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Effects of glycosylation on melanoma interactions with type IV collagen modelsUnknown Date (has links)
Tumor cells interact with basement membrane collagen at the site of extravasation through distinct cellular receptors, including the α2β1 and α3β1integrins. These receptors are known to be differentially expressed in metastatic tumors, relative to the normal cells, depending on tumor type and stage of progression. The binding sites within type IV collagen for the α2β1 andα3β1 integrins have been identified. Since both of the integinspecific sequences possess at least one glycosylated Hyl residue, we questioned whether glycosylation could modulate integrin binding. Triple-helical peptides with and without Lys substituted by glycosylated Hyl for Lys543 and Lys540 from the human a1(IV)531-543 gene sequence (α3β integrin-specific) and Lys393 from the human a1(IV)382-393 gene sequence (α2β1 integrin-specific) were synthesized and utilized in the present study. / Cellular response to these triple helical ligands was tested with a primary melanoma cell line, WM-115, and three highly metastatic melanoma cell lines , WM-266-4, M14#5, and SK-MEL-2. Cell adhesion and cell spreading assays yielded differing results depending on whether the ligands contained glycosylated Hyl residues or not. In general, a decrease in cellular affinity toward the ligands was observed when glycosylated Hyl was present. Differences in the levels of adhesion and spreading between cell lines representing different stages of melanoma were also observed. Neutral B-galactosidase activity was detected in all four cell lines. Enzymatic activity levels were comparable for the three metastatic cell lines, whereas distinctively higher activity was detected for cells originating from a primary lesion. This acitivity can signal the potential of tumor cells to enhance and recover their invasive abilities. / The ability of each cell line to remove the galactose from the peptide ligands has been investigated, to test whether tumor cells can reestablish binding relationships between the α2β1 and α3β1 integrins and type IV collagen that are reduced by glycosylation. / by Beatrix Aukszi. / Thesis (Ph.D.)--Florida Atlantic University, 2008. / Includes bibliography. / Electronic reproduction. Boca Raton, Fla., 2008. Mode of access: World Wide Web.
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Mechanistic studies to evaluate the targeting specificity of novel RGD Micelles to the αVβ3 integrin receptorRaj, April 01 January 2012 (has links)
Current chemotherapeutics pose many di sadvantages due to their lack of specificity and low therapeutic index. To overcome these challenges, research has focused its attention on the development of nano-based delivery systems that can penetrate the leaky vasculature of tumor endothelium, use site-directed ligands that can bind with high affinity and specific ity to tumor cells, physically entrap poorly soluble drugs, and deliver these cytotoxic agents directly to the tumor site. One approach to nanosystem drug delivery is with the use of peptide amphiphiles (PAs) that are conjugated with the Arginine-Glycine-Aspartic Acid (RGD) motif to actively target a αVβ3 integrin receptors on cancer cells or tumor endothelium. The current work is focused on mechanistic studies to evaluate the uptake of novel RGD amphiphi les with varying alkyl chain lengths (palmitic acid : Cl 6 and stearic acid: C 18) and hydrophilic linkers, 8-amino- 3,6-dioxaoctonoic acid (ADA) or glucose, as micellar delivery systems of hydrophobic anticancer agents. PAs were confirmed for their self-assembling properties and further evaluated for their RGD-mediated binding specificity to purified αVβ3 integrin through a competitive binding fluorescence polarization assay (with novel RGD micelles displacing an integrin-bound fluorescent RGD probe by as much as 63.03%). Ultimately, these nanocarriers were assessed for their ability to deliver phys ically entrapped fluorescein isoth iocyanate (FITC) to A2058 cells overexpressing αVβ3 integrin receptors. Results from confocal microscopy indicate that uptake of RGD micelles was driven by an energy-dependent mechanism, as statistically significant levels of FITC internalization was seen at 37°C versus 4°C (p-value<0.05 for all treatment groups); moreover, intracellular fluorescence was notably higher (as much as 4-fold) when delivered through novel RGD conjugates as opposed to its free form. Regardless of chain length and the number of hydrophilic linkers, all RGD PAs showed promising results as micellar carriers that can effectively deliver their payload to the target tumor site via receptor mediated endocytosis.
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Functional Insights Into Oncogenic Protein Tyrosine Phosphatases By Mass SpectrometryWalls, Chad Daniel 29 January 2014 (has links)
Indiana University-Purdue University Indianapolis (IUPUI) / Phosphatase of Regenerating Liver 3 (PRL3) is suspected to be a causative factor toward cellular metastasis when overexpressed. To date, the molecular basis for PRL3 function remains an enigma, justifying the use of 'shot-gun'-style phosphoproteomic strategies to define the PRL3-mediated signaling network. On the basis of aberrant Src tyrosine kinase activation following ectopic PRL3 expression, phosphoproteomic data reveal a signal transduction network downstream of a mitogenic and chemotactic PDGF (α and β), Eph (A2, B3, B4), and Integrin (β1 and β5) receptor array known to be utilized by migratory mesenchymal cells during development and acute wound healing in the adult animal. Tyrosine phosphorylation is present on a multitude of signaling effectors responsible for Rho-family GTPase, PI3K-Akt, Jak-STAT3, and Ras-ERK1/2 pathway activation, linking observations made by the field as a whole under Src as a primary signal transducer. Our phosphoproteomic data paint the most comprehensive picture to date of how PRL3 drives pro-metastatic molecular events through Src activation. The Src-homology 2 (SH2) domain-containing tyrosine phosphatase 2 (SHP2), encoded by the Ptpn11 gene, is a bona-fide proto-oncogene responsible for the activation of the Ras/ERK1/2 pathway following mitogen stimulation. The molecular basis for SHP2 function is pTyr-ligand-mediated alleviation of intramolecular autoinhibition by the N-terminal SH2 domain (N-SH2 domain) upon the PTP catalytic domain. Pathogenic mutations that reside within the interface region between the N-SH2 and PTP domains are postulated to weaken the autoinhibitory interaction leading to SHP2 catalytic activation in the open conformation. Conversely, a subset of mutations resides within the catalytic active site and cause catalytic impairment. These catalytically impaired SHP2 mutants potentiate the pathogenesis of LEOPARD-syndrome (LS), a neuro-cardio-facial-cutaneous (NCFC) syndrome with very similar clinical presentation to related Noonan syndrome (NS), which is known to be caused by gain-of-function (GOF) SHP2 mutants. Here we apply hydrogen-deuterium exchange mass spectrometry (H/DX-MS) to provide direct evidence that LS-associated SHP2 mutations which cause catalytic impairment also weaken the autoinhibitory interaction that the N-SH2 domain makes with the PTP domain. Our H/DX-MS study shows that LS-SHP2 mutants possess a biophysical property that is absolutely required for GOF-effects to be realized, in-vivo.
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