Importance of the Structural Components of C-linked Glycopeptides to Specific-antifreeze Activity: From Glycopeptides to Small Molecule Inhibitors of Ice Recrystallization

One of the largest problems in current medicine is the shortage of organs for transplant due to technological limitations in the storage of organs for any length of time. A possible solution to this problem would involve cryopreservation. However, current cryopreservatives such as sucrose or DMSO ha...

Full description

Bibliographic Details
Main Author: Trant, John F.
Language:en
Published: 2012
Subjects:
Online Access:http://hdl.handle.net/10393/20710
id ndltd-LACETR-oai-collectionscanada.gc.ca-OOU.-en#10393-20710
record_format oai_dc
spelling ndltd-LACETR-oai-collectionscanada.gc.ca-OOU.-en#10393-207102013-01-11T13:33:12ZImportance of the Structural Components of C-linked Glycopeptides to Specific-antifreeze Activity: From Glycopeptides to Small Molecule Inhibitors of Ice RecrystallizationTrant, John F.AntifreezeOrganic SynthesisBioorganic chemistryRecrystallization inhibitioncarbohydratessmall moleculeglycopeptidebeta peptideCuAACOne of the largest problems in current medicine is the shortage of organs for transplant due to technological limitations in the storage of organs for any length of time. A possible solution to this problem would involve cryopreservation. However, current cryopreservatives such as sucrose or DMSO have concerning cytotoxic issues that limit their possible applications. A major cause of cryoinjury is the uncontrolled recrystallization of inter and intra-cellular ice crystals that occurs during the thawing process leading to mechanical damage and dehydration. The Ben lab has thus been interested in the design of compounds that are capable of inhibiting this process but do not possess other undesirable properties found in the native compounds. These synthetic analogues have been shown to increase cellular viability post-thaw. A series of mixed α/β glycopeptides are prepared and analyzed for antifreeze properties. The results of this study imply that it is not the gross conformation of the glycopeptide that is responsible for activity, but rather that intramolecular relationships may be responsible for disrupting the reorganization of ice. A technique was devised for the incorporation of triazoles into the analogues to investigate the importance of the linker and to greatly simplify the synthesis of a library of glycoconjugates. It was found that the IRI activity of glycopeptides is very sensitive to the distance between carbohydrate and peptide backbone. The electron density at the anomeric oxygen is an important parameter with respect to intramolecular networks. A series of substituted galactosides is presented that modify the electronics of the anomeric oxygen. The results demonstrate that decreasing electron density at this position appears to improve IRI activity in a predictable manner. To better understand the remarkable IRI activity of a key analogue, it was systematically truncated. This study led to the serendipitous discovery of a series of very highly IRI active analogues that do not contain a peptide backbone. These compounds represent the first non-glycopeptides that can show very significant IRI activity even at very low concentrations. The final portion of the thesis reports the efforts towards the preparation of a carbasugar analogue of AFGP-8.2012-02-22T16:24:00Z2012-02-22T16:24:00Z20122012-02-22Thèse / Thesishttp://hdl.handle.net/10393/20710en
collection NDLTD
language en
sources NDLTD
topic Antifreeze
Organic Synthesis
Bioorganic chemistry
Recrystallization inhibition
carbohydrates
small molecule
glycopeptide
beta peptide
CuAAC
spellingShingle Antifreeze
Organic Synthesis
Bioorganic chemistry
Recrystallization inhibition
carbohydrates
small molecule
glycopeptide
beta peptide
CuAAC
Trant, John F.
Importance of the Structural Components of C-linked Glycopeptides to Specific-antifreeze Activity: From Glycopeptides to Small Molecule Inhibitors of Ice Recrystallization
description One of the largest problems in current medicine is the shortage of organs for transplant due to technological limitations in the storage of organs for any length of time. A possible solution to this problem would involve cryopreservation. However, current cryopreservatives such as sucrose or DMSO have concerning cytotoxic issues that limit their possible applications. A major cause of cryoinjury is the uncontrolled recrystallization of inter and intra-cellular ice crystals that occurs during the thawing process leading to mechanical damage and dehydration. The Ben lab has thus been interested in the design of compounds that are capable of inhibiting this process but do not possess other undesirable properties found in the native compounds. These synthetic analogues have been shown to increase cellular viability post-thaw. A series of mixed α/β glycopeptides are prepared and analyzed for antifreeze properties. The results of this study imply that it is not the gross conformation of the glycopeptide that is responsible for activity, but rather that intramolecular relationships may be responsible for disrupting the reorganization of ice. A technique was devised for the incorporation of triazoles into the analogues to investigate the importance of the linker and to greatly simplify the synthesis of a library of glycoconjugates. It was found that the IRI activity of glycopeptides is very sensitive to the distance between carbohydrate and peptide backbone. The electron density at the anomeric oxygen is an important parameter with respect to intramolecular networks. A series of substituted galactosides is presented that modify the electronics of the anomeric oxygen. The results demonstrate that decreasing electron density at this position appears to improve IRI activity in a predictable manner. To better understand the remarkable IRI activity of a key analogue, it was systematically truncated. This study led to the serendipitous discovery of a series of very highly IRI active analogues that do not contain a peptide backbone. These compounds represent the first non-glycopeptides that can show very significant IRI activity even at very low concentrations. The final portion of the thesis reports the efforts towards the preparation of a carbasugar analogue of AFGP-8.
author Trant, John F.
author_facet Trant, John F.
author_sort Trant, John F.
title Importance of the Structural Components of C-linked Glycopeptides to Specific-antifreeze Activity: From Glycopeptides to Small Molecule Inhibitors of Ice Recrystallization
title_short Importance of the Structural Components of C-linked Glycopeptides to Specific-antifreeze Activity: From Glycopeptides to Small Molecule Inhibitors of Ice Recrystallization
title_full Importance of the Structural Components of C-linked Glycopeptides to Specific-antifreeze Activity: From Glycopeptides to Small Molecule Inhibitors of Ice Recrystallization
title_fullStr Importance of the Structural Components of C-linked Glycopeptides to Specific-antifreeze Activity: From Glycopeptides to Small Molecule Inhibitors of Ice Recrystallization
title_full_unstemmed Importance of the Structural Components of C-linked Glycopeptides to Specific-antifreeze Activity: From Glycopeptides to Small Molecule Inhibitors of Ice Recrystallization
title_sort importance of the structural components of c-linked glycopeptides to specific-antifreeze activity: from glycopeptides to small molecule inhibitors of ice recrystallization
publishDate 2012
url http://hdl.handle.net/10393/20710
work_keys_str_mv AT trantjohnf importanceofthestructuralcomponentsofclinkedglycopeptidestospecificantifreezeactivityfromglycopeptidestosmallmoleculeinhibitorsoficerecrystallization
_version_ 1716575579772289024