Surface grafting of polymers via living radical polymerization techniques; polymeric supports for combinatorial chemistry

Zwaneveld, Nikolas Anton Amadeus, Chemical Engineering & Industrial Chemistry, UNSW

January 2006

The use of living radical polymerization methods has shown significant potential to control grafting of polymers from inert polymeric substrates. The objective of this thesis is to create advanced substrates for use in combinatorial chemistry applications through the use of g-radiation as a radical source, and the use of RAFT, ATRP and RATRP living radical techniques to control grafting polymerization. The substrates grafted were polypropylene SynPhase lanterns from Mimotopes and are intended to be used as supports for combinatorial chemistry. ATRP was used to graft polymers to SynPhase lanterns using a technique where the lantern was functionalized by exposing the lanterns to gamma-radiation from a 60Co radiation source in the presence of carbon tetra-bromide, producing short chain polystyrene tethered bromine atoms, and also with CBr4 directly functionalizing the surface. Styrene was then grafted off these lanterns using ATRP. MMA was graft to the surface of SynPhase lanterns, using g-radiation initiated RATRP at room temperature. It was found that the addition of the thermal initiator, AIBN, successfully increased the concentration of radicals to a level where we could achieve proper control of the polymerization. RAFT was used to successfully control the grafting of styrene, acrylic acid and N,N???-dimethylacrylamide to polypropylene SynPhase Lanterns via a -initiated RAFT agent mediated free radical polymerization process using cumyl phenyldithioacetate and cumyl dithiobenzoate RAFT agents. Amphiphilic brush copolymers were produced with a novel combined RAFT and ATRP system. Polystyrene-co-poly(vinylbenzyl chloride) created using gamma-radiation and controlled with the RAFT agent PEPDA was used as a backbone. The VBC moieties were then used as initiator sites for the ATRP grafting of t-BA to give a P(t-BA) brush that was then hydrolyzed to produce a PAA brush polymer. FMOC loading tests were conducted on all these lanterns to assess their effectiveness as combinatorial chemistry supports. It was found that the loading could be controlled by adjusting the graft ratio of the lanterns and had a comparable loading to those commercially produced by Mimotopes.

ATRP

RAFT

Radiation

polymerization

grafting

living radical polymerization

Control of budburst in `Citrus` : studies on the dormancy of buds of `Citrus sinensis` (L.) Osbeck after insertion into rootstock stems / by Hakimah Halim

Halim, Hakimah

January 1985

Some ill. mounted / Bibliography: leaves 198-215 / xv, 215 leaves, [4] leaves of plates : ill. (some col.) ; 30 cm. / Title page, contents and abstract only. The complete thesis in print form is available from the University Library. / Thesis (Ph.D.)--University of Adelaide, Dept. of Plant Physiology, 1985

634.3141099423 19

Budding.

Grafting.

Orange Growth.

Orange Propagation.

Bioactivity Grafting of Cyclic Peptides: Structure Activity Studies of Grafted Cyclotides and SFTI-1

Sunithi Gunasekera

Unknown Date

Peptides are considered as drugs of the future because of their advantageous features of high specificity and low toxicity. However, the complete therapeutic potential of peptides has not yet been realized because of the in vivo instability displayed by most potential peptides. In this thesis, two naturally derived cyclic peptides, cyclotides and sunflower trypsin inhibitor 1 (SFTI-1), were utilized to impart stability to linear bioactive epitopes and enhance their therapeutic potential in a biological environment. Cyclotides are plant derived mini-proteins with compact folded structures and exceptional stability. Their stability derives from a head-to-tail cyclised backbone coupled with a cystine knot arrangement of three-conserved disulfide bonds. Sunflower typsin inhibitor 1 (SFTI-1) is a stable cyclic peptide containing a single disulfide bond. Taking advantage of these stable cyclic peptide frameworks, novel drug leads to inhibit/stimulate angiogenesis were developed by using the approach of ‘epitope grafting’ in which linear epitopes were grafted onto the cyclic peptide frameworks. Angiogenesis is a physiological condition that is unregulated in the progression of many diseases, including cancers and cardiovascular diseases. Thus the drug leads designed in the current project have potential therapeutic applications to combat cancers and cardiovascular diseases. To fully exploit cyclotides as drug scaffolds, it is imperative to understand their folding. Two main subfamilies, referred to as the Möbius and bracelet cyclotides have been identified and interestingly, they require dramatically different in vitro folding conditions to achieve formation of the conserved cyclic cystine knot motif. To determine the underlying structural elements that influence cyclotide folding, the in vitro folding of a suite of hybrid cyclotides based on combination of the Möbius cyclotide kalata B1 and the bracelet cyclotide cycloviolacin O1 was examined in this thesis. The pathways of folding of the two cyclotide subfamilies were found to be different and primarily dictated by specific residues harboured within inter-cysteine loops 2 and 6. Two changes in these loops, an amino acid substitution in loop 2 and an amino acid addition in loop 6 enabled the folding of cycloviolacin O1 under conditions where folding does not occur in vitro for the native peptide. Thus, the study identified key residues that are not in close proximity in the primary sequence or three-dimensional structure which assist folding in cyclotides. A key intermediate species in the folding pathway was isolated and characterised, and found to contain a native-like hairpin structure that appears to be a nucleation locus early in the folding process. The intermediate does not have native disulfide connectivities, but disulfide shuffling processes ultimately lead to a rearrangement to the native form. Overall these mechanistic findings on the folding of cyclotides are potentially valuable for protein engineering applications that utilize cystine-rich peptides as scaffolds in the design of new drug leads. The current study has also enabled the extention of the grafting studies to the bracelet cyclotide subfamily, which was intractable to grafting prior to this work. Cyclotides are gene encoded macrocyclic proteins and another way to exploit their potential as drug scaffolds, would be to develop combinatorial cyclotide libraries. The most efficient way to generate engineered cyclotides would be via recombinant expression, which currently remains unsuccessful, partly due to lack of understanding of the mechanism of cyclotide backbone cyclization. Understanding how the cyclotide precursor folds may provide clues to how cyliclization occurs. A conserved region known as the N-terminal repeat (NTR) region in the cyclotide precursor has been speculated to play an important role in precursor folding. In this thesis, the function of the NTR in the folding of the cyclotide precursor in vitro was examined via the design of a series of constructs for the precursor protein for the prototypic kalata B1 cyclotide, with incremental additions of the NTR region. Analysis of the constructs by NMR spectroscopy for evidence of secondary structure revealed that the NTR does not assist folding of the cyclotide precursor in vitro. Using diffusion NMR, the unstructured nature of the constructs was localized to the NTR region. In a complementary study, structural analysis of the full length cyclotide precursor was carried out by expressing the precursor gene for kalata B1 in a bacterial expression system. The full-length precursor was found to be unstructured in solution despite approximately half of the precursor comprising the mature domain and NTR, both of which are structured in isolation. The unstructured nature of the cyclotide precursor suggested that a different environment, or indeed interaction of the NTR with a particular enzyme involved in processing, is necessary for it to adopt a well-defined conformation and allow processing to produce the mature circular protein. The information that NTR alone may not assist folding of the cyclotide precursors has provided new impetus to examine the role of other potential folding auxiliaries such as protein disulfide isomerase in cyclotide folding and has indirectly advanced the production of cyclotides via transgenic means. In summary, this thesis has provided a fundamental insight into the folding of cyclotides, both when expressed as part of a precursor protein and in isolation via solid phase chemical synthesis, and has exploited the potential of cyclic peptide scaffolds in drug design applications.

270000 Biological Sciences

Cyclotides

NMR

Grafting

Peptides

Drug design

Folding

Bioactivity Grafting of Cyclic Peptides: Structure Activity Studies of Grafted Cyclotides and SFTI-1

Sunithi Gunasekera

Unknown Date

Peptides are considered as drugs of the future because of their advantageous features of high specificity and low toxicity. However, the complete therapeutic potential of peptides has not yet been realized because of the in vivo instability displayed by most potential peptides. In this thesis, two naturally derived cyclic peptides, cyclotides and sunflower trypsin inhibitor 1 (SFTI-1), were utilized to impart stability to linear bioactive epitopes and enhance their therapeutic potential in a biological environment. Cyclotides are plant derived mini-proteins with compact folded structures and exceptional stability. Their stability derives from a head-to-tail cyclised backbone coupled with a cystine knot arrangement of three-conserved disulfide bonds. Sunflower typsin inhibitor 1 (SFTI-1) is a stable cyclic peptide containing a single disulfide bond. Taking advantage of these stable cyclic peptide frameworks, novel drug leads to inhibit/stimulate angiogenesis were developed by using the approach of ‘epitope grafting’ in which linear epitopes were grafted onto the cyclic peptide frameworks. Angiogenesis is a physiological condition that is unregulated in the progression of many diseases, including cancers and cardiovascular diseases. Thus the drug leads designed in the current project have potential therapeutic applications to combat cancers and cardiovascular diseases. To fully exploit cyclotides as drug scaffolds, it is imperative to understand their folding. Two main subfamilies, referred to as the Möbius and bracelet cyclotides have been identified and interestingly, they require dramatically different in vitro folding conditions to achieve formation of the conserved cyclic cystine knot motif. To determine the underlying structural elements that influence cyclotide folding, the in vitro folding of a suite of hybrid cyclotides based on combination of the Möbius cyclotide kalata B1 and the bracelet cyclotide cycloviolacin O1 was examined in this thesis. The pathways of folding of the two cyclotide subfamilies were found to be different and primarily dictated by specific residues harboured within inter-cysteine loops 2 and 6. Two changes in these loops, an amino acid substitution in loop 2 and an amino acid addition in loop 6 enabled the folding of cycloviolacin O1 under conditions where folding does not occur in vitro for the native peptide. Thus, the study identified key residues that are not in close proximity in the primary sequence or three-dimensional structure which assist folding in cyclotides. A key intermediate species in the folding pathway was isolated and characterised, and found to contain a native-like hairpin structure that appears to be a nucleation locus early in the folding process. The intermediate does not have native disulfide connectivities, but disulfide shuffling processes ultimately lead to a rearrangement to the native form. Overall these mechanistic findings on the folding of cyclotides are potentially valuable for protein engineering applications that utilize cystine-rich peptides as scaffolds in the design of new drug leads. The current study has also enabled the extention of the grafting studies to the bracelet cyclotide subfamily, which was intractable to grafting prior to this work. Cyclotides are gene encoded macrocyclic proteins and another way to exploit their potential as drug scaffolds, would be to develop combinatorial cyclotide libraries. The most efficient way to generate engineered cyclotides would be via recombinant expression, which currently remains unsuccessful, partly due to lack of understanding of the mechanism of cyclotide backbone cyclization. Understanding how the cyclotide precursor folds may provide clues to how cyliclization occurs. A conserved region known as the N-terminal repeat (NTR) region in the cyclotide precursor has been speculated to play an important role in precursor folding. In this thesis, the function of the NTR in the folding of the cyclotide precursor in vitro was examined via the design of a series of constructs for the precursor protein for the prototypic kalata B1 cyclotide, with incremental additions of the NTR region. Analysis of the constructs by NMR spectroscopy for evidence of secondary structure revealed that the NTR does not assist folding of the cyclotide precursor in vitro. Using diffusion NMR, the unstructured nature of the constructs was localized to the NTR region. In a complementary study, structural analysis of the full length cyclotide precursor was carried out by expressing the precursor gene for kalata B1 in a bacterial expression system. The full-length precursor was found to be unstructured in solution despite approximately half of the precursor comprising the mature domain and NTR, both of which are structured in isolation. The unstructured nature of the cyclotide precursor suggested that a different environment, or indeed interaction of the NTR with a particular enzyme involved in processing, is necessary for it to adopt a well-defined conformation and allow processing to produce the mature circular protein. The information that NTR alone may not assist folding of the cyclotide precursors has provided new impetus to examine the role of other potential folding auxiliaries such as protein disulfide isomerase in cyclotide folding and has indirectly advanced the production of cyclotides via transgenic means. In summary, this thesis has provided a fundamental insight into the folding of cyclotides, both when expressed as part of a precursor protein and in isolation via solid phase chemical synthesis, and has exploited the potential of cyclic peptide scaffolds in drug design applications.

270000 Biological Sciences

Cyclotides

NMR

Grafting

Peptides

Drug design

Folding

Bioactivity Grafting of Cyclic Peptides: Structure Activity Studies of Grafted Cyclotides and SFTI-1

Sunithi Gunasekera

Unknown Date

Peptides are considered as drugs of the future because of their advantageous features of high specificity and low toxicity. However, the complete therapeutic potential of peptides has not yet been realized because of the in vivo instability displayed by most potential peptides. In this thesis, two naturally derived cyclic peptides, cyclotides and sunflower trypsin inhibitor 1 (SFTI-1), were utilized to impart stability to linear bioactive epitopes and enhance their therapeutic potential in a biological environment. Cyclotides are plant derived mini-proteins with compact folded structures and exceptional stability. Their stability derives from a head-to-tail cyclised backbone coupled with a cystine knot arrangement of three-conserved disulfide bonds. Sunflower typsin inhibitor 1 (SFTI-1) is a stable cyclic peptide containing a single disulfide bond. Taking advantage of these stable cyclic peptide frameworks, novel drug leads to inhibit/stimulate angiogenesis were developed by using the approach of ‘epitope grafting’ in which linear epitopes were grafted onto the cyclic peptide frameworks. Angiogenesis is a physiological condition that is unregulated in the progression of many diseases, including cancers and cardiovascular diseases. Thus the drug leads designed in the current project have potential therapeutic applications to combat cancers and cardiovascular diseases. To fully exploit cyclotides as drug scaffolds, it is imperative to understand their folding. Two main subfamilies, referred to as the Möbius and bracelet cyclotides have been identified and interestingly, they require dramatically different in vitro folding conditions to achieve formation of the conserved cyclic cystine knot motif. To determine the underlying structural elements that influence cyclotide folding, the in vitro folding of a suite of hybrid cyclotides based on combination of the Möbius cyclotide kalata B1 and the bracelet cyclotide cycloviolacin O1 was examined in this thesis. The pathways of folding of the two cyclotide subfamilies were found to be different and primarily dictated by specific residues harboured within inter-cysteine loops 2 and 6. Two changes in these loops, an amino acid substitution in loop 2 and an amino acid addition in loop 6 enabled the folding of cycloviolacin O1 under conditions where folding does not occur in vitro for the native peptide. Thus, the study identified key residues that are not in close proximity in the primary sequence or three-dimensional structure which assist folding in cyclotides. A key intermediate species in the folding pathway was isolated and characterised, and found to contain a native-like hairpin structure that appears to be a nucleation locus early in the folding process. The intermediate does not have native disulfide connectivities, but disulfide shuffling processes ultimately lead to a rearrangement to the native form. Overall these mechanistic findings on the folding of cyclotides are potentially valuable for protein engineering applications that utilize cystine-rich peptides as scaffolds in the design of new drug leads. The current study has also enabled the extention of the grafting studies to the bracelet cyclotide subfamily, which was intractable to grafting prior to this work. Cyclotides are gene encoded macrocyclic proteins and another way to exploit their potential as drug scaffolds, would be to develop combinatorial cyclotide libraries. The most efficient way to generate engineered cyclotides would be via recombinant expression, which currently remains unsuccessful, partly due to lack of understanding of the mechanism of cyclotide backbone cyclization. Understanding how the cyclotide precursor folds may provide clues to how cyliclization occurs. A conserved region known as the N-terminal repeat (NTR) region in the cyclotide precursor has been speculated to play an important role in precursor folding. In this thesis, the function of the NTR in the folding of the cyclotide precursor in vitro was examined via the design of a series of constructs for the precursor protein for the prototypic kalata B1 cyclotide, with incremental additions of the NTR region. Analysis of the constructs by NMR spectroscopy for evidence of secondary structure revealed that the NTR does not assist folding of the cyclotide precursor in vitro. Using diffusion NMR, the unstructured nature of the constructs was localized to the NTR region. In a complementary study, structural analysis of the full length cyclotide precursor was carried out by expressing the precursor gene for kalata B1 in a bacterial expression system. The full-length precursor was found to be unstructured in solution despite approximately half of the precursor comprising the mature domain and NTR, both of which are structured in isolation. The unstructured nature of the cyclotide precursor suggested that a different environment, or indeed interaction of the NTR with a particular enzyme involved in processing, is necessary for it to adopt a well-defined conformation and allow processing to produce the mature circular protein. The information that NTR alone may not assist folding of the cyclotide precursors has provided new impetus to examine the role of other potential folding auxiliaries such as protein disulfide isomerase in cyclotide folding and has indirectly advanced the production of cyclotides via transgenic means. In summary, this thesis has provided a fundamental insight into the folding of cyclotides, both when expressed as part of a precursor protein and in isolation via solid phase chemical synthesis, and has exploited the potential of cyclic peptide scaffolds in drug design applications.

270000 Biological Sciences

Cyclotides

NMR

Grafting

Peptides

Drug design

Folding

Biomaterials and microfabrication techniques for improved peripheral nerve regeneration

Song, Minjung.

January 2007

Thesis (Ph. D.)--Rutgers University, 2007. / "Graduate Program in Biomedical Engineering." Includes bibliographical references.

Histological analysis of the temporomandibular joint after replacement of the mandibular condyle using costochondral and sternoclavicular joint grafts in Macaca mulatta a thesis submitted in partial fulfillment ... in orthodontics ... /

Daniels, Samuel.

January 1986

Thesis (M.S.)--University of Michigan, 1986.

Particulate allogeneic bone grafts into maxillary alveolar clefts in humans a thesis submitted in partial fulfillment ... oral and maxillofacial surgery ... /

Nique, Thomas Alan.

January 1985

Thesis (M.S.)--University of Michigan, 1985.

Repair of diaphyseal defects Experimental studies on the role of bone grafts in reconstruction of circumferential defects in long bones.

Albrektsson, Björn,

January 1971

Akademisk avhandling--Universitetet i Göteborg. / Extra t.p., with thesis statement, inserted. Bibliography: p. 88-95.

Particulate allogeneic bone grafts into maxillary alveolar clefts in humans a thesis submitted in partial fulfillment ... oral and maxillofacial surgery ... /

Nique, Thomas Alan.

January 1985

Thesis (M.S.)--University of Michigan, 1985.