Global ETD Search

1	The synthesis of isosteres of pawhuskin- and schweinfurthin-based stilbenes Stockdale, David Paul 15 December 2017 (has links) The pawhuskins and schweinfurthins are two classes of stilbene natural product compounds that exhibit interesting biological activity, and because of this they have been studied extensively in our lab through synthetic means. The pawhuskins are a class of small molecule non-nitrogenous opioid receptor modulators that differ significantly in structure from the classical opioid receptor ligands. Some of the natural schweinfurnthins show strong and differential antiproliferative behavior towards a variety of human cancer cell lines. Prior to this research, a significant structure-activity relationship study conducted in our lab has produced a large library of analogues of both classes of compounds. The most potent of theses analogues have served as lead compounds in this study where the stilbene motif present in both classes was substituted with either an amide or triazole linkage. For the new pawhuskin analogues, three of the amide isomers and a triazole isomer synthesized showed antagonist activity for the opioid growth factor (OGF)/opioid growth factor receptor (OGFR) axis which is involved in cellular and organ growth control. This cellular signaling mechanism is targeted by “low-dose” naltrexone therapy which is being tested clinically for multiple sclerosis, Crohn’s disease, cancer, and wound healing disorders. The compounds described here are the first selective small molecule ligands for the OGF/OGFR system and will serve as important leads and probes for further study. For the new schweinfurthins analogues, all compounds synthesized retained antiproliferative activity against similar cancer cell lines to that of the natural compounds. The new amide analogues were produced in pairs only differing in the orientation of the amide linkage replacement for the stilbene motif. Signifigantly greater activity was seen for one orientation of the amide over the other. The synthetic efforts towards all of these analogues will be described herein along with their intriguing biological properties. Amide isostere Cancer Opioid growth factor Pawhuskins Schweinfurthins Triazole isostere Chemistry
2	Les cyclopropanes monofluorés : nouvelle architecture pour la conception de peptidomimétiques / Fluorinated cyclopropanes : a new scaffold for the conception of peptidomimetics Milanole, Gaëlle 08 November 2013 (has links) L’intérêt des composés organiques fluorés est de nos jours de plus en plus important en raison de leur large domaine d’application (agrochimie, nucléaire, matériaux, chimie médicinale…). Par exemple, en chimie médicinale, la présence d’un ou plusieurs atomes de fluor au sein de biomolécules conduit très souvent à une amélioration de leur profil thérapeutique. Par ailleurs, le cyclopropane, le plus petit et le plus tendu des cycloalcanes, permet également de modifier les caractéristiques pharmacologiques de composés biologiques de par sa géométrie inhabituelle. En effet, la rigidification structurale apportée par ce motif influe sur la biodisponibilité d’une biomolécule en améliorant sa sélectivité et son affinité pour un récepteur biologique. Dans ce contexte, nous avons choisi d’associer les propriétés remarquables de l’atome de fluor à la contrainte structurale du cyclopropane dans le but d’élaborer deux nouvelles classes de fluoropeptidomimétiques.Tout d’abord, nous nous sommes intéressés à la modification de la chaîne latérale d’acides aminés naturels en développant la synthèse des analogues cyclopropaniques fluorés de la méthionine, de la leucine, de la lysine et de l’arginine. Nous avons ensuite appliqué l’un de nos acides aminés cyclopropaniques fluorés à la synthèse totale de l’analogue fluoré d’un inhibiteur de la sérineprotéase NS3/4A, le TMC 435.Enfin, dans le but de proposer une voie de synthèse générale permettant l’accès aux pseudopeptides fluorés comportant un monofluorocyclopropane à la place du lien peptidique, nous avons développé une nouvelle stratégie basée sur une étape d‘addition nucléophile de réactifs organométalliques sur des N-(tert-butanesulfinyl)-α-fluoroimines chirales. / Fluoroorganic compounds are increasingly popular owing to their wide range of applications. For instance, in the field of medicinal chemistry, fluorinated molecules often lead to an improvement of the therapeutic profile compared to non-fluorinated derivatives. Besides, with its unique bonding properties, the cyclopropane ring provides unusual physical and pharmacological properties to structures that incorporate it. Indeed, the structural constraint provided by the cyclopropane ring clearly alters the selectivity and the affinity for a binding site. In this context, we decided to combine the cyclopropane and the fluorine atom to develop two new classes of peptidomimetics. First, we focused on the modification of the side chain of natural aminoacids (methionine, leucine,lysine and arginine) and the synthesis of fluorinated cyclopropyl analogues was achieved. Then, we applied our strategy to the synthesis of the fluorinated analogue of the TMC 435, a NS3/4A serine protease inhibitor involved in the replication cycle of Hepatitis C virus. Finally, in our project aiming at proposing a general method to access pseudopeptides featuring a fluorinated cyclopropane moiety as the peptide bond isostere, we develop a new strategy based on the nucleophilic addition of organometallic reagents to N-(tert-butanesulfinyl)-α-fluoroimines. This methodology allows us to control the asymmetric center on the N-terminal side of the peptide. Cyclopropane Fluor Acides aminés Peptidomimétiques Virus hépatite C Isostere Cyclopropane Fluor Aminoacids Peptidomimetics Hepatitis C Virus Isostere
3	Les cyclopropanes monofluorés : nouvelle architecture pour la conception de peptidomimétiques Milanole, Gaëlle 08 November 2013 (has links) (PDF) L'intérêt des composés organiques fluorés est de nos jours de plus en plus important en raison de leur large domaine d'application (agrochimie, nucléaire, matériaux, chimie médicinale...). Par exemple, en chimie médicinale, la présence d'un ou plusieurs atomes de fluor au sein de biomolécules conduit très souvent à une amélioration de leur profil thérapeutique. Par ailleurs, le cyclopropane, le plus petit et le plus tendu des cycloalcanes, permet également de modifier les caractéristiques pharmacologiques de composés biologiques de par sa géométrie inhabituelle. En effet, la rigidification structurale apportée par ce motif influe sur la biodisponibilité d'une biomolécule en améliorant sa sélectivité et son affinité pour un récepteur biologique. Dans ce contexte, nous avons choisi d'associer les propriétés remarquables de l'atome de fluor à la contrainte structurale du cyclopropane dans le but d'élaborer deux nouvelles classes de fluoropeptidomimétiques.Tout d'abord, nous nous sommes intéressés à la modification de la chaîne latérale d'acides aminés naturels en développant la synthèse des analogues cyclopropaniques fluorés de la méthionine, de la leucine, de la lysine et de l'arginine. Nous avons ensuite appliqué l'un de nos acides aminés cyclopropaniques fluorés à la synthèse totale de l'analogue fluoré d'un inhibiteur de la sérineprotéase NS3/4A, le TMC 435.Enfin, dans le but de proposer une voie de synthèse générale permettant l'accès aux pseudopeptides fluorés comportant un monofluorocyclopropane à la place du lien peptidique, nous avons développé une nouvelle stratégie basée sur une étape d'addition nucléophile de réactifs organométalliques sur des N-(tert-butanesulfinyl)-α-fluoroimines chirales. [CHIM:OTHE] Chemical Sciences/Other [CHIM:OTHE] Chimie/Autre Cyclopropane Fluor Acides aminés Peptidomimétiques Virus hépatite C Isostere
4	I. Collagen-like polypeptides. II. Helix-turn-helix peptides and turn mimetics Dai, Nan 15 August 2008 (has links) Collagen is one of the most important and abundant proteins in mammals. It consists of three left-handed PPII helixes coiled along a common axis to form a very compact right-handed super helix. The primary structure is shown to be (Gly-Xaa-Yaa)n repeats with high content of prolyl residues at both Xaa and Yaa positions. <i>Cis-trans</i> isomerization of the prolyl amide bonds is one of the rate-limiting steps during collagen triple helix folding. The conformationally locked alkene isosteres Fmoc-Gly-Ψ[(E)CH=C]-Pro-Hyp(tBu)-OH and Fmoc-Pro-Ψ[(E)CH=C]-Pro-OH were designed and synthesized. The synthesis of the Gly-Pro isostere had no stereo-control, and the two diastereomers of the tripeptide isostere Fmoc-Gly-Ψ[(E)CH=C]-Pro-Hyp(tBu)-OBn were separated by normal phase HPLC. Although the stereoselectivity of the asymmetric reduction was not good for the Pro-Pro isostere, the resulting diastereomers was separable by flash chromatography, and the absolute stereochemistry of the two diastereomers was determined by Mosher's method. The Gly-Pro alkenyl peptides, and their control peptide Ac-(Gly-Pro-Hyp)8-Gly-Gly-Tyr-NH2 were synthesized and purified. All three peptides showed a maximum around 225 nm and a minimum close to 200 nm in the CD spectra, which indicated the formation of PPII helixes. The Tm value of the control peptide was determined to be 50.0 °C. The peptide with Gly-Ψ[(E)CH=C]-L-Pro-Hyp as the guest triplet formed a stable triple helix with a Tm value of 28.3 °C. The peptide with Gly-Ψ[(E)CH=C]-D-Pro-Hyp as the guest triplet showed a linear decrease in the ellipticity with increasing temperature, which indicated that no triple helix was formed. The Pro-Pro alkenyl peptide and its control peptide H-(Pro-Pro-Gly)₁₀-OH were synthesized and purified. The T<sub>m</sub> value of control peptide was determined to be 31.6 °C by extrapolation to 0 M TMAO in PBS buffer, which was very close to the measured value of 31.5 °C. The Pro-Pro alkenyl peptide began to show a maximum around 225 nm in the CD spectra when the concentration of TMAO was higher than 2.5 M. After extrapolation to 0 M TMAO, the T<sub>m</sub> value was determined to be –22.0 °C. These results indicate that the backbone inter-chain hydrogen bond is one of the major forces in stabilizing the collagen triple helix, while <i>cis-trans</i> isomerization has limited contribution. The intrinsic properties of the amide bond may have huge influence on the stability of the collagen triple helix. The helix-turn-helix motif is an important tertiary structure in DNA-binding proteins. Stepwise modifications of the Antennapedia HTH peptide (27-55) were performed to improve the helicity and stability. The peptide with more side-chain ion-pairs was over 4 times more helical than the native Antp peptide, while the Ala-based peptide was over 9 times more helical than the native peptide. A 12-membered ring, Fmoc-protected HTH-turn mimic was designed and synthesized, and was ready for solid phase peptide synthesis. The solubility of the cyclic peptide was very poor, and the purification of the final product was very difficult. The solubility problem might also affect solid phase peptide synthesis in the future. / Ph. D. helicity HTH-turn mimic. conformationally locked isostere polypeptides triple helix stability collagen helix-turn-helix
5	The MHC-glycopeptide-T cell interaction in collagen induced arthritis : a study using glycopeptides, isosteres and statistical molecular design in a mouse model for rheumatoid arthritis Holm, Lotta January 2006 (has links) <p>Rheumatoid arthritis (RA) is an autoimmune disease affecting approximately 1% of the population in the western world. It is characterised by a tissue specific attack of cartilage in peripheral joints. Collagen induced arthritis (CIA) is one of the most commonly used animal models for (RA), with similar symptoms and histopathology. CIA is induced by immunisation of mice with type II collagen (CII), and the immunodominant part was previously found to be located between residues 256-270. This thesis describes the interaction between the MHC molecule, glycopeptide antigens from CII and the T cells that is essential in development of CIA. The glycopeptide properties for binding to the mouse MHC molecule Aq have been studied, as well as interaction points in the glycopeptide that are critical for stimulation of a T-cell response.</p><p>The thesis is based on five studies. In the first paper the minimal glycopeptide core, that is required for binding to the Aq molecule while still giving a full T cell response was determined. The second paper studied the roles of amino acid side-chains and a backbone amide bond as T-cell contact points. In the third paper the hydrogen bond donor-acceptor characteristics of the 4-OH galactose hydroxyl group of the glycopeptide was studied in detail. In the fourth paper we established a structure activity relationship (QSAR model) for (glyco)peptide binding to the Aq molecule. Finally, the stereochemical requirements for glycopeptide binding to the Aq molecule and for T-cell recognition was studied in the fifth paper.</p><p>The study was performed using collagen glycopeptide analogues, which were synthesised on solid phase. Amide bond and hydroxyl group isosteres were introduced for study of hydrogen bond donor-acceptor characteristics. Statistical methods were used to design a representative peptide test set and in establishing a QSAR model.</p><p>The results give a deeper understanding of the interactions involved in the ternary MHC-glycopeptide-T cell complex. This information contributes to research directed towards finding new treatments for RA.</p> Rheumatoid arthritis collagen T-cell class II MHC solid phase peptide synthesis glycopeptide peptide isostere PCA statistical molecular design PLS QSAR sequence binding motif Organic chemistry Organisk kemi
6	The MHC-glycopeptide-T cell interaction in collagen induced arthritis : a study using glycopeptides, isosteres and statistical molecular design in a mouse model for rheumatoid arthritis Holm, Lotta January 2006 (has links) Rheumatoid arthritis (RA) is an autoimmune disease affecting approximately 1% of the population in the western world. It is characterised by a tissue specific attack of cartilage in peripheral joints. Collagen induced arthritis (CIA) is one of the most commonly used animal models for (RA), with similar symptoms and histopathology. CIA is induced by immunisation of mice with type II collagen (CII), and the immunodominant part was previously found to be located between residues 256-270. This thesis describes the interaction between the MHC molecule, glycopeptide antigens from CII and the T cells that is essential in development of CIA. The glycopeptide properties for binding to the mouse MHC molecule Aq have been studied, as well as interaction points in the glycopeptide that are critical for stimulation of a T-cell response. The thesis is based on five studies. In the first paper the minimal glycopeptide core, that is required for binding to the Aq molecule while still giving a full T cell response was determined. The second paper studied the roles of amino acid side-chains and a backbone amide bond as T-cell contact points. In the third paper the hydrogen bond donor-acceptor characteristics of the 4-OH galactose hydroxyl group of the glycopeptide was studied in detail. In the fourth paper we established a structure activity relationship (QSAR model) for (glyco)peptide binding to the Aq molecule. Finally, the stereochemical requirements for glycopeptide binding to the Aq molecule and for T-cell recognition was studied in the fifth paper. The study was performed using collagen glycopeptide analogues, which were synthesised on solid phase. Amide bond and hydroxyl group isosteres were introduced for study of hydrogen bond donor-acceptor characteristics. Statistical methods were used to design a representative peptide test set and in establishing a QSAR model. The results give a deeper understanding of the interactions involved in the ternary MHC-glycopeptide-T cell complex. This information contributes to research directed towards finding new treatments for RA. Rheumatoid arthritis collagen T-cell class II MHC solid phase peptide synthesis glycopeptide peptide isostere PCA statistical molecular design PLS QSAR sequence binding motif Organic chemistry Organisk kemi
7	Modified Glycopeptides Targeting Rheumatoid Arthritis : Exploring molecular interactions in class II MHC/glycopeptide/T-cell receptor complexes Andersson, Ida E. January 2011 (has links) Rheumatoid arthritis (RA) is an autoimmune inflammatory disease that leads to degradation of cartilage and bone mainly in peripheral joints. In collagen-induced arthritis (CIA), a mouse model for RA, activation of autoimmune CD4+ T cells depends on a molecular recognition system where T-cell receptors (TCRs) recognize a complex between the class II MHC Aq protein and CII259-273, a glycopeptide epitope from type II collagen (CII). Interestingly, vaccination with the Aq/CII259-273 complex can relieve symptoms and cause disease regression in mice. This thesis describes the use of modified glycopeptides to explore interactions important for binding to the Aq protein and recognition by autoimmune T-cell hybridomas obtained from mice with CIA. The CII259-273 glycopeptide was modified by replacement of backbone amides with different amide bond isosteres, as well as substitution of two residues that anchor the glycopeptide in prominent pockets in the Aq binding site. A three-dimensional structure of the Aq/glycopeptide complex was modeled to provide a structural basis for interpretation of the modified glycopeptide’s immunological activities. Overall, it was found that the amide bond isosteres affected Aq binding more than could be explained by the static model of the Aq/glycopeptide complex. Molecular dynamics (MD) simulations, however, revealed that the introduced amide bond isosteres substantially altered the hydrogen-bonding network formed between the N-terminal 259-265 backbone sequence of CII259-273 and Aq. These results indicated that the N-terminal hydrogen-bonding interactions follow a cooperative model, where the strength and presence of individual hydrogen bonds depended on the neighboring interactions. The two important anchor residues Ile260 and Phe263 were investigated using a designed library of CII259-273 based glycopeptides with substitutions by different (non-)natural amino acids at positions 260 and 263. Evaluation of binding to the Aq protein showed that there was scope for improvement in position 263 while Ile was preferred in position 260. The obtained SAR understanding provided a valuable basis for future development of modified glycopeptides with improved Aq binding. Furthermore, the modified glycopeptides elicited varying T-cell responses that generally could be correlated to their ability to bind to Aq. However, in several cases, there was a lack of correlation between Aq binding and T-cell recognition, which indicated that the interactions with the TCRs were determined by other factors, such as presentation of altered epitopes and changes in the kinetics of the TCR’s interaction with the Aq/glycopeptide complex. Several of the modified glycopeptides were also found to bind well to the human RA-associated DR4 protein and elicit strong responses with T-cell hybridomas obtained from transgenic mice expressing DR4 and the human CD4 co-receptor. This encourages future investigations of modified glycopeptides that can be used to further probe the MHC/glycopeptide/TCR recognition system and that also constitute potential therapeutic vaccines for treatment of RA. As a step towards this goal, three modified glycopeptides presented in this thesis have been identified as candidates for vaccination studies using the CIA mouse model. Major histocompatibility complex class II MHC T-cell receptor rheumatoid arthritis collagen-induced arthritis glycopeptide amide bond isostere comparative modeling rational design molecular docking molecular dynamics simulation statistical molecular design Bioorganic chemistry Bioorganisk kemi
8	Investigating the Intercarbonyl X...C' (X=O/S/N) Interactions in Short Peptides and Peptidomimetics. Evidence of charge->II* Interactions. Synthesis and Characterization of Thioimidate Isostere Containing Peptidomimetics Tumminakatti, Shama January 2016 (has links) (PDF) This thesis entitled “Investigating the Intercarbonyl X···C′ (X = O/S/N) Interactions in Short Peptides and Peptidomimetics. Evidence of Charge→π* Interactions. Synthesis and Characterization of Thioimidate Isostere Containing Peptidomimetics” is divided into two chapters. First chapter is further subdivided into four sections where investigation of the nature of intercarbonyl X···C′ (X = O/S/N) interactions in short peptides and peptidomimetics has been described. The second chapter also has been subdivided into three parts where the syntheses and characterization of thioimidate (1,3-thiazine) and imidate (1,3-oxazine) isostere containing peptidomimetics have been discussed. Chapter 1: Section A: Revisiting the earlier models for the intercarbonyl O···C′ interactions The proximity between carbonyls is ubiquitous in crystals. Here we review the key reports that have assigned an n→π* nature to interactions between carbonyl oxygen (O) atoms and adjacent carbonyl carbon (C′) atoms (O···C′). Based on earlier hypotheses (by Burgi-Dunitz) that suggest that “the minimum energy trajectory of a nitrogen nucleophile adding to the C′ of carbonyl is at N···C′ distances of ≤ 3.2 Å and along N···C′=O angles of 109±10o”, the optimum trajectory for addition of an O to an adjacent C′ has also been assigned to be the same (O···C′ distance ≤ 3.2 Å and O···C′=O angle is 109±10o). Additionally, all O and C′ atoms within these boundary conditions in crystal structures were assigned a status of interacting and those outside of the same as non-interacting. Based on quantum mechanical models for electronic orbitals that contain the valence electrons of such proximal O and C′ atoms – derived through NBO (Natural Bond Order) calculations (on crystal structures) – it has been proposed that the filled non-bonding lone pair orbital of the O (donor) overlaps with the empty π* orbital of the carbonyl C′ (acceptor), in these O···C′ interactions. Hence, these have been termed as n→π* interactions. Using DFT (Density Functional Theory) calculations energies for these interactions have been predicted to range from 0.5 to 5.0 kcal mol-1, which are similar to those for other strong non-covalent interactions such as H-bonding, weak cation-π, etc. This n→π* interaction model is assumed to prevail between adjacent carbonyls (Oi-1···C′i) at Xaa-Pro dipeptide motifs and to be exclusively responsible for the changes in equilibrium constant values (Kc/t) for the trans to cis isomerisation reaction at Xaa-Pro peptide bond in chosen analogue molecules. Based on this assumption, these Kc/t values have been used as direct experimental equivalents for the energies of these n→π* interactions. Simultaneous to such review of literature, this chapter highlights several anomalies in this n→π* model for the intercarbonyl O···C′ interactions. We discuss the alternate models that also exist for the O···C′ proximities and show that several features – such as improved pyramidalization at the acceptor carbonyl; decrease in Kc/t values at Xaa-Pro peptide bonds; and small changes in 13C NMR chemical shift values for the acceptor carbonyls; etc. – that accompany the shortening of O···C′ distance, can be explained without invoking the n→π* interaction model. Moreover, we discuss key observations such as the presence of near-symmetric antiparallel short contacts between carbonyl groups (C=O) in crystal structures, which cannot be explained by the quantum mechanical n→π* model for the O···C′ interactions. Chapter 1: Section B: Spectroscopic and kinetic investigations into the nature of X···C′ (X = O/S) interactions in N-acyl homoserine lactones (AHLs) In this section the key interactions involving the adjacent carbonyls in model N-acyl homoserine lactones (AHLs) (which are signalling molecules in quorum sensing) in solution, their electronic nature and their influence on solvolysis of the lactone ring have been investigated. Earlier, in the crystal structures of two sterically encumbered synthetic AHL analogues N-trimethyl acetyl homoserine lactone and N-tribromoacetyl homosrine lactone the presence of an n→π* orbital overlap type interaction between Oacyl and C′lact had been suggested. Based primarily on this, the operation of similar OacylC′lact interaction was proposed in all AHLs in their solution conformations as well. More intriguingly, the interaction was hypothesized to decrease the rates of lactone hydrolysis, rendering AHLs with longer biological half-life. This is contrary to physical organic understanding of nucleophilic catalysis of addition to carbonyls. Here we synthesize a variety of AHLs and analyze their NMR and FT-IR data in solution. The spectral data reveal that the role of the N-acyl group in AHLs is to withdraw eˉs from lactone C=O inductively and to improve electronic shielding at C′lact. Lack of appreciable changes in C=O stretching frequencies of lactone and 13C NMR chemical shift values of C′lact indicate the absence of electronic perturbation of the π* of the lactone. Similar non-variance of spectral bands with improvement in nucleophilicity of the N-acyl group indicates the absence of any evidence for n→π* nature for the O···C′ interactions (between the lone pair of eˉs from Oacyl to π* at C′lact). Further the spectroscopic data indicate that any change in charge at the acyl O is felt by C′lact and this weak interaction releases energy in the order of ≤ 0.05 kcal mol-1. The combined influence of the electron withdrawing N-acyl group and the weak Oacyl···C′lact interaction in AHLs is that, increasing the charge at Oacyl increases the rate of solvolysis of lactone. Analysis of the conformation of the lactone ring in the LuxR receptor-bound and unbound crystal structure forms reveals the flattening of the puckered ring in the LuxR bound state – facilitated by several interactions with the receptor. Conserved interactions between LuxR and AHLs lock the N-acyl carbonyl motif such that they are orthogonal to the lactone carbonyl and intramolecular interaction between Oacyl and C′lact is precluded. We propose the design of flat cyclic analogues of γ-butyrolactone bearing electron withdrawing side chains as potential molecules for taking advantage of bacterial quorum sensing in environmental applications and biotechnology. Chapter 1: Section C: Spectroscopic investigation into the nature of intercarbonyl X•••C′ (X = O/S/N) interactions: Carbamyl-cisPro model systems In this section we investigate the nature of intercarbonyl X···C′ interactions in carbamyl-Pro model systems using spectroscopic methods like FT-IR and 1D NMR. Further we derive the enthalpic and entropic contributions towards the free energy for trans to cis isomerization (Kc/t) at these model carbamyl-Pro systems. Our results reveal that changes in Kc/t values cannot always be used as proof for the presence or absence of electronic interactions, and hence to unambiguously suggest the nature of these interactions. Cis/trans isomerism exists at Xaa-Pro amide and carbamate motifs, and it was proposed that in acyl-Pro systems the O···C′ interactions are responsible for the stability of either cis or trans depending upon their direction of operation (Forward direction: O of Xaa is the donor of electrons to π* at C′ of Pro; Reverse direction: O of Pro is the donor of electrons to π* at C′ of Xaa). Investigation of the carbamyl-Pro systems can shed further light on this hypothesis. Hence we undertook the first spectroscopic and Van’t Hoff analysis of homologous carbamyl-Pro model systems. The Kc/t of the homologous series surprisingly increased with increase in the bulk at R (R varies from Me to tBu). The spectroscopic data revealed the presence of charge→σ* interactions at carbamyl groups. This interaction locks the carbamyl motif in the s-transoid conformation, along the C′-O σ-bond. Such conformational lock is observed to be greater in carbamyl groups where R has at least one Cα-H bond. Interestingly, we observe the absence of X···C′ electronic interactions that may selectively stabilize the cisPro conformer in these molecules. Van’t Hoff analyses on the other hand showed that as the number of Me substituents in R increases (R = Me to iPr), there is a favorable increase in entropy ( So) associated with the transPro to cisPro conformational isomerism. As a result, the population of the cisPro conformer improves significantly as the steric bulk at R increases. We note that the enthalpy of cisPro is however relatively small and remains unfavourable as R-bulk increases (Me to iPr). These data reveal the influence of electrostatic interactions between charged groups, on the change in entropy associated with cis/trans isomerism at carbamayl-Pro motifs. This not only opposes the n→π* model, but also provides an example for the important point that changes in Kc/t can/should not be taken as direct evidences of any single electronic interaction. Importantly, this study provides another example where electronic interactions between charged, polarized carbonyl motif rather than nonbonding lone pair eˉs of carbonyl motifs influence cis/trans isomerism at Xaa-Pro systems. Chapter 1: Section D: Investigation of the stereoelectronic nature of the X···C′ (X = O/S) contacts In this section we provide experimental evidence for the existence of inverse correlation between the charge on the O nucleophile and the O···C′ distances. We show that O and C′ atoms (of adjacent carbonyls), which are separated at distances > 3.20 Å in carefully chosen analogues, come together to σ-bonding distances when the charge on O is increased to -1. Additionally, the influence of backbone steric factors on these charge→π* interactions is investigated. A partial covalent nature was proposed for the O···C′ interactions. Our study showed that the shortest intercarbonyl O···C′ distances between the O of 1°, 2° and 3° amide carbonyls and proximal C′ in molecules found in the Cambridge Structural Database (CSD) (v5.36, November 2014) show an inverse linear correlation with the partial negative charge (δ‾) on the amide carbonyl O rendered by natural amide carbonyl polarization. These data suggest the interaction of charge on the nucleophilic O with π* of the acceptor carbonyl. Further on increasing the charge on nucleophilic carbonyl O to -1 in the model compound, we achieved the formation of σ-bond through non-native (natively disallowed) Oi‾¹→C′i-1 interaction. Here we provide the first experimental evidences that suggest the interaction between charge of O and π* at adjacent C′ (the charge→π* interaction) and the latent covalent nature of the O···C′ interactions. This charge→π* model explains the origins of variations in O···C′ distances (3.20 Å–1.43 Å) in proteins and complexes that occur to suit biological functions; and the mutual interactions between antiparallel carbonyls. Further the effect of 3 key steric factors – namely the allowed τ (N-Cα-C′) angle, entropy and allowed (ϕ,ψ) angles – on the non-native Oi→C′i-1 interactions were investigated in the model compounds. Our kinetic data revealed that, the allowed τ angles have the greatest influence on charge→π* interaction, followed by entropy. Importantly the allowed (ϕ,ψ) torsional angles for residues, that govern protein folding pathways, have little influence on the O···C′ electronic interactions. Chapter 2: Section A: Design and synthesis of novel 1,3-Thiazine containing peptidomimetics This section describes the first synthesis of peptidomimetics containing the 1,3-thiazine isostere (thioimidate isostere for the peptide bond), at the C-terminus and also at the middle of the peptide. The synthesis of the 6-membered heterocycles – 1,3-oxazine (Oxa) – have earlier been reported. Oxa motifs constrain preceding amino acid backbones into natively disallowed conformations. Here we present the first synthesis of peptidomimetics containing the 1,3-thiazine (Thi) (the thioimidate analogue of Oxa) motif, by the treatment of N-(3-hydroxypropyl)thioamides with MsCl/Et3N, which leads to intramolecular S-alkylation / cyclization. When placed at the C-terminus of acyl-Pro motifs the Thi group selectively improves the stability of the rare s-cis conformation of the acyl-Pro peptide bond. Further this method has been used to synthesize peptidomimetics in which an endogenous peptide bond is replaced with the Thi isostere. These Thi analogues are shown to be stable to standard conditions of peptide coupling and N- and C- terminus protection, deprotection and can be extended selectively at their N- or C- termini. Chapter 2: Section B: Epimerization in 1,3-Thiazine containing peptidomimetics The epimerization in 1,3-thiazine containing peptidomimetics and its mechanism has been described in this section. Further the aggregation behaviour of these thiazines, in solution and crystal structures, has been studied. It has been well-documented that epimerization (Racemization) occurs at the chiral centers at the C(2) exo methine of 1,3-thiazolines and 1,3-thiazoles. Similar epimerizations in 1,3-thiazines have however not been explored. Here we report our observation of epimerization in chiral aminoacid (non Pro) containing 1,3-thiazine peptidomimetics. Our studies revealed that, the epimerization happens at C2 positions of chiral (non-Pro) amino acids-derived 1,3-thiazine containing peptiomimetics. And NH of chiral (non-Pro) amino acid fused to Thi ring at C2 position is necessary for the epimerization. Further we investigated the Boc-Xaa-Thi analogues in solution, which showed two resonances for the carbamate N-H (HN) and the H of Xaa, irrespective of the side chain in Xaa, in CDCl3 a weakly polar solvent. The integral ratios of the major : minor peak increased with increase in concentration for Boc-Val-Thi, indicating the formation of H-bonded aggregates. Even in the polar aprotic (DMSO-d6) and polar protic (D2O) solvents the two sets of resonances were observed for Boc-Val-Thi in 1H NMR. But when the thioimidate N is protonated (N of Thi is no longer a H-bond acceptor), showed only a single set of resonances. Formation of intermolecular H-bonds involving N of Thi in solution is thus evident in the aggregates. This is further suggested by the crystal structures obtained for the peptide mimetics Boc-Val-Thi, Boc-Leu-Thi and Boc-Phe-Thi in which the racemic pair, instead of one enantiomer of it, are present in the unit cell and are locked in a pair of intermolecular 10 membered H-bonding interactions between NThi and HLeu similar to an antiparallel β-sheet. A mechanism for racemization is proposed, where this strong H-bond assists enamination/racemization process. Chapter 2: Section C: Influence of a disallowed conformation of Aib on the structure of a 310-helical fold In this section, the effect of the presence of a disallowed conformation of Aib at the C-terminus of a 310-helical peptide, on the structure and fold of the rest of the peptide body has been studied in solution. We constrain the C-terminal Aib in the Aib-rich octapeptide (N-tert-butoxycarbonyl-Leu1-Aib2-Ala3-Leu4-Aib5-Ala6-Phe7-Aib8-CO2Me (1), which adopts a complete 310-helical conformation throughout the peptide body in the crystal structure and in solution) in one of its disallowed conformations using a method earlier developed in our group. This involves the synthetic modification of the C-terminal ester (Aib8-CO2Me) in 1 to an Oxa (Aib8-Oxa) in 2 and the study of its effect on the peptide body. Analyses of the solution FT-IR, CD, ¹H, 2D (TOCSY, HSQC, HMBC and ROESY) and solvent polarity dependent NMR data reveal that 2 adopts a 310-helical conformation similar to that of 1. The C-terminal CO2Me → Oxa (E → O) modified Aib8-Oxa motif is constrained in a unique conformation where the two Cβ atoms of Aib8 are staggered with respect to the Aib8 C=O and are both interacting with the two Hβ of Phe7. Here the Aib* backbone is constrained by a 5-membered ring NOxa∙∙∙HAib* H-bond, in a C5i structure. Solvent polarity dependent ¹H NMR data indicate the formation and persistence of C5i H-bond at the Aib8-Oxa motif in 2. Analyses of the ROESY, solvent polarity dependent ¹H NMR and CD spectra reveal that four crucial changes in ROESY cross peaks occur at the Phe7-Aib8 motif of 2, compared to that in 1. From these spectroscopic data it has been confirmed that there is no change in the structure of 2 from Leu1 to Ala6. Whatever the crucial changes happened are at Phe7-Aib8 motif of 2. Hence our study showed that the significant structural consequences of this disallowed conformation of Aib are primarily observed to occur in the residue in its immediate vicinity, rather than in the whole peptide body. Presence of a disallowed fold at a residue need not result in disruption of the structure, or the overall fold, in the rest of the peptide body. Nature of Intercarbonyl Synthesis of Thiomidate Isotere Isostere Peptidomimetics Peptides and Peptidomimetics 1,3-Thiazine Peptide Mimics N-acyl Homoserine Lactones (AHLs) Carbamyl-cisPro Model Systems X···C′ (X = O/S) Contacts Aib Organic Chemistry
9	Isomerization-Locked Alkene Analogues of Xaa–Pro Dipeptides in the Proteins Collagen and Bora Arcoria, Paul Joseph 25 July 2022 (has links) Collagen is one of the most abundant human proteins. It exists as a right-handed superhelix called the triple helix. The triple helix consists of three left-handed polyproline type II (PPII helices) that intertwine around a common axis. Each PPII helix has the repeating peptide sequence (Gly–Xaa–Yaa)n with a high content of (2S)-proline (Pro) in the Xaa position (ca. 28%) and (2S,4R)-hydroxyproline (Hyp) in the Yaa position (ca. 38%). Unique to the prolyl amide is the ease of cis-trans isomerization. Since the triple helix necessitates that all peptide bonds be in the trans conformation, isomerization is the rate-limiting step in collagen folding. However, eliminating isomerization with a trans-locked alkene isostere destabilizes collagen-like peptides. Collagen is stabilized by electronic interactions, namely the n→π* interaction. Halo-alkene isosteres may be used to recapture these electronic interactions and stabilize a collagen-like peptide. An in-depth conformational analysis was conducted at the MP2/6-311+G(2d,p) level of theory to determine the viability of conformationally-locked halo-alkene isosteres. Fluoro-alkenes and chloro-alkenes were modeled at both the Gly–Pro and Pro–Pro (as a Pro–Hyp mimic) amide positions. Compared to the collagen crystal structure PDB ID: 1K6F, we found the fluoro-alkenes were closer geometric matches to both Gly–Pro and Pro–Pro than the corresponding chloro-alkenes. The chloro-alkene was predicted to have stronger n→π* interactions. The trans-locked proteo-alkene was also analyzed to understand why it destabilized the triple helix. We found that these models had other local minima close to the desired PPII geometry, likely leading to enhanced backbone flexibility. This deleterious flexibility was not predicted for either fluoro-alkene or chloro-alkene models. The conformationally-locked halo-alkene isostere Fmoc–Gly–Ψ[(Z)CF=C]-Pro–Hyp(tBu)–OH was designed and synthesized as a (Z)-fluoro-alkene Gly–Pro isostere. We used the chiral catalyst, L-Thr, for asymmetric aldol addition to cyclopentanone, which inadvertently enhanced the yield of the wrong enantiomer, in contrast with aldol addition to cyclohexanone. A Mg2+-promoted Horner-Wadsworth-Emmons reaction afforded the (Z)-fluoro-alkene over the (E)-fluoro-alkene in about a 2:1 ratio. The two diastereomers, Fmoc–Gly–Ψ[(Z)CF=C]-L-Pro–Hyp(tBu)–OH and Fmoc–Gly–Ψ[(Z)CF=C]-D-Pro–Hyp(tBu)–OH were separated by supercritical CO2 chromatography. The collagen-like peptides Ac–(Gly–Pro–Hyp)3–Gly–Ψ[(Z)CF=C]-L-Pro–Hyp–(Gly–Pro–Hyp)4–Gly–Gly–Tyr–NH2, Ac–(Gly–Pro–Hyp)3–Gly–Ψ[(Z)CF=C]-D-Pro–Hyp–(Gly–Pro–Hyp)4–Gly–Gly–Tyr–NH2, and the control peptide Ac–(Gly–Pro–Hyp)8–Gly–Gly–Tyr–NH2 were synthesized on solid-phase resin. The CD spectra of all three peptides showed the characteristic collagen triple-helix signature. The folding stability was determined by thermal melting (Tm). The peptide with the fluoro-alkene guest, Gly–Ψ[(Z)CF=C]-L-Pro–Hyp, was found to have a Tm value of 42.2 °C. The Tm of the control peptide was found to be 49.0 °C, a difference in stability of only ΔTm –6.8. Thus, the (Z)-fluoro-alkene as a Gly–Pro isostere forms a relatively stable triple helix. The peptide with the Gly–Ψ[(Z)CF=C]-D-Pro–Hyp guest was shown to have a linear relationship between ellipticity and temperature, indicating that a stable triple helix did not form. The enhanced stability of the (Z)-fluoro-alkene compared to the (E)-alkene Gly–Pro isostere (Tm = 28.3 °C) may be due to a stabilizing n→π* interaction, as determined by NMR deshielding of the 19F nucleus in the collagen-like peptide. In biological systems, isomerization of the prolyl amide is catalyzed by enzymes called PPIases. The PPIase Pin1 specifically catalyzes isomerization of the pSer–Pro sequence from the cis-conformation to the trans-conformation. Pin1 plays a crucial role in the G2→M transition of the cell cycle, implying the importance of cis-trans isomerization. The dipeptides H–Ser–Ψ[(Z)CH=C]-Pro–OH, H–Ser–Ψ[(E)CH=C]-Pro–OH and native H–Ser–Pro–OH were synthesized by literature methods, and activated for aminoacylation of tRNACUA for in vitro transcription-translation. Aminoacylation by chemical methods required the synthesis of a pdCpA dinucleotide. Formation of the dipeptide-dinucleotide complex was not completed because protection of the Ser side chain was problematic. On the other hand, conversion of the dipeptide into the 3,5-dinitrobenzyl ester conjugate allowed for enzymatic aminoacylation using the dFx flexizyme, an RNA enzyme. The native dipeptide was successfully coupled to tRNACUA and is ready for incorporation into a full-length Bora protein by in vitro transcription-translation. Both cis- and trans-locked alkene mimics have been converted to their respective 3,5-dinitrobenzyl ester conjugates. / Doctor of Philosophy / The proline amide (Xaa–Pro) in peptides and proteins is unique in that it allows for cis-trans isomerization. The triple-helix region of human collagen consists mostly of the repeating sequence (Gly–Pro–Hyp)n. Xaa–Pro amide-bond isomerization is rate-limiting for triple-helix formation. We eliminated isomerization at one position in a collagen-like peptide with a locked alkene mimic of Gly–Pro to attempt to stablize the triple-helix. Our computational results predicted that a fluoro-alkene Gly–Pro isostere would be a close geometric match for the native amide. Experimental results showed that a collagen-like peptide with a fluoro-alkene Gly–Pro isostere has an unfolding temperature that is 6.9 °C lower than the native control peptide. 19F NMR data of the collagen-like peptide shows a surprising deshielding of the fluorine nucleus, suggesting its participation in a stabilizing n→π* electronic interaction, similar to the native amide. Isomerization also plays a key role in proper cell division. We followed established methods to synthesize the cis- and trans-locked alkene mimics of Boc–Ser–Pro–OH and converted them into the 3,5-dinitrobenzyl ester conjugates. The 3,5-dinitrobenzyl ester is recognized by the dinitrobenzyl flexizyme (dFx) for enzymatic aminoacylation of tRNA. Once the alkene isosteres are aminoacylated, they will be incorporated into a full-length cell cycle regulatory protein called Bora to determine whether the cis- or trans-Pro state is necessary for healthy human mitosis, and which results in cancerous human mitosis. collagen triple helix polyproline type II helix peptide fluoro-alkene chloro-alkene proteo-alkene conformationally-locked isostere stability n→π* Ser–cis-Pro Ser–trans-Pro aminoacylation flexizyme cell cycle mitosis
10	Synthèse et analyse conformationelle de dipeptides contenant l’isostère hydroxyéthylène Genest, Nicolas 01 1900 (has links) Dans ce mémoire, je présente mes études sur une stratégie efficace développée pour la synthèse de cétones homoallyliques substituées à partir de l’addition en cascade de réactifs de Grignard vinyliques substitués sur des α-amino esters catalysée par des sels de cuivre. L’utilisation de ces cétones homoallyliques a permis d’obtenir des mimes peptidiques comprenant un isostère de type hydroxyéthylène du lien amide. L’étape clé de cette stratégie repose sur la synthèse de cétones homoallyliques substituées intermédiaires à partir de la réaction d’additions en cascade catalysée au cuivre, de bromure de β,β-diméthylevinyle magnésium sur des analogues d’esters de la phénylalanine et de la sérine. Les cétones homoallyliques résultantes sont réduites sélectivement en alcool, la liaison double est clivée oxydativement et l’acide carboxylique résultant est couplé à un acide aminé. Afin d’évaluer l’effet qu’ont le remplacement du lien amide central dans un coude β par un hydroxyéthylène et de la présence d’un gem diméthyle sur la chaîne carbonée sur la conformation tridimensionnelle adoptée par les tripeptides générés, des analyses à l’état solide par diffraction aux rayons X, des analyses en solution par la spectroscopie RMN et des expériences de type NOESY ont été réalisées. Ces études ont permis de définir un nouveau type de coude β. La présence de pont hydrogène intramoléculaire et l’effet de restriction de conformation induit par le gem diméthyle, généralement appelé effet Thorpe-Ingold, favorisent la formation d’un coude β. / In this thesis, I discuss my studies toward the synthesis of substituted homoallylic ketones from the copper-catalyzed cascade addition of substitued vinyl Grignard reagents to carboxylic esters. The homoallylic ketones were used to provide different peptidomimetics containing a hydroxyethylene isostere instead of an amide bond. The methyl ester of phenylalanine and serine derivatives were reacted in copper-catalyzed cascade additions of substitued vinylmagnesium bromide to provide substitued homoallylic ketone intermediates. Selective reduction of the ketone to an alcohol, oxidative cleavage of the double bond, followed by peptide coupling with amino acid lead to the desired peptidomimic. The influence of changing the central amide bond for a hydroxyethylene isostere in a β-turn and the effect of a gem dimethyl group on the backbone conformation adopted by the newly synthesized tripeptides, were studied by X-ray diffraction and solution NMR spectroscopy using NOESY experiments. From these studies, it was revealed that the iso-butyric acid hydroxyethylene isomer induced a β-turn-like conformation, and may serve as a novel scaffold for peptide mimicry. Mime peptidique Peptidomimétisme Analyse conformationnelle Hydroxyéthylène Isostère Acide amino iso-butyrique Cétone homoallylique Repliement bêta Peptidomimetic Peptide mimic Conformational analysis Hydroxyethylene Isostere Amino iso-butyric acid Homoallylic ketone Copper catalyzed cascade reaction β,β-dimethylvinyl magnesium bromide Beta-turn

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