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ab14509 has been referenced in 29 publications.

  • Wang M  et al. A basal cell defect promotes budding of prostatic intraepithelial neoplasia. J Cell Sci 130:104-110 (2017). PubMed: 27609833
  • Li Y  et al. MMP-2 and MMP-13 affect vasculogenic mimicry formation in large cell lung cancer. J Cell Mol Med 21:3741-3751 (2017). PubMed: 28766880
  • Yang S  et al. Abnormalities in the basement membrane structure promote basal keratinocytes in the epidermis of hypertrophic scars to adopt a proliferative phenotype. Int J Mol Med 37:1263-73 (2016). IHC-P ; Human . PubMed: 26986690
  • Fedorenko IV  et al. Fibronectin induction abrogates the BRAF inhibitor response of BRAF V600E/PTEN-null melanoma cells. Oncogene 35:1225-35 (2016). WB . PubMed: 26073081
  • Richards KF  et al. Human papillomavirus species-specific interaction with the basement membrane-resident non-heparan sulfate receptor. Viruses 6:4856-79 (2014). PubMed: 25490765
  • Brock A  et al. Silencing HoxA1 by intraductal injection of siRNA lipidoid nanoparticles prevents mammary tumor progression in mice. Sci Transl Med 6:217ra2 (2014). Mouse, Human . PubMed: 24382894
  • Montagner A  et al. Src is activated by the nuclear receptor peroxisome proliferator-activated receptor ß/d in ultraviolet radiation-induced skin cancer. EMBO Mol Med 6:80-98 (2014). IF . PubMed: 24203162
  • Fang JY  et al. Tumor bioengineering using a transglutaminase crosslinked hydrogel. PLoS One 9:e105616 (2014). ICC/IF ; Human . PubMed: 25133673
  • Cerqueira C  et al. Heparin increases the infectivity of Human Papillomavirus type 16 independent of cell surface proteoglycans and induces L1 epitope exposure. Cell Microbiol 15:1818-36 (2013). PubMed: 23601855
  • Pinto S  et al. An organotypic coculture model supporting proliferation and differentiation of medullary thymic epithelial cells and promiscuous gene expression. J Immunol 190:1085-93 (2013). PubMed: 23269248
  • Lam CR  et al. Loss of TAK1 increases cell traction force in a ROS-dependent manner to drive epithelial-mesenchymal transition of cancer cells. Cell Death Dis 4:e848 (2013). PubMed: 24113182
  • Richards KF  et al. Multiple heparan sulfate binding site engagements are required for the infectious entry of human papillomavirus type 16. J Virol 87:11426-37 (2013). PubMed: 23966387
  • Higgins CA  et al. Microenvironmental reprogramming by three-dimensional culture enables dermal papilla cells to induce de novo human hair-follicle growth. Proc Natl Acad Sci U S A 110:19679-88 (2013). PubMed: 24145441
  • Sarkar TR  et al. Identification of a Src tyrosine kinase/SIAH2 E3 ubiquitin ligase pathway that regulates C/EBPd expression and contributes to transformation of breast tumor cells. Mol Cell Biol 32:320-32 (2012). ICC/IF ; Human . PubMed: 22037769
  • Behrens DT  et al. The epidermal basement membrane is a composite of separate laminin- or collagen IV-containing networks connected by aggregated perlecan, but not by nidogens. J Biol Chem : (2012). WB . PubMed: 22493504
  • Dasgupta J  et al. Structural basis of oligosaccharide receptor recognition by human papillomavirus. J Biol Chem 286:2617-24 (2011). ICC/IF ; Human . PubMed: 21115492
  • Danussi C  et al. EMILIN1-a4/a9 integrin interaction inhibits dermal fibroblast and keratinocyte proliferation. J Cell Biol 195:131-45 (2011). IHC-Fr ; Mouse . PubMed: 21949412
  • Nishie W  et al. Dynamic interactions of epidermal collagen XVII with the extracellular matrix: laminin 332 as a major binding partner. Am J Pathol 179:829-37 (2011). WB ; Human . PubMed: 21801871
  • Santamato A  et al. Hepatic stellate cells stimulate HCC cell migration via laminin-5 production. Clin Sci (Lond) 121:159-68 (2011). PubMed: 21413933
  • Imanishi H  et al. Laminin-511, inducer of hair growth, is down-regulated and its suppressor in hair growth, laminin-332 up-regulated in chemotherapy-induced alopecia. J Dermatol Sci 58:43-54 (2010). PubMed: 20211547
  • Tateishi C  et al. Spatial and temporal control of laminin-511 and -332 expressions during catagen. J Dermatol Sci 58:55-63 (2010). PubMed: 20226633
  • Visser MB & Pollitt CC Characterization of extracellular matrix macromolecules in primary cultures of equine keratinocytes. BMC Vet Res 6:16 (2010). ICC/IF ; Horse . PubMed: 20230631
  • Broutian TR  et al. Differential binding patterns to host cells associated with particles of several human alphapapillomavirus types. J Gen Virol 91:531-40 (2010). ICC/IF ; Human . PubMed: 19846678
  • Johnson KM  et al. Role of heparan sulfate in attachment to and infection of the murine female genital tract by human papillomavirus. J Virol 83:2067-74 (2009). IHC-Fr ; Mouse . PubMed: 19073722
  • Doehn U  et al. RSK is a principal effector of the RAS-ERK pathway for eliciting a coordinate promotile/invasive gene program and phenotype in epithelial cells. Mol Cell 35:511-22 (2009). WB ; Human, Dog . PubMed: 19716794
  • Bienkowska-Haba M  et al. Target cell cyclophilins facilitate human papillomavirus type 16 infection. PLoS Pathog 5:e1000524 (2009). PubMed: 19629175
  • Day PM  et al. Mechanisms of human papillomavirus type 16 neutralization by l2 cross-neutralizing and l1 type-specific antibodies. J Virol 82:4638-46 (2008). ICC/IF ; Human . PubMed: 18305047
  • Selinka HC  et al. Inhibition of transfer to secondary receptors by heparan sulfate-binding drug or antibody induces noninfectious uptake of human papillomavirus. J Virol 81:10970-80 (2007). ICC/IF ; Human . PubMed: 17686860
  • Day PM  et al. Neutralization of human papillomavirus with monoclonal antibodies reveals different mechanisms of inhibition. J Virol 81:8784-92 (2007). ICC/IF ; Human . PubMed: 17553881


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