abcam, ab78078) was used in immunocytochemistry on mouse samples at 1:400 (fig 7a). Front Cell Neurosci (2017) ncbi
mouse monoclonal (2G10)
  • immunohistochemistry; mouse; loading ...; fig 3A
In order to assess the role of P2X7 in neurodegenerative amyotrophic lateral sclerosis disease progression, Abcam TUBB3 antibody (Abcam, ab78078) was used in immunohistochemistry on mouse samples (fig 3A). Peerj (2017) ncbi
mouse monoclonal (TU-20)
  • immunohistochemistry - paraffin section; rat; 1:200; loading ...; fig st15
In order to outline the protocols for antibodies used for immunohistochemical studies, Abcam TUBB3 antibody (Abcam, ab7751) was used in immunohistochemistry - paraffin section on rat samples at 1:200 (fig st15). J Toxicol Pathol (2017) ncbi
mouse monoclonal (2G10)
  • immunohistochemistry - paraffin section; mouse; 1:250; loading ...; fig 6j
Abcam TUBB3 antibody (Abcam, ab78078) was used in immunohistochemistry - paraffin section on mouse samples at 1:250 (fig 6j). Ann Neurol (2017) ncbi
mouse monoclonal (2G10)
  • western blot; rat; 1:100; loading ...
In order to develop methods to study vesicle-associated proteins and exocytosis in stellate astrocytes, Abcam TUBB3 antibody (Abcam, ab78078) was used in western blot on rat samples at 1:100. J Gen Physiol (2017) ncbi
mouse monoclonal (2G10)
  • western blot; human; loading ...; fig 9c
Abcam TUBB3 antibody (Abcam, ab78078) was used in western blot on human samples (fig 9c). Oncotarget (2016) ncbi
mouse monoclonal (TU-20)
  • immunocytochemistry; rat; 1:100; loading ...
In order to study the use of hematopoietic stem cells to treat glioblastoma, Abcam TUBB3 antibody (Abcam, 7751) was used in immunocytochemistry on rat samples at 1:100. Mol Med Rep (2016) ncbi
mouse monoclonal (TU-20)
  • western blot; human; fig 3a
Abcam TUBB3 antibody (Abcam, ab7751) was used in western blot on human samples (fig 3a). Mol Brain (2016) ncbi
mouse monoclonal (TU-20)
  • immunocytochemistry; rat; 1:100; fig 1
In order to clarify the interaction between microglial cells and cancer stem cells, Abcam TUBB3 antibody (Abcam, 7751) was used in immunocytochemistry on rat samples at 1:100 (fig 1). Oncol Lett (2016) ncbi
mouse monoclonal (TU-20)
  • immunocytochemistry; mouse; 1:500; fig 1
Abcam TUBB3 antibody (Abcam, ab7751) was used in immunocytochemistry on mouse samples at 1:500 (fig 1). J Neuroinflammation (2016) ncbi
mouse monoclonal (TU-20)
  • immunohistochemistry - frozen section; mouse; loading ...; fig 4f
Abcam TUBB3 antibody (Abcam, TU-20) was used in immunohistochemistry - frozen section on mouse samples (fig 4f). J Virol (2016) ncbi
mouse monoclonal (TU-20)
  • immunocytochemistry; rat; 1:1000; fig 2
  • western blot; rat; fig s5
In order to elucidate an increase of apoptosis and disruption of cytoskeleton organization of rat neural crest stem cells via upregulating CXCR4 expression and RhoA-ROCK1-p38 MAPK-p53 signaling due to simulated microgravity, Abcam TUBB3 antibody (Abcam, TU-20) was used in immunocytochemistry on rat samples at 1:1000 (fig 2) and in western blot on rat samples (fig s5). Stem Cells Dev (2016) ncbi
mouse monoclonal (TU-20)
  • immunocytochemistry; mouse; 1:500; fig 7
Abcam TUBB3 antibody (Abcam, ab7751) was used in immunocytochemistry on mouse samples at 1:500 (fig 7). Nat Commun (2016) ncbi
mouse monoclonal (2G10)
  • immunohistochemistry; human; 1:500; fig 7a
Abcam TUBB3 antibody (Abcam, ab78078) was used in immunohistochemistry on human samples at 1:500 (fig 7a). Biol Open (2016) ncbi
mouse monoclonal (TU-20)
  • immunocytochemistry; human; 1:200
Abcam TUBB3 antibody (Abcam, AB7751) was used in immunocytochemistry on human samples at 1:200. PLoS ONE (2014) ncbi
mouse monoclonal (TU-20)
  • western blot; mouse; 1:200
Abcam TUBB3 antibody (Abcam, ab7751) was used in western blot on mouse samples at 1:200. Mol Neurobiol (2014) ncbi
mouse monoclonal (TU-20)
  • immunocytochemistry; rat; 1:1000
Abcam TUBB3 antibody (Abcam, ab7751) was used in immunocytochemistry on rat samples at 1:1000. Neurochem Int (2013) ncbi
mouse monoclonal (TU-20)
  • immunohistochemistry; human; 1:1000
Abcam TUBB3 antibody (Abcam, ab7751) was used in immunohistochemistry on human samples at 1:1000. Stem Cells Dev (2013) ncbi
Invitrogen
mouse monoclonal (2G10)
  • immunohistochemistry - frozen section; rabbit; 1:100; loading ...; fig 4e
In order to evaluate the efficacy of subconjunctival delivery of TNF-alpha antibodies using a polymer-based drug delivery system, Invitrogen TUBB3 antibody (Thermo Scientific, MA1118) was used in immunohistochemistry - frozen section on rabbit samples at 1:100 (fig 4e). Invest Ophthalmol Vis Sci (2017) ncbi
mouse monoclonal (2G10-TB3)
  • immunohistochemistry; mouse; 1:250; fig 2d
In order to identify genes in endothelial cells activated following interactions with neurons during vascular development, Invitrogen TUBB3 antibody (eBioscience, 50-4510) was used in immunohistochemistry on mouse samples at 1:250 (fig 2d). J Cell Sci (2017) ncbi
mouse monoclonal (TU-20)
  • western blot; human; 1:2000; fig 9
In order to test if progerin elicits spatiotemporal deviations in mitotic processes in Hutchinson-Gilford progeria syndrome fibroblasts, Invitrogen TUBB3 antibody (Thermo Fisher, MA1-19187) was used in western blot on human samples at 1:2000 (fig 9). Oncotarget (2016) ncbi
mouse monoclonal (2G10)
  • immunocytochemistry; human; 1:100; fig 5e
In order to study the differentiation of oral mucosa stromal cells into neural crest stem cells and assess their therapeutic value, Invitrogen TUBB3 antibody (eBioscience, 2G10) was used in immunocytochemistry on human samples at 1:100 (fig 5e). Stem Cells Transl Med (2016) ncbi
Novus Biologicals
mouse monoclonal (SDL.3D10)
  • western blot; human; 1:5000; loading ...; fig 3b
Novus Biologicals TUBB3 antibody (Novus, NB120-11314) was used in western blot on human samples at 1:5000 (fig 3b). Acta Neuropathol (2017) ncbi
Bio-Rad
mouse monoclonal (TU-20)
  • immunocytochemistry; human; fig 7
In order to examine how the elasticity of the matrix affects the pluripotency of hPSCs, Bio-Rad TUBB3 antibody (AbD Serotec, MCA2047) was used in immunocytochemistry on human samples (fig 7). Sci Rep (2015) ncbi
mouse monoclonal (TU-20)
  • immunocytochemistry; rat; 1:500; fig 2a
Bio-Rad TUBB3 antibody (AbD Serotec, MCA2047) was used in immunocytochemistry on rat samples at 1:500 (fig 2a). J Neurosci Res (2015) ncbi
Santa Cruz Biotechnology
mouse monoclonal (2G10)
  • immunocytochemistry; rat; 1:1000
Santa Cruz Biotechnology TUBB3 antibody (Santa Cruz Biotechnology, sc-80005) was used in immunocytochemistry on rat samples at 1:1000. Oxid Med Cell Longev (2014) ncbi
mouse monoclonal (2G10)
  • immunocytochemistry; rat; 1:550
Santa Cruz Biotechnology TUBB3 antibody (Santa Cruz, sc-80005) was used in immunocytochemistry on rat samples at 1:550. Cell Mol Neurobiol (2014) ncbi
Sigma-Aldrich
mouse monoclonal (SDL.3D10)
  • immunocytochemistry; human; 1:200; loading ...; fig s2
Sigma-Aldrich TUBB3 antibody (Sigma-Aldrich, T8660) was used in immunocytochemistry on human samples at 1:200 (fig s2). PLoS Pathog (2018) ncbi
mouse monoclonal (SDL.3D10)
  • immunocytochemistry; human; 1:300; loading ...; fig s4c
Sigma-Aldrich TUBB3 antibody (Sigma, T8660) was used in immunocytochemistry on human samples at 1:300 (fig s4c). Nat Neurosci (2018) ncbi
mouse monoclonal (SDL.3D10)
  • immunocytochemistry; human; 1:1000; loading ...; fig 3b
Sigma-Aldrich TUBB3 antibody (Sigma, T8660) was used in immunocytochemistry on human samples at 1:1000 (fig 3b). Stem Cell Res (2018) ncbi
mouse monoclonal (SDL.3D10)
  • immunocytochemistry; human; 1:500; fig 6e
Sigma-Aldrich TUBB3 antibody (Sigma-Aldrich, T8660) was used in immunocytochemistry on human samples at 1:500 (fig 6e). Cell (2018) ncbi
mouse monoclonal (SDL.3D10)
  • immunohistochemistry - paraffin section; mouse; loading ...; fig 4b
Sigma-Aldrich TUBB3 antibody (Sigma, T8660) was used in immunohistochemistry - paraffin section on mouse samples (fig 4b). J Neurosci (2017) ncbi
mouse monoclonal (SDL.3D10)
  • immunocytochemistry; human; 1:1000; loading ...; tbl 1
In order to generate an induced pluripotent stem cell line from an essential thrombocythemia patient with a heterozygous MPL V501L mutation, Sigma-Aldrich TUBB3 antibody (Sigma, T8660) was used in immunocytochemistry on human samples at 1:1000 (tbl 1). Stem Cell Res (2017) ncbi
mouse monoclonal (SDL.3D10)
  • immunocytochemistry; mouse; 1:1000; loading ...; fig 3d
Sigma-Aldrich TUBB3 antibody (Sigma-Aldrich, T8660) was used in immunocytochemistry on mouse samples at 1:1000 (fig 3d). Stem Cell Reports (2017) ncbi
mouse monoclonal (SDL.3D10)
  • immunocytochemistry; human; loading ...; fig 5e
Sigma-Aldrich TUBB3 antibody (Sigma-Aldrich, T8660) was used in immunocytochemistry on human samples (fig 5e). Stem Cell Res (2017) ncbi
mouse monoclonal (SDL.3D10)
  • immunocytochemistry; human; loading ...; fig 3b
In order to evaluate the role of ROCK kinases in the regulation of cell migration, growth and differentiation of Ewing sarcoma cells, Sigma-Aldrich TUBB3 antibody (Sigma, T5076) was used in immunocytochemistry on human samples (fig 3b). Oncol Rep (2017) ncbi
mouse monoclonal (SDL.3D10)
  • immunocytochemistry; mouse; 1:1000; loading ...; fig 1a
  • western blot; mouse; 1:2000; loading ...; fig 6a
In order to elucidate how nuclear editing of substrates contributes to neuronal function and brain development, Sigma-Aldrich TUBB3 antibody (Sigma, SDL.3D10) was used in immunocytochemistry on mouse samples at 1:1000 (fig 1a) and in western blot on mouse samples at 1:2000 (fig 6a). J Cell Sci (2017) ncbi
mouse monoclonal (SDL.3D10)
  • immunocytochemistry; human; 1:300; loading ...; fig s1h
In order to show that a degenerative phenotype exhibiting mutant pendrin aggregates and increased susceptibility to cellular stresses in cochlear epithelial cells induced from patient-derived induced pluripotent stem cells, Sigma-Aldrich TUBB3 antibody (Sigma, T8660) was used in immunocytochemistry on human samples at 1:300 (fig s1h). Cell Rep (2017) ncbi
mouse monoclonal (SDL.3D10)
  • western blot; mouse; 1:1000; loading ...; fig 1a
In order to clarify the role of m-AAA protease in adult glial cells, Sigma-Aldrich TUBB3 antibody (Sigma, T8660) was used in western blot on mouse samples at 1:1000 (fig 1a). PLoS Genet (2016) ncbi
mouse monoclonal (SDL.3D10)
  • immunohistochemistry; mouse; 1:1000; loading ...; tbl 1
In order to report the relationship between pre-tumor cells and their surrounding stroma in cerebellar tumor medulloblastoma, Sigma-Aldrich TUBB3 antibody (Sigma, T8660) was used in immunohistochemistry on mouse samples at 1:1000 (tbl 1). elife (2016) ncbi
mouse monoclonal (SDL.3D10)
  • immunocytochemistry; mouse; 1:3000; loading ...; fig 4a
In order to assess the differentiation potential of hippocampal neural stem cells, Sigma-Aldrich TUBB3 antibody (Sigma, T5076) was used in immunocytochemistry on mouse samples at 1:3000 (fig 4a). Mol Med Rep (2016) ncbi
mouse monoclonal (SDL.3D10)
  • immunohistochemistry - frozen section; African green monkey; 1:250; fig 4
Sigma-Aldrich TUBB3 antibody (Sigma, T8660) was used in immunohistochemistry - frozen section on African green monkey samples at 1:250 (fig 4). Biomed Res Int (2016) ncbi
mouse monoclonal (SDL.3D10)
  • immunocytochemistry; human; 1:2000; loading ...
In order to test if Morpholino-modified antisense oligonucleotide alter SMN2 splicing, Sigma-Aldrich TUBB3 antibody (Sigma, T8660) was used in immunocytochemistry on human samples at 1:2000. Mol Ther (2016) ncbi
mouse monoclonal (SDL.3D10)
  • immunocytochemistry; mouse; 1:500; loading ...; fig 3a
  • western blot; mouse; 1:500; loading ...; fig 3b
In order to investigate the contribution of YAP in mouse neocortical astrocytic differentiation and proliferation, Sigma-Aldrich TUBB3 antibody (Sigma, T8660) was used in immunocytochemistry on mouse samples at 1:500 (fig 3a) and in western blot on mouse samples at 1:500 (fig 3b). Development (2016) ncbi
mouse monoclonal (SDL.3D10)
  • immunocytochemistry; human; 1:4000; loading ...; tbl 2
Sigma-Aldrich TUBB3 antibody (Sigma, T8660) was used in immunocytochemistry on human samples at 1:4000 (tbl 2). Stem Cell Res (2016) ncbi
mouse monoclonal (SDL.3D10)
  • immunocytochemistry; human; 1:4000; fig 1e
Sigma-Aldrich TUBB3 antibody (Sigma-Aldrich, T8660) was used in immunocytochemistry on human samples at 1:4000 (fig 1e). Stem Cell Res (2016) ncbi
mouse monoclonal (SDL.3D10)
  • immunohistochemistry - paraffin section; mouse; fig 3
In order to learn of the restriction in brain cell types and possible connection to autism by alphaT-catenin, Sigma-Aldrich TUBB3 antibody (Sigma, T8660) was used in immunohistochemistry - paraffin section on mouse samples (fig 3). J Mol Psychiatry (2016) ncbi
mouse monoclonal (SDL.3D10)
  • immunohistochemistry - paraffin section; dog; 1:1000; fig 2
Sigma-Aldrich TUBB3 antibody (Sigma, T8660) was used in immunohistochemistry - paraffin section on dog samples at 1:1000 (fig 2). Brain Behav (2016) ncbi
mouse monoclonal (SDL.3D10)
  • immunocytochemistry; human; 1:1000; fig 1
  • western blot; human; fig 5
Sigma-Aldrich TUBB3 antibody (Sigma, T8660) was used in immunocytochemistry on human samples at 1:1000 (fig 1) and in western blot on human samples (fig 5). PLoS ONE (2016) ncbi
mouse monoclonal (SDL.3D10)
  • immunocytochemistry; mouse; 1:1000; loading ...; fig s8a
In order to use naked mole-rat-induced pluripotent stem cells to study mechanisms of cancer resistance, Sigma-Aldrich TUBB3 antibody (Sigma Aldrich, T8660) was used in immunocytochemistry on mouse samples at 1:1000 (fig s8a). Nat Commun (2016) ncbi
mouse monoclonal (SDL.3D10)
  • immunocytochemistry; human; 1:500; fig 6f
Sigma-Aldrich TUBB3 antibody (Sigma-Aldrich, T8660) was used in immunocytochemistry on human samples at 1:500 (fig 6f). Mol Med Rep (2016) ncbi
mouse monoclonal (SDL.3D10)
  • immunohistochemistry - frozen section; white-tufted-ear marmoset; 1:250; fig 1
In order to research functional compensation by overlapping expression of anion exchangers in the cochlea of a non-human primate, Sigma-Aldrich TUBB3 antibody (Sigma, T8660) was used in immunohistochemistry - frozen section on white-tufted-ear marmoset samples at 1:250 (fig 1). Neurosci Res (2016) ncbi
mouse monoclonal (SDL.3D10)
  • immunocytochemistry; mouse; 1:400; fig 1a
Sigma-Aldrich TUBB3 antibody (Sigma-Aldrich,, T8660) was used in immunocytochemistry on mouse samples at 1:400 (fig 1a). BMC Biol (2016) ncbi
mouse monoclonal (SDL.3D10)
  • immunohistochemistry; human; 1:400; fig 3b
In order to present a xeno-free cryopreservation protocol for single human pluripotent stem cells, Sigma-Aldrich TUBB3 antibody (Sigma, T8660) was used in immunohistochemistry on human samples at 1:400 (fig 3b). Methods Mol Biol (2016) ncbi
mouse monoclonal (SDL.3D10)
  • western blot; mouse; fig 1
In order to elucidate induction of glutamatergic subtype markers in their descendant neurons by P2Y4 nucleotide receptor in neuronal precursors, Sigma-Aldrich TUBB3 antibody (Sigma, T5076) was used in western blot on mouse samples (fig 1). Stem Cell Reports (2016) ncbi
mouse monoclonal (SDL.3D10)
  • immunohistochemistry; African green monkey; 1:250; fig 1i
In order to compare the expression of deafness genes in mice and the common marmoset, Sigma-Aldrich TUBB3 antibody (Sigma-Aldrich, T8660) was used in immunohistochemistry on African green monkey samples at 1:250 (fig 1i). Sci Rep (2016) ncbi
mouse monoclonal (SDL.3D10)
  • immunohistochemistry; rat; 1:400; loading ...; fig 7h
In order to use electroconducting microfibers to synergistically stimulate the proliferation and migration of glial progenitor cells, Sigma-Aldrich TUBB3 antibody (Sigma, T8660) was used in immunohistochemistry on rat samples at 1:400 (fig 7h). Acta Biomater (2016) ncbi
mouse monoclonal (SDL.3D10)
  • immunocytochemistry; human; 1:1000; fig 1
Sigma-Aldrich TUBB3 antibody (Sigma, T8660) was used in immunocytochemistry on human samples at 1:1000 (fig 1). Basic Res Cardiol (2016) ncbi
mouse monoclonal (SDL.3D10)
  • immunocytochemistry; human; 1:200; tbl 1
In order to study of normal human retina and macromolecular markers and applications to human retinal disease, Sigma-Aldrich TUBB3 antibody (Sigma, T8660) was used in immunocytochemistry on human samples at 1:200 (tbl 1). Exp Eye Res (2016) ncbi
mouse monoclonal (SDL.3D10)
  • immunohistochemistry; mouse; 1:800; fig 1
  • western blot; mouse; 1:800; fig 6
In order to report that Caspr regulates the temporal specification of cell fate in radial glial cells of the developing cerebral cortex through Notch signaling, Sigma-Aldrich TUBB3 antibody (Sigma-Aldrich, T5076) was used in immunohistochemistry on mouse samples at 1:800 (fig 1) and in western blot on mouse samples at 1:800 (fig 6). Cereb Cortex (2017) ncbi
mouse monoclonal (SDL.3D10)
  • immunohistochemistry - frozen section; mouse; 1:300; fig 1
Sigma-Aldrich TUBB3 antibody (Sigma, T8660) was used in immunohistochemistry - frozen section on mouse samples at 1:300 (fig 1). Stem Cell Reports (2016) ncbi
mouse monoclonal (SDL.3D10)
  • immunocytochemistry; human; 1:3000; fig s2
In order to research the role of increased alpha-synuclein due to SNCA gene triplication and its role in Parkinson stem cells, Sigma-Aldrich TUBB3 antibody (Sigma, T8660) was used in immunocytochemistry on human samples at 1:3000 (fig s2). Cell Death Dis (2015) ncbi
mouse monoclonal (SDL.3D10)
  • immunohistochemistry; giant panda; 1:100; fig 3
Sigma-Aldrich TUBB3 antibody (Sigma, T8660) was used in immunohistochemistry on giant panda samples at 1:100 (fig 3). PLoS ONE (2015) ncbi
mouse monoclonal (SDL.3D10)
  • immunohistochemistry; mouse
Sigma-Aldrich TUBB3 antibody (Sigma, T5076) was used in immunohistochemistry on mouse samples . Cell Rep (2015) ncbi
mouse monoclonal (SDL.3D10)
  • immunocytochemistry; rat; 1:200
Sigma-Aldrich TUBB3 antibody (Sigma, T-8660) was used in immunocytochemistry on rat samples at 1:200. Cell J (2015) ncbi
mouse monoclonal (SDL.3D10)
  • immunohistochemistry - paraffin section; mouse; 1:400; fig 4
Sigma-Aldrich TUBB3 antibody (Sigma, T5076) was used in immunohistochemistry - paraffin section on mouse samples at 1:400 (fig 4). PLoS ONE (2015) ncbi
mouse monoclonal (SDL.3D10)
  • immunocytochemistry; human
Sigma-Aldrich TUBB3 antibody (Sigma, T8660) was used in immunocytochemistry on human samples . Biomaterials (2015) ncbi
mouse monoclonal (SDL.3D10)
  • immunocytochemistry; mouse; 1:400; loading ...; tbl 1
In order to report a protocol that reliably directs the differentiation of induced pluripotent stem cells to oligodendrocyte progenitor cells that are capable of maturing into oligodendrocytes, Sigma-Aldrich TUBB3 antibody (Sigma, T8660) was used in immunocytochemistry on mouse samples at 1:400 (tbl 1). Cell Transplant (2016) ncbi
mouse monoclonal (SDL.3D10)
  • immunohistochemistry - frozen section; mouse; 1:800; fig s8
Sigma-Aldrich TUBB3 antibody (Sigma, T5076) was used in immunohistochemistry - frozen section on mouse samples at 1:800 (fig s8). Nat Med (2015) ncbi
mouse monoclonal (SDL.3D10)
  • immunocytochemistry; mouse; 1:200; loading ...; fig 1h
Sigma-Aldrich TUBB3 antibody (Sigma, T8660) was used in immunocytochemistry on mouse samples at 1:200 (fig 1h). PLoS ONE (2015) ncbi
mouse monoclonal (SDL.3D10)
  • immunocytochemistry; white-tufted-ear marmoset; 1:400; fig 3
  • immunohistochemistry; white-tufted-ear marmoset; 1:600; fig 3
Sigma-Aldrich TUBB3 antibody (Sigma, T8660) was used in immunocytochemistry on white-tufted-ear marmoset samples at 1:400 (fig 3) and in immunohistochemistry on white-tufted-ear marmoset samples at 1:600 (fig 3). PLoS ONE (2015) ncbi
mouse monoclonal (SDL.3D10)
  • immunocytochemistry; human; 1:1000; fig s6
  • western blot; human; 1:1000
Sigma-Aldrich TUBB3 antibody (Sigma, T8660) was used in immunocytochemistry on human samples at 1:1000 (fig s6) and in western blot on human samples at 1:1000. BMC Genomics (2015) ncbi
mouse monoclonal (SDL.3D10)
  • immunocytochemistry; human
Sigma-Aldrich TUBB3 antibody (Sigma, T8660) was used in immunocytochemistry on human samples . Methods Mol Biol (2016) ncbi
mouse monoclonal (SDL.3D10)
  • immunohistochemistry; Styela plicata; 1:100
  • western blot; Styela plicata; 1:2500
Sigma-Aldrich TUBB3 antibody (Sigma, T5076) was used in immunohistochemistry on Styela plicata samples at 1:100 and in western blot on Styela plicata samples at 1:2500. Dev Neurobiol (2015) ncbi
mouse monoclonal (SDL.3D10)
  • western blot; mouse; 1:1000; fig s3
In order to investigate the mechanisms underlying the specification of branch location, Sigma-Aldrich TUBB3 antibody (Sigma, T8660) was used in western blot on mouse samples at 1:1000 (fig s3). Nat Cell Biol (2014) ncbi
mouse monoclonal (SDL.3D10)
  • immunocytochemistry; rat; 1:1000; fig S2
In order to show that fibroblast growth factors and bone morphogenetic proteins contribute to astrocyte development, Sigma-Aldrich TUBB3 antibody (Sigma, T8660) was used in immunocytochemistry on rat samples at 1:1000 (fig S2). PLoS ONE (2014) ncbi
mouse monoclonal (SDL.3D10)
  • immunohistochemistry - frozen section; mouse; 1:500; fig 1b
In order to study the initiation and regulation of radial migration, Sigma-Aldrich TUBB3 antibody (Sigma, T8660) was used in immunohistochemistry - frozen section on mouse samples at 1:500 (fig 1b). Nat Commun (2014) ncbi
mouse monoclonal (SDL.3D10)
  • immunocytochemistry; human; 1:5000
Sigma-Aldrich TUBB3 antibody (Sigma, T8660) was used in immunocytochemistry on human samples at 1:5000. Transl Psychiatry (2014) ncbi
mouse monoclonal (SDL.3D10)
  • immunohistochemistry; mouse; 1:500; fig 1
In order to elucidate the regulatory mechanisms by which Msi1 is selectively expressed in neural stem/progenitor cells, Sigma-Aldrich TUBB3 antibody (Sigma, T8660) was used in immunohistochemistry on mouse samples at 1:500 (fig 1). Stem Cells Dev (2014) ncbi
mouse monoclonal (SDL.3D10)
  • western blot; rat; 1:20000
Sigma-Aldrich TUBB3 antibody (Sigma, T8660) was used in western blot on rat samples at 1:20000. J Neurosci (2014) ncbi
mouse monoclonal (SDL.3D10)
  • immunocytochemistry; human; 1:400
Sigma-Aldrich TUBB3 antibody (Sigma, T8660) was used in immunocytochemistry on human samples at 1:400. J Vis Exp (2014) ncbi
mouse monoclonal (SDL.3D10)
  • immunocytochemistry; human; 1:400
In order to use a multiplex high-throughput gene expression assay to detect endogenous expression of multiple developmental, functional, and disease markers in iPS cell-derived retinal pigment epithelium, Sigma-Aldrich TUBB3 antibody (Sigma-Aldrich, T8660) was used in immunocytochemistry on human samples at 1:400. Stem Cells Transl Med (2014) ncbi
mouse monoclonal (SDL.3D10)
  • immunocytochemistry; mouse; 1:400; loading ...; fig 4c
Sigma-Aldrich TUBB3 antibody (Sigma, T8660) was used in immunocytochemistry on mouse samples at 1:400 (fig 4c). Mol Neurobiol (2015) ncbi
mouse monoclonal (SDL.3D10)
  • immunocytochemistry; human; 1:1000
Sigma-Aldrich TUBB3 antibody (Sigma, T8660) was used in immunocytochemistry on human samples at 1:1000. J Comp Neurol (2014) ncbi
mouse monoclonal (SDL.3D10)
  • immunocytochemistry; human; 1:500
Sigma-Aldrich TUBB3 antibody (Sigma, T8660) was used in immunocytochemistry on human samples at 1:500. J Neurosci Methods (2014) ncbi
mouse monoclonal (SDL.3D10)
  • immunohistochemistry; mouse; 1:1000
Sigma-Aldrich TUBB3 antibody (Sigma, T8660) was used in immunohistochemistry on mouse samples at 1:1000. Stem Cells Dev (2014) ncbi
mouse monoclonal (SDL.3D10)
  • immunocytochemistry; dog
Sigma-Aldrich TUBB3 antibody (Sigma, T8660) was used in immunocytochemistry on dog samples . Methods Mol Biol (2013) ncbi
mouse monoclonal (SDL.3D10)
  • immunohistochemistry - paraffin section; mouse; 1:200
Sigma-Aldrich TUBB3 antibody (Sigma, SDL.3D10) was used in immunohistochemistry - paraffin section on mouse samples at 1:200. J Comp Neurol (2013) ncbi
mouse monoclonal (SDL.3D10)
  • western blot; human
Sigma-Aldrich TUBB3 antibody (Sigma, T8660) was used in western blot on human samples . Am J Physiol Renal Physiol (2013) ncbi
mouse monoclonal (SDL.3D10)
  • immunocytochemistry; human; 1:1000
Sigma-Aldrich TUBB3 antibody (Sigma, T8660) was used in immunocytochemistry on human samples at 1:1000. Cytotherapy (2013) ncbi
mouse monoclonal (SDL.3D10)
  • immunohistochemistry; human; 1:1000
In order to study a cellular model of Dravet syndrome, Sigma-Aldrich TUBB3 antibody (Sigma-Aldrich, T8660) was used in immunohistochemistry on human samples at 1:1000. Mol Brain (2013) ncbi
mouse monoclonal (SDL.3D10)
  • immunocytochemistry; mouse
Sigma-Aldrich TUBB3 antibody (Sigma, T8660) was used in immunocytochemistry on mouse samples . EMBO J (2013) ncbi
mouse monoclonal (SDL.3D10)
  • immunocytochemistry; human
  • immunohistochemistry; human
Sigma-Aldrich TUBB3 antibody (Sigma, T8660) was used in immunocytochemistry on human samples and in immunohistochemistry on human samples . Acta Neurobiol Exp (Wars) (2013) ncbi
mouse monoclonal (SDL.3D10)
  • immunocytochemistry; human; 1:1,000
Sigma-Aldrich TUBB3 antibody (Sigma, T8660) was used in immunocytochemistry on human samples at 1:1,000. Stem Cells Transl Med (2012) ncbi
mouse monoclonal (SDL.3D10)
  • immunohistochemistry; African green monkey; 1:200
Sigma-Aldrich TUBB3 antibody (Sigma, T8660) was used in immunohistochemistry on African green monkey samples at 1:200. J Comp Neurol (2011) ncbi
mouse monoclonal (SDL.3D10)
  • immunohistochemistry - frozen section; mouse; 1:250
In order to investigate the neurnal migration during development of the olfactory nerve, Sigma-Aldrich TUBB3 antibody (Sigma, T8660) was used in immunohistochemistry - frozen section on mouse samples at 1:250. J Comp Neurol (2010) ncbi
mouse monoclonal (SDL.3D10)
  • immunocytochemistry; human; 1:1000
Sigma-Aldrich TUBB3 antibody (Sigma, T8660) was used in immunocytochemistry on human samples at 1:1000. J Comp Neurol (2009) ncbi
mouse monoclonal (SDL.3D10)
  • immunohistochemistry; rat; 1:200
  • western blot; rat; 1:200
Sigma-Aldrich TUBB3 antibody (Sigma, T8660) was used in immunohistochemistry on rat samples at 1:200 and in western blot on rat samples at 1:200. J Comp Neurol (2009) ncbi
mouse monoclonal (SDL.3D10)
  • immunohistochemistry; mouse; 1:6000
Sigma-Aldrich TUBB3 antibody (Sigma, T8660) was used in immunohistochemistry on mouse samples at 1:6000. J Comp Neurol (2009) ncbi
mouse monoclonal (SDL.3D10)
  • immunohistochemistry - paraffin section; mouse; 1:500
Sigma-Aldrich TUBB3 antibody (Sigma, T8660) was used in immunohistochemistry - paraffin section on mouse samples at 1:500. J Comp Neurol (2009) ncbi
mouse monoclonal (SDL.3D10)
  • immunohistochemistry; rat; 1:200
Sigma-Aldrich TUBB3 antibody (Sigma-Aldrich, T8660) was used in immunohistochemistry on rat samples at 1:200. J Comp Neurol (2007) ncbi
EMD Millipore
mouse monoclonal (TU-20)
  • western blot; mouse; loading ...; fig 1e
EMD Millipore TUBB3 antibody (Millipore, MAB1637) was used in western blot on mouse samples (fig 1e). Cell Rep (2018) ncbi
mouse monoclonal (TU-20)
  • immunocytochemistry; human; loading ...; fig s1k
EMD Millipore TUBB3 antibody (EMD Millipore, MAB1637) was used in immunocytochemistry on human samples (fig s1k). Nat Med (2018) ncbi
mouse monoclonal (TU-20)
  • western blot; rat; 1:1000; loading ...; fig 3a
In order to study the impact of diet and stress on adult rat behavior and hippocampal plasticity, EMD Millipore TUBB3 antibody (Millipore, MAB1637) was used in western blot on rat samples at 1:1000 (fig 3a). Mol Neurobiol (2018) ncbi
mouse monoclonal (TU-20)
  • immunocytochemistry; mouse; 1:200; fig 2a
EMD Millipore TUBB3 antibody (Millipore Bioscience, MAB1637) was used in immunocytochemistry on mouse samples at 1:200 (fig 2a). Front Cell Neurosci (2017) ncbi
mouse monoclonal (TU-20)
  • western blot; mouse; loading ...; fig 2d
EMD Millipore TUBB3 antibody (Millipore, MAB1637) was used in western blot on mouse samples (fig 2d). Stem Cells Int (2017) ncbi
mouse monoclonal (TU-20)
  • immunohistochemistry - frozen section; rat; fig s1d
EMD Millipore TUBB3 antibody (EMD Millipore, MAB1637) was used in immunohistochemistry - frozen section on rat samples (fig s1d). Sci Rep (2017) ncbi
mouse monoclonal (TU-20)
  • immunohistochemistry - frozen section; mouse; 1:500; fig 1
EMD Millipore TUBB3 antibody (Millipore, MAB1637) was used in immunohistochemistry - frozen section on mouse samples at 1:500 (fig 1). Cell Rep (2016) ncbi
mouse monoclonal (TU-20)
  • immunohistochemistry - frozen section; mouse; fig 5
EMD Millipore TUBB3 antibody (Millipore, 1637) was used in immunohistochemistry - frozen section on mouse samples (fig 5). Mol Cell Neurosci (2016) ncbi
mouse monoclonal (TU-20)
  • immunocytochemistry; human; 1:400; fig s2
EMD Millipore TUBB3 antibody (Millipore, MAB1637) was used in immunocytochemistry on human samples at 1:400 (fig s2). PLoS ONE (2016) ncbi
mouse monoclonal (TU-20)
  • immunocytochemistry; human; 1:400; loading ...; tbl s4
  • western blot; human; 1:400; loading ...; tbl s4
EMD Millipore TUBB3 antibody (Millipore, MAB1637) was used in immunocytochemistry on human samples at 1:400 (tbl s4) and in western blot on human samples at 1:400 (tbl s4). Stem Cell Res (2016) ncbi
mouse monoclonal (TU-20)
  • immunocytochemistry; human; 1:700; loading ...; fig 5a
In order to elucidate the relationship between protease prolyl endopeptidase and neural cell adhesion molecule, EMD Millipore TUBB3 antibody (Millipore, MAB1637) was used in immunocytochemistry on human samples at 1:700 (fig 5a). J Cell Sci (2016) ncbi
mouse monoclonal (TU-20)
  • immunocytochemistry; human; fig 1
In order to describe a protocol for retinal ganglion cell differentiation, EMD Millipore TUBB3 antibody (Millipore, MAB1637) was used in immunocytochemistry on human samples (fig 1). Sci Rep (2016) ncbi
mouse monoclonal (TU-20)
  • immunocytochemistry; human; 1:50; fig 4
In order to research differentiation of functional glutamatergic neurons from placenta-derived multipotent cells by knocking down of heat-shock protein 27, EMD Millipore TUBB3 antibody (Chemicon, MAB1637) was used in immunocytochemistry on human samples at 1:50 (fig 4). Sci Rep (2016) ncbi
mouse monoclonal (TU-20)
  • immunohistochemistry - paraffin section; mouse; loading ...; fig s1a
EMD Millipore TUBB3 antibody (Millipore, MAB1637) was used in immunohistochemistry - paraffin section on mouse samples (fig s1a). J Clin Invest (2016) ncbi
mouse monoclonal (TU-20)
  • immunohistochemistry - frozen section; chicken; 1:250; fig 8a
EMD Millipore TUBB3 antibody (Millipore, MAB1637) was used in immunohistochemistry - frozen section on chicken samples at 1:250 (fig 8a). J Comp Neurol (2017) ncbi
mouse monoclonal (TU-20)
  • immunocytochemistry; human; 1:400; fig 1
EMD Millipore TUBB3 antibody (millipore, MAB1637) was used in immunocytochemistry on human samples at 1:400 (fig 1). Stem Cell Rev (2016) ncbi
mouse monoclonal (TU-20)
  • immunocytochemistry; mouse; 1:1000; loading ...; fig 3d
EMD Millipore TUBB3 antibody (Millipore, MAB1637) was used in immunocytochemistry on mouse samples at 1:1000 (fig 3d). PLoS ONE (2016) ncbi
mouse monoclonal (TU-20)
  • immunohistochemistry - frozen section; human; 1:100; fig 4
EMD Millipore TUBB3 antibody (Millipore, MAB1637) was used in immunohistochemistry - frozen section on human samples at 1:100 (fig 4). J Clin Invest (2016) ncbi
mouse monoclonal (TU-20)
  • immunocytochemistry; human; 1:2000; fig 2
EMD Millipore TUBB3 antibody (Millipore, MAB1637) was used in immunocytochemistry on human samples at 1:2000 (fig 2). Nat Med (2016) ncbi
mouse monoclonal (TU-20)
  • immunohistochemistry; mouse; fig 5
EMD Millipore TUBB3 antibody (Millipore, 1637) was used in immunohistochemistry on mouse samples (fig 5). elife (2016) ncbi
mouse monoclonal (TU-20)
  • immunocytochemistry; mouse; fig 1
EMD Millipore TUBB3 antibody (Chemicon, CBL412) was used in immunocytochemistry on mouse samples (fig 1). Sci Rep (2016) ncbi
mouse monoclonal (TU-20)
  • immunocytochemistry; mouse; 1:500; fig 5d
EMD Millipore TUBB3 antibody (Millipore, MAB1637) was used in immunocytochemistry on mouse samples at 1:500 (fig 5d). Biomicrofluidics (2015) ncbi
mouse monoclonal (TU-20)
  • immunohistochemistry; human
In order to investigate the role of FOXG1 in neuronal differentiation, EMD Millipore TUBB3 antibody (Millipore, MAB1637) was used in immunohistochemistry on human samples . Hum Pathol (2015) ncbi
mouse monoclonal (TU-20)
  • immunocytochemistry; mouse; 1:1000; fig 2e
EMD Millipore TUBB3 antibody (Millipore, MAB1637) was used in immunocytochemistry on mouse samples at 1:1000 (fig 2e). Sci Rep (2015) ncbi
mouse monoclonal (TU-20)
  • immunocytochemistry; mouse; 1:50; fig 3
EMD Millipore TUBB3 antibody (Millipore, MAB1637) was used in immunocytochemistry on mouse samples at 1:50 (fig 3). Cell Death Differ (2016) ncbi
mouse monoclonal (TU-20)
  • immunohistochemistry - frozen section; mouse; 1:250; fig s3
EMD Millipore TUBB3 antibody (Millipore, MAB1637) was used in immunohistochemistry - frozen section on mouse samples at 1:250 (fig s3). PLoS ONE (2015) ncbi
mouse monoclonal (TU-20)
  • immunocytochemistry; mouse; 1:500; fig 1e
EMD Millipore TUBB3 antibody (Millipore, MAB1637) was used in immunocytochemistry on mouse samples at 1:500 (fig 1e). Dis Model Mech (2015) ncbi
mouse monoclonal (TU-20)
  • immunocytochemistry; mouse
  • immunocytochemistry; human; 1:100-1:500; fig 5c
EMD Millipore TUBB3 antibody (Millipore,, MAB1637) was used in immunocytochemistry on mouse samples and in immunocytochemistry on human samples at 1:100-1:500 (fig 5c). Cell Death Differ (2016) ncbi
mouse monoclonal (TU-20)
  • immunocytochemistry; human; 1:100; fig 2
In order to study induced pluripotent stem cells derived from patients with amyotrophic lateral sclerosis, EMD Millipore TUBB3 antibody (Chemicon Mab, 1637) was used in immunocytochemistry on human samples at 1:100 (fig 2). Dis Model Mech (2015) ncbi
mouse monoclonal (TU-20)
  • immunocytochemistry; human; 1:200; fig 2
EMD Millipore TUBB3 antibody (Millipore, MAB1637) was used in immunocytochemistry on human samples at 1:200 (fig 2). Nat Commun (2015) ncbi
mouse monoclonal (TU-20)
  • immunohistochemistry - paraffin section; human; fig S6
EMD Millipore TUBB3 antibody (Millipore, CBL412X) was used in immunohistochemistry - paraffin section on human samples (fig S6). PLoS ONE (2015) ncbi
mouse monoclonal (TU-20)
  • immunocytochemistry; human; 1:100; fig 1
In order to study neuron properties derived from induced pluripotent stem cells of Gaucher disease type 2 patient fibroblasts as a role in neuropathology, EMD Millipore TUBB3 antibody (Millipore, MAB1637) was used in immunocytochemistry on human samples at 1:100 (fig 1). PLoS ONE (2015) ncbi
mouse monoclonal (TU-20)
  • immunohistochemistry; Chinese soft-shelled turtle; 1:200
  • immunohistochemistry; Paroedura; 1:200
EMD Millipore TUBB3 antibody (Millipore, MAB1637) was used in immunohistochemistry on Chinese soft-shelled turtle samples at 1:200 and in immunohistochemistry on Paroedura samples at 1:200. Front Neurosci (2015) ncbi
mouse monoclonal (TU-20)
  • flow cytometry; mouse; 1:100; loading ...; fig 4b
  • immunocytochemistry; mouse; 1:100; loading ...; fig 6a
In order to measure NFAT isoforms in neural precursor cells, EMD Millipore TUBB3 antibody (Millipore, MAB1637) was used in flow cytometry on mouse samples at 1:100 (fig 4b) and in immunocytochemistry on mouse samples at 1:100 (fig 6a). Glia (2015) ncbi
mouse monoclonal (TU-20)
  • immunohistochemistry; mouse
EMD Millipore TUBB3 antibody (Millipore, MAB1637) was used in immunohistochemistry on mouse samples . Hear Res (2015) ncbi
mouse monoclonal (TU-20)
  • immunocytochemistry; rat; 1:200
EMD Millipore TUBB3 antibody (Millipore, CBL412A5) was used in immunocytochemistry on rat samples at 1:200. Toxicol In Vitro (2015) ncbi
mouse monoclonal (TU-20)
  • immunocytochemistry; sheep; 10 ug/ml; loading ...; fig 2
In order to study the reprogramming of ovine induced pluripotent stem cells, EMD Millipore TUBB3 antibody (Millipore, MAB1637) was used in immunocytochemistry on sheep samples at 10 ug/ml (fig 2). Cell Reprogram (2015) ncbi
mouse monoclonal (TU-20)
  • immunocytochemistry; mouse; 1:200
EMD Millipore TUBB3 antibody (Millipore, MAB1637) was used in immunocytochemistry on mouse samples at 1:200. Toxicol Appl Pharmacol (2014) ncbi
mouse monoclonal (TU-20)
  • immunocytochemistry; human; 1:200
EMD Millipore TUBB3 antibody (Millipore, TU-20) was used in immunocytochemistry on human samples at 1:200. PLoS ONE (2014) ncbi
mouse monoclonal (TU-20)
  • immunohistochemistry - frozen section; human; 1:200
EMD Millipore TUBB3 antibody (Millipore, MAB1637) was used in immunohistochemistry - frozen section on human samples at 1:200. Neuroscience (2015) ncbi
mouse monoclonal (TU-20)
  • immunohistochemistry - frozen section; rat; 1:100
  • western blot; rat; 1:100
EMD Millipore TUBB3 antibody (Millipore, MAB1637) was used in immunohistochemistry - frozen section on rat samples at 1:100 and in western blot on rat samples at 1:100. PLoS ONE (2014) ncbi
mouse monoclonal (TU-20)
  • immunocytochemistry; rat; 1:100
In order to determine which stage of neurogenesis is under the regulation of L-type Ca2+ channels, EMD Millipore TUBB3 antibody (Merck Millipore, MAB1637) was used in immunocytochemistry on rat samples at 1:100. Dev Growth Differ (2014) ncbi
mouse monoclonal (TU-20)
  • western blot; human; 1:250
EMD Millipore TUBB3 antibody (Millipore, MAB1637) was used in western blot on human samples at 1:250. Stem Cell Rev (2015) ncbi
mouse monoclonal (TU-20)
  • immunocytochemistry; mouse
EMD Millipore TUBB3 antibody (Millipore, MAB1637) was used in immunocytochemistry on mouse samples . Neurosci Lett (2014) ncbi
mouse monoclonal (TU-20)
  • immunocytochemistry; mouse; 1:500
In order to describe the development a neurosphere culture method that results in highly proliferative stem/progenitor cell population, EMD Millipore TUBB3 antibody (Merck Millipore, MAB1637) was used in immunocytochemistry on mouse samples at 1:500. Int J Dev Neurosci (2014) ncbi
mouse monoclonal (TU-20)
  • immunocytochemistry; human; 1:100
EMD Millipore TUBB3 antibody (Millipore, MAB1637) was used in immunocytochemistry on human samples at 1:100. Acta Naturae (2014) ncbi
mouse monoclonal (TU-20)
  • immunocytochemistry; mouse; 1:600
EMD Millipore TUBB3 antibody (Millipore, MAB1637) was used in immunocytochemistry on mouse samples at 1:600. Cytotechnology (2015) ncbi
mouse monoclonal (TU-20)
  • immunocytochemistry; mouse; 1:300
In order to investigate the role of repressor element 1-silencing transcription factor in neurodegeneration during ageing, EMD Millipore TUBB3 antibody (Millipore, mab1637) was used in immunocytochemistry on mouse samples at 1:300. Nature (2014) ncbi
mouse monoclonal (TU-20)
  • In-Cell Western; mouse; 1:1000
  • immunohistochemistry - frozen section; mouse; 1:1000
EMD Millipore TUBB3 antibody (Chemicon-Millipore, MAB1637) was used in In-Cell Western on mouse samples at 1:1000 and in immunohistochemistry - frozen section on mouse samples at 1:1000. J Mol Neurosci (2014) ncbi
mouse monoclonal (TU-20)
  • immunocytochemistry; mouse; 1:500
EMD Millipore TUBB3 antibody (Millipore, MAB1637) was used in immunocytochemistry on mouse samples at 1:500. PLoS ONE (2014) ncbi
mouse monoclonal (TU-20)
  • immunohistochemistry - frozen section; rat; 1:250
EMD Millipore TUBB3 antibody (Millipore, CBL412X) was used in immunohistochemistry - frozen section on rat samples at 1:250. Hear Res (2014) ncbi
mouse monoclonal (TU-20)
  • immunohistochemistry - frozen section; rat; 1:200
  • western blot; rat; 1:200
EMD Millipore TUBB3 antibody (Millipore, MAB1637) was used in immunohistochemistry - frozen section on rat samples at 1:200 and in western blot on rat samples at 1:200. J Neurol Sci (2014) ncbi
mouse monoclonal (TU-20)
  • immunocytochemistry; human; 1:200
EMD Millipore TUBB3 antibody (Chemcon, MAB1637) was used in immunocytochemistry on human samples at 1:200. PLoS ONE (2013) ncbi
mouse monoclonal (TU-20)
  • immunocytochemistry; human; 1:100
In order to evaluate a cell culture system for long-term passaging of human pluripotent stem cells, EMD Millipore TUBB3 antibody (Millipore, MAB1637) was used in immunocytochemistry on human samples at 1:100. J Neurosci Res (2013) ncbi
mouse monoclonal (TU-20)
  • immunohistochemistry; human; 1:200
In order to characterize a rare case of gliosarcoma, EMD Millipore TUBB3 antibody (Chemicon, Tu-20) was used in immunohistochemistry on human samples at 1:200. Clin Neuropathol (2013) ncbi
mouse monoclonal (TU-20)
  • immunocytochemistry; human; 1:200; fig 6
EMD Millipore TUBB3 antibody (Chemicon, MAB1637) was used in immunocytochemistry on human samples at 1:200 (fig 6). Nucleic Acids Res (2013) ncbi
mouse monoclonal (TU-20)
  • immunocytochemistry; human; 1:400
  • western blot; human; 1:2000
In order to investigate the effect of valproate in the activation of FGF1 gene promoter, EMD Millipore TUBB3 antibody (EMD Millipore, MAB1637) was used in immunocytochemistry on human samples at 1:400 and in western blot on human samples at 1:2000. J Neurochem (2013) ncbi
mouse monoclonal (TU-20)
  • immunohistochemistry - frozen section; African green monkey; 1:100
In order to evaluate the cellular transduction efficacy of intrathecal delivery of adeno-associated viruses, EMD Millipore TUBB3 antibody (Millipore, MAB1637) was used in immunohistochemistry - frozen section on African green monkey samples at 1:100. Hum Gene Ther (2013) ncbi
mouse monoclonal (TU-20)
  • immunohistochemistry - frozen section; mouse
EMD Millipore TUBB3 antibody (Millipore, Mab 1637) was used in immunohistochemistry - frozen section on mouse samples . PLoS ONE (2012) ncbi
mouse monoclonal (TU-20)
  • immunohistochemistry - frozen section; dog; 1:300
  • immunocytochemistry; dog; 1:300
EMD Millipore TUBB3 antibody (Chemicon, MAB1637) was used in immunohistochemistry - frozen section on dog samples at 1:300 and in immunocytochemistry on dog samples at 1:300. Histochem Cell Biol (2013) ncbi
mouse monoclonal (TU-20)
  • immunocytochemistry; Rhesus monkey; 1:500
EMD Millipore TUBB3 antibody (Chemicon, MAB1637) was used in immunocytochemistry on Rhesus monkey samples at 1:500. Stem Cells Dev (2013) ncbi
mouse monoclonal (TU-20)
  • immunocytochemistry; rat; 1:500
  • western blot; rat
EMD Millipore TUBB3 antibody (Millipore, MAB1637) was used in immunocytochemistry on rat samples at 1:500 and in western blot on rat samples . Mol Biol Cell (2012) ncbi
mouse monoclonal (TU-20)
  • immunohistochemistry - frozen section; mouse; 1:2000
EMD Millipore TUBB3 antibody (Millipore, MAB1637) was used in immunohistochemistry - frozen section on mouse samples at 1:2000. J Comp Neurol (2012) ncbi
mouse monoclonal (TU-20)
  • western blot; pig
EMD Millipore TUBB3 antibody (Millipore, MAB1637) was used in western blot on pig samples . Mol Cell Proteomics (2011) ncbi
mouse monoclonal (TU-20)
  • immunohistochemistry - frozen section; mouse; 1:50
EMD Millipore TUBB3 antibody (Chemicon, MAB1637) was used in immunohistochemistry - frozen section on mouse samples at 1:50. J Comp Neurol (2008) ncbi
Articles Reviewed
  1. Schaffer T, Smith J, Cook E, Phan T, Margolis S. PKCε Inhibits Neuronal Dendritic Spine Development through Dual Phosphorylation of Ephexin5. Cell Rep. 2018;25:2470-2483.e8 pubmed publisher
  2. Tseligka E, Sobo K, Stoppini L, Cagno V, Abdul F, Piuz I, et al. A VP1 mutation acquired during an enterovirus 71 disseminated infection confers heparan sulfate binding ability and modulates ex vivo tropism. PLoS Pathog. 2018;14:e1007190 pubmed publisher
  3. Karow M, Camp J, Falk S, Gerber T, Pataskar A, Gac Santel M, et al. Direct pericyte-to-neuron reprogramming via unfolding of a neural stem cell-like program. Nat Neurosci. 2018;21:932-940 pubmed publisher
  4. Wang C, Najm R, Xu Q, Jeong D, Walker D, Balestra M, et al. Gain of toxic apolipoprotein E4 effects in human iPSC-derived neurons is ameliorated by a small-molecule structure corrector. Nat Med. 2018;24:647-657 pubmed publisher
  5. Wu M, Liu S, Gao Y, Bai H, Machairaki V, Li G, et al. Conditional gene knockout and reconstitution in human iPSCs with an inducible Cas9 system. Stem Cell Res. 2018;29:6-14 pubmed publisher
  6. Aneichyk T, Hendriks W, Yadav R, Shin D, Gao D, Vaine C, et al. Dissecting the Causal Mechanism of X-Linked Dystonia-Parkinsonism by Integrating Genome and Transcriptome Assembly. Cell. 2018;172:897-909.e21 pubmed publisher
  7. de la Torre Ubieta L, Stein J, Won H, Opland C, Liang D, Lu D, et al. The Dynamic Landscape of Open Chromatin during Human Cortical Neurogenesis. Cell. 2018;172:289-304.e18 pubmed publisher
  8. Hernández I, Torres Peraza J, Santos Galindo M, Ramos Morón E, Fernandez Fernandez M, Pérez Álvarez M, et al. The neuroprotective transcription factor ATF5 is decreased and sequestered into polyglutamine inclusions in Huntington's disease. Acta Neuropathol. 2017;134:839-850 pubmed publisher
  9. Smith R, Huang Y, Tian T, Vojtasova D, Mesalles Naranjo O, Pollard S, et al. The Transcription Factor Foxg1 Promotes Optic Fissure Closure in the Mouse by Suppressing Wnt8b in the Nasal Optic Stalk. J Neurosci. 2017;37:7975-7993 pubmed publisher
  10. Arcego D, Toniazzo A, Krolow R, Lampert C, Berlitz C, Dos Santos Garcia E, et al. Impact of High-Fat Diet and Early Stress on Depressive-Like Behavior and Hippocampal Plasticity in Adult Male Rats. Mol Neurobiol. 2018;55:2740-2753 pubmed publisher
  11. Liu S, Ye Z, Gao Y, He C, Williams D, MOLITERNO A, et al. Generation of human iPSCs from an essential thrombocythemia patient carrying a V501L mutation in the MPL gene. Stem Cell Res. 2017;18:57-59 pubmed publisher
  12. Bryukhovetskiy I, Lyakhova I, Mischenko P, Milkina E, Zaitsev S, Khotimchenko Y, et al. Alkaloids of fascaplysin are effective conventional chemotherapeutic drugs, inhibiting the proliferation of C6 glioma cells and causing their death in vitro. Oncol Lett. 2017;13:738-746 pubmed publisher
  13. Jin X, Yu Z, Chen F, Lu G, Ding X, Xie L, et al. Neuronal Nitric Oxide Synthase in Neural Stem Cells Induces Neuronal Fate Commitment via the Inhibition of Histone Deacetylase 2. Front Cell Neurosci. 2017;11:66 pubmed publisher
  14. Po A, Begalli F, Abballe L, Alfano V, Besharat Z, Catanzaro G, et al. ?-Arrestin1/miR-326 Transcription Unit Is Epigenetically Regulated in Neural Stem Cells Where It Controls Stemness and Growth Arrest. Stem Cells Int. 2017;2017:5274171 pubmed publisher
  15. Shan M, Lin S, Li S, Du Y, Zhao H, Hong H, et al. TIR-Domain-Containing Adapter-Inducing Interferon-? (TRIF) Is Essential for MPTP-Induced Dopaminergic Neuroprotection via Microglial Cell M1/M2 Modulation. Front Cell Neurosci. 2017;11:35 pubmed publisher
  16. Bartlett R, Sluyter V, Watson D, Sluyter R, Yerbury J. P2X7 antagonism using Brilliant Blue G reduces body weight loss and prolongs survival in female SOD1G93A amyotrophic lateral sclerosis mice. Peerj. 2017;5:e3064 pubmed publisher
  17. Itakura G, Kawabata S, Ando M, Nishiyama Y, Sugai K, Ozaki M, et al. Fail-Safe System against Potential Tumorigenicity after Transplantation of iPSC Derivatives. Stem Cell Reports. 2017;8:673-684 pubmed publisher
  18. Arioka Y, Ito H, Hirata A, Semi K, Yamada Y, Seishima M. Behavior of leucine-rich repeat-containing G-protein coupled receptor 5-expressing cells in the reprogramming process. Stem Cell Res. 2017;20:1-9 pubmed publisher
  19. Furukawa S, Nagaike M, Ozaki K. Databases for technical aspects of immunohistochemistry. J Toxicol Pathol. 2017;30:79-107 pubmed publisher
  20. Zhou C, Robert M, Kapoulea V, Lei F, Stagner A, Jakobiec F, et al. Sustained Subconjunctival Delivery of Infliximab Protects the Cornea and Retina Following Alkali Burn to the Eye. Invest Ophthalmol Vis Sci. 2017;58:96-105 pubmed publisher
  21. Pinca R, Manara M, Chiadini V, Picci P, Zucchini C, Scotlandi K. Targeting ROCK2 rather than ROCK1 inhibits Ewing sarcoma malignancy. Oncol Rep. 2017;37:1387-1393 pubmed publisher
  22. Yoshitomi Y, Ikeda T, Saito H, Yoshitake Y, Ishigaki Y, Hatta T, et al. JunB regulates angiogenesis and neurovascular parallel alignment in mouse embryonic skin. J Cell Sci. 2017;130:916-926 pubmed publisher
  23. Behm M, Wahlstedt H, Widmark A, Eriksson M, Ohman M. Accumulation of nuclear ADAR2 regulates adenosine-to-inosine RNA editing during neuronal development. J Cell Sci. 2017;130:745-753 pubmed publisher
  24. Wang D, Wang A, Wu F, Qiu X, Li Y, Chu J, et al. Sox10+ adult stem cells contribute to biomaterial encapsulation and microvascularization. Sci Rep. 2017;7:40295 pubmed publisher
  25. Hosoya M, Fujioka M, Sone T, Okamoto S, Akamatsu W, Ukai H, et al. Cochlear Cell Modeling Using Disease-Specific iPSCs Unveils a Degenerative Phenotype and Suggests Treatments for Congenital Progressive Hearing Loss. Cell Rep. 2017;18:68-81 pubmed publisher
  26. Kemp K, Cerminara N, Hares K, Redondo J, Cook A, Haynes H, et al. Cytokine therapy-mediated neuroprotection in a Friedreich's ataxia mouse model. Ann Neurol. 2017;81:212-226 pubmed publisher
  27. Wang S, Jacquemyn J, Murru S, Martinelli P, Barth E, Langer T, et al. The Mitochondrial m-AAA Protease Prevents Demyelination and Hair Greying. PLoS Genet. 2016;12:e1006463 pubmed publisher
  28. Wolfes A, Ahmed S, Awasthi A, Stahlberg M, Rajput A, Magruder D, et al. A novel method for culturing stellate astrocytes reveals spatially distinct Ca2+ signaling and vesicle recycling in astrocytic processes. J Gen Physiol. 2017;149:149-170 pubmed publisher
  29. McKenzie C, D Avino P. Investigating cytokinesis failure as a strategy in cancer therapy. Oncotarget. 2016;7:87323-87341 pubmed publisher
  30. Bassett E, Tokarew N, Allemano E, Mazerolle C, Morin K, Mears A, et al. Norrin/Frizzled4 signalling in the preneoplastic niche blocks medulloblastoma initiation. elife. 2016;5: pubmed publisher
  31. Bryukhovetskiy I, Dyuizen I, Shevchenko V, Bryukhovetskiy A, Mischenko P, Milkina E, et al. Hematopoietic stem cells as a tool for the treatment of glioblastoma multiforme. Mol Med Rep. 2016;14:4511-4520 pubmed publisher
  32. Vasconcelos F, Sessa A, Laranjeira C, Raposo A, Teixeira V, Hagey D, et al. MyT1 Counteracts the Neural Progenitor Program to Promote Vertebrate Neurogenesis. Cell Rep. 2016;17:469-483 pubmed publisher
  33. Fogarty L, Song B, Suppiah Y, Hasan S, Martin H, Hogan S, et al. Bcl-xL dependency coincides with the onset of neurogenesis in the developing mammalian spinal cord. Mol Cell Neurosci. 2016;77:34-46 pubmed publisher
  34. Xing H, Lim Y, Chong J, Lee J, Aarsland D, Ballard C, et al. Increased phosphorylation of collapsin response mediator protein-2 at Thr514 correlates with ?-amyloid burden and synaptic deficits in Lewy body dementias. Mol Brain. 2016;9:84 pubmed publisher
  35. Ahmadian Baghbaderani B, Tian X, Scotty Cadet J, Shah K, Walde A, Tran H, et al. A Newly Defined and Xeno-Free Culture Medium Supports Every-Other-Day Medium Replacement in the Generation and Long-Term Cultivation of Human Pluripotent Stem Cells. PLoS ONE. 2016;11:e0161229 pubmed publisher
  36. Bryukhovetskiy I, Manzhulo I, Mischenko P, Milkina E, Dyuizen I, Bryukhovetskiy A, et al. Cancer stem cells and microglia in the processes of glioblastoma multiforme invasive growth. Oncol Lett. 2016;12:1721-1728 pubmed
  37. Hansen S, Stummann T, Borland H, Hasholt L, Tumer Z, Nielsen J, et al. Induced pluripotent stem cell - derived neurons for the study of spinocerebellar ataxia type 3. Stem Cell Res. 2016;17:306-317 pubmed publisher
  38. Mao S, Li X, Wang J, Ding X, Zhang C, Li L. miR-17-92 facilitates neuronal differentiation of transplanted neural stem/precursor cells under neuroinflammatory conditions. J Neuroinflammation. 2016;13:208 pubmed publisher
  39. Jaako K, Waniek A, Parik K, Klimaviciusa L, Aonurm Helm A, Noortoots A, et al. Prolyl endopeptidase is involved in the degradation of neural cell adhesion molecules in vitro. J Cell Sci. 2016;129:3792-3802 pubmed
  40. Gill K, Hung S, Sharov A, Lo C, Needham K, Lidgerwood G, et al. Enriched retinal ganglion cells derived from human embryonic stem cells. Sci Rep. 2016;6:30552 pubmed publisher
  41. Cheng Y, Huang C, Lee Y, Tien L, Ku W, Chien R, et al. Knocking down of heat-shock protein 27 directs differentiation of functional glutamatergic neurons from placenta-derived multipotent cells. Sci Rep. 2016;6:30314 pubmed publisher
  42. Shivkumar M, Lawler C, Milho R, Stevenson P. Herpes Simplex Virus 1 Interaction with Myeloid Cells In Vivo. J Virol. 2016;90:8661-72 pubmed publisher
  43. Ding Y, Zhang Z, Ma J, Xia H, Wang Y, Liu Y, et al. Directed differentiation of postnatal hippocampal neural stem cells generates nuclear receptor related?1 protein? and tyrosine hydroxylase?expressing cells. Mol Med Rep. 2016;14:1993-9 pubmed publisher
  44. Sanges D, Simonte G, Di Vicino U, Romo N, Pinilla I, Nicolas M, et al. Reprogramming Müller glia via in vivo cell fusion regenerates murine photoreceptors. J Clin Invest. 2016;126:3104-16 pubmed publisher
  45. Kukreja S, Gautam P, Saxena R, Saxena M, Udaykumar N, Kumar A, et al. Identification of novel candidate regulators of retinotectal map formation through transcriptional profiling of the chick optic tectum. J Comp Neurol. 2017;525:459-477 pubmed publisher
  46. Hosoya M, Fujioka M, Okano H, Ogawa K. Distinct Expression Pattern of a Deafness Gene, KIAA1199, in a Primate Cochlea. Biomed Res Int. 2016;2016:1781894 pubmed publisher
  47. Osman E, Washington C, Kaifer K, Mazzasette C, Patitucci T, Florea K, et al. Optimization of Morpholino Antisense Oligonucleotides Targeting the Intronic Repressor Element1 in Spinal Muscular Atrophy. Mol Ther. 2016;24:1592-601 pubmed publisher
  48. Huang Z, Hu J, Pan J, Wang Y, Hu G, Zhou J, et al. YAP stabilizes SMAD1 and promotes BMP2-induced neocortical astrocytic differentiation. Development. 2016;143:2398-409 pubmed publisher
  49. Hansen S, Borland H, Hasholt L, Tumer Z, Nielsen J, Rasmussen M, et al. Generation of spinocerebellar ataxia type 3 patient-derived induced pluripotent stem cell line SCA3.B11. Stem Cell Res. 2016;16:589-92 pubmed publisher
  50. Hansen S, Borland H, Hasholt L, Tumer Z, Nielsen J, Rasmussen M, et al. Generation of spinocerebellar ataxia type 3 patient-derived induced pluripotent stem cell line SCA3.A11. Stem Cell Res. 2016;16:553-6 pubmed publisher
  51. Folmsbee S, Wilcox D, Tyberghein K, De Bleser P, Tourtellotte W, van Hengel J, et al. ?T-catenin in restricted brain cell types and its potential connection to autism. J Mol Psychiatry. 2016;4:2 pubmed publisher
  52. Baghbaderani B, Syama A, Sivapatham R, Pei Y, Mukherjee O, Fellner T, et al. Detailed Characterization of Human Induced Pluripotent Stem Cells Manufactured for Therapeutic Applications. Stem Cell Rev. 2016;12:394-420 pubmed publisher
  53. Lin S, Gou G, Hsia C, Ho C, Huang K, Wu Y, et al. Simulated Microgravity Disrupts Cytoskeleton Organization and Increases Apoptosis of Rat Neural Crest Stem Cells Via Upregulating CXCR4 Expression and RhoA-ROCK1-p38 MAPK-p53 Signaling. Stem Cells Dev. 2016;25:1172-93 pubmed publisher
  54. Spitzbarth I, Lempp C, Kegler K, Ulrich R, Kalkuhl A, Deschl U, et al. Immunohistochemical and transcriptome analyses indicate complex breakdown of axonal transport mechanisms in canine distemper leukoencephalitis. Brain Behav. 2016;6:e00472 pubmed publisher
  55. Jang H, Hong Y, Choi H, Song H, Byun S, Uhm S, et al. Changes in Parthenogenetic Imprinting Patterns during Reprogramming by Cell Fusion. PLoS ONE. 2016;11:e0156491 pubmed publisher
  56. Momcilovic O, Sivapatham R, Oron T, Meyer M, Mooney S, Rao M, et al. Derivation, Characterization, and Neural Differentiation of Integration-Free Induced Pluripotent Stem Cell Lines from Parkinson's Disease Patients Carrying SNCA, LRRK2, PARK2, and GBA Mutations. PLoS ONE. 2016;11:e0154890 pubmed publisher
  57. Miyawaki S, Kawamura Y, Oiwa Y, Shimizu A, Hachiya T, Bono H, et al. Tumour resistance in induced pluripotent stem cells derived from naked mole-rats. Nat Commun. 2016;7:11471 pubmed publisher
  58. Zhang N, Chen B, Wang W, Chen C, Kang J, Deng S, et al. Isolation, characterization and multi-lineage differentiation of stem cells from human exfoliated deciduous teeth. Mol Med Rep. 2016;14:95-102 pubmed publisher
  59. Hosoya M, Fujioka M, Kobayashi R, Okano H, Ogawa K. Overlapping expression of anion exchangers in the cochlea of a non-human primate suggests functional compensation. Neurosci Res. 2016;110:1-10 pubmed publisher
  60. Navarra A, Musto A, Gargiulo A, Petrosino G, Pierantoni G, Fusco A, et al. Hmga2 is necessary for Otx2-dependent exit of embryonic stem cells from the pluripotent ground state. BMC Biol. 2016;14:24 pubmed publisher
  61. Meng G, Poon A, Liu S, Rancourt D. An Effective and Reliable Xeno-free Cryopreservation Protocol for Single Human Pluripotent Stem Cells. Methods Mol Biol. 2016;1516:47-56 pubmed publisher
  62. Eisch V, Lu X, Gabriel D, Djabali K. Progerin impairs chromosome maintenance by depleting CENP-F from metaphase kinetochores in Hutchinson-Gilford progeria fibroblasts. Oncotarget. 2016;7:24700-18 pubmed publisher
  63. Deborde S, Omelchenko T, Lyubchik A, Zhou Y, He S, McNamara W, et al. Schwann cells induce cancer cell dispersion and invasion. J Clin Invest. 2016;126:1538-54 pubmed publisher
  64. Francis K, Ton A, Xin Y, O Halloran P, Wassif C, Malik N, et al. Modeling Smith-Lemli-Opitz syndrome with induced pluripotent stem cells reveals a causal role for Wnt/β-catenin defects in neuronal cholesterol synthesis phenotypes. Nat Med. 2016;22:388-96 pubmed publisher
  65. Uda Y, Xu S, Matsumura T, Takei Y. P2Y4 Nucleotide Receptor in Neuronal Precursors Induces Glutamatergic Subtype Markers in Their Descendant Neurons. Stem Cell Reports. 2016;6:474-482 pubmed publisher
  66. Hosoya M, Fujioka M, Ogawa K, Okano H. Distinct Expression Patterns Of Causative Genes Responsible For Hereditary Progressive Hearing Loss In Non-Human Primate Cochlea. Sci Rep. 2016;6:22250 pubmed publisher
  67. Collazos Castro J, García Rama C, Alves Sampaio A. Glial progenitor cell migration promotes CNS axon growth on functionalized electroconducting microfibers. Acta Biomater. 2016;35:42-56 pubmed publisher
  68. Zhang W, Kim P, Chen Z, Lokman H, Qiu L, Zhang K, et al. MiRNA-128 regulates the proliferation and neurogenesis of neural precursors by targeting PCM1 in the developing cortex. elife. 2016;5: pubmed publisher
  69. Wu X, Fleming A, Ricketts T, Pavel M, Virgin H, Menzies F, et al. Autophagy regulates Notch degradation and modulates stem cell development and neurogenesis. Nat Commun. 2016;7:10533 pubmed publisher
  70. Heeren A, He N, de Souza A, Goercharn Ramlal A, van Iperen L, Roost M, et al. On the development of extragonadal and gonadal human germ cells. Biol Open. 2016;5:185-94 pubmed publisher
  71. Zhang Q, Dan J, Wang H, Guo R, Mao J, Fu H, et al. Tcstv1 and Tcstv3 elongate telomeres of mouse ES cells. Sci Rep. 2016;6:19852 pubmed publisher
  72. Malan D, Zhang M, Stallmeyer B, Müller J, Fleischmann B, Schulze Bahr E, et al. Human iPS cell model of type 3 long QT syndrome recapitulates drug-based phenotype correction. Basic Res Cardiol. 2016;111:14 pubmed publisher
  73. de Souza C, Nivison Smith L, Christie D, Polkinghorne P, McGhee C, Kalloniatis M, et al. Macromolecular markers in normal human retina and applications to human retinal disease. Exp Eye Res. 2016;150:135-48 pubmed publisher
  74. Wu Z, Li D, Huang Y, Chen X, Huang W, Liu C, et al. Caspr Controls the Temporal Specification of Neural Progenitor Cells through Notch Signaling in the Developing Mouse Cerebral Cortex. Cereb Cortex. 2017;27:1369-1385 pubmed publisher
  75. Kawabata S, Takano M, Numasawa Kuroiwa Y, Itakura G, Kobayashi Y, Nishiyama Y, et al. Grafted Human iPS Cell-Derived Oligodendrocyte Precursor Cells Contribute to Robust Remyelination of Demyelinated Axons after Spinal Cord Injury. Stem Cell Reports. 2016;6:1-8 pubmed publisher
  76. Higuchi A, Kao S, Ling Q, Chen Y, Li H, Alarfaj A, et al. Long-term xeno-free culture of human pluripotent stem cells on hydrogels with optimal elasticity. Sci Rep. 2015;5:18136 pubmed publisher
  77. Oliveira L, Falomir Lockhart L, Botelho M, Lin K, Wales P, Koch J, et al. Elevated α-synuclein caused by SNCA gene triplication impairs neuronal differentiation and maturation in Parkinson's patient-derived induced pluripotent stem cells. Cell Death Dis. 2015;6:e1994 pubmed publisher
  78. Abe S, Yamaguchi S, Sato Y, Harada K. Sphere-Derived Multipotent Progenitor Cells Obtained From Human Oral Mucosa Are Enriched in Neural Crest Cells. Stem Cells Transl Med. 2016;5:117-28 pubmed publisher
  79. Chen Y, Peng C, Tung Y. Flip channel: A microfluidic device for uniform-sized embryoid body formation and differentiation. Biomicrofluidics. 2015;9:054111 pubmed publisher
  80. Adesina A, Veo B, Courteau G, Mehta V, Wu X, Pang K, et al. FOXG1 expression shows correlation with neuronal differentiation in cerebellar development, aggressive phenotype in medulloblastomas, and survival in a xenograft model of medulloblastoma. Hum Pathol. 2015;46:1859-71 pubmed publisher
  81. Prescott H, Manning C, Gardner A, Ritchie W, Pizzi R, Girling S, et al. Giant Panda (Ailuropoda melanoleuca) Buccal Mucosa Tissue as a Source of Multipotent Progenitor Cells. PLoS ONE. 2015;10:e0138840 pubmed publisher
  82. Choi H, Kim J, Hong Y, Song H, Seo H, Do J. In vivo reprogrammed pluripotent stem cells from teratomas share analogous properties with their in vitro counterparts. Sci Rep. 2015;5:13559 pubmed publisher
  83. Barão S, Gärtner A, Leyva Díaz E, Demyanenko G, Munck S, Vanhoutvin T, et al. Antagonistic Effects of BACE1 and APH1B-γ-Secretase Control Axonal Guidance by Regulating Growth Cone Collapse. Cell Rep. 2015;12:1367-76 pubmed publisher
  84. Wang J, Zhang Y, Hou J, Qian X, Zhang H, Zhang Z, et al. Ube2s regulates Sox2 stability and mouse ES cell maintenance. Cell Death Differ. 2016;23:393-404 pubmed publisher
  85. Mohammadi A, Attari F, Babapour V, Hassani S, Masoudi N, Shahverdi A, et al. Generation of Rat Embryonic Germ Cells via Inhibition of TGFß and MEK Pathways. Cell J. 2015;17:288-95 pubmed
  86. Cadalbert L, Ghaffar F, Stevenson D, Bryson S, Vaz F, Gottlieb E, et al. Mouse Tafazzin Is Required for Male Germ Cell Meiosis and Spermatogenesis. PLoS ONE. 2015;10:e0131066 pubmed publisher
  87. Cases O, Joseph A, Obry A, Santin M, Ben Yacoub S, Pâques M, et al. Foxg1-Cre Mediated Lrp2 Inactivation in the Developing Mouse Neural Retina, Ciliary and Retinal Pigment Epithelia Models Congenital High Myopia. PLoS ONE. 2015;10:e0129518 pubmed publisher
  88. Szlachcic W, Switonski P, Krzyzosiak W, Figlerowicz M, Figiel M. Huntington disease iPSCs show early molecular changes in intracellular signaling, the expression of oxidative stress proteins and the p53 pathway. Dis Model Mech. 2015;8:1047-57 pubmed publisher
  89. Huang X, Hu Q, Braun G, Pallaoro A, Morales D, ZASADZINSKI J, et al. Light-activated RNA interference in human embryonic stem cells. Biomaterials. 2015;63:70-9 pubmed publisher
  90. Petroni M, Sardina F, Heil C, Sahún Roncero M, Colicchia V, Veschi V, et al. The MRN complex is transcriptionally regulated by MYCN during neural cell proliferation to control replication stress. Cell Death Differ. 2016;23:197-206 pubmed publisher
  91. Lenzi J, De Santis R, de Turris V, Morlando M, Laneve P, Calvo A, et al. ALS mutant FUS proteins are recruited into stress granules in induced pluripotent stem cell-derived motoneurons. Dis Model Mech. 2015;8:755-66 pubmed publisher
  92. Chen H, Aksoy I, Gonnot F, Osteil P, Aubry M, Hamela C, et al. Reinforcement of STAT3 activity reprogrammes human embryonic stem cells to naive-like pluripotency. Nat Commun. 2015;6:7095 pubmed publisher
  93. Terzic D, Maxon J, Krevitt L, DiBartolomeo C, Goyal T, Low W, et al. Directed Differentiation of Oligodendrocyte Progenitor Cells From Mouse Induced Pluripotent Stem Cells. Cell Transplant. 2016;25:411-24 pubmed publisher
  94. Tate C, Mc Entire J, Pallini R, Vakana E, Wyss L, Blosser W, et al. A BMP7 Variant Inhibits Tumor Angiogenesis In Vitro and In Vivo through Direct Modulation of Endothelial Cell Biology. PLoS ONE. 2015;10:e0125697 pubmed publisher
  95. Vicuña L, Strochlic D, Latremoliere A, Bali K, Simonetti M, Husainie D, et al. The serine protease inhibitor SerpinA3N attenuates neuropathic pain by inhibiting T cell-derived leukocyte elastase. Nat Med. 2015;21:518-23 pubmed publisher
  96. Deleyrolle L, Sabourin J, Rothhut B, Fujita H, Guichet P, Teigell M, et al. OCAM regulates embryonic spinal cord stem cell proliferation by modulating ErbB2 receptor. PLoS ONE. 2015;10:e0122337 pubmed publisher
  97. Sun Y, Florer J, Mayhew C, Jia Z, Zhao Z, Xu K, et al. Properties of neurons derived from induced pluripotent stem cells of Gaucher disease type 2 patient fibroblasts: potential role in neuropathology. PLoS ONE. 2015;10:e0118771 pubmed publisher
  98. Debowski K, Warthemann R, Lentes J, Salinas Riester G, Dressel R, Langenstroth D, et al. Non-viral generation of marmoset monkey iPS cells by a six-factor-in-one-vector approach. PLoS ONE. 2015;10:e0118424 pubmed publisher
  99. Hossini A, Megges M, Prigione A, Lichtner B, Toliat M, Wruck W, et al. Induced pluripotent stem cell-derived neuronal cells from a sporadic Alzheimer's disease donor as a model for investigating AD-associated gene regulatory networks. BMC Genomics. 2015;16:84 pubmed publisher
  100. Nomura T, Yamashita W, Gotoh H, Ono K. Genetic manipulation of reptilian embryos: toward an understanding of cortical development and evolution. Front Neurosci. 2015;9:45 pubmed publisher
  101. Serrano Pérez M, Fernández M, Neria F, Berjón Otero M, Doncel Pérez E, Cano E, et al. NFAT transcription factors regulate survival, proliferation, migration, and differentiation of neural precursor cells. Glia. 2015;63:987-1004 pubmed publisher
  102. Braude J, Vijayakumar S, Baumgarner K, Laurine R, Jones T, Jones S, et al. Deletion of Shank1 has minimal effects on the molecular composition and function of glutamatergic afferent postsynapses in the mouse inner ear. Hear Res. 2015;321:52-64 pubmed publisher
  103. Arel Dubeau A, Longpré F, Bournival J, Tremblay C, Demers Lamarche J, Haskova P, et al. Cucurbitacin E has neuroprotective properties and autophagic modulating activities on dopaminergic neurons. Oxid Med Cell Longev. 2014;2014:425496 pubmed publisher
  104. Dixon A, Philbert M. Morphometric assessment of toxicant induced neuronal degeneration in full and restricted contact co-cultures of embryonic cortical rat neurons and astrocytes: using m-Dinitrobezene as a model neurotoxicant. Toxicol In Vitro. 2015;29:564-74 pubmed publisher
  105. Sivapatham R, Zeng X. Generation and Characterization of Patient-Specific Induced Pluripotent Stem Cell for Disease Modeling. Methods Mol Biol. 2016;1353:25-44 pubmed publisher
  106. German S, Campbell K, Thornton E, McLachlan G, Sweetman D, Alberio R. Ovine induced pluripotent stem cells are resistant to reprogramming after nuclear transfer. Cell Reprogram. 2015;17:19-27 pubmed publisher
  107. Knerlich Lukoschus F, Krossa S, Krause J, Mehdorn H, Scheidig A, Held Feindt J. Impact of chemokines on the properties of spinal cord-derived neural progenitor cells in a rat spinal cord lesion model. J Neurosci Res. 2015;93:562-71 pubmed publisher
  108. Medina B, Santos de Abreu I, Cavalcante L, Silva W, da Fonseca R, Allodi S, et al. 3-acetylpyridine-induced degeneration in the adult ascidian neural complex: Reactive and regenerative changes in glia and blood cells. Dev Neurobiol. 2015;75:877-93 pubmed publisher
  109. Liu J, Bain L. Arsenic inhibits hedgehog signaling during P19 cell differentiation. Toxicol Appl Pharmacol. 2014;281:243-53 pubmed publisher
  110. Shimamoto A, Kagawa H, Zensho K, Sera Y, Kazuki Y, Osaki M, et al. Reprogramming suppresses premature senescence phenotypes of Werner syndrome cells and maintains chromosomal stability over long-term culture. PLoS ONE. 2014;9:e112900 pubmed publisher
  111. Lim A, Shin K, Zhao C, Kawano S, Beachy P. Spatially restricted Hedgehog signalling regulates HGF-induced branching of the adult prostate. Nat Cell Biol. 2014;16:1135-45 pubmed publisher
  112. Scholze A, Foo L, Mulinyawe S, Barres B. BMP signaling in astrocytes downregulates EGFR to modulate survival and maturation. PLoS ONE. 2014;9:e110668 pubmed publisher
  113. Liu W, Edin F, Atturo F, Rieger G, Löwenheim H, Senn P, et al. The pre- and post-somatic segments of the human type I spiral ganglion neurons--structural and functional considerations related to cochlear implantation. Neuroscience. 2015;284:470-82 pubmed publisher
  114. McLean N, Popescu B, Gordon T, Zochodne D, Verge V. Delayed nerve stimulation promotes axon-protective neurofilament phosphorylation, accelerates immune cell clearance and enhances remyelination in vivo in focally demyelinated nerves. PLoS ONE. 2014;9:e110174 pubmed publisher
  115. Teh D, Ishizuka T, Yawo H. Regulation of later neurogenic stages of adult-derived neural stem/progenitor cells by L-type Ca2+ channels. Dev Growth Differ. 2014;56:583-94 pubmed publisher
  116. Ye T, Ip J, Fu A, Ip N. Cdk5-mediated phosphorylation of RapGEF2 controls neuronal migration in the developing cerebral cortex. Nat Commun. 2014;5:4826 pubmed publisher
  117. Wang J, Shamah S, Sun A, Waldman I, Haggarty S, Perlis R. Label-free, live optical imaging of reprogrammed bipolar disorder patient-derived cells reveals a functional correlate of lithium responsiveness. Transl Psychiatry. 2014;4:e428 pubmed publisher
  118. Jha B, Rao M, Malik N. Motor neuron differentiation from pluripotent stem cells and other intermediate proliferative precursors that can be discriminated by lineage specific reporters. Stem Cell Rev. 2015;11:194-204 pubmed publisher
  119. Kawase S, Kuwako K, Imai T, Renault Mihara F, Yaguchi K, Itohara S, et al. Regulatory factor X transcription factors control Musashi1 transcription in mouse neural stem/progenitor cells. Stem Cells Dev. 2014;23:2250-61 pubmed publisher
  120. Kamishibahara Y, Kawaguchi H, Shimizu N. Promotion of mouse embryonic stem cell differentiation by Rho kinase inhibitor Y-27632. Neurosci Lett. 2014;579:58-63 pubmed publisher
  121. Torrado E, Gomes C, Santos G, Fernandes A, Brites D, Falcão A. Directing mouse embryonic neurosphere differentiation toward an enriched neuronal population. Int J Dev Neurosci. 2014;37:94-9 pubmed publisher
  122. Kehoe L, Bellone C, De Roo M, Zandueta A, Dey P, Pérez Otaño I, et al. GluN3A promotes dendritic spine pruning and destabilization during postnatal development. J Neurosci. 2014;34:9213-21 pubmed publisher
  123. Ganz J, Arie I, Buch S, Zur T, Barhum Y, Pour S, et al. Dopaminergic-like neurons derived from oral mucosa stem cells by developmental cues improve symptoms in the hemi-parkinsonian rat model. PLoS ONE. 2014;9:e100445 pubmed publisher
  124. Karow M, Schichor C, Beckervordersandforth R, Berninger B. Lineage-reprogramming of pericyte-derived cells of the adult human brain into induced neurons. J Vis Exp. 2014;: pubmed publisher
  125. Ferrer M, Corneo B, Davis J, Wan Q, Miyagishima K, King R, et al. A multiplex high-throughput gene expression assay to simultaneously detect disease and functional markers in induced pluripotent stem cell-derived retinal pigment epithelium. Stem Cells Transl Med. 2014;3:911-22 pubmed publisher
  126. Li T, Yang D, Li J, Tang Y, Yang J, Le W. Critical role of Tet3 in neural progenitor cell maintenance and terminal differentiation. Mol Neurobiol. 2015;51:142-54 pubmed publisher
  127. Muchkaeva I, Dashinimaev E, Artyuhov A, Myagkova E, Vorotelyak E, Yegorov Y, et al. Generation of iPS Cells from Human Hair Follice Dermal Papilla Cells. Acta Naturae. 2014;6:45-53 pubmed
  128. Donai K, Inagaki A, So K, Kuroda K, Sone H, Kobayashi M, et al. Low-molecular-weight inhibitors of cell differentiation enable efficient growth of mouse iPS cells under feeder-free conditions. Cytotechnology. 2015;67:191-7 pubmed publisher
  129. Lu T, Aron L, Zullo J, Pan Y, Kim H, Chen Y, et al. REST and stress resistance in ageing and Alzheimer's disease. Nature. 2014;507:448-54 pubmed publisher
  130. Zhang P, Wu C, Liu N, Niu L, Yan Z, Feng Y, et al. Protocadherin 11 x regulates differentiation and proliferation of neural stem cell in vitro and in vivo. J Mol Neurosci. 2014;54:199-210 pubmed publisher
  131. Sareen D, Gowing G, Sahabian A, Staggenborg K, Paradis R, Avalos P, et al. Human induced pluripotent stem cells are a novel source of neural progenitor cells (iNPCs) that migrate and integrate in the rodent spinal cord. J Comp Neurol. 2014;522:2707-28 pubmed publisher
  132. Macdonald C, Unsworth C, Graham E. Enrichment of differentiated hNT neurons and subsequent analysis using flow-cytometry and xCELLigence sensing. J Neurosci Methods. 2014;227:47-56 pubmed publisher
  133. Ono T, Suzuki Y, Kato Y, Fujita R, Araki T, Yamashita T, et al. A single-cell and feeder-free culture system for monkey embryonic stem cells. PLoS ONE. 2014;9:e88346 pubmed publisher
  134. Sun F, Zhou K, Wang S, Liang P, Zhu M, Qiu J. Expression patterns of atrial natriuretic peptide and its receptors within the cochlear spiral ganglion of the postnatal rat. Hear Res. 2014;309:103-12 pubmed publisher
  135. Gao X, Zhang J, Zhang J, Zou H, Liu J. Identification of rat respiratory mucosa stem cells and comparison of the early neural differentiation potential with the bone marrow mesenchymal stem cells in vitro. Cell Mol Neurobiol. 2014;34:257-68 pubmed publisher
  136. Nakajima T, Yanagihara M, Nishii H. Temporal and regional patterns of Smad activation in the rat hippocampus following global ischemia. J Neurol Sci. 2014;337:25-37 pubmed publisher
  137. Hu Y, Ru N, Xiao H, Chaturbedi A, Hoa N, Tian X, et al. Tumor-specific chromosome mis-segregation controls cancer plasticity by maintaining tumor heterogeneity. PLoS ONE. 2013;8:e80898 pubmed publisher
  138. Momcilovic O, Liu Q, Swistowski A, Russo Tait T, Zhao Y, Rao M, et al. Genome wide profiling of dopaminergic neurons derived from human embryonic and induced pluripotent stem cells. Stem Cells Dev. 2014;23:406-20 pubmed publisher
  139. Sha L, Wu X, Yao Y, Wen B, Feng J, Sha Z, et al. Notch signaling activation promotes seizure activity in temporal lobe epilepsy. Mol Neurobiol. 2014;49:633-44 pubmed publisher
  140. Tobias I, Brooks C, Teichroeb J, Betts D. Derivation and culture of canine embryonic stem cells. Methods Mol Biol. 2013;1074:69-83 pubmed publisher
  141. Stover A, Brick D, Nethercott H, Banuelos M, Sun L, O Dowd D, et al. Process-based expansion and neural differentiation of human pluripotent stem cells for transplantation and disease modeling. J Neurosci Res. 2013;91:1247-62 pubmed publisher
  142. Shintaku M, Yoneda H, Hirato J, Nagaishi M, Okabe H. Gliosarcoma with ependymal and PNET-like differentiation. Clin Neuropathol. 2013;32:508-14 pubmed publisher
  143. Hou P, Chuang C, Kao C, Chou S, Stone L, Ho H, et al. LHX2 regulates the neural differentiation of human embryonic stem cells via transcriptional modulation of PAX6 and CER1. Nucleic Acids Res. 2013;41:7753-70 pubmed publisher
  144. Yang W, Wang X, Duan C, Lu L, Yang H. Alpha-synuclein overexpression increases phospho-protein phosphatase 2A levels via formation of calmodulin/Src complex. Neurochem Int. 2013;63:180-94 pubmed publisher
  145. Milman P, Woulfe J. Novel variant of neuronal intranuclear rodlet immunoreactive for 40 kDa huntingtin associated protein and ubiquitin in the mouse brain. J Comp Neurol. 2013;521:3832-46 pubmed publisher
  146. Zhou X, Wang H, Burg M, Ferraris J. High NaCl-induced inhibition of PTG contributes to activation of NFAT5 through attenuation of the negative effect of SHP-1. Am J Physiol Renal Physiol. 2013;305:F362-9 pubmed publisher
  147. Liu Q, Pedersen O, Peng J, Couture L, Rao M, Zeng X. Optimizing dopaminergic differentiation of pluripotent stem cells for the manufacture of dopaminergic neurons for transplantation. Cytotherapy. 2013;15:999-1010 pubmed publisher
  148. Kao C, Hsu Y, Liu J, Lee D, Chung Y, Chiu I. The mood stabilizer valproate activates human FGF1 gene promoter through inhibiting HDAC and GSK-3 activities. J Neurochem. 2013;126:4-18 pubmed publisher
  149. Higurashi N, Uchida T, Lossin C, Misumi Y, Okada Y, Akamatsu W, et al. A human Dravet syndrome model from patient induced pluripotent stem cells. Mol Brain. 2013;6:19 pubmed publisher
  150. Sparmann A, Xie Y, Verhoeven E, Vermeulen M, Lancini C, Gargiulo G, et al. The chromodomain helicase Chd4 is required for Polycomb-mediated inhibition of astroglial differentiation. EMBO J. 2013;32:1598-612 pubmed publisher
  151. Ruzicka J, Romanyuk N, Hejcl A, Vetrik M, Hruby M, Cocks G, et al. Treating spinal cord injury in rats with a combination of human fetal neural stem cells and hydrogels modified with serotonin. Acta Neurobiol Exp (Wars). 2013;73:102-15 pubmed
  152. Samaranch L, Salegio E, San Sebastián W, Kells A, Bringas J, Forsayeth J, et al. Strong cortical and spinal cord transduction after AAV7 and AAV9 delivery into the cerebrospinal fluid of nonhuman primates. Hum Gene Ther. 2013;24:526-32 pubmed publisher
  153. Shim J, Lee T, Shin D. Enrichment and characterization of human dermal stem/progenitor cells by intracellular granularity. Stem Cells Dev. 2013;22:1264-74 pubmed publisher
  154. Xu J, Nonogaki M, Madhira R, Ma H, Hermanson O, Kioussi C, et al. Population-specific regulation of Chmp2b by Lbx1 during onset of synaptogenesis in lateral association interneurons. PLoS ONE. 2012;7:e48573 pubmed publisher
  155. Liu Q, Spusta S, Mi R, Lassiter R, Stark M, Hoke A, et al. Human neural crest stem cells derived from human ESCs and induced pluripotent stem cells: induction, maintenance, and differentiation into functional schwann cells. Stem Cells Transl Med. 2012;1:266-78 pubmed publisher
  156. Walton R, Parmentier T, Wolfe J. Postnatal neural precursor cell regions in the rostral subventricular zone, hippocampal subgranular zone and cerebellum of the dog (Canis lupus familiaris). Histochem Cell Biol. 2013;139:415-29 pubmed publisher
  157. Putkhao K, Kocerha J, Cho I, Yang J, Parnpai R, Chan A. Pathogenic cellular phenotypes are germline transmissible in a transgenic primate model of Huntington's disease. Stem Cells Dev. 2013;22:1198-205 pubmed publisher
  158. Liu Y, Chen Y, Lu X, Wang Y, Duan Y, Cheng C, et al. SCYL1BP1 modulates neurite outgrowth and regeneration by regulating the Mdm2/p53 pathway. Mol Biol Cell. 2012;23:4506-14 pubmed publisher
  159. Espana A, Clotman F. Onecut transcription factors are required for the second phase of development of the A13 dopaminergic nucleus in the mouse. J Comp Neurol. 2012;520:1424-41 pubmed publisher
  160. Yun Hong Y, Chih Fan C, Chia Wei C, Yen Chung C. A study of the spatial protein organization of the postsynaptic density isolated from porcine cerebral cortex and cerebellum. Mol Cell Proteomics. 2011;10:M110.007138 pubmed publisher
  161. Sawamoto K, Hirota Y, Alfaro Cervello C, Soriano Navarro M, He X, Hayakawa Yano Y, et al. Cellular composition and organization of the subventricular zone and rostral migratory stream in the adult and neonatal common marmoset brain. J Comp Neurol. 2011;519:690-713 pubmed publisher
  162. Miller A, Treloar H, Greer C. Composition of the migratory mass during development of the olfactory nerve. J Comp Neurol. 2010;518:4825-41 pubmed publisher
  163. Leonard B, Mastroeni D, Grover A, Liu Q, Yang K, Gao M, et al. Subventricular zone neural progenitors from rapid brain autopsies of elderly subjects with and without neurodegenerative disease. J Comp Neurol. 2009;515:269-94 pubmed publisher
  164. Furmanski O, Gajavelli S, Lee J, Collado M, Jergova S, Sagen J. Combined extrinsic and intrinsic manipulations exert complementary neuronal enrichment in embryonic rat neural precursor cultures: an in vitro and in vivo analysis. J Comp Neurol. 2009;515:56-71 pubmed publisher
  165. Komitova M, Zhu X, Serwanski D, Nishiyama A. NG2 cells are distinct from neurogenic cells in the postnatal mouse subventricular zone. J Comp Neurol. 2009;512:702-16 pubmed publisher
  166. Yu T, Fotaki V, Mason J, Price D. Analysis of early ventral telencephalic defects in mice lacking functional Gli3 protein. J Comp Neurol. 2009;512:613-27 pubmed publisher
  167. Kawano J, Tanizawa Y, Shinoda K. Wolfram syndrome 1 (Wfs1) gene expression in the normal mouse visual system. J Comp Neurol. 2008;510:1-23 pubmed publisher
  168. Berglöf E, af Bjerkén S, Stromberg I. Glial influence on nerve fiber formation from rat ventral mesencephalic organotypic tissue cultures. J Comp Neurol. 2007;501:431-42 pubmed