Stereocontrolled synthesis using organosilanes

Daly, Matthew John

January 1996

No description available.

660

Silicon; Peptide isosteres

Synthetic analogues of a neuropeptide (Phe-Met-Arg-Phe-NH←2)

Chen, Yuchen

January 1993

No description available.

631.8

Design and Synthesis of Serine and Aspartic Protease Inhibitors

Wångsell, Fredrik

January 2006

<p>This thesis describes the design and synthesis of compounds that are</p><p>intended to inhibit serine and aspartic proteases. The first part of the text deals with preparation of inhibitors of the hepatitis C virus (HCV) NS3 serine protease. Hepatitis C is predominantly a chronic disease that afflicts about 170 million people worldwide. The NS3 protease, encoded by HCV, is essential for replication of the virus and has become one of the main targets when developing drugs to fight HCV. The inhibitors discussed here constitute surrogates for the widely used <em>N</em>-acyl-hydroxyproline isostere designated 4-hydroxy-cyclopentene. The stereochemistry of the 4-hydroxy-cyclopentene scaffold was determined by nuclear overhauser effect spectroscopy (NOESY) and the regiochemistry by heteronuclear multiple bond correlation (HMBC). The scaffold was decorated with different substituents to obtain both linear and macrocyclic HCV NS3 protease inhibitors that display low nanomolar activity. The second part of the thesis describes the design and synthesis of potential aspartic protease inhibitors. The hydroxyethylene motif was used as a noncleavable transition state isostere. The synthetic route yielded a pivotal intermediate with excellent stereochemical control, which was corroborated by NOESY experiments. This intermediate can be diversified with different substituents to furnish novel aspartic protease inhibitors.</p> / Report code: LIU-TEK-LIC-2006:45

organic chemistry

organic synthesis

metathesis

HCV

NS3

protease

proline isosteres

inhibitor

aspartic protease inhibitors

hydroxyethylene

Organic synthesis

Organisk syntes

Structure-Based Design and Synthesis of Protease Inhibitors Using Cycloalkenes as Proline Bioisosteres and Combinatorial Syntheses of a Targeted Library

Thorstensson, Fredrik

January 2005

Structure-based drug design and combinatorial chemistry play important roles in the search for new drugs, and both these elements of medicinal chemistry were included in the present studies. This thesis outlines the synthesis of protease inhibitors against thrombin and the HCV NS3 protease, as well as the synthesis of a combinatorial library using solid phase chemistry.In the current work potent thrombin inhibitors were generated based on the D-Phe-Pro-Arg motif incorporating cyclopentene and cyclohexene scaffolds that were synthesized by ring-closing metathesis chemistry. A structure-activity relationship study was carried out using the crystallographic results for one of the inhibitors co-crystallized with thrombin. HCV NS3 protease inhibitors comprising the proline bioisostere 4-hydroxy-cyclopent-2-ene-1,2-dicarbboxylic acid were synthesized displaying low nanomolar activity. The stereochemistry and regiochemistry of the scaffolds were determined by NOESY and HMBC spectra, respectively. The final diastereomeric target compounds were isolated and annotated by applying TOCSY and ROESY NMR experiments. Furthermore, a 4-phenyl-2-carboxypiperazine targeted combinatorial chemistry library was synthesized to be used early in the lead discovery phase. This was done using a scaffold that was synthesized by palladiumcatalyzed aromatic amination chemistry and subsequently derivatized with eight electrophiles and ten nucleophiles.

organic chemistry

organic synthesis

combinatorial synthesis

metathesis

olefin metathesis

thrombin

HCV

NS3

protease

proline isosteres

inhibitor

Organic synthesis

Organisk syntes

Design and Synthesis of Serine and Aspartic Protease Inhibitors

Wångsell, Fredrik

January 2006

This thesis describes the design and synthesis of compounds that are intended to inhibit serine and aspartic proteases. The first part of the text deals with preparation of inhibitors of the hepatitis C virus (HCV) NS3 serine protease. Hepatitis C is predominantly a chronic disease that afflicts about 170 million people worldwide. The NS3 protease, encoded by HCV, is essential for replication of the virus and has become one of the main targets when developing drugs to fight HCV. The inhibitors discussed here constitute surrogates for the widely used N-acyl-hydroxyproline isostere designated 4-hydroxy-cyclopentene. The stereochemistry of the 4-hydroxy-cyclopentene scaffold was determined by nuclear overhauser effect spectroscopy (NOESY) and the regiochemistry by heteronuclear multiple bond correlation (HMBC). The scaffold was decorated with different substituents to obtain both linear and macrocyclic HCV NS3 protease inhibitors that display low nanomolar activity. The second part of the thesis describes the design and synthesis of potential aspartic protease inhibitors. The hydroxyethylene motif was used as a noncleavable transition state isostere. The synthetic route yielded a pivotal intermediate with excellent stereochemical control, which was corroborated by NOESY experiments. This intermediate can be diversified with different substituents to furnish novel aspartic protease inhibitors. / <p>Report code: LIU-TEK-LIC-2006:45</p>

organic chemistry

organic synthesis

metathesis

HCV

NS3

protease

proline isosteres

inhibitor

aspartic protease inhibitors

hydroxyethylene

Organic Chemistry

Organisk kemi

Design, Syntheses, and Bioactivities of Conformationally Locked Pin1 Ground State Inhibitors

Wang, Xiaodong

12 April 2005

Pin1 (protein interacting with NIMA 1) is a peptidyl-prolyl isomerase involved in mitosis. As a potential anti-cancer drug target, Pin1 interacts and regulates the activity of an increasing number of cell cycle enzymes by an unknown mechanism. These cell cycle enzymes include Cdc25, Cdc27, Cyclin D1, Myt1, Wee1, NIMA, Cdc2, Plk1 and c-Myc. Recent research has revealed that Pin1 is overexpressed in a variety of cancer cell lines and Pin1 inhibitors inhibit proliferation activity of several cancer cells overexpressing Pin1. The most potent Pin1 inhibitors identified so far are in the micromolar range and no pharmacophore has been identified. In order to assist the understanding of the biological function of Pin1 using molecular probes, two amide isosteres of Ser-<i>trans</i>-Pro and Ser-<i>cis</i>-Pro dipeptides were designed and stereoselectively synthesized. The conformationally locked Ser–<i>trans</i>–Pro mimic, Boc-SerΨ[(<i>E</i>)CH=C]Pro–OH, was synthesized through the use of an Ireland-Claisen [3,3]-sigmatropic rearrangement in nine steps with 13% overall yield from a serine derivative. The Ser-<i>cis</i>-Pro mimic, Boc-SerΨ[(<i>Z</i>)CH=C]Pro–OH, was synthesized through the use of a Still-Wittig [2,3]-sigmatropic rearrangement in 11 steps with an overall yield of 20% from the same starting material. Conformationally locked peptidomimetics, including two exactly matched peptidomimetics, Ac–Phe–Phe–pSer–Ψ(<i>E</i>)CH=C]Pro–Arg–NH2 and Ac–Phe–Phe–pSer–Ψ[(<i>Z</i>)CH=C]Pro–Arg–NH2, were synthesized from these Ser-Pro isosteres using Fmoc SPPS. A protocol for in vitro Pin1 inhibition assay was established for measuring the inhibition constant for these peptidomimetics. A conformationally locked cis peptidomimetic inhibits Pin1 with a <i>K</i>_i of 1.7 <i>μ</i>M, 23-fold more potent than its trans counterpart, illustrating the preference of Pin1 for a cis amide bond in its PPIase domain. The A2780 ovarian cancer cell antiproliferation activity of these peptidomimetics parallels their respective Pin1 inhibition data. This research provides a start toward more drug-like Pin1 inhibitor design. Gly–<i>trans</i>–Pro isosteres were synthesized using the Ireland-Claisen route. The construction of a non-peptidic (Z)-alkene library for Pin1 inhibition was attempted using the Ser-<i>cis</i>-Pro mimic, Boc—SerΨ[(Z)CH=C]Pro–OH as the core. / Ph. D.

conformation

collagen

inhibition

assay

Ser-trans-Pro

Ser-cis-Pro

peptidomimetics

solid phase peptide synthesis

cell cycle

Pin1

isosteres

mimic

Modifications structurales, coordination de métaux et auto-assemblage de foldamères d’oligoquinolines carboxamides / Structural modifications, metal coordination and self-assembly of quinoline oligoamide foldamers

Wang, Jinhua

18 July 2019

Les foldamères d’oligoquinoline carboxamide forment des structures hélicoïdales en solution et dans le solide. Ces structures sont stabilisées par liaisons hydrogène, empilement aromatique et interactions électrostatiques. Dans une première partie de ce manuscrit, les fonctions amide connectant les unités quinolines ont été substituées par des fonctions vinylène, isostères de celles-ci. Ces composés quinolynènes-vinylènes, seuls, forment principalement des structures étendues en solution. Toutefois lorsque ces nouvelles unités sont en faible proportion au sein de l’oligomères contenant principalement de connections amides, des architectures hélicoïdales ont pu être obtenues. Dans une seconde partie, des ions Cu (II) ont été introduits au centre des hélices d’oligoquinoline carboxamide. Ces ions sont liés aux atomes d’azote des quinolines, et à ceux des fonctions amides après leur déprotonation. Une organisation linéaire de ces ions a été observée dans le solide. L’auto-assemblage d’hélices, en faisceaux, par empilement aromatique d’unités acridines portées par les chaines latérales a été entrepris dans une troisième partie de ce manuscrit. De faibles associations ont pu être mises en évidence en solution. Dans le solide ces interactions, bien que faibles, ont permis le contrôle de l’organisation des hélices dans le cristal. Dans une dernière partie de ce manuscrit, la coordination de métaux a été utilisée afin de permettre l’assemblage d’hélices d’oligoquinoline carboxamide. Des ligands acridine et pyridine ont été fixés sur la périphérie de l’hélice de façon à permettre la coordination par des métaux de transition tel que le palladium (II). Ces assemblages d’hélices induits par le palladium, ont été caractérisés par RMN en solution et par diffraction des rayons X dans le solide. / Oligo-quinolinecarboxamide foldamers form stable helical structures in solution and in the solid state. These helices are stabilized by hydrogen bonds, π-π stacking and electrostatic interactions. In a first part of this manuscript, vinyl functions have been introduced as isosteres of amides. The resulting quinolylene-vinylene oligomers form mainly extended structures in solution. Helical folded conformations can nevertheless be stabilized by attaching two segments of oligoamides at both ends of an oligoquinolylene-vinylene. In a second part, copper (II) ions have been loaded into the single helices of quinolinecarboxamide foldamers. The copper (II) ions coordinate the nitrogen atoms of the quinoline units and also deprotonated amide nitrogen atoms. A one dimensional alignment of the copper (II) ions was observed in the solid state. In a third part, acridine functionalized foldamers were prepared in order to test their self-assembly into bundles through interactions between aromatic functions at the exterior of helices. Associations of the acridine functionalized oligoamides are weak in organic solution. In contrast, in the solid state, interactions between helices are mainly governed by acridine units. In a fourth part, metal coordination has been used to promote helix-helix assembly of quinoline oligoamides foldamers. Acridine and pyridine rings have been attached on the side chains of these oligomers to allow coordination with metals, palladium (II) in this case. The helix-helix assembly of quinoline oligoamides by palladium coordination has been confirmed by NMR and x-ray diffraction.

Foldamères

Isostères

Auto-Organisation

Chimie supramoléculaire

Coordination de métal

Diffraction des rayons X

RMN

Foldamers

Isosteres

Self-Assembly

Supramolecular Chemistry

Metal Coordination

X-Ray Diffraction

MNR

Part 1 Design, Synthesis and Bioactivity of a Phosphorylated Prodrug for the Inhibition of Pin1; Part 2 Conformational Specificity of Cdc25c Substrate for Cdc2 Kinase using LC-MS/MS

Zhao, Song

18 January 2008

The phosphorylation-dependent PPIase (peptidyl prolyl isomerase), Pin1 (Protein interacting with NIMA#1), has been found to regulate cell cycle through a simple conformational change, the cis-trans isomerization of phospho-Ser/Thr-Pro amide bonds. A variety of key cell cycle regulatory phosphoproteins, including Cdc25 phosphatase,Cdc27, p53 oncogene, c-Myc oncogene, Wee1 kinase, Myt1 kinase, and NIMA kinas, have been confirmed as substrates of Pin1. Pin1 was also observed to be overexpressed in a variety of cancer cell lines, and the inhibitors of Pin1 showed antiproliferative activities towards these cancer cells. These results implied that Pin1 might serve as a potential anti-cancer drug target. Besides, Pin1 has an important neuroprotective function and represents a potential new therapeutic agent for Alzheimer's disease. In order to understand the interaction between Pin1 and Cdc25c and the role of Pin1 in the mechanism for the regulation of mitosis, two amide isosteres, Ser-Ψ[(Z)CH=C]-Pro-OH and Ser-Ψ[(E)CH=C]-Pro-OH were incorporated into two peptidomimetics derived from human Cdc25c. Phosphorylation of these two peptidomimetics by the incubation with Cdc2 was studied using LC-MS/MS technique. It was found that Cdc2 kinase was conformationally specific to its Cdc25c substrate. Only the trans conformer of Cdc25c at its Ser168-Pro position can be recognized and phosphorylated by Cdc2 kinase, thereby creating the binding site for Pin1. In an effort to improve the cell permeability of the charged inhibitors of Pin1, bisPOM (pivaloyloxymethyl) prodrug moiety was introduced to mask the phosphate group of Fmoc-pSer-Ψ[(Z)CH=C]-Pro-(2)-N-(3)-ethylaminoindole, which is one inhibitor of Pin1. Fmoc-pSer-Ψ[(Z)CH=C]-Pro-(2)-N-(3)-ethylaminoindole and its bisPOM prodrug were synthesized efficiently starting with Boc-Ser-Ψ[(Z)CH=C]-Pro-OH in 24% and 12% yields respectively. The charged inhibitor showed a moderate inhibition towards Pin1 (IC50 = 28.3 μM). Its antiproliferative activity towards A2780 ovarian cancer cells (IC50 = 46.2 μM) was significantly improved by its bisPOM prodrug (IC50 = 26.9 μM), which is comparable to the IC50 of the charged inhibitor towards Pin1 enzymatic activity. These results not only established the bisPOM strategy as an efficient prodrug choice for Pin1 inhibitors, but also added additional evidence for Pin1 as a potential anticancer drug target. / Ph. D.

peptidomimetics

cell cycle

Cdc2

conformation

Cdc25

Ser-trans-Pro

Ser-cis-Pro

Pin1

isosteres

LC-MS/MS

assay

inhibition

kinase

phosphorylation

Design And Access To Disallowed And Unusual Conformers Of Peptides In Crystals And In Solution : Structural Consequences Of The Imidate And Thioimidate Isosteres For The Peptide Bond

Reddy, N Damodara

12 1900

This thesis entitled “Design and Access to Disallowed and Unusual Conformers of Peptides in Crystals and in Solution: Structural Consequences of the Imidate and Thioimidate Isosteres for the Peptide bond” is divided into eight chapters. Imidate Modification The range of disallowed dihedral angles for residues in peptides is governed by their local steric and electrostatic clashes. Rare tolerances of violations in these angles are attributed to distortions in both local and global bond characteristics of the peptides. Discerning the origins of such disallowed angles and the consequent distortions in body of the peptides is essential, for a complete understanding of the protein fold, to improve the crystal database for validation of rare but acceptable residue conformations and for validation and improvement of theoretical models that evaluate the interactions that define the Ramachandran space. Unlike for the ordered secondary structures such as β-sheets α-helices and β-turns currently there are no models for residues constrained in disallowed folds. We reasoned that residues may be stabilized in disallowed folds in peptides if a neighbouring group and The range of disallowed dihedral angles ( , ψ) for residues in peptides is governed by their hence its local unfavorable clashes can be selectively modified to a motif that favors such space Steric clashes of the type H•••Xi±n involving the backbone amide hydrogen (H) contribute to ~60% of disallowed ,ψspace. Conversion of an amide to an imidate (A→I) will remove the corresponding H and hence the steric clashes related to it in peptides. Importantly, this will introduce an H-bond acceptor N (of imidate) in place of an H-bond donor NH (of amide), which will allow formation of unusual H-bonding interactions between the imidate N and the neighbouring Hs and hence constrain residues in otherwise inaccessible dihedral angles. The conversion of A→I is challenging owing to difficulties in selective synthesis, stability and purification of the imidate motif. We address all these concerns by the selective conversion of a backbone amide in peptides to the relatively stable cyclic 5,6-dihydro-4H-1,3-oxazine imidate isostere, by an intra¬molecular nucleophilic cyclo-O-alkylation reaction. Chapter 1:SectionB: Autocyclo-O-Alkylation of N-(3-Bromopropyl)amides into 2-Alkyl-5,6-Dihydro-4H-1,3-Oxazinehydrobromides We are describing the reactivity of N-(3-bromopropyl)amides that are precursors for 2-peptide-5,6-dihydro-4H-1,3-oxazine. The starting materials, 3-bromopropylamides, were synthesized in good yields by coupling the corresponding carboxylic acids and anhydrides with 3-bromopropylaminehydrobromide using standard mixed anhydride peptide coupling protocol. N-(3-bromopropyl)-acylamides are unstable during the isolation. Time-dependent 1H NMR of all the acetamides revealed that they underwent clean auto-cyclization to form the corresponding 2-alkyl-5,6-dihydro-4H-1,3-oxazine hydrobromides following first order rate. The salts were easily isolated in high purity by trituration of the mixtures with ether. The t1/2 of autocycliation of decreased upon increase in electron density on the R-carbon. Notably, the tert-butyl substituent cyclized significantly faster than acetamide which have enolizable hydrogens at the R-carbon. Thus, the cyclization rate is affected predominantly by the inductive effect of the R-carbon substituents. The formamide remained stable and unchanged due to the poor electron-donating ability of hydrogen. Chapter 1: Section C: Intramolecular Hydrogen Bond Assistance Improves Autocyclization in N-(3-Bromopropyl)amides The autocyclisation do not go to 100% completion. This is because the released hydrobromic acid quenches the nucleophilicity of amide carbonyl oxygen. In order to scavenge hydro bromic acid, we used 1 equivalent of DIEA base is acting only acid scavenger which conformed by unaffecting the reaction rate upon increasing equivalents of DIEA. We found that autocyclisation of N-(3-bromopropyl)amides rates in peptides involved in intramolecular backbone H-bonding interactions improve the autocyclization rates significantly than unstructured (random coil) peptides. Even with in the ordered structures the rate depends on the proximity of H-bonding distances as well as the H-bond acceptor strength. Half-life of autocyclisation in various peptide secondary structures are determined from time variant 1H NMR studies performed at 60 mM peptide concentration in CDCl3 at 32 oC. Chapter 2: Section A: Synthesis and Isolation of 5,6 Dihydro-4H-1,3-Oxazine Containing Peptidomimetics We have introduced 5,6-Dihydro-4H-1,3-oxazine as the imidate isostere at C-terminus of a number of peptides through NaH (base) mediated intramolecular cyclo-O-alkylation of N-(3-bromopropyl)amides. The amide to imidate (A→I) modification reaction is faster (1-5.5 h), Exhibiting no electronic and structural effects under these conditions. The side product NaBr can be easily separated by filtration through celite. No side products were observed and there is no need of further purification to get pure 1,3-oxazines in quantitative yields in all the peptidomimetics. Using this synthetic protocol we have synthesised a variety of 1,3-oxazine containing peptide analogues including aliphatic, branched aliphatic, polar side chains and larger peptides. We show that the retention of configuration at Cαof peptides during the base mediated cyclo-O-alkylation reaction. that the C5i.structures are more populated at Aib due to operation of The Thorpe-Ingold effect. The strength of hydrogen bonding interaction in C5i structure is similar to those of the highly buried backbone hydrogen bonding interaction found in the middle of a model 310-helical peptide as indicated by DMSO titration experiments. Chapter 3: Section A: Consequences of "Disallowed" Conformations on Constrained β-Turn Peptides Here we are describe the consequence of disallowed conformations the on a C-terminus of a type-II β-turn. We choose stereochemically constrained Type-II β-turn Pro-Aib dipeptide analogue which is the ideal model to mirror the structural effects of introducing the A→I modification at the C-terminus. The imidate containing peptidomimetic crystallised in dichloromethane and hexane mixture. Analysis of crystal structure revealed that Aib NH is involved in 3-centered H-bonding interactions with the N of oxazine and N of proline. This constrains Aib in a conformation that is natively disallowed to it. The (, ) angles of Aib residue fall in the (180,0) region which is strictly disallowed for natural peptides due to steric clashes involving the back bone amide N-H. More importantly there are two C•••O interactions which are accomidated in the crystal structures. Both oxygen‟s were place in staggered orientation of the Pro oxygen (OPro) between the two β-CH3 groups of Aib, which is again strictly disallowed in natural peptides due to strong C•••Oi-1 hard sphere clashes. However no vdW space violations are observed between these atoms. Chapter 3: Section B: Conformational Effects of “Disallowed Aib on a 310-Helical peptide In order to investigate the origins and consequences of “disallowed” conformations on a folded helical peptide body, the conformationally stable peptide sequence Boc-Leu1-Aib2-Ala3-Leu4-Aib5-Ala6-Phe7-Aib8-OMe (310-helix-OMe)was chosen which is known to adopt 310-helix in crystal structure. Analyses of the ROESY spectra, DMSO titration experiments, and CD spectra of 310-helix-OMe and its Oxa analogue reveal that their solution conformations are identical to those of the crystal structure of 310-helix-OMeSix sequential i+3→i intramolecular backbone H-bonds stabilize the 310-helical peptide fold in both peptides in solvents of varying polarity. The N-terminal and central segments of the helical molecules are quite structurally rigid and are not deformed. The presence of the disallowed Aib*8 residue in Oxa analogue has a clear conformational effect mainly on the residue Phe7. It looks like the Phe7 amide H is involved in shielding, the Aib*8 amide H through a bifurcated hydrogen bonding interactions with the nitrogen of oxazine and carbonyl oxygen of Ala6 residue. Maximum structural distortion effect on the registers closest to the putative imidate bond. Our results show that “disallowed folds need not denature order in the peptide fold”. Chapter 4: Synthetic Methods for Introducing the A → I Modification anywhere along the Peptide Chain Here we describe the incorporation of imidate isostere in the middle of any peptide sequence. In Oxa selectivity is towards 5-exo-cyclo-O-alkylation in 1 : 4. In Thi it is towards 6-exo-cyclo-S-alkylation in 3 : 1 ratio. This is because of better nucleophile of sulphur (S). We saw that Thi is stable to peptide coupling, N-and C-terminus protection, deprotection conditions and can be easily incorporated in middle of peptide. Chapter 5: Section A: Cis-trans Isomerism in the X-Pro Peptide Bond In tertiary amides like X-Pro peptides having high propensity to access cis conformations due to similar environment in both cis and trans around the Cof X. X-Pro peptide bonds, constrained in s-cis conformations are prevalently found in the turn regions of peptides with the residue „X‟ in the i+1position and Pro at the i+2position of the β¬turn. These types of turns are termed as the type VI β-turns. For better understanding of the molecular recognition at specific cis X-Pro peptide bonds in biological events, the structure and dynamics of various constrained cis X-Pro peptide bond analogues with varying steric and electronic perturbations have been studied. Many models have been developed for stabilizing cis conformer by perturbation of molecular recognition surface of proline by employing steric and electronic interaction. In biological functions proline molecular recognition surface and cis X-Pro peptide bond more important. There is need of novel method for stabilizing X-Pro peptide bond in cis conformer without modifying the pyrolidine ring in proline. Chapter 5: Section B: Biasing the cis/trans Equilibrium in X Pro Peptides using Reverse ni → ni-1 * Interactions Here we present our findings that peptidomimetics containing the 5,6-dihydro-4H-1,3¬oxazine (Oxa) and 5,6-dihydro-4H-1,3-thiazine (Thi) functional groups at the C-terminus of Pro selectively and remotely stabilize the s-cis rotamers of the preceding pyrrolyl (Xaa-Pro) 3° amide bonds, while conserving these recognition elements. The cis/trans equilibrium of Xaa-Pro peptide bonds is shifted significantly in favor of the satirically disfavored cis isomers in these peptidomimetics (upto ~90%). We also provide evidence for the influence of an unusual n→ πi-1 * interaction in the cis, and the n)(n repulsion in the trans, conformers of these molecules to beat the origin of such the origin of such cis stabilization. Chapter 6: Steric Interactions in the cis Piv-Pro Peptide Bond The inaccessibility of cis Piv-Pro rotamer in any peptide is believed to be because the steric clashes between substituents on CX and CPro are unavoidable in this conformer. Here we access the cisPiv-Pro conformer in crystal structure of Piv-Pro-Aib-OMe and that it is sufficiently flexible to undergo bond distortions and avoid all steric clashes between substituents on CPiv and CPro . It is however the unavoidable distortions in the dihedral angle of the Prothe cisPiv-Proconformer. The cisPiv -Pro conformer is indeed accessible, if such distortions are accommodated in the peptide. Chapter 7: Steric and Electronic Interactions in the cis Isomer of Piv-Pro Peptide Bond in Solution We have studied the electronic and steric interactions and the conformational equilibrium in two sets of homologous peptides, X-Pro-Aib-OMe (which contain Aib) and X-Pro-NH-Me, where X is acetyl, propionyl, isobutyryl and pivaloyl, in solvents of varying polarities consisting of carbontetrachloride, chloroform or dimethylsulfoxide, by means of their 1H and 13C-NMR, and FT-IR spectra. Formation of n * interactions between the carbonyls that flank the Aib residue, influences the alleviation of steric interactions that are believed to preclude access to the cis conformer of the Piv-Pro peptide bond. The cis Piv-Pro conformer is observable in the Aib containing peptides, at ambient conditions by FT-IR and at temperatures as low as 273 K by NMR. We estimate that the steric interactions contribute < 0.5 kcal/mol to the conformational free energy of X-Pro peptide bond isomerism, irrespective of the steric bulk on the acyl (X) group. The relative strengths of intramolecular hydrogen bonding interactions involving the X-Pro peptide motif in different conformers of these peptides influence their relative conformational stabilities. Chapter 8: Remote Effect of Oxa and Thi Functional Groups on cis-trans Isomerism at X-Pro Peptide Bonds The C5a interaction at Pro residue occurs in the transition states for the intramolecular acid catalysis of cis → trans isomerization in peptidyl prolyl isomerases (PPIs) and enables the decrease in transition energy barrier for the isomerization process. We show that the NPro….HAib interactions in C5a structures can be remotely effected in order to control in equilibrium constant values of the cis/trans isomerism (Kc/t) in X-Pro¬Aib-Oxa and Thi containing peptides. By this method we observed improvement in Kc/t values from 0.18 in esters to 0.56 in Thi and 0.66 in Oxa containing peptides. Analyses of the ROESY spectra, DMSO titration experiments, variable temperature experiments and FT-IR spectra of R-CO-Pro-Aib-Oxa (R = Me, Et, iPr) and its Thi analogues reveals that both interactions (C5a and C5i) are persistent in cis and trans conformers of this peptidomimetics. (for structural formula pl. see the abstract.)

Peptides

Peptide Bonds

Imidate Isosteres

Thioimidate Isoteres

Peptides - Disallowed Conformations

Amide-Imidate Modification

Amides - Autocyclization

Peptide Bonds - Isomerism

Peptidomimetics

beta-Turn Peptides

Cis-trans Isomerism

cis Piv-Pro Peptide Bond

Piv-Pro Peptide Bond

Biochemistry

Nove izostere i bioizostere prirodnih stiril-laktona: dizajn, sinteza i antiproliferativna aktivnost / Novel isosteres and bioisosteres of natural styryl lactones: design,synthesis and antiproliferative activity

Francuz Jovana

14 April 2015

<p>U&nbsp; radu&nbsp; su&nbsp; ostvarene&nbsp; vi&scaron;efazne&nbsp; sinteze&nbsp; većeg&nbsp; broja&nbsp; analoga&nbsp; prirodnih&nbsp; stiril-laktona&nbsp; (+)-goniofufurona&nbsp; i&nbsp; 7-epi-(+)-goniofufurona&nbsp; polazeći&nbsp; iz&nbsp; D-glukoze.<br />Ispitana&nbsp; je&nbsp; in&nbsp; vitro&nbsp; citotoksičnost&nbsp; sintetizovanih&nbsp; analoga&nbsp; prema&nbsp; devet<br />malignih&nbsp; i&nbsp; jednoj&nbsp; zdravoj&nbsp; ćelijskoj&nbsp; liniji.&nbsp; Uspostavljeni&nbsp; su&nbsp; korelacioni&nbsp; odnosi<br />izmedju&nbsp; strukture&nbsp; i&nbsp; antiproliferati vne&nbsp; aktivnosti&nbsp; sintetizovanih&nbsp; proizvoda, pored&nbsp; toga&nbsp; uradjeni&nbsp; su&nbsp; i&nbsp; dodatni&nbsp; biolo&scaron;ki&nbsp; testovi&nbsp; koji&nbsp; se&nbsp; odnose&nbsp; na dokazivanje&nbsp; mehanizma&nbsp; citotoksičnog&nbsp; dejstva&nbsp; pomenutih&nbsp; stiril-laktona&nbsp; i analoga.</p> / <p>Multistep&nbsp; synthesis&nbsp; of&nbsp;&nbsp; a&nbsp; number&nbsp; of&nbsp; natural&nbsp; styryl&nbsp; lactones&nbsp;goniofufurone&nbsp; and&nbsp; 7-epi-goniofufurone&nbsp; analogues&nbsp; was&nbsp; achieved&nbsp;starting&nbsp; f rom&nbsp; D-glucose.&nbsp; In&nbsp; vitro&nbsp; cytotoxicity&nbsp; of&nbsp; newly&nbsp; synthetized analogues&nbsp; against&nbsp; nine&nbsp; human&nbsp; tumour&nbsp; cell&nbsp; lines&nbsp; and&nbsp; against&nbsp; a single normal cell line was evaluated. Structure-activity relationships were&nbsp; established&nbsp; for&nbsp; both&nbsp; natural&nbsp; products&nbsp; and&nbsp; analogues.&nbsp; Some additional&nbsp; biological&nbsp; tests&nbsp; related&nbsp; to&nbsp; the&nbsp; cell mechanisms&nbsp; underlying the&nbsp; cytotoxicity&nbsp; of&nbsp;&nbsp; the&nbsp; mentioned&nbsp; styryl&nbsp; lactones&nbsp; and&nbsp; analogues, were also carried out.</p>