PURPOSE: Expression of lysosome-associated membrane protein-1 (LAMP1) on the surface correlates with metastatic potential of B16 melanoma cells. Downregulation of their expression in high metastatic (B16F10) cells reduced their surface expression and metastatic potential. Present investigations explore if overexpression of LAMP1 on the surface of low metastatic (B16F1) cells augment their metastatic ability, and if so, how? METHODS: B16F1 cells were transduced with lentiviral vector carrying mutant-LAMP1 (Y386A) (mutLAMP1). Surface expression of LAMP1 and carbohydrates was analyzed by flow cytometry, immunofluorescence and/or immunoprecipitation and Western blotting. Cell spreading and motility were assessed on components of extracellular matrix (ECM) (fibronectin) and basement membrane (BM) (matrigel), and galectin-3-coated coverslips/plates. Metastatic potential was assessed using experimental metastasis assay. RESULTS: Pre-incubation with anti-LAMP1 antibodies significantly reduced lung metastasis of B16F10 cells. Overexpression of mutLAMP1 significantly increased its surface expression on B16F1 cells, resulting in increased cellular spreading and motility on fibronectin and matrigel. LAMP1 is the major carrier of poly-N-acetyllactosamine (polyLacNAc) on B16F10 cells. However, significantly higher expression of mutLAMP1 had no effect on galectin-3 binding on cell surface or on spreading or motility of cells on galectin-3-coated coverslips/plates. These cells also failed to show any gain in metastatic ability. This could be because LAMP1 from these cells carried significantly lower levels of polyLacNAc in comparison with B16F10 cells. CONCLUSIONS: PolyLacNAc on B16F10 cells and galectin-3 on lungs are the major participants in melanoma metastasis. Although surface LAMP1 promotes interactions with organ ECM and BM, carbohydrates on LAMP1 play a decisive role in dictating lung metastasis.
PURPOSE: Expression of lysosome-associated membrane protein-1 (LAMP1) on the surface correlates with metastatic potential of B16 melanoma cells. Downregulation of their expression in high metastatic (B16F10) cells reduced their surface expression and metastatic potential. Present investigations explore if overexpression of LAMP1 on the surface of low metastatic (B16F1) cells augment their metastatic ability, and if so, how? METHODS: B16F1 cells were transduced with lentiviral vector carrying mutant-LAMP1 (Y386A) (mutLAMP1). Surface expression of LAMP1 and carbohydrates was analyzed by flow cytometry, immunofluorescence and/or immunoprecipitation and Western blotting. Cell spreading and motility were assessed on components of extracellular matrix (ECM) (fibronectin) and basement membrane (BM) (matrigel), and galectin-3-coated coverslips/plates. Metastatic potential was assessed using experimental metastasis assay. RESULTS: Pre-incubation with anti-LAMP1 antibodies significantly reduced lung metastasis of B16F10 cells. Overexpression of mutLAMP1 significantly increased its surface expression on B16F1 cells, resulting in increased cellular spreading and motility on fibronectin and matrigel. LAMP1 is the major carrier of poly-N-acetyllactosamine (polyLacNAc) on B16F10 cells. However, significantly higher expression of mutLAMP1 had no effect on galectin-3 binding on cell surface or on spreading or motility of cells on galectin-3-coated coverslips/plates. These cells also failed to show any gain in metastatic ability. This could be because LAMP1 from these cells carried significantly lower levels of polyLacNAc in comparison with B16F10 cells. CONCLUSIONS:PolyLacNAc on B16F10 cells and galectin-3 on lungs are the major participants in melanoma metastasis. Although surface LAMP1 promotes interactions with organ ECM and BM, carbohydrates on LAMP1 play a decisive role in dictating lung metastasis.
Authors: Jayshree Advani; Yashwanth Subbannayya; Krishna Patel; Aafaque Ahmad Khan; Arun H Patil; Ankit P Jain; Hitendra S Solanki; Aneesha Radhakrishnan; Sneha M Pinto; Nandini A Sahasrabuddhe; Joji K Thomas; Premendu P Mathur; Bipin G Nair; Xiaofei Chang; T S Keshava Prasad; David Sidransky; Harsha Gowda; Aditi Chatterjee Journal: OMICS Date: 2017-07
Authors: Christina Schiza; Dimitrios Korbakis; Efstratia Panteleli; Keith Jarvi; Andrei P Drabovich; Eleftherios P Diamandis Journal: Mol Cell Proteomics Date: 2018-08-10 Impact factor: 5.911
Authors: Stacy A Malaker; Michael J Ferracane; Florence R Depontieu; Angela L Zarling; Jeffrey Shabanowitz; Dina L Bai; Suzanne L Topalian; Victor H Engelhard; Donald F Hunt Journal: J Proteome Res Date: 2016-09-13 Impact factor: 4.466
Authors: Jakub Pospíšil; Tomáš Lukeš; Justin Bendesky; Karel Fliegel; Kathrin Spendier; Guy M Hagen Journal: Gigascience Date: 2019-01-01 Impact factor: 6.524
Authors: Amy H Ponsford; Thomas A Ryan; Andrea Raimondi; Emanuele Cocucci; Susanne A Wycislo; Florian Fröhlich; Laura E Swan; Massimiliano Stagi Journal: Autophagy Date: 2020-06-09 Impact factor: 16.016