This is a Validated Antibody Database (VAD) review about cow ACTC1, based on 49 published articles (read how Labome selects the articles), using ACTC1 antibody in all methods. It is aimed to help Labome visitors find the most suited ACTC1 antibody. Please note the number of articles fluctuates since newly identified citations are added and citations for discontinued catalog numbers are removed regularly.
ACTC1 synonym: ACTC; actin, alpha cardiac muscle 1; alpha-cardiac actin

Invitrogen
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 ACTC1 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; baker's yeast; fig 2c
In order to report that Lpl1 as a target of the Rpn4 response, Invitrogen ACTC1 antibody (ThermoFisher, MA511866) was used in western blot on baker's yeast samples (fig 2c). Mol Biol Cell (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 ACTC1 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; loading ...; fig 5g
In order to investigate the alternative splicing of E-cadherin mRNA, Invitrogen ACTC1 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 ACTC1 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 (mAbGEa)
  • western blot; baker's yeast; fig 2
In order to investigate the connection between calorie restriction and magnesium, Invitrogen ACTC1 antibody (Thermo Scientific, MA1-744) was used in western blot on baker's yeast samples (fig 2). Nucleic Acids Res (2016) ncbi
mouse monoclonal (mAbGEa)
  • western blot; human; 1:500; loading ...; fig 1a
In order to make mutant mice to determine the impact of REV3L catalytic activity, Invitrogen ACTC1 antibody (Pierce, MA1-744) was used in western blot on human samples at 1:500 (fig 1a). DNA Repair (Amst) (2016) ncbi
mouse monoclonal (mAbGEa)
  • immunoprecipitation; rat; fig 2
In order to analyze the formation of supramolecular complexes through non-overlapping binding sites for drebrin, ZO-1, and tubulin by connexin43, Invitrogen ACTC1 antibody (Thermo scientific, MA1-744) was used in immunoprecipitation on rat samples (fig 2). PLoS ONE (2016) ncbi
mouse monoclonal (mAbGEa)
  • western blot; thale cress; fig 1
In order to study the contribution to pattern-triggered immunity from the GSK3/Shaggy-like kinase ASKalpha, Invitrogen ACTC1 antibody (Thermo Scientific, MA1-744) was used in western blot on thale cress samples (fig 1). Plant Physiol (2016) ncbi
mouse monoclonal (mAbGEa)
  • western blot; pig; loading ...; fig 2c
In order to test if adipose tissues have epigenetically distinct subpopulations of adipocytes, Invitrogen ACTC1 antibody (Thermo Scientific, mAbGEa) was used in western blot on pig samples (fig 2c). PLoS ONE (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 ACTC1 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; mouse; 1:3000; fig 1
  • western blot; human; 1:3000; fig 3
In order to investigate the PTHrP-cAMP-CREB1 axis in osteosarcoma, Invitrogen ACTC1 antibody (Thermo Scientific, Ab-5) was used in western blot on mouse samples at 1:3000 (fig 1) and in western blot on human samples at 1:3000 (fig 3). elife (2016) ncbi
mouse monoclonal (mAbGEa)
  • western blot; baker's yeast; 1:1000; fig 3
In order to regulating actin cable dynamics in budding yeast by fimbrin phosphorylation by metaphase Cdk1, Invitrogen ACTC1 antibody (Thermo Fisher scientific, mAbGEa) was used in western blot on baker's yeast samples at 1:1000 (fig 3). Nat Commun (2016) ncbi
mouse monoclonal (ACTN05 (C4))
  • western blot; dog; fig 8
In order to study how the role of increased caveolin-1 can help with repair to intervertebral disc degeneration, Invitrogen ACTC1 antibody (Neomarkers, pan Ab-5) was used in western blot on dog samples (fig 8). Arthritis Res Ther (2016) ncbi
mouse monoclonal (mAbGEa)
  • western blot; mouse; fig 2
In order to identify factors that are altered in the lacrimal gland by comparing several mouse models of disease with healthy mice, Invitrogen ACTC1 antibody (Thermo Scientific, mAbGEa) was used in western blot on mouse samples (fig 2). Invest Ophthalmol Vis Sci (2015) ncbi
mouse monoclonal (mAbGEa)
  • western blot; baker's yeast; 1:1000; fig 2, 4
In order to report roles for kinesin and nuclear pore complexes in DNA repair by break-induced replication, Invitrogen ACTC1 antibody (Fisher, MA1-744) was used in western blot on baker's yeast samples at 1:1000 (fig 2, 4). Nat Commun (2015) ncbi
mouse monoclonal (mAbGEa)
  • western blot; thale cress; 1:1000; fig 1
In order to distinguish the effects of photoreceptor signaling on clock function from those of photosynthesis, Invitrogen ACTC1 antibody (Thermo Scientific, MA1-744) was used in western blot on thale cress samples at 1:1000 (fig 1). Plant Physiol (2015) ncbi
mouse monoclonal (mAbGEa)
  • western blot; human; 1:1000; fig 6
In order to examine the effects of neokestose on cell proliferation, cell cycle, and apoptosis of colonic cells, Invitrogen ACTC1 antibody (Thermo Fisher, MA1-744) was used in western blot on human samples at 1:1000 (fig 6). Mol Med Rep (2015) ncbi
mouse monoclonal (mAbGEa)
  • western blot; scFv
In order to characterize the Las17 G-actin-binding motif in vitro and in vivo, Invitrogen ACTC1 antibody (Fisher, MA1-744) was used in western blot on scFv samples . Traffic (2015) 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 ACTC1 antibody (Molecular probes, C4) was used in western blot on human samples at 1:10,000 (fig 5). Nat Commun (2015) ncbi
mouse monoclonal (MSA06 (HUC1-1))
  • immunohistochemistry - paraffin section; Atlantic salmon; fig 5a
In order to study the development of atherosclerosis in salmon, Invitrogen ACTC1 antibody (Thermo Fisher Scientific, MS-1296-P) was used in immunohistochemistry - paraffin section on Atlantic salmon samples (fig 5a). J Fish Dis (2016) ncbi
mouse monoclonal (mAbGEa)
  • western blot; human
In order to determine how HER2/HER3 regulates extracellular acidification and cell migration, Invitrogen ACTC1 antibody (Thermo Scientific, MA1-744) was used in western blot on human samples . Cell Signal (2014) ncbi
mouse monoclonal (mAbGEa)
  • western blot; common platanna
In order to study metabolic regulation of CaMKII protein and caspases in Xenopus, Invitrogen ACTC1 antibody (Thermo Scientific, MA1-744) was used in western blot on common platanna samples . J Biol Chem (2013) ncbi
Santa Cruz Biotechnology
mouse monoclonal (5C5)
  • western blot; rat; 1:10,000; loading ...; fig 1h
Santa Cruz Biotechnology ACTC1 antibody (Santa Cruz, sc-58670) was used in western blot on rat samples at 1:10,000 (fig 1h). Diabetologia (2016) ncbi
mouse monoclonal (5C5)
  • immunohistochemistry; mouse; 1:100; fig 1
Santa Cruz Biotechnology ACTC1 antibody (Santa Cruz, sc-58670) was used in immunohistochemistry on mouse samples at 1:100 (fig 1). Genes Dev (2015) ncbi
mouse monoclonal (5C5)
  • western blot; mouse; 1:200; fig 1B
Santa Cruz Biotechnology ACTC1 antibody (Santa Cruz, sc-58670) was used in western blot on mouse samples at 1:200 (fig 1B). Autophagy (2016) ncbi
mouse monoclonal (5C5)
  • western blot; human; fig 2
In order to demonstrate that androgen receptor signaling modulates the unfolded protein response in prostate cancer cells, Santa Cruz Biotechnology ACTC1 antibody (Santa Cruz, sc-58670) was used in western blot on human samples (fig 2). EMBO Mol Med (2015) ncbi
mouse monoclonal (5C5)
  • immunocytochemistry; human; fig 3
Santa Cruz Biotechnology ACTC1 antibody (Santa Cruz Biotechnology, sc-58670) was used in immunocytochemistry on human samples (fig 3). Cytotechnology (2016) ncbi
mouse monoclonal (5C5)
  • immunohistochemistry - frozen section; rat; fig 3
In order to develop a bioreactor system that allows for the control of the mechanical stimulation of engineered cardiac tissue on a cycle-by-cycle basis, Santa Cruz Biotechnology ACTC1 antibody (Santa, sc-58670) was used in immunohistochemistry - frozen section on rat samples (fig 3). J Tissue Eng Regen Med (2017) ncbi
mouse monoclonal (5C5)
  • immunohistochemistry - frozen section; rat
Santa Cruz Biotechnology ACTC1 antibody (Santa Cruz Biotechnology, sc-58670) was used in immunohistochemistry - frozen section on rat samples . Tissue Eng Part A (2014) ncbi
Sigma-Aldrich
mouse monoclonal (Ac1-20.4.2)
  • immunohistochemistry - paraffin section; rat; 1:100; loading ...; fig 5a
Sigma-Aldrich ACTC1 antibody (Sigma, A9357) was used in immunohistochemistry - paraffin section on rat samples at 1:100 (fig 5a). J Histochem Cytochem (2017) ncbi
mouse monoclonal (Ac1-20.4.2)
  • immunocytochemistry; mouse; 1:400; fig 3a
In order to develop a protocol to generate expandable and multipotent induced cardiac progenitor cells from mouse adult fibroblasts, Sigma-Aldrich ACTC1 antibody (Sigma, A9357) was used in immunocytochemistry on mouse samples at 1:400 (fig 3a). Nat Protoc (2017) ncbi
mouse monoclonal (5C5)
  • western blot; mouse; 1:2000; loading ...; fig s4d
In order to discover that a common null polymorphism (R577X) in ACTN3 results in significantly reduced muscle strength in patients with Duchenne muscular dystrophy, Sigma-Aldrich ACTC1 antibody (Sigma, A2172) was used in western blot on mouse samples at 1:2000 (fig s4d). Nat Commun (2017) ncbi
mouse monoclonal (Ac1-20.4.2)
  • immunocytochemistry; human; 1:200; fig 5
Sigma-Aldrich ACTC1 antibody (Sigma, A9357) was used in immunocytochemistry on human samples at 1:200 (fig 5). Int J Med Sci (2016) ncbi
mouse monoclonal (5C5)
  • western blot; human; 1:5000; fig 5
Sigma-Aldrich ACTC1 antibody (Sigma, A-2172) was used in western blot on human samples at 1:5000 (fig 5). Mol Metab (2016) ncbi
mouse monoclonal (5C5)
  • immunohistochemistry - frozen section; human; 1:100; loading ...; fig 6a
In order to describe a preclinical platform for validation of new therapies in human heart tissue, Sigma-Aldrich ACTC1 antibody (Sigma, A2172) was used in immunohistochemistry - frozen section on human samples at 1:100 (fig 6a). Sci Rep (2016) ncbi
mouse monoclonal (5C5)
  • immunohistochemistry - paraffin section; mouse; 1:15-1:100; fig 3
Sigma-Aldrich ACTC1 antibody (Sigma Aldrich, A2172) was used in immunohistochemistry - paraffin section on mouse samples at 1:15-1:100 (fig 3). Oxid Med Cell Longev (2016) ncbi
mouse monoclonal (5C5)
  • western blot; human; 1:10,000; fig 3
Sigma-Aldrich ACTC1 antibody (Sigma, A2172) was used in western blot on human samples at 1:10,000 (fig 3). Oncotarget (2016) ncbi
mouse monoclonal (5C5)
  • western blot; rat; 1:1000; fig 4
Sigma-Aldrich ACTC1 antibody (Sigma, A2172) was used in western blot on rat samples at 1:1000 (fig 4). Int J Mol Med (2015) ncbi
mouse monoclonal (5C5)
  • western blot; mouse; 1:5000; fig 1
Sigma-Aldrich ACTC1 antibody (Sigma, A2172) was used in western blot on mouse samples at 1:5000 (fig 1). PLoS ONE (2015) ncbi
mouse monoclonal (Ac1-20.4.2)
  • immunocytochemistry; mouse; fig 4b
Sigma-Aldrich ACTC1 antibody (Sigma, A9357) was used in immunocytochemistry on mouse samples (fig 4b). PLoS ONE (2015) ncbi
mouse monoclonal (5C5)
  • immunocytochemistry; mouse; 1:400
Sigma-Aldrich ACTC1 antibody (Sigma, A2172) was used in immunocytochemistry on mouse samples at 1:400. J Physiol (2015) ncbi
mouse monoclonal (5C5)
  • western blot; mouse; 1:40,000; fig 4
In order to examine the contribution of neuronal NOSmu on skeletal muscle glucose uptake during ex vivo contraction, Sigma-Aldrich ACTC1 antibody (Sigma Aldrich, A2172) was used in western blot on mouse samples at 1:40,000 (fig 4). J Appl Physiol (1985) (2015) ncbi
mouse monoclonal (5C5)
  • western blot; human; 1:5000
In order to show that the loss of claudin-5 in cardiomyocytes and endothelial cells is prevalent in human heart failure, Sigma-Aldrich ACTC1 antibody (Sigma, A2172) was used in western blot on human samples at 1:5000. Cardiovasc Pathol (2015) ncbi
mouse monoclonal (5C5)
  • immunohistochemistry - paraffin section; mouse; 1:100; fig 4
In order to study the effect of mild coxsackievirus B infection on the heart, Sigma-Aldrich ACTC1 antibody (Sigma, A2172) was used in immunohistochemistry - paraffin section on mouse samples at 1:100 (fig 4). PLoS Pathog (2014) ncbi
mouse monoclonal (5C5)
  • western blot; rat; 1:5000
Sigma-Aldrich ACTC1 antibody (Sigma, A2172) was used in western blot on rat samples at 1:5000. PLoS ONE (2014) ncbi
mouse monoclonal (5C5)
  • western blot; mouse; 1:2000; fig 7
Sigma-Aldrich ACTC1 antibody (Sigma, 5C5) was used in western blot on mouse samples at 1:2000 (fig 7). Hum Mol Genet (2014) ncbi
mouse monoclonal (5C5)
  • immunocytochemistry; common platanna; 1:500; tbl 1
Sigma-Aldrich ACTC1 antibody (Sigma, A2172) was used in immunocytochemistry on common platanna samples at 1:500 (tbl 1). Methods (2014) ncbi
mouse monoclonal (5C5)
  • immunocytochemistry; mouse; loading ...; fig 7e
  • western blot; mouse; loading ...; fig 5b
Sigma-Aldrich ACTC1 antibody (Sigma-Aldrich, A2172) was used in immunocytochemistry on mouse samples (fig 7e) and in western blot on mouse samples (fig 5b). Wound Repair Regen (2013) ncbi
Articles Reviewed
  1. Nofi C, Bogatyryov Y, Dedkov E. Preservation of Functional Microvascular Bed Is Vital for Long-Term Survival of Cardiac Myocytes Within Large Transmural Post-Myocardial Infarction Scar. J Histochem Cytochem. 2017;:22155417741640 pubmed publisher
  2. 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
  3. Lalit P, Rodriguez A, Downs K, Kamp T. Generation of multipotent induced cardiac progenitor cells from mouse fibroblasts and potency testing in ex vivo mouse embryos. Nat Protoc. 2017;12:1029-1054 pubmed publisher
  4. Hogarth M, Houweling P, Thomas K, Gordish Dressman H, Bello L, Pegoraro E, et al. Evidence for ACTN3 as a genetic modifier of Duchenne muscular dystrophy. Nat Commun. 2017;8:14143 pubmed publisher
  5. Weisshaar N, Welsch H, Guerra Moreno A, Hanna J. Phospholipase Lpl1 links lipid droplet function with quality control protein degradation. Mol Biol Cell. 2017;28:716-725 pubmed publisher
  6. 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
  7. Sung I, Son H, Ullah I, Bharti D, Park J, Cho Y, et al. Cardiomyogenic Differentiation of Human Dental Follicle-derived Stem Cells by Suberoylanilide Hydroxamic Acid and Their In Vivo Homing Property. Int J Med Sci. 2016;13:841-852 pubmed
  8. 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
  9. van Moorsel D, Hansen J, Havekes B, Scheer F, Jorgensen J, Hoeks J, et al. Demonstration of a day-night rhythm in human skeletal muscle oxidative capacity. Mol Metab. 2016;5:635-645 pubmed publisher
  10. 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
  11. Abraham K, Chan J, Salvi J, Ho B, Hall A, Vidya E, et al. Intersection of calorie restriction and magnesium in the suppression of genome-destabilizing RNA-DNA hybrids. Nucleic Acids Res. 2016;44:8870-8884 pubmed
  12. Fritzen R, Delbos F, De Smet A, Palancade B, Canman C, Aoufouchi S, et al. A single aspartate mutation in the conserved catalytic site of Rev3L generates a hypomorphic phenotype in vivo and in vitro. DNA Repair (Amst). 2016;46:37-46 pubmed publisher
  13. Kang C, Qiao Y, Li G, Baechle K, Camelliti P, Rentschler S, et al. Human Organotypic Cultured Cardiac Slices: New Platform For High Throughput Preclinical Human Trials. Sci Rep. 2016;6:28798 pubmed publisher
  14. Ambrosi C, Ren C, Spagnol G, Cavin G, CONE A, Grintsevich E, et al. Connexin43 Forms Supramolecular Complexes through Non-Overlapping Binding Sites for Drebrin, Tubulin, and ZO-1. PLoS ONE. 2016;11:e0157073 pubmed publisher
  15. Stampfl H, Fritz M, Dal Santo S, Jonak C. The GSK3/Shaggy-Like Kinase ASKα Contributes to Pattern-Triggered Immunity. Plant Physiol. 2016;171:1366-77 pubmed publisher
  16. Yu P, Ji L, Lee K, Yu M, He C, Ambati S, et al. Subsets of Visceral Adipose Tissue Nuclei with Distinct Levels of 5-Hydroxymethylcytosine. PLoS ONE. 2016;11:e0154949 pubmed publisher
  17. 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
  18. 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
  19. Miao Y, Han X, Zheng L, Xie Y, Mu Y, Yates J, et al. Fimbrin phosphorylation by metaphase Cdk1 regulates actin cable dynamics in budding yeast. Nat Commun. 2016;7:11265 pubmed publisher
  20. 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
  21. Sparks L, Gemmink A, Phielix E, Bosma M, Schaart G, Moonen Kornips E, et al. ANT1-mediated fatty acid-induced uncoupling as a target for improving myocellular insulin sensitivity. Diabetologia. 2016;59:1030-9 pubmed publisher
  22. Umazume T, Thomas W, Campbell S, Aluri H, Thotakura S, Zoukhri D, et al. Lacrimal Gland Inflammation Deregulates Extracellular Matrix Remodeling and Alters Molecular Signature of Epithelial Stem/Progenitor Cells. Invest Ophthalmol Vis Sci. 2015;56:8392-402 pubmed publisher
  23. SINGLA D, Wang J. Fibroblast Growth Factor-9 Activates c-Kit Progenitor Cells and Enhances Angiogenesis in the Infarcted Diabetic Heart. Oxid Med Cell Longev. 2016;2016:5810908 pubmed publisher
  24. Hunt L, Xu B, Finkelstein D, Fan Y, Carroll P, Cheng P, et al. The glucose-sensing transcription factor MLX promotes myogenesis via myokine signaling. Genes Dev. 2015;29:2475-89 pubmed publisher
  25. Sin J, Andres A, Taylor D, Weston T, Hiraumi Y, Stotland A, et al. Mitophagy is required for mitochondrial biogenesis and myogenic differentiation of C2C12 myoblasts. Autophagy. 2016;12:369-80 pubmed publisher
  26. Verbrugge S, Al M, Assaraf Y, Kammerer S, Chandrupatla D, Honeywell R, et al. Multifactorial resistance to aminopeptidase inhibitor prodrug CHR2863 in myeloid leukemia cells: down-regulation of carboxylesterase 1, drug sequestration in lipid droplets and pro-survival activation ERK/Akt/mTOR. Oncotarget. 2016;7:5240-57 pubmed publisher
  27. Yan G, Wang Q, Hu S, Wang D, Qiao Y, Ma G, et al. Digoxin inhibits PDGF-BB-induced VSMC proliferation and migration through an increase in ILK signaling and attenuates neointima formation following carotid injury. Int J Mol Med. 2015;36:1001-11 pubmed publisher
  28. Chung D, Chan J, Strecker J, Zhang W, Ebrahimi Ardebili S, Lu T, et al. Perinuclear tethers license telomeric DSBs for a broad kinesin- and NPC-dependent DNA repair process. Nat Commun. 2015;6:7742 pubmed publisher
  29. Jones M, Hu W, Litthauer S, Lagarias J, Harmer S. A Constitutively Active Allele of Phytochrome B Maintains Circadian Robustness in the Absence of Light. Plant Physiol. 2015;169:814-25 pubmed publisher
  30. Cardona M, López J, Serafín A, Rongvaux A, Inserte J, García Dorado D, et al. Executioner Caspase-3 and 7 Deficiency Reduces Myocyte Number in the Developing Mouse Heart. PLoS ONE. 2015;10:e0131411 pubmed publisher
  31. Belian E, Noseda M, Abreu Paiva M, Leja T, Sampson R, Schneider M. Forward Programming of Cardiac Stem Cells by Homogeneous Transduction with MYOCD plus TBX5. PLoS ONE. 2015;10:e0125384 pubmed publisher
  32. Kapoor N, Tran A, Kang J, Zhang R, Philipson K, Goldhaber J. Regulation of calcium clock-mediated pacemaking by inositol-1,4,5-trisphosphate receptors in mouse sinoatrial nodal cells. J Physiol. 2015;593:2649-63 pubmed publisher
  33. Sheng X, Arnoldussen Y, Storm M, Tesikova M, Nenseth H, Zhao S, et al. Divergent androgen regulation of unfolded protein response pathways drives prostate cancer. EMBO Mol Med. 2015;7:788-801 pubmed publisher
  34. Lee S, Chang J, Wu J, Sheu D. Antineoplastic effect of a novel chemopreventive agent, neokestose, on the Caco-2 cell line via inhibition of expression of nuclear factor-κB and cyclooxygenase-2. Mol Med Rep. 2015;12:1114-8 pubmed publisher
  35. Hong Y, Frugier T, Zhang X, Murphy R, Lynch G, Betik A, et al. Glucose uptake during contraction in isolated skeletal muscles from neuronal nitric oxide synthase μ knockout mice. J Appl Physiol (1985). 2015;118:1113-21 pubmed publisher
  36. Taşlı P, Doğan A, Demirci S, Şahin F. Myogenic and neurogenic differentiation of human tooth germ stem cells (hTGSCs) are regulated by pluronic block copolymers. Cytotechnology. 2016;68:319-29 pubmed publisher
  37. Feliciano D, Tolsma T, Farrell K, Aradi A, Di Pietro S. A second Las17 monomeric actin-binding motif functions in Arp2/3-dependent actin polymerization during endocytosis. Traffic. 2015;16:379-97 pubmed publisher
  38. 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
  39. Swager S, Delfín D, Rastogi N, Wang H, Canan B, Fedorov V, et al. Claudin-5 levels are reduced from multiple cell types in human failing hearts and are associated with mislocalization of ephrin-B1. Cardiovasc Pathol. 2015;24:160-167 pubmed publisher
  40. Dalum A, Tangen R, Falk K, Hordvik I, Rosenlund G, Torstensen B, et al. Coronary changes in the Atlantic salmon Salmo salar L: characterization and impact of dietary fatty acid compositions. J Fish Dis. 2016;39:41-54 pubmed publisher
  41. Sin J, Puccini J, Huang C, Konstandin M, Gilbert P, Sussman M, et al. The impact of juvenile coxsackievirus infection on cardiac progenitor cells and postnatal heart development. PLoS Pathog. 2014;10:e1004249 pubmed publisher
  42. Morgan K, Black L. Investigation into the effects of varying frequency of mechanical stimulation in a cycle-by-cycle manner on engineered cardiac construct function. J Tissue Eng Regen Med. 2017;11:342-353 pubmed publisher
  43. Deng Y, Xie D, Fang M, Zhu G, Chen C, Zeng H, et al. Astrocyte-derived proinflammatory cytokines induce hypomyelination in the periventricular white matter in the hypoxic neonatal brain. PLoS ONE. 2014;9:e87420 pubmed publisher
  44. Morgan K, Black L. Mimicking isovolumic contraction with combined electromechanical stimulation improves the development of engineered cardiac constructs. Tissue Eng Part A. 2014;20:1654-67 pubmed publisher
  45. Garton F, Seto J, Quinlan K, Yang N, Houweling P, North K. ?-Actinin-3 deficiency alters muscle adaptation in response to denervation and immobilization. Hum Mol Genet. 2014;23:1879-93 pubmed publisher
  46. Sollome J, Thavathiru E, Camenisch T, Vaillancourt R. HER2/HER3 regulates extracellular acidification and cell migration through MTK1 (MEKK4). Cell Signal. 2014;26:70-82 pubmed publisher
  47. Nworu C, Krieg P, Gregorio C. Preparation of developing Xenopus muscle for sarcomeric protein localization by high-resolution imaging. Methods. 2014;66:370-9 pubmed publisher
  48. McCoy F, Darbandi R, Chen S, Eckard L, Dodd K, Jones K, et al. Metabolic regulation of CaMKII protein and caspases in Xenopus laevis egg extracts. J Biol Chem. 2013;288:8838-48 pubmed publisher
  49. Tomasek J, Haaksma C, Schwartz R, Howard E. Whole animal knockout of smooth muscle alpha-actin does not alter excisional wound healing or the fibroblast-to-myofibroblast transition. Wound Repair Regen. 2013;21:166-76 pubmed publisher