This is a Validated Antibody Database (VAD) review about chicken ACTG1, based on 128 published articles (read how Labome selects the articles), using ACTG1 antibody in all methods. It is aimed to help Labome visitors find the most suited ACTG1 antibody. Please note the number of articles fluctuates since newly identified citations are added and citations for discontinued catalog numbers are removed regularly.
Knockout validation
MilliporeSigma
mouse monoclonal (2-2.1.14.17)
  • immunohistochemistry knockout validation; human; 1:2000; loading ...; fig 4b
MilliporeSigma ACTG1 antibody (Sigma-Aldrich, A8481) was used in immunohistochemistry knockout validation on human samples at 1:2000 (fig 4b). Plasmid (2018) ncbi
MilliporeSigma
mouse monoclonal (AC-40)
  • western blot; mouse; 1:4000; loading ...; fig s3-1c
MilliporeSigma ACTG1 antibody (Sigma-Aldrich, A4700) was used in western blot on mouse samples at 1:4000 (fig s3-1c). elife (2020) ncbi
domestic rabbit polyclonal
  • flow cytometry; human; 1:1000; loading ...; fig s5g
MilliporeSigma ACTG1 antibody (Sigma, A2103) was used in flow cytometry on human samples at 1:1000 (fig s5g). Science (2020) ncbi
mouse monoclonal (AC-40)
  • western blot; human; loading ...; fig 1a, 4a, 4b
MilliporeSigma ACTG1 antibody (Sigma-Aldrich, A4700) was used in western blot on human samples (fig 1a, 4a, 4b). JCI Insight (2020) ncbi
domestic rabbit polyclonal
  • western blot; human; fig 1e
MilliporeSigma ACTG1 antibody (Sigma, A2103) was used in western blot on human samples (fig 1e). Transl Oncol (2020) ncbi
mouse monoclonal (2-2.1.14.17)
  • western blot; human; loading ...; fig 3j
MilliporeSigma ACTG1 antibody (Sigma-Aldrich, A8481) was used in western blot on human samples (fig 3j). Autophagy (2019) ncbi
mouse monoclonal (AC-40)
  • western blot; human; 1:100; loading ...; fig 13a
MilliporeSigma ACTG1 antibody (Sigma, A4700) was used in western blot on human samples at 1:100 (fig 13a). elife (2019) ncbi
mouse monoclonal (2-2.1.14.17)
  • western blot; human; loading ...; fig 2d
MilliporeSigma ACTG1 antibody (Sigma-Aldrich, A8481) was used in western blot on human samples (fig 2d). Cell Death Dis (2019) ncbi
mouse monoclonal (2-2.1.14.17)
  • immunohistochemistry knockout validation; human; 1:2000; loading ...; fig 4b
MilliporeSigma ACTG1 antibody (Sigma-Aldrich, A8481) was used in immunohistochemistry knockout validation on human samples at 1:2000 (fig 4b). Plasmid (2018) ncbi
mouse monoclonal (AC-40)
  • western blot; human; loading ...; fig s3a
MilliporeSigma ACTG1 antibody (Sigma, AC-40) was used in western blot on human samples (fig s3a). PLoS Pathog (2018) ncbi
domestic rabbit polyclonal
  • western blot; mouse; 1:8000; loading ...; fig 6t
MilliporeSigma ACTG1 antibody (Sigma, A2103) was used in western blot on mouse samples at 1:8000 (fig 6t). J Exp Med (2018) ncbi
mouse monoclonal (AC-40)
  • immunohistochemistry - paraffin section; pigs ; 1:200; loading ...; fig st1
In order to outline the protocols for antibodies used for immunohistochemical studies, MilliporeSigma ACTG1 antibody (Sigma-Aldrich, A4700) was used in immunohistochemistry - paraffin section on pigs samples at 1:200 (fig st1). J Toxicol Pathol (2017) ncbi
mouse monoclonal (AC-40)
  • western blot; mouse; fig 1A
MilliporeSigma ACTG1 antibody (Sigma-Aldrich, A4700) was used in western blot on mouse samples (fig 1A). Exp Cell Res (2016) ncbi
mouse monoclonal (AC-40)
  • immunocytochemistry; mouse; 1:100; fig 6
MilliporeSigma ACTG1 antibody (Sigma, A4700) was used in immunocytochemistry on mouse samples at 1:100 (fig 6). Sci Rep (2016) ncbi
mouse monoclonal (2-2.1.14.17)
  • western blot; human; 1:1000; fig 4
MilliporeSigma ACTG1 antibody (Sigma, A8481) was used in western blot on human samples at 1:1000 (fig 4). Oncol Lett (2016) ncbi
mouse monoclonal (AC-40)
  • western blot; human; fig 1
MilliporeSigma ACTG1 antibody (Sigma, A4700) was used in western blot on human samples (fig 1). Biosci Rep (2016) ncbi
mouse monoclonal (AC-40)
  • western blot; human; fig 6
MilliporeSigma ACTG1 antibody (Sigma, A4700) was used in western blot on human samples (fig 6). elife (2016) ncbi
domestic rabbit polyclonal
  • western blot; mouse; 1:1000; fig 6
MilliporeSigma ACTG1 antibody (Sigma, A2103) was used in western blot on mouse samples at 1:1000 (fig 6). PLoS Pathog (2016) ncbi
mouse monoclonal (AC-40)
  • immunohistochemistry; human; fig 4
In order to study the human corneal endothelial cell via a 3D map, MilliporeSigma ACTG1 antibody (Sigma, A4700) was used in immunohistochemistry on human samples (fig 4). Sci Rep (2016) ncbi
mouse monoclonal (AC-40)
  • western blot; human; 1:2000; fig 3
MilliporeSigma ACTG1 antibody (Sigma, AC-40) was used in western blot on human samples at 1:2000 (fig 3). Int J Mol Sci (2016) ncbi
mouse monoclonal (AC-40)
  • western blot; human; 1:5000; fig s1
In order to elucidate initiation of directional invasion via the action of Rap1 GTPase as a tension sensor by applied stretch, MilliporeSigma ACTG1 antibody (Sigma, A4700) was used in western blot on human samples at 1:5000 (fig s1). J Cell Sci (2017) ncbi
mouse monoclonal (AC-40)
  • western blot; mouse; 1:10,000; fig 4
  • western blot; human; 1:10,000; fig 5
In order to study increased viral resistance in humans and not mice by ISG15 deficiency, MilliporeSigma ACTG1 antibody (Sigma-Aldrich, AC-40) was used in western blot on mouse samples at 1:10,000 (fig 4) and in western blot on human samples at 1:10,000 (fig 5). Nat Commun (2016) ncbi
mouse monoclonal (AC-40)
  • western blot; mouse; fig 1
In order to study slow-twitch type 1 muscle fibers and diaphragm assessment in mice overexpressing phospholamban, MilliporeSigma ACTG1 antibody (Sigma, A4700) was used in western blot on mouse samples (fig 1). Brain Behav (2016) ncbi
mouse monoclonal (AC-40)
  • western blot; mouse; 1:1000; fig 3
MilliporeSigma ACTG1 antibody (Sigma Aldrich, AC-40) was used in western blot on mouse samples at 1:1000 (fig 3). Sci Rep (2016) ncbi
domestic rabbit polyclonal
  • western blot; mouse; 1:1000; fig 2
In order to determine inhibition of NLRC4-mediated inflammasome activation and binding to annexin A2 by the tick protein sialostatin L2, MilliporeSigma ACTG1 antibody (Sigma, A2103) was used in western blot on mouse samples at 1:1000 (fig 2). Infect Immun (2016) ncbi
mouse monoclonal (AC-40)
  • western blot; human; fig 3
MilliporeSigma ACTG1 antibody (Sigma, A4700) was used in western blot on human samples (fig 3). Endocrinology (2016) ncbi
mouse monoclonal (AC-40)
  • western blot; human; fig 6
MilliporeSigma ACTG1 antibody (Sigma, A4700) was used in western blot on human samples (fig 6). Oncotarget (2016) ncbi
mouse monoclonal (AC-40)
  • western blot; human; fig 6
In order to characterize multiple molecularly defined cancer indications by studying ROS1, ALK inhibitor, Entrectinib, a Pan-TRK activity, MilliporeSigma ACTG1 antibody (Sigma, A4700) was used in western blot on human samples (fig 6). Mol Cancer Ther (2016) ncbi
mouse monoclonal (AC-40)
  • western blot; human; 1:1000; fig 1
MilliporeSigma ACTG1 antibody (Sigma, A-4700) was used in western blot on human samples at 1:1000 (fig 1). PLoS ONE (2016) ncbi
mouse monoclonal (AC-40)
  • other; human; loading ...; fig st1
In order to use size exclusion chromatography-microsphere-based affinity proteomics to study clinical samples obtained from pediatric acute leukemia patients, MilliporeSigma ACTG1 antibody (SIGMA, AC-40) was used in other on human samples (fig st1). Mol Cell Proteomics (2016) ncbi
mouse monoclonal (AC-40)
  • western blot; human; fig 4
MilliporeSigma ACTG1 antibody (Sigma Aldrich, A4700) was used in western blot on human samples (fig 4). Oncotarget (2016) ncbi
mouse monoclonal (AC-40)
  • western blot; human; fig 3
MilliporeSigma ACTG1 antibody (Sigma, AC40) was used in western blot on human samples (fig 3). PLoS Pathog (2016) ncbi
mouse monoclonal (AC-40)
  • western blot; human; fig 1a
MilliporeSigma ACTG1 antibody (Sigma Aldrich, ac-40) was used in western blot on human samples (fig 1a). Mol Oncol (2016) ncbi
mouse monoclonal (AC-40)
  • immunocytochemistry; rat; fig 2
In order to study Arf6 and how it regulates cylcing of releasable synaptic vesicles at the hippocampal synapse, MilliporeSigma ACTG1 antibody (Sigma, A4700) was used in immunocytochemistry on rat samples (fig 2). elife (2016) ncbi
mouse monoclonal (AC-40)
  • western blot; human; 1:5000
In order to determine the mechanisms of resistance to the pan-HER family inhibitor AZD8931, MilliporeSigma ACTG1 antibody (Sigma, A4700) was used in western blot on human samples at 1:5000. Dis Model Mech (2016) ncbi
domestic rabbit polyclonal
  • western blot; human; tbl 1
MilliporeSigma ACTG1 antibody (Sigma, A2103) was used in western blot on human samples (tbl 1). Redox Biol (2016) ncbi
mouse monoclonal (AC-40)
  • western blot; zebrafish ; fig 2
In order to analyze Danio rerio for calsequestrins in cardiac and skeletal muscle, MilliporeSigma ACTG1 antibody (Sigma, A4700) was used in western blot on zebrafish samples (fig 2). J Muscle Res Cell Motil (2016) ncbi
domestic rabbit polyclonal
MilliporeSigma ACTG1 antibody (Sigma-Aldrich, A2103) was used . Sci Rep (2015) ncbi
mouse monoclonal (AC-40)
  • western blot; mouse; loading ...; fig 7
MilliporeSigma ACTG1 antibody (Sigma, AC-40) was used in western blot on mouse samples (fig 7). Am J Physiol Renal Physiol (2016) ncbi
mouse monoclonal (AC-40)
  • western blot; human; fig 3
MilliporeSigma ACTG1 antibody (Sigma, A4700) was used in western blot on human samples (fig 3). BMC Cancer (2015) ncbi
mouse monoclonal (AC-40)
  • western blot; human; 1:1000; fig 4
MilliporeSigma ACTG1 antibody (Sigma, A4700) was used in western blot on human samples at 1:1000 (fig 4). J Cell Sci (2015) ncbi
mouse monoclonal (AC-40)
  • western blot; mouse; fig 4
In order to study the role of autophagy during pancreatitis, MilliporeSigma ACTG1 antibody (Sigma, A4700) was used in western blot on mouse samples (fig 4). Proc Natl Acad Sci U S A (2015) ncbi
mouse monoclonal (AC-40)
  • western blot; mouse; 1:2000; fig 1b
MilliporeSigma ACTG1 antibody (Sigma, A4700) was used in western blot on mouse samples at 1:2000 (fig 1b). Nat Commun (2015) ncbi
mouse monoclonal (AC-40)
  • western blot; mouse; fig s7
In order to study hepatocellular carcinoma and ectopic lymphoid structures function as microniches for tumor progenitor cells, MilliporeSigma ACTG1 antibody (Sigma-Aldrich, AC-40) was used in western blot on mouse samples (fig s7). Nat Immunol (2015) ncbi
mouse monoclonal (AC-40)
  • western blot; mouse
In order to test if bisecting GlcNAc would stabilize BACE1 protein upon oxidative stress, MilliporeSigma ACTG1 antibody (Sigma, A4700) was used in western blot on mouse samples . Biochem J (2016) ncbi
mouse monoclonal (AC-40)
  • western blot; mouse; 1:2500; fig 2c
In order to research Alzheimer's disease brain and neuronal uptake and propagation of a rare phosphorylated high-molecular-weight tau, MilliporeSigma ACTG1 antibody (Sigma-Aldrich, A4700) was used in western blot on mouse samples at 1:2500 (fig 2c). Nat Commun (2015) ncbi
mouse monoclonal (AC-40)
  • western blot; human; 1:10,000; fig s2b
In order to elucidate how EGFR mutations contribute to glioblastoma development, MilliporeSigma ACTG1 antibody (Sigma, A4700) was used in western blot on human samples at 1:10,000 (fig s2b). Mol Cell (2015) ncbi
mouse monoclonal (AC-40)
  • western blot; human; fig 2
MilliporeSigma ACTG1 antibody (Sigma-Aldrich, A4700) was used in western blot on human samples (fig 2). Oncogene (2016) ncbi
mouse monoclonal (AC-40)
  • western blot; human; 1:10,000; fig 1
MilliporeSigma ACTG1 antibody (Sigma, 4700) was used in western blot on human samples at 1:10,000 (fig 1). Biomed Res Int (2015) ncbi
mouse monoclonal (AC-40)
  • western blot; Xenopus laevis; 1:800; fig 3
MilliporeSigma ACTG1 antibody (Sigma, Ac-40) was used in western blot on Xenopus laevis samples at 1:800 (fig 3). Protoplasma (2016) ncbi
mouse monoclonal (AC-40)
  • western blot; human; fig 1b
In order to summarize HSV-1 infection and the SUMO2 proteome, MilliporeSigma ACTG1 antibody (Sigma, AC-40) was used in western blot on human samples (fig 1b). PLoS Pathog (2015) ncbi
mouse monoclonal (AC-40)
  • western blot; hamsters; 1:2000; fig 3
MilliporeSigma ACTG1 antibody (Sigma, A4700) was used in western blot on hamsters samples at 1:2000 (fig 3). Nucleic Acids Res (2015) ncbi
mouse monoclonal (AC-40)
  • western blot; human; 1:1000; fig s5
MilliporeSigma ACTG1 antibody (Sigma-Aldrich, AC-40) was used in western blot on human samples at 1:1000 (fig s5). PLoS ONE (2015) ncbi
mouse monoclonal (AC-40)
  • western blot; pigs ; 1:5000; fig 3
MilliporeSigma ACTG1 antibody (Sigma, A4700) was used in western blot on pigs samples at 1:5000 (fig 3). Sci Rep (2015) ncbi
mouse monoclonal (AC-40)
  • western blot; human; 1:5000; fig 4
In order to identify microtubule-associated proteins that interact with ch-TOG to regulate bipolar spindle assembly in human cells, MilliporeSigma ACTG1 antibody (Sigma, AC40) was used in western blot on human samples at 1:5000 (fig 4). Sci Rep (2015) ncbi
mouse monoclonal (AC-40)
  • western blot; rat; 1:2000; fig 2
MilliporeSigma ACTG1 antibody (Sigma, A 4700) was used in western blot on rat samples at 1:2000 (fig 2). J Neurosci (2015) ncbi
mouse monoclonal (AC-40)
  • western blot; human; 1:2000; fig 3
MilliporeSigma ACTG1 antibody (Sigma-Aldrich, A4700) was used in western blot on human samples at 1:2000 (fig 3). Cell Death Dis (2015) ncbi
mouse monoclonal (AC-40)
  • western blot; mouse
In order to determine the strain- and sex-dependent glomerular extracellular matrix signatures, MilliporeSigma ACTG1 antibody (Sigma-Aldrich-Aldrich, AC-40) was used in western blot on mouse samples . J Am Soc Nephrol (2015) ncbi
mouse monoclonal (AC-40)
  • western blot; human; fig s2
MilliporeSigma ACTG1 antibody (Sigma, A4700) was used in western blot on human samples (fig s2). Nature (2015) ncbi
mouse monoclonal (AC-40)
  • western blot; rat; 1:5000; fig 3
  • western blot; African green monkey; 1:5000; fig s8
In order to study the roles of miR-26a and miR-384-5p in long-term potentiation, MilliporeSigma ACTG1 antibody (Sigma-Aldrich, A4700) was used in western blot on rat samples at 1:5000 (fig 3) and in western blot on African green monkey samples at 1:5000 (fig s8). Nat Commun (2015) ncbi
mouse monoclonal (AC-40)
  • western blot; human; 1:500; fig 8
In order to investigate how PINK1 recruits Parkin, MilliporeSigma ACTG1 antibody (Sigma-Aldrich, AC-40) was used in western blot on human samples at 1:500 (fig 8). J Cell Biol (2015) ncbi
mouse monoclonal (AC-40)
  • western blot; mouse; fig 2
MilliporeSigma ACTG1 antibody (Sigma, A4700) was used in western blot on mouse samples (fig 2). Mol Biol Cell (2015) ncbi
domestic rabbit polyclonal
MilliporeSigma ACTG1 antibody (Sigma-Aldrich, A2103) was used . PLoS ONE (2015) ncbi
mouse monoclonal (AC-40)
  • western blot; mouse; 1:5000
MilliporeSigma ACTG1 antibody (Sigma-Aldrich, A4700) was used in western blot on mouse samples at 1:5000. PLoS ONE (2015) ncbi
mouse monoclonal (AC-40)
  • western blot; rat
MilliporeSigma ACTG1 antibody (Sigma Chemical, A4700) was used in western blot on rat samples . FEBS Lett (2015) ncbi
mouse monoclonal (AC-40)
  • western blot; human; fig s3
MilliporeSigma ACTG1 antibody (Sigma, AC-40) was used in western blot on human samples (fig s3). Aging Cell (2015) ncbi
mouse monoclonal (AC-40)
  • western blot; rat; 1:1000
MilliporeSigma ACTG1 antibody (Sigma-Aldrich, A4700) was used in western blot on rat samples at 1:1000. Int J Dev Neurosci (2015) ncbi
mouse monoclonal (AC-40)
  • western blot; human
MilliporeSigma ACTG1 antibody (Sigma, AC-40) was used in western blot on human samples . Oncotarget (2014) ncbi
mouse monoclonal (AC-40)
  • western blot; mouse; 1:10000
In order to study the role of dysbindin in the regulation of dendritic spine dynamics, MilliporeSigma ACTG1 antibody (Sigma-Aldrich, A4700) was used in western blot on mouse samples at 1:10000. J Neurosci (2014) ncbi
mouse monoclonal (AC-40)
  • western blot; mouse; 1:20000
In order to examine the involvement of calreticulin in the neurodegeration in ALS model mice, MilliporeSigma ACTG1 antibody (Sigma-Aldrich, AC40) was used in western blot on mouse samples at 1:20000. Neurobiol Dis (2015) ncbi
mouse monoclonal (AC-40)
  • western blot; rat; 1:2000
In order to investigate the effect of early postnatal overfeeding on insulin signaling in the ventral tegmental area, MilliporeSigma ACTG1 antibody (Sigma, A4700) was used in western blot on rat samples at 1:2000. Behav Brain Res (2015) ncbi
mouse monoclonal (AC-40)
  • western blot; domestic goat; 1:1000; fig 3
MilliporeSigma ACTG1 antibody (Sigma, A4700) was used in western blot on domestic goat samples at 1:1000 (fig 3). PLoS ONE (2014) ncbi
mouse monoclonal (AC-40)
  • western blot; human; fig 6
MilliporeSigma ACTG1 antibody (Sigma, AC40) was used in western blot on human samples (fig 6). Oncogene (2015) ncbi
mouse monoclonal (AC-40)
  • western blot; human
In order to study the effect of bluetongue virus on type I interferon response, MilliporeSigma ACTG1 antibody (Sigma-Aldrich, AC40) was used in western blot on human samples . J Virol (2014) ncbi
mouse monoclonal (AC-40)
  • western blot; mouse; 1:10,000
MilliporeSigma ACTG1 antibody (Sigma, A4700) was used in western blot on mouse samples at 1:10,000. Eur Neuropsychopharmacol (2014) ncbi
mouse monoclonal (AC-40)
  • western blot; mouse
In order to show that Cdk5 phosphorylation of SynI fine tunes the recruitment of synaptic vesicles to the active recycling pool and contributes to the Cdk5-mediated homeostatic responses, MilliporeSigma ACTG1 antibody (Sigma-Aldrich, A4700) was used in western blot on mouse samples . J Neurosci (2014) ncbi
mouse monoclonal (AC-40)
  • western blot; mouse; fig 4
MilliporeSigma ACTG1 antibody (Sigma Aldrich, #AC40) was used in western blot on mouse samples (fig 4). Cancer Med (2014) ncbi
mouse monoclonal (AC-40)
  • western blot; human; 1:5000
MilliporeSigma ACTG1 antibody (Sigma, A4700) was used in western blot on human samples at 1:5000. Biochim Biophys Acta (2014) ncbi
mouse monoclonal (AC-40)
  • immunoprecipitation; human
  • immunocytochemistry; human
  • western blot; human
MilliporeSigma ACTG1 antibody (Sigma-Aldrich, AC40) was used in immunoprecipitation on human samples , in immunocytochemistry on human samples and in western blot on human samples . Mol Cells (2013) ncbi
mouse monoclonal (AC-40)
  • western blot; mouse; 1:500
MilliporeSigma ACTG1 antibody (Sigma-Aldrich, A4700) was used in western blot on mouse samples at 1:500. J Neurosci (2013) ncbi
mouse monoclonal (AC-40)
  • western blot; human; 1:3000
In order to study BRAF mutations and RET/PTC rearrangements in papillary thyroid carcinomas, MilliporeSigma ACTG1 antibody (Sigma-Aldrich, A4700) was used in western blot on human samples at 1:3000. Head Neck (2014) ncbi
mouse monoclonal (AC-40)
  • western blot; rat
In order to examine the roles of SAP102 in cortical synapse development, MilliporeSigma ACTG1 antibody (Sigma, AC40) was used in western blot on rat samples . J Neurosci (2013) ncbi
mouse monoclonal (AC-40)
  • western blot; zebrafish ; 1:1000
In order to study the role of MANF during dopaminergic neuron development in larval zebrafish, MilliporeSigma ACTG1 antibody (Sigma, AC40) was used in western blot on zebrafish samples at 1:1000. Dev Biol (2012) ncbi
mouse monoclonal (AC-40)
  • western blot; rat; 1:4000
MilliporeSigma ACTG1 antibody (Sigma, A4700) was used in western blot on rat samples at 1:4000. J Histochem Cytochem (2012) ncbi
mouse monoclonal (AC-40)
  • western blot; human; 1:10,000; fig s2
MilliporeSigma ACTG1 antibody (Sigma, A4700) was used in western blot on human samples at 1:10,000 (fig s2). PLoS ONE (2010) ncbi
Invitrogen
mouse monoclonal (ACTN05 (C4))
  • western blot; human; loading ...
Invitrogen ACTG1 antibody (Thermo Fisher, MA5-11869) was used in western blot on human samples . PLoS ONE (2020) ncbi
mouse monoclonal (ACTN05 (C4))
  • western blot; human; 1:2000; loading ...; fig 1b
Invitrogen ACTG1 antibody (ThermoFisher, MA5-11869) was used in western blot on human samples at 1:2000 (fig 1b). Nat Commun (2019) ncbi
mouse monoclonal (ACTN05 (C4))
  • western blot; human; 1:4000; loading ...; fig 1b
Invitrogen ACTG1 antibody (Thermo fisher, MA5-11869) was used in western blot on human samples at 1:4000 (fig 1b). Nature (2019) ncbi
mouse monoclonal (ACTN05 (C4))
  • western blot; human; 1:50; loading ...; fig 2d
Invitrogen ACTG1 antibody (Thermo, MA5-11869) was used in western blot on human samples at 1:50 (fig 2d). Nat Commun (2018) ncbi
mouse monoclonal (ACTN05 (C4))
  • western blot; human; 1:1000; loading ...; fig 2e
In order to study the involvement of RNase III nucleases in antiviral systems, Invitrogen ACTG1 antibody (Thermo Fisher, MS-1295-P) was used in western blot on human samples at 1:1000 (fig 2e). Nature (2017) ncbi
mouse monoclonal (ACTN05 (C4))
  • western blot; zebrafish ; 1:5000; loading ...; fig s2e
In order to propose that neurodevelopmental disorders and brain tumors may arise from changes in oncogenes, Invitrogen ACTG1 antibody (Neomarkers, ACTN05) was used in western blot on zebrafish samples at 1:5000 (fig s2e). Dis Model Mech (2017) ncbi
mouse monoclonal (ACTN05 (C4))
  • western blot; human; 1:100; loading ...; fig 1b
In order to find that TrpC5 regulates differentiation in colorectal cancer, Invitrogen ACTG1 antibody (Invitrogen, MA5-11869) was used in western blot on human samples at 1:100 (fig 1b). Clin Sci (Lond) (2017) ncbi
mouse monoclonal (ACTN05 (C4))
  • western blot; human; loading ...; fig 5g
In order to investigate the alternative splicing of E-cadherin mRNA, Invitrogen ACTG1 antibody (Neomarkers, ACTN05) was used in western blot on human samples (fig 5g). J Cell Physiol (2017) ncbi
mouse monoclonal (ACTN05 (C4))
  • western blot; human; 1:300; fig 2
In order to study CD133+ subpopulations in pancreatic cancer, Invitrogen ACTG1 antibody (Thermo Fisher Scientific, Ab-5) was used in western blot on human samples at 1:300 (fig 2). Oncol Lett (2016) ncbi
mouse monoclonal (ACTN05 (C4))
  • western blot; human; fig 1
In order to study how PARylation regulates Top1 nuclear dynamics, Invitrogen ACTG1 antibody (Neo Markers, ACTN05) was used in western blot on human samples (fig 1). Nucleic Acids Res (2016) ncbi
mouse monoclonal (ACTN05 (C4))
  • western blot; mouse; fig 3b
In order to screen for deubiquitinase inhibitors that prevent infection of macrophages by intracellular pathogens, Invitrogen ACTG1 antibody (Thermo Scientific, ACTN05) was used in western blot on mouse samples (fig 3b). Antimicrob Agents Chemother (2016) ncbi
mouse monoclonal (ACTN05 (C4))
  • western blot; human; 1:3000; fig 3
  • western blot; mouse; 1:3000; fig 1
In order to investigate the PTHrP-cAMP-CREB1 axis in osteosarcoma, Invitrogen ACTG1 antibody (Thermo Scientific, Ab-5) was used in western blot on human samples at 1:3000 (fig 3) and in western blot on mouse samples at 1:3000 (fig 1). elife (2016) ncbi
mouse monoclonal (ACTN05 (C4))
  • western blot; human; fig 1
In order to study attenuation of AKT signaling to promote internal ribosome entry site-dependent translation and expression of c-MYC by the human papillomavirus 16 E7 oncoprotein, Invitrogen ACTG1 antibody (Thermo Scientific, MS-1295-P1) was used in western blot on human samples (fig 1). J Virol (2016) ncbi
mouse monoclonal (ACTN05 (C4))
  • western blot; dogs; fig 8
In order to study how the role of increased caveolin-1 can help with repair to intervertebral disc degeneration, Invitrogen ACTG1 antibody (Neomarkers, pan Ab-5) was used in western blot on dogs samples (fig 8). Arthritis Res Ther (2016) ncbi
mouse monoclonal (ACTN05 (C4))
  • western blot; human; 1:10,000; fig 3
In order to investigate how redox reactions affect treatment of chronic lymphocytic leukemia, Invitrogen ACTG1 antibody (Pierce Biotechnology, MA5-11869) was used in western blot on human samples at 1:10,000 (fig 3). Mol Med Rep (2015) ncbi
mouse monoclonal (ACTN05 (C4))
  • western blot; human
In order to study the role of ADAM17 in cellular senescence and senescence secretome, Invitrogen ACTG1 antibody (Thermo Scientific, MA5-11869) was used in western blot on human samples . Breast Cancer Res (2015) ncbi
mouse monoclonal (ACTN05 (C4))
  • western blot; fruit fly ; 1:4000; fig 9
In order to suggest that CDK8-CycC links nutrient intake to EcR activity and Drosophila development, Invitrogen ACTG1 antibody (Thermo Scientific, MA5-11869)) was used in western blot on fruit fly samples at 1:4000 (fig 9). PLoS Biol (2015) ncbi
mouse monoclonal (ACTN05 (C4))
  • western blot; mouse; 1:500; fig 5a
In order to assess the anti-fatigue effects of Myelophil, Invitrogen ACTG1 antibody (Thermo Fisher, MA5-11869) was used in western blot on mouse samples at 1:500 (fig 5a). Eur J Pharmacol (2015) ncbi
mouse monoclonal (ACTN05 (C4))
  • western blot; human
In order to discuss using serum CSE1L as a biomarker for assessing the efficacy of cancer therapy, Invitrogen ACTG1 antibody (Lab Vision, Ab-5) was used in western blot on human samples . J Transl Med (2015) ncbi
mouse monoclonal (ACTN05 (C4))
  • western blot; mouse; 1:500
In order to evaluate the anti-fatigue effects of Gongjin-Dan in a chronic forced exercise mouse model, Invitrogen ACTG1 antibody (Thermo Fisher, MA5-11869) was used in western blot on mouse samples at 1:500. J Ethnopharmacol (2015) ncbi
mouse monoclonal (ACTN05 (C4))
  • western blot; mouse
In order to evaluate the protective effect of dietary cis9, trans11 conjugated linoleic acid on gliadin-induced enteropathy, Invitrogen ACTG1 antibody (Thermo Scientific, ACTN05) was used in western blot on mouse samples . Eur J Nutr (2016) ncbi
mouse monoclonal (ACTN05 (C4))
  • western blot; human; 1:10,000; fig 5
In order to show that sustained Zeb2 expression initiates T-cell leukemia, Invitrogen ACTG1 antibody (Molecular probes, C4) was used in western blot on human samples at 1:10,000 (fig 5). Nat Commun (2015) ncbi
mouse monoclonal (ACTN05 (C4))
  • western blot; mouse; fig 1,2,3,4,5,6
In order to determine the role of progesterone receptor activation in increasing protein turnover and downregulation of GATA3 transcriptional repression which promotes breast tumor growth, Invitrogen ACTG1 antibody (neomarkers, ACTN05) was used in western blot on mouse samples (fig 1,2,3,4,5,6). Breast Cancer Res (2014) ncbi
mouse monoclonal (ACTN05 (C4))
  • western blot; human
In order to examine the effects of miR-23a in cell death, Invitrogen ACTG1 antibody (NeoMarkers, ACTN05) was used in western blot on human samples . Cell Death Dis (2014) ncbi
mouse monoclonal (ACTN05 (C4))
  • western blot; fruit fly ; 1:4000
In order to study the role of Histone lysine demethylase 2 (KDM2) in Drosophila development, Invitrogen ACTG1 antibody (Thermo Scientific, MA5-11869) was used in western blot on fruit fly samples at 1:4000. Mech Dev (2014) ncbi
mouse monoclonal (ACTN05 (C4))
  • western blot; dogs; 1:2000
In order to analyze divergent LEF1 expression in ligand-independent canonical Wnt activity in canine mammary tumor cell lines, Invitrogen ACTG1 antibody (Thermo, MS-1295-P1) was used in western blot on dogs samples at 1:2000. PLoS ONE (2014) ncbi
mouse monoclonal (ACTN05 (C4))
In order to investigate the role of Wdr1 in actin dynamics, Invitrogen ACTG1 antibody (Thermo Fisher Scientific, MS-1295-P1ABX) was used . Am J Pathol (2014) ncbi
mouse monoclonal (ACTN05 (C4))
  • western blot; mouse; 1:1000; fig 5
In order to investigate the relationship between vitamin D and parathyroid hormone signaling during skeletal development, Invitrogen ACTG1 antibody (NeoMarkers, MS-1295-P1) was used in western blot on mouse samples at 1:1000 (fig 5). J Cell Physiol (2014) ncbi
mouse monoclonal (ACTN05 (C4))
  • western blot; mouse; fig 1
In order to investigate the role of caspase-2 in programed cell death during infection with Brucella abortus, Invitrogen ACTG1 antibody (Thermo Scientific, MS1295P1) was used in western blot on mouse samples (fig 1). Front Cell Infect Microbiol (2013) ncbi
mouse monoclonal (ACTN05 (C4))
  • western blot; mouse
In order to test if enterically targeted rapamycin prevents neoplasia and extends survival of cancer prone Apc(Min/+) mice, Invitrogen ACTG1 antibody (Thermo Fisher, ACTN05) was used in western blot on mouse samples . Cancer Prev Res (Phila) (2014) ncbi
mouse monoclonal (HHF35)
  • immunohistochemistry; human; 1:100; tbl 1
In order to report on a case of plexiform fibromyxoma of the stomach, Invitrogen ACTG1 antibody (Neomarker, HHF-35) was used in immunohistochemistry on human samples at 1:100 (tbl 1). Int J Surg Pathol (2014) ncbi
mouse monoclonal (ACTN05 (C4))
  • western blot; human; fig 3
In order to report that CSE1L regulates the association of alpha-tubulin with beta-tubulin and promotes migration of MCF-7 breast cancer cells, Invitrogen ACTG1 antibody (Lab Vision, Ab-5) was used in western blot on human samples (fig 3). Exp Cell Res (2010) ncbi
mouse monoclonal (ACTN05 (C4))
  • western blot; mouse; fig 6
In order to characterize a mouse model of endocrine-resistant breast cancer, Invitrogen ACTG1 antibody (Neomarkers, ACTN05) was used in western blot on mouse samples (fig 6). PLoS ONE (2010) ncbi
mouse monoclonal (ACTN05 (C4))
  • western blot; human; fig 8
In order to report on two cases of classic and desmoplastic medulloblastoma and the characterization of two new cell lines, Invitrogen ACTG1 antibody (Neomarkers, ACTN05) was used in western blot on human samples (fig 8). Neuropathology (2009) ncbi
mouse monoclonal (ACTN05 (C4))
  • western blot; human; fig 4
In order to ascertain the role of epithelial cadherin in gamete interaction, Invitrogen ACTG1 antibody (Neomarkers, ACTN05) was used in western blot on human samples (fig 4). Mol Hum Reprod (2008) ncbi
mouse monoclonal (ACTN05 (C4))
  • western blot; human; 1:1000
  • western blot; rat; 1:1000
In order to compare hippocampi from temporal lobe epilepsy patients with those from non-epileptic patients, Invitrogen ACTG1 antibody (LabVision, ACTN05) was used in western blot on human samples at 1:1000 and in western blot on rat samples at 1:1000. Brain (2007) ncbi
Santa Cruz Biotechnology
mouse monoclonal (B4)
  • immunohistochemistry; mouse; 1:100; loading ...; fig s1b
  • western blot; mouse; 1:1000; loading ...; fig 6c
Santa Cruz Biotechnology ACTG1 antibody (Santa Cruz Biotechnology, sc-53142) was used in immunohistochemistry on mouse samples at 1:100 (fig s1b) and in western blot on mouse samples at 1:1000 (fig 6c). J Clin Invest (2019) ncbi
mouse monoclonal (B4)
  • western blot; human; 1:2500; loading ...; fig 3a
Santa Cruz Biotechnology ACTG1 antibody (Santa Cruz Biotechnology, Inc, sc-53142) was used in western blot on human samples at 1:2500 (fig 3a). Mol Med Rep (2018) ncbi
mouse monoclonal (B4)
  • western blot; human; 1:1000; loading ...; fig 3a
Santa Cruz Biotechnology ACTG1 antibody (Santa Cruz, sc-53142) was used in western blot on human samples at 1:1000 (fig 3a). Mol Med Rep (2017) ncbi
mouse monoclonal (B4)
  • immunohistochemistry - paraffin section; mouse; fig 8
Santa Cruz Biotechnology ACTG1 antibody (Santa Cruz, sc53142) was used in immunohistochemistry - paraffin section on mouse samples (fig 8). Sci Rep (2016) ncbi
mouse monoclonal (B4)
  • immunohistochemistry - paraffin section; rat; 1:100; fig 2
Santa Cruz Biotechnology ACTG1 antibody (Santa Cruz Biotechnology, sc-53142) was used in immunohistochemistry - paraffin section on rat samples at 1:100 (fig 2). Mol Med Rep (2016) ncbi
mouse monoclonal (B4)
  • western blot; human; fig 6
Santa Cruz Biotechnology ACTG1 antibody (Santa Cruz, sc-53142) was used in western blot on human samples (fig 6). Oncotarget (2015) ncbi
mouse monoclonal (B4)
  • western blot; human
Santa Cruz Biotechnology ACTG1 antibody (Santa Cruz, sc-53142) was used in western blot on human samples . Mol Cell Endocrinol (2015) ncbi
mouse monoclonal (B4)
  • immunocytochemistry; human
  • western blot; human
Santa Cruz Biotechnology ACTG1 antibody (Santa Cruz, sc-53142) was used in immunocytochemistry on human samples and in western blot on human samples . Cell Cycle (2013) ncbi
Articles Reviewed
  1. Chen A, Santana A, Doudican N, Roudiani N, Laursen K, Therrien J, et al. MAGE-A3 is a prognostic biomarker for poor clinical outcome in cutaneous squamous cell carcinoma with perineural invasion via modulation of cell proliferation. PLoS ONE. 2020;15:e0241551 pubmed publisher
  2. Fomicheva M, Macara I. Genome-wide CRISPR screen identifies noncanonical NF-κB signaling as a regulator of density-dependent proliferation. elife. 2020;9: pubmed publisher
  3. Zatulovskiy E, Zhang S, Berenson D, Topacio B, Skotheim J. Cell growth dilutes the cell cycle inhibitor Rb to trigger cell division. Science. 2020;369:466-471 pubmed publisher
  4. Mallampalli R, Li X, Jang J, Kaminski T, Hoji A, Coon T, et al. Cigarette smoke exposure enhances transforming acidic coiled-coil-containing protein 2 turnover and thereby promotes emphysema. JCI Insight. 2020;5: pubmed publisher
  5. Chen W, Wang Q, Xu X, Saxton B, Tessema M, Leng S, et al. Vasorin/ATIA Promotes Cigarette Smoke-Induced Transformation of Human Bronchial Epithelial Cells by Suppressing Autophagy-Mediated Apoptosis. Transl Oncol. 2020;13:32-41 pubmed publisher
  6. Zhang B, Chen H, Ouyang J, Xie Y, Chen L, Tan Q, et al. SQSTM1-dependent autophagic degradation of PKM2 inhibits the production of mature IL1B/IL-1β and contributes to LIPUS-mediated anti-inflammatory effect. Autophagy. 2019;:1-17 pubmed publisher
  7. Fons N, Sundaram R, Breuer G, Peng S, McLean R, Kalathil A, et al. PPM1D mutations silence NAPRT gene expression and confer NAMPT inhibitor sensitivity in glioma. Nat Commun. 2019;10:3790 pubmed publisher
  8. V gtle T, Sharma S, Mori J, Nagy Z, Semeniak D, Scandola C, et al. Heparan sulfates are critical regulators of the inhibitory megakaryocyte-platelet receptor G6b-B. elife. 2019;8: pubmed publisher
  9. Ni Z, Kuang L, Chen H, Xie Y, Zhang B, Ouyang J, et al. The exosome-like vesicles from osteoarthritic chondrocyte enhanced mature IL-1β production of macrophages and aggravated synovitis in osteoarthritis. Cell Death Dis. 2019;10:522 pubmed publisher
  10. Zhao B, Du F, Xu P, Shu C, Sankaran B, Bell S, et al. A conserved PLPLRT/SD motif of STING mediates the recruitment and activation of TBK1. Nature. 2019;: pubmed publisher
  11. Li B, He J, Lv H, Liu Y, Lv X, Zhang C, et al. c-Abl regulates YAPY357 phosphorylation to activate endothelial atherogenic responses to disturbed flow. J Clin Invest. 2019;129:1167-1179 pubmed publisher
  12. Nagasaki A, Kato Y, Meguro K, Yamagishi A, Nakamura C, Uyeda T. A genome editing vector that enables easy selection and identification of knockout cells. Plasmid. 2018;98:37-44 pubmed publisher
  13. Urata S, Kenyon E, Nayak D, Cubitt B, Kurosaki Y, Yasuda J, et al. BST-2 controls T cell proliferation and exhaustion by shaping the early distribution of a persistent viral infection. PLoS Pathog. 2018;14:e1007172 pubmed publisher
  14. Reichenbach N, Delekate A, Breithausen B, Keppler K, Poll S, Schulte T, et al. P2Y1 receptor blockade normalizes network dysfunction and cognition in an Alzheimer's disease model. J Exp Med. 2018;215:1649-1663 pubmed publisher
  15. Lino Cardenas C, Kessinger C, Cheng Y, MacDonald C, Macgillivray T, Ghoshhajra B, et al. An HDAC9-MALAT1-BRG1 complex mediates smooth muscle dysfunction in thoracic aortic aneurysm. Nat Commun. 2018;9:1009 pubmed publisher
  16. Li T, Zhao J. Knockdown of elF3a inhibits TGF??1?induced extracellular matrix protein expression in keloid fibroblasts. Mol Med Rep. 2018;17:4057-4061 pubmed publisher
  17. Aguado L, Schmid S, May J, Sabin L, Panis M, Blanco Melo D, et al. RNase III nucleases from diverse kingdoms serve as antiviral effectors. Nature. 2017;547:114-117 pubmed publisher
  18. Chen S, Wang Y, Zhang W, Dong M, Zhang J. Sclareolide enhances gemcitabine?induced cell death through mediating the NICD and Gli1 pathways in gemcitabine?resistant human pancreatic cancer. Mol Med Rep. 2017;15:1461-1470 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. Mayrhofer M, Gourain V, Reischl M, Affaticati P, Jenett A, Joly J, et al. A novel brain tumour model in zebrafish reveals the role of YAP activation in MAPK- and PI3K-induced malignant growth. Dis Model Mech. 2017;10:15-28 pubmed publisher
  21. Chen Z, Tang C, Zhu Y, Xie M, He D, Pan Q, et al. TrpC5 regulates differentiation through the Ca2+/Wnt5a signalling pathway in colorectal cancer. Clin Sci (Lond). 2017;131:227-237 pubmed publisher
  22. Matos M, Lapyckyj L, Rosso M, Besso M, Mencucci M, Briggiler C, et al. Identification of a Novel Human E-Cadherin Splice Variant and Assessment of Its Effects Upon EMT-Related Events. J Cell Physiol. 2017;232:1368-1386 pubmed publisher
  23. Zhao G, Zhu P, Renvoisé B, Maldonado Baez L, Park S, Blackstone C. Mammalian knock out cells reveal prominent roles for atlastin GTPases in ER network morphology. Exp Cell Res. 2016;349:32-44 pubmed publisher
  24. Frolikova M, Sebkova N, Ded L, Dvorakova Hortova K. Characterization of CD46 and ?1 integrin dynamics during sperm acrosome reaction. Sci Rep. 2016;6:33714 pubmed publisher
  25. Sousa A, Rei M, Freitas R, Ricardo S, Caffrey T, David L, et al. Effect of MUC1/?-catenin interaction on the tumorigenic capacity of pancreatic CD133+ cells. Oncol Lett. 2016;12:1811-1817 pubmed
  26. Li J, Yang Z, Chen Z, Bao Y, Zhang H, Fang X, et al. ATF3 suppresses ESCC via downregulation of ID1. Oncol Lett. 2016;12:1642-1648 pubmed
  27. Weikel K, Cacicedo J, Ruderman N, Ido Y. Knockdown of GSK3β increases basal autophagy and AMPK signalling in nutrient-laden human aortic endothelial cells. Biosci Rep. 2016;36: pubmed publisher
  28. Bercovich Kinori A, Tai J, Gelbart I, Shitrit A, Ben Moshe S, Drori Y, et al. A systematic view on influenza induced host shutoff. elife. 2016;5: pubmed publisher
  29. Wang X, Shaw D, Hammond H, Sutterwala F, Rayamajhi M, Shirey K, et al. The Prostaglandin E2-EP3 Receptor Axis Regulates Anaplasma phagocytophilum-Mediated NLRC4 Inflammasome Activation. PLoS Pathog. 2016;12:e1005803 pubmed publisher
  30. Das S, Rehman I, Ghosh A, Sengupta S, Majumdar P, Jana B, et al. Poly(ADP-ribose) polymers regulate DNA topoisomerase I (Top1) nuclear dynamics and camptothecin sensitivity in living cells. Nucleic Acids Res. 2016;44:8363-75 pubmed publisher
  31. He Z, Forest F, Gain P, Rageade D, Bernard A, Acquart S, et al. 3D map of the human corneal endothelial cell. Sci Rep. 2016;6:29047 pubmed publisher
  32. Ikeuchi M, Fukumoto Y, Honda T, Kuga T, Saito Y, Yamaguchi N, et al. v-Src Causes Chromosome Bridges in a Caffeine-Sensitive Manner by Generating DNA Damage. Int J Mol Sci. 2016;17: pubmed publisher
  33. Freeman S, Christian S, Austin P, Iu I, Graves M, Huang L, et al. Applied stretch initiates directional invasion through the action of Rap1 GTPase as a tension sensor. J Cell Sci. 2017;130:152-163 pubmed publisher
  34. Speer S, Li Z, Buta S, Payelle Brogard B, Qian L, Vigant F, et al. ISG15 deficiency and increased viral resistance in humans but not mice. Nat Commun. 2016;7:11496 pubmed publisher
  35. Passalacqua K, Charbonneau M, Donato N, Showalter H, Sun D, Wen B, et al. Anti-infective Activity of 2-Cyano-3-Acrylamide Inhibitors with Improved Drug-Like Properties against Two Intracellular Pathogens. Antimicrob Agents Chemother. 2016;60:4183-96 pubmed publisher
  36. Fajardo V, Smith I, Bombardier E, Chambers P, Quadrilatero J, Tupling A. Diaphragm assessment in mice overexpressing phospholamban in slow-twitch type I muscle fibers. Brain Behav. 2016;6:e00470 pubmed publisher
  37. Dinger K, Kasper P, Hucklenbruch Rother E, Vohlen C, Jobst E, Janoschek R, et al. Early-onset obesity dysregulates pulmonary adipocytokine/insulin signaling and induces asthma-like disease in mice. Sci Rep. 2016;6:24168 pubmed publisher
  38. Walia M, Ho P, Taylor S, Ng A, Gupte A, Chalk A, et al. Activation of PTHrP-cAMP-CREB1 signaling following p53 loss is essential for osteosarcoma initiation and maintenance. elife. 2016;5: pubmed publisher
  39. Körber N, Stein V. In vivo imaging demonstrates dendritic spine stabilization by SynCAM 1. Sci Rep. 2016;6:24241 pubmed publisher
  40. Wang X, Shaw D, Sakhon O, Snyder G, Sundberg E, Santambrogio L, et al. The Tick Protein Sialostatin L2 Binds to Annexin A2 and Inhibits NLRC4-Mediated Inflammasome Activation. Infect Immun. 2016;84:1796-1805 pubmed publisher
  41. Yu J, Berga S, Johnston MacAnanny E, Sidell N, Bagchi I, Bagchi M, et al. Endometrial Stromal Decidualization Responds Reversibly to Hormone Stimulation and Withdrawal. Endocrinology. 2016;157:2432-46 pubmed publisher
  42. Strickland S, Vande Pol S. The Human Papillomavirus 16 E7 Oncoprotein Attenuates AKT Signaling To Promote Internal Ribosome Entry Site-Dependent Translation and Expression of c-MYC. J Virol. 2016;90:5611-5621 pubmed publisher
  43. Jennewein L, Ronellenfitsch M, Antonietti P, Ilina E, Jung J, Stadel D, et al. Diagnostic and clinical relevance of the autophago-lysosomal network in human gliomas. Oncotarget. 2016;7:20016-32 pubmed publisher
  44. Wang X, Chen L, Liu J, Yan T, Wu G, Xia Y, et al. In vivo treatment of rat arterial adventitia with interleukin‑1β induces intimal proliferation via the JAK2/STAT3 signaling pathway. Mol Med Rep. 2016;13:3451-8 pubmed publisher
  45. Ardini E, Menichincheri M, Banfi P, Bosotti R, De Ponti C, Pulci R, et al. Entrectinib, a Pan-TRK, ROS1, and ALK Inhibitor with Activity in Multiple Molecularly Defined Cancer Indications. Mol Cancer Ther. 2016;15:628-39 pubmed publisher
  46. Bach F, Zhang Y, Miranda Bedate A, Verdonschot L, Bergknut N, Creemers L, et al. Increased caveolin-1 in intervertebral disc degeneration facilitates repair. Arthritis Res Ther. 2016;18:59 pubmed publisher
  47. Liu L, Tong Q, Liu S, Cui J, Zhang Q, Sun W, et al. ZEB1 Upregulates VEGF Expression and Stimulates Angiogenesis in Breast Cancer. PLoS ONE. 2016;11:e0148774 pubmed publisher
  48. Kanderová V, Kuzilkova D, Stuchly J, Vaskova M, Brdicka T, Fiser K, et al. High-resolution Antibody Array Analysis of Childhood Acute Leukemia Cells. Mol Cell Proteomics. 2016;15:1246-61 pubmed publisher
  49. Pivonello C, Negri M, De Martino M, Napolitano M, De Angelis C, Provvisiero D, et al. The dual targeting of insulin and insulin-like growth factor 1 receptor enhances the mTOR inhibitor-mediated antitumor efficacy in hepatocellular carcinoma. Oncotarget. 2016;7:9718-31 pubmed publisher
  50. Suzuki Y, Chin W, Han Q, Ichiyama K, Lee C, Eyo Z, et al. Characterization of RyDEN (C19orf66) as an Interferon-Stimulated Cellular Inhibitor against Dengue Virus Replication. PLoS Pathog. 2016;12:e1005357 pubmed publisher
  51. Hrstka R, Bouchalova P, Michalová E, Matoulkova E, Muller P, Coates P, et al. AGR2 oncoprotein inhibits p38 MAPK and p53 activation through a DUSP10-mediated regulatory pathway. Mol Oncol. 2016;10:652-62 pubmed publisher
  52. Tagliatti E, Fadda M, Falace A, Benfenati F, Fassio A. Arf6 regulates the cycling and the readily releasable pool of synaptic vesicles at hippocampal synapse. elife. 2016;5: pubmed publisher
  53. Creedon H, Balderstone L, Muir M, Balla J, Gómez Cuadrado L, Tracey N, et al. Use of a genetically engineered mouse model as a preclinical tool for HER2 breast cancer. Dis Model Mech. 2016;9:131-40 pubmed publisher
  54. Marazita M, Dugour A, Marquioni Ramella M, Figueroa J, Suburo A. Oxidative stress-induced premature senescence dysregulates VEGF and CFH expression in retinal pigment epithelial cells: Implications for Age-related Macular Degeneration. Redox Biol. 2016;7:78-87 pubmed publisher
  55. Furlan S, Mosole S, Murgia M, Nagaraj N, Argenton F, Volpe P, et al. Calsequestrins in skeletal and cardiac muscle from adult Danio rerio. J Muscle Res Cell Motil. 2016;37:27-39 pubmed publisher
  56. Hu X, Garcia C, Fazli L, Gleave M, Vitek M, Jansen M, et al. Inhibition of Pten deficient Castration Resistant Prostate Cancer by Targeting of the SET - PP2A Signaling axis. Sci Rep. 2015;5:15182 pubmed publisher
  57. Alnasser H, Guan Q, Zhang F, Gleave M, Nguan C, Du C. Requirement of clusterin expression for prosurvival autophagy in hypoxic kidney tubular epithelial cells. Am J Physiol Renal Physiol. 2016;310:F160-73 pubmed publisher
  58. Lohberger B, Leithner A, Stuendl N, Kaltenegger H, Kullich W, Steinecker Frohnwieser B. Diacerein retards cell growth of chondrosarcoma cells at the G2/M cell cycle checkpoint via cyclin B1/CDK1 and CDK2 downregulation. BMC Cancer. 2015;15:891 pubmed publisher
  59. Osmanagic Myers S, Rus S, Wolfram M, Brunner D, Goldmann W, Bonakdar N, et al. Plectin reinforces vascular integrity by mediating crosstalk between the vimentin and the actin networks. J Cell Sci. 2015;128:4138-50 pubmed publisher
  60. Antonucci L, Fagman J, Kim J, Todoric J, Gukovsky I, Mackey M, et al. Basal autophagy maintains pancreatic acinar cell homeostasis and protein synthesis and prevents ER stress. Proc Natl Acad Sci U S A. 2015;112:E6166-74 pubmed publisher
  61. Oh Y, Park H, Shin J, Lee J, Park H, Kho D, et al. Ndrg1 is a T-cell clonal anergy factor negatively regulated by CD28 costimulation and interleukin-2. Nat Commun. 2015;6:8698 pubmed publisher
  62. Finkin S, Yuan D, Stein I, Taniguchi K, Weber A, Unger K, et al. Ectopic lymphoid structures function as microniches for tumor progenitor cells in hepatocellular carcinoma. Nat Immunol. 2015;16:1235-44 pubmed publisher
  63. Kizuka Y, Nakano M, Kitazume S, Saito T, Saido T, Taniguchi N. Bisecting GlcNAc modification stabilizes BACE1 protein under oxidative stress conditions. Biochem J. 2016;473:21-30 pubmed publisher
  64. Zhang W, Pelicano H, Yin R, Zeng J, Wen T, Ding L, et al. Effective elimination of chronic lymphocytic leukemia cells in the stromal microenvironment by a novel drug combination strategy using redox-mediated mechanisms. Mol Med Rep. 2015;12:7374-88 pubmed publisher
  65. Takeda S, Wegmann S, Cho H, DeVos S, Commins C, Roe A, et al. Neuronal uptake and propagation of a rare phosphorylated high-molecular-weight tau derived from Alzheimer's disease brain. Nat Commun. 2015;6:8490 pubmed publisher
  66. Liu F, Hon G, Villa G, Turner K, Ikegami S, Yang H, et al. EGFR Mutation Promotes Glioblastoma through Epigenome and Transcription Factor Network Remodeling. Mol Cell. 2015;60:307-18 pubmed publisher
  67. Li Z, Hao Q, Luo J, Xiong J, Zhang S, Wang T, et al. USP4 inhibits p53 and NF-κB through deubiquitinating and stabilizing HDAC2. Oncogene. 2016;35:2902-12 pubmed publisher
  68. Woolery K, Mohamed M, Linger R, Dobrinski K, Roman J, Kruk P. BRCA1 185delAG Mutation Enhances Interleukin-1β Expression in Ovarian Surface Epithelial Cells. Biomed Res Int. 2015;2015:652017 pubmed publisher
  69. Morancho B, Martínez Barriocanal Ã, Villanueva J, Arribas J. Role of ADAM17 in the non-cell autonomous effects of oncogene-induced senescence. Breast Cancer Res. 2015;17:106 pubmed publisher
  70. Xie X, Hsu F, Gao X, Xu W, Ni J, Xing Y, et al. CDK8-Cyclin C Mediates Nutritional Regulation of Developmental Transitions through the Ecdysone Receptor in Drosophila. PLoS Biol. 2015;13:e1002207 pubmed publisher
  71. Dubińska Magiera M, Chmielewska M, Kozioł K, Machowska M, Hutchison C, Goldberg M, et al. Xenopus LAP2β protein knockdown affects location of lamin B and nucleoporins and has effect on assembly of cell nucleus and cell viability. Protoplasma. 2016;253:943-56 pubmed publisher
  72. Sloan E, Tatham M, Groslambert M, Glass M, Orr A, Hay R, et al. Analysis of the SUMO2 Proteome during HSV-1 Infection. PLoS Pathog. 2015;11:e1005059 pubmed publisher
  73. Lee J, Kim H, Han J, Kim Y, Son C. Anti-fatigue effect of Myelophil in a chronic forced exercise mouse model. Eur J Pharmacol. 2015;764:100-8 pubmed publisher
  74. Breslin C, Hornyak P, Ridley A, Rulten S, Hanzlikova H, Oliver A, et al. The XRCC1 phosphate-binding pocket binds poly (ADP-ribose) and is required for XRCC1 function. Nucleic Acids Res. 2015;43:6934-44 pubmed publisher
  75. Mercer J, Argus J, Crabtree D, KEENAN M, Wilks M, Chi J, et al. Modulation of PICALM Levels Perturbs Cellular Cholesterol Homeostasis. PLoS ONE. 2015;10:e0129776 pubmed publisher
  76. Lee W, Shen S, Shih Y, Chou C, Tseng J, Chin S, et al. Early decline in serum phospho-CSE1L levels in vemurafenib/sunitinib-treated melanoma and sorafenib/lapatinib-treated colorectal tumor xenografts. J Transl Med. 2015;13:191 pubmed publisher
  77. Cui J, Bai X, Sun X, Cai G, Hong Q, Ding R, et al. Rapamycin protects against gentamicin-induced acute kidney injury via autophagy in mini-pig models. Sci Rep. 2015;5:11256 pubmed publisher
  78. Barr A, Bakal C. A sensitised RNAi screen reveals a ch-TOG genetic interaction network required for spindle assembly. Sci Rep. 2015;5:10564 pubmed publisher
  79. Formisano L, Guida N, Valsecchi V, Cantile M, Cuomo O, Vinciguerra A, et al. Sp3/REST/HDAC1/HDAC2 Complex Represses and Sp1/HIF-1/p300 Complex Activates ncx1 Gene Transcription, in Brain Ischemia and in Ischemic Brain Preconditioning, by Epigenetic Mechanism. J Neurosci. 2015;35:7332-48 pubmed publisher
  80. Mahale S, Bharate S, Manda S, Joshi P, Jenkins P, Vishwakarma R, et al. Antitumour potential of BPT: a dual inhibitor of cdk4 and tubulin polymerization. Cell Death Dis. 2015;6:e1743 pubmed publisher
  81. Peiris Pagès M, Sotgia F, Lisanti M. Chemotherapy induces the cancer-associated fibroblast phenotype, activating paracrine Hedgehog-GLI signalling in breast cancer cells. Oncotarget. 2015;6:10728-45 pubmed
  82. Randles M, Woolf A, Huang J, Byron A, Humphries J, Price K, et al. Genetic Background is a Key Determinant of Glomerular Extracellular Matrix Composition and Organization. J Am Soc Nephrol. 2015;26:3021-34 pubmed publisher
  83. Berkovits B, Mayr C. Alternative 3' UTRs act as scaffolds to regulate membrane protein localization. Nature. 2015;522:363-7 pubmed publisher
  84. Chien P, Lin C, Hsiao L, Yang C. c-Src/Pyk2/EGFR/PI3K/Akt/CREB-activated pathway contributes to human cardiomyocyte hypertrophy: Role of COX-2 induction. Mol Cell Endocrinol. 2015;409:59-72 pubmed publisher
  85. Hong S, Lee J, Lee J, Lee H, Kim H, Lee S, et al. The traditional drug Gongjin-Dan ameliorates chronic fatigue in a forced-stress mouse exercise model. J Ethnopharmacol. 2015;168:268-78 pubmed publisher
  86. Gu Q, Yu D, Hu Z, Liu X, Yang Y, Luo Y, et al. miR-26a and miR-384-5p are required for LTP maintenance and spine enlargement. Nat Commun. 2015;6:6789 pubmed publisher
  87. Okatsu K, Koyano F, Kimura M, Kosako H, Saeki Y, Tanaka K, et al. Phosphorylated ubiquitin chain is the genuine Parkin receptor. J Cell Biol. 2015;209:111-28 pubmed publisher
  88. Bergamo P, Palmieri G, Cocca E, Ferrandino I, Gogliettino M, Monaco A, et al. Adaptive response activated by dietary cis9, trans11 conjugated linoleic acid prevents distinct signs of gliadin-induced enteropathy in mice. Eur J Nutr. 2016;55:729-740 pubmed publisher
  89. Yazlovitskaya E, Tseng H, Viquez O, Tu T, Mernaugh G, McKee K, et al. Integrin α3β1 regulates kidney collecting duct development via TRAF6-dependent K63-linked polyubiquitination of Akt. Mol Biol Cell. 2015;26:1857-74 pubmed publisher
  90. Jamison S, Lin Y, Lin W. Pancreatic endoplasmic reticulum kinase activation promotes medulloblastoma cell migration and invasion through induction of vascular endothelial growth factor A. PLoS ONE. 2015;10:e0120252 pubmed publisher
  91. Dicay M, Hirota C, Ronaghan N, Peplowski M, Zaheer R, Carati C, et al. Interferon-γ suppresses intestinal epithelial aquaporin-1 expression via Janus kinase and STAT3 activation. PLoS ONE. 2015;10:e0118713 pubmed publisher
  92. Bobba A, Amadoro G, La Piana G, Petragallo V, Calissano P, Atlante A. Glucose-6-phosphate tips the balance in modulating apoptosis in cerebellar granule cells. FEBS Lett. 2015;589:651-8 pubmed publisher
  93. Gibbs Seymour I, Markiewicz E, Bekker Jensen S, Mailand N, Hutchison C. Lamin A/C-dependent interaction with 53BP1 promotes cellular responses to DNA damage. Aging Cell. 2015;14:162-9 pubmed publisher
  94. Goossens S, Radaelli E, Blanchet O, Durinck K, Van der Meulen J, Peirs S, et al. ZEB2 drives immature T-cell lymphoblastic leukaemia development via enhanced tumour-initiating potential and IL-7 receptor signalling. Nat Commun. 2015;6:5794 pubmed publisher
  95. Izzo F, Mercogliano F, Venturutti L, Tkach M, Inurrigarro G, Schillaci R, et al. Progesterone receptor activation downregulates GATA3 by transcriptional repression and increased protein turnover promoting breast tumor growth. Breast Cancer Res. 2014;16:491 pubmed publisher
  96. Colman J, Laureano D, Reis T, Krolow R, Dalmaz C, Benetti C, et al. Variations in the neonatal environment modulate adult behavioral and brain responses to palatable food withdrawal in adult female rats. Int J Dev Neurosci. 2015;40:70-5 pubmed publisher
  97. Giovannini C, Minguzzi M, Baglioni M, Fornari F, Giannone F, Ravaioli M, et al. Suppression of p53 by Notch3 is mediated by Cyclin G1 and sustained by MDM2 and miR-221 axis in hepatocellular carcinoma. Oncotarget. 2014;5:10607-20 pubmed
  98. Roufayel R, Johnston D, Mosser D. The elimination of miR-23a in heat-stressed cells promotes NOXA-induced cell death and is prevented by HSP70. Cell Death Dis. 2014;5:e1546 pubmed publisher
  99. Jia J, Hu Z, Nordman J, Li Z. The schizophrenia susceptibility gene dysbindin regulates dendritic spine dynamics. J Neurosci. 2014;34:13725-36 pubmed publisher
  100. Bernard Marissal N, Sunyach C, Marissal T, Raoul C, Pettmann B. Calreticulin levels determine onset of early muscle denervation by fast motoneurons of ALS model mice. Neurobiol Dis. 2015;73:130-6 pubmed publisher
  101. Portella A, Silveira P, Laureano D, Cardoso S, Bittencourt V, Noschang C, et al. Litter size reduction alters insulin signaling in the ventral tegmental area and influences dopamine-related behaviors in adult rats. Behav Brain Res. 2015;278:66-73 pubmed publisher
  102. Ni W, Qiao J, Hu S, Zhao X, Regouski M, Yang M, et al. Efficient gene knockout in goats using CRISPR/Cas9 system. PLoS ONE. 2014;9:e106718 pubmed publisher
  103. Zhang X, Ma W, Cui J, Yao H, Zhou H, Ge Y, et al. Regulation of p21 by TWIST2 contributes to its tumor-suppressor function in human acute myeloid leukemia. Oncogene. 2015;34:3000-10 pubmed publisher
  104. Zheng Y, Hsu F, Xu W, Xie X, Ren X, Gao X, et al. A developmental genetic analysis of the lysine demethylase KDM2 mutations in Drosophila melanogaster. Mech Dev. 2014;133:36-53 pubmed publisher
  105. Doceul V, Chauveau E, Lara E, Breard E, Sailleau C, Zientara S, et al. Dual modulation of type I interferon response by bluetongue virus. J Virol. 2014;88:10792-802 pubmed publisher
  106. Howell K, Pillai A. Effects of prenatal hypoxia on schizophrenia-related phenotypes in heterozygous reeler mice: a gene × environment interaction study. Eur Neuropsychopharmacol. 2014;24:1324-36 pubmed publisher
  107. Gracanin A, Timmermans Sprang E, van Wolferen M, Rao N, Grizelj J, Vince S, et al. Ligand-independent canonical Wnt activity in canine mammary tumor cell lines associated with aberrant LEF1 expression. PLoS ONE. 2014;9:e98698 pubmed publisher
  108. Verstegen A, Tagliatti E, Lignani G, Marte A, Stolero T, Atias M, et al. Phosphorylation of synapsin I by cyclin-dependent kinase-5 sets the ratio between the resting and recycling pools of synaptic vesicles at hippocampal synapses. J Neurosci. 2014;34:7266-80 pubmed publisher
  109. Yuan B, Wan P, Chu D, Nie J, Cao Y, Luo W, et al. A cardiomyocyte-specific Wdr1 knockout demonstrates essential functional roles for actin disassembly during myocardial growth and maintenance in mice. Am J Pathol. 2014;184:1967-80 pubmed publisher
  110. Bach F, Rutten K, Hendriks K, Riemers F, Cornelissen P, de Bruin A, et al. The paracrine feedback loop between vitamin D? (1,25(OH)?D?) and PTHrP in prehypertrophic chondrocytes. J Cell Physiol. 2014;229:1999-2014 pubmed publisher
  111. Schroder W, Major L, Le T, Gardner J, Sweet M, Janciauskiene S, et al. Tumor cell-expressed SerpinB2 is present on microparticles and inhibits metastasis. Cancer Med. 2014;3:500-13 pubmed publisher
  112. Qi M, Zhang J, Zeng W, Chen X. DNAJB1 stabilizes MDM2 and contributes to cancer cell proliferation in a p53-dependent manner. Biochim Biophys Acta. 2014;1839:62-9 pubmed publisher
  113. Bronner D, O Riordan M, He Y. Caspase-2 mediates a Brucella abortus RB51-induced hybrid cell death having features of apoptosis and pyroptosis. Front Cell Infect Microbiol. 2013;3:83 pubmed publisher
  114. Bi J, Wang R, Zhang Y, Han X, Ampah K, Liu W, et al. Identification of nucleolin as a lipid-raft-dependent ?1-integrin-interacting protein in A375 cell migration. Mol Cells. 2013;36:507-17 pubmed publisher
  115. Hasty P, Livi C, Dodds S, Jones D, Strong R, Javors M, et al. eRapa restores a normal life span in a FAP mouse model. Cancer Prev Res (Phila). 2014;7:169-78 pubmed publisher
  116. Sadakata T, Kakegawa W, Shinoda Y, Hosono M, Katoh Semba R, Sekine Y, et al. CAPS1 deficiency perturbs dense-core vesicle trafficking and Golgi structure and reduces presynaptic release probability in the mouse brain. J Neurosci. 2013;33:17326-34 pubmed publisher
  117. Lee P, Yau D, Lau P, Chan J. Plexiform fibromyxoma (plexiform angiomyxoid myofibroblastic tumor) of stomach: an unusual presentation as a fistulating abscess. Int J Surg Pathol. 2014;22:286-90 pubmed publisher
  118. Henderson Y, Toro Serra R, Chen Y, Ryu J, Frederick M, Zhou G, et al. Src inhibitors in suppression of papillary thyroid carcinoma growth. Head Neck. 2014;36:375-84 pubmed publisher
  119. Murata Y, Constantine Paton M. Postsynaptic density scaffold SAP102 regulates cortical synapse development through EphB and PAK signaling pathway. J Neurosci. 2013;33:5040-52 pubmed publisher
  120. Sánchez Alvarez R, Martinez Outschoorn U, Lin Z, Lamb R, Hulit J, Howell A, et al. Ethanol exposure induces the cancer-associated fibroblast phenotype and lethal tumor metabolism: implications for breast cancer prevention. Cell Cycle. 2013;12:289-301 pubmed publisher
  121. Chen Y, Sundvik M, Rozov S, Priyadarshini M, Panula P. MANF regulates dopaminergic neuron development in larval zebrafish. Dev Biol. 2012;370:237-49 pubmed publisher
  122. Wakabayashi T, Kosaka J, Mori T, Yamada H. Prolonged expression of Puma in cholinergic amacrine cells during the development of rat retina. J Histochem Cytochem. 2012;60:777-88 pubmed
  123. Tai C, Shen S, Lee W, Liao C, Deng W, Chiou H, et al. Increased cellular apoptosis susceptibility (CSE1L/CAS) protein expression promotes protrusion extension and enhances migration of MCF-7 breast cancer cells. Exp Cell Res. 2010;316:2969-81 pubmed publisher
  124. Kurz A, Double K, Lastres Becker I, Tozzi A, Tantucci M, Bockhart V, et al. A53T-alpha-synuclein overexpression impairs dopamine signaling and striatal synaptic plasticity in old mice. PLoS ONE. 2010;5:e11464 pubmed publisher
  125. Polo M, Arnoni M, Riggio M, Wargon V, Lanari C, Novaro V. Responsiveness to PI3K and MEK inhibitors in breast cancer. Use of a 3D culture system to study pathways related to hormone independence in mice. PLoS ONE. 2010;5:e10786 pubmed publisher
  126. Holthouse D, Dallas P, Ford J, Fabian V, Murch A, Watson M, et al. Classic and desmoplastic medulloblastoma: complete case reports and characterizations of two new cell lines. Neuropathology. 2009;29:398-409 pubmed publisher
  127. Marín Briggiler C, Veiga M, Matos M, Echeverría M, Furlong L, Vazquez Levin M. Expression of epithelial cadherin in the human male reproductive tract and gametes and evidence of its participation in fertilization. Mol Hum Reprod. 2008;14:561-71 pubmed publisher
  128. Rigau V, Morin M, Rousset M, de Bock F, Lebrun A, Coubes P, et al. Angiogenesis is associated with blood-brain barrier permeability in temporal lobe epilepsy. Brain. 2007;130:1942-56 pubmed