The structural complexity of glycosaminoglycans (GAGs) such as heparin and heparan sulfate (HS) and their numerous biological roles, brings forth the need to develop new methods, capable of studying GAGs and their interactions with peptides and proteins under native settings. This thesis explores the development of chemical tools to study heparin/HS binding interactions under physiologically relevant conditions using fluorescence. In chapter 2, we designed peptide-based quinolinium probes to study the structural requirements of cationic peptides required for high affinity peptide-heparin interactions. These fluorescent probes enabled the study of peptide-heparin interactions at nM concentrations allowing the calculation of peptide-heparin binding constants. It was observed that peptides with positive charge displayed on one face of an α-helix in a continuous arrangement bound to heparin with the highest affinity and that heparin likely prefers to bind to these peptides while remaining in an extended conformation.
In chapter 3, we set out to study an important biological role of HS which involves the binding and sequestering of proteins at the cell surface, facilitating endocytosis. HS has been implicated in the mechanism of cell penetrating peptide (CPP) cell uptake, with different CPPs showing different degrees of HS dependence on uptake as well as different mechanisms of entry. The role of HS in the mechanism of CPP uptake was investigated in chapter 3 using fluorescent peptide-based probes incorporating fluorophore/quencher pairs. These were used to identify and characterize the ability of heparin/HS to bind and cluster with CPPs to form colloidally stable aggregates. It was shown that the CPP Antp formed much more stable clusters with heparin than the TAT peptide despite both peptides having similar binding affinity for a single heparin chain. These findings were used to explain the cell surface HS dependence of Antp on cell uptake via endocytosis in contrast to the low dependance of TAT on HS and its uptake via translocation. A general model relating the ability of a CPP to cluster surface HS to its preferred mechanism of cell entry was proposed. In chapter 4, a strategy to selectively, and site specifically acylate carbohydrate binding proteins was developed using thioester-based affinity conjugates. It was possible to label maltose binding protein, a periplasmic protein, with high yield and selectivity at a single lysine residue proximal to the maltose binding site. Selective protein labeling could be carried out in bacterial cell extracts and in live bacterial cells. This strategy can potentially be applied to develop protein-based carbohydrate biosensors as well as profile carbohydrate binding proteins in biological samples.
Identifer | oai:union.ndltd.org:LACETR/oai:collectionscanada.gc.ca:OTU.1807/32878 |
Date | 31 August 2012 |
Creators | Rullo, Anthony |
Contributors | Nitz, Mark |
Source Sets | Library and Archives Canada ETDs Repository / Centre d'archives des thèses électroniques de Bibliothèque et Archives Canada |
Language | en_ca |
Detected Language | English |
Type | Thesis |
Page generated in 0.0014 seconds