Combinatorial design and synthesis of peptidomimics and small molecules for protein-protein interactions

Park, Chihyo

25 April 2007

The solid phase combinatorial method is an excellent tool for the modulation of protein-protein interactions through focused library generations. Nucleophilic aromatic substitution reactions with an iodinated template on solid phase has opened a door for easy and pure libraries of 13-22 membered medium and macrocyclic peptidomimetics. These peptide mimics showed promising activities for tyrosine kinase receptors. Iodine functionality can then be used to modify the products, on the resin, via Sonogashira and Suzuki couplings and presumably through other organometallic catalysis. The coupled products can have conformational biases that differ from the iodinated macrocycles. These coupling reactions also provide a means to introduce additional pharmacophores and to adjust the solubilities of the products. The fluorinated template also gave libraries of cyclic peptidomimetics on solid phase in good yields and purities. These libraries have improved water solubility over the iodinated libraries. The 3-fluorinated template yielded better results than the 5- fluorinated template. Some compounds showed biological activities in cell survival assays providing strong support of our approach to mimic external β-turn sequences in target proteins. Intrasite dimerization with 1,5-hexadiyne gave a homodimer as a byproduct. Solidphase synthesis of bivalent turn mimics with fluorescent tags has been demonstrated. The key feature of this synthetic route is that homo- and hetero-dimers can be formed chemoselectively from unprotected monomeric precursors. The dimerization reaction is very mild and versatile, as only potassium carbonate is required to affect the coupling. Solution phase library synthesis of small molecule mimics is presented. Some monomers of full sequence mimics have been prepared to afford dimer generations. Theses monomers were combined with linker handles to afford diverse length of dimers. Final combination of monomers to make bivalent compounds is in progress.

Peptidomimics

Small molecule mimics

The synthesis of cyclic hexapeptide host molecules

Leah, Stephen Anthony John

January 1997

No description available.

547

Supramolecular chemistry; Enzyme mimics

Thiazolium salts as thiamin models

Savle, Prashant S.

January 1993

No description available.

547

Vitamin B; Enzyme mimics

Design and Synthesis of Peptidomimics Constrained in Helical and Sheet Conformations using a Novel Covalent Surrogate for the Peptide Main Chain Hydrogen Bond

Nallapati, Lakshmi Aparna

January 2015

This thesis entitled “Design and Synthesis of Peptidomimics Constrained in Helical and Sheet Conformations Using a Novel Covalent Surrogate for the Peptide Main Chain Hydrogen Bond” is divided into six chapters. Chapter 1: Introduction to Ordered Conformations of Peptides and Strategies for Constraining Short Peptides in Ordered Conformations. The first chapter describes the different types of protein secondary structures and introduces the various prominent strategies developed thus far to constrain short peptides in ordered secondary structure-like conformations, with specific emphasis on helical and parallel β-sheet folds. Chapter 2: Design of Structure and General Methodology for the synthesis of Novel H-Bond Surrogate Constrained Cyclic α-Helical Mimics Here we develop the first design of the propyl linker as a covalent surrogate for the peptide H-bond. The first synthetic methodology is described for the synthesis of constraining shortest peptide sequences (tripeptides) in α-helix-like conformations. The Macrolactamization strategy proved to work best as the final step for cyclization. All residues of the turn are completely retained in the constrained sequence, unlike any other earlier method. More importantly, there are no metal involved as catalysts in any of the synthetic transformations, hence removing the problem of metal-bound cyclic structures – which have otherwise rendered these structures non-usable as drug leads in the earlier models. Gly-rich peptides have been constrained as extreme cases of highest chain entropy and least helix propensity. Both secondary and tertiary amide containing peptides have been synthesized using this protocol. Note that the macrolactamization was found to be better than the Fukuyama-Mitsunobu N-alkylation protocol for the final cyclization step. Chapter 3: Synthesis of C-terminal Extended HBS-Constrained Helical Turn Mimics – Validation of the Versatility of Current synthetic protocol The developed cyclization protocol is extended towards the synthesis of C-terminal extended α-helical turn mimics using a solution phase peptide synthesis procedure. Peptides which extend belong the helical turn by a high entropy Gly-residue at the C-terminal are synthesized. The versatility of the synthetic methodology to accommodate sterically constrained amino acid residues – in the form of phenylalanine residue – at any of the positions i+1, i+2 or i+3 of the constrained helical turn is demonstrated. The synthesized are easily isolated without need for column chromatography, in high purity and good yields – this is due to the presence of the N-terminal amino group, salts of which are easily triturated to remove all other organic impurities. Chapter 4: Synthesis and CD conformational analyses of HBS constrained α-Helical turn mimics containing residues with improved helical propensities Alanine residue has the highest helix propensity among all other natural α-amino acid residues. Its enthalpic contribution to the helical conformation is 1 kcal/mol more than that for the Gly residue, which has the least propensity. Incorporation of Ala residue in the Gly-rich cyclic sequences in either the middle of constrained tripeptide or as the C-terminal extended residue has been accomplished. Comparison of the CD spectra of the synthesized cyclic α-helical turn peptides reveals that a tertiary amide linkage is essential for the propyl linker at the C-terminal amino appendage, for helicity to be observed. Helicity improves upon introduction of the first extended residue. The constrained and C-terminal extended α-helical turn mimics show consistently high helicity irrespective of the helix propensities of the component residues showing that the covalent propyl linker surrogate for the H-bond overwhelms the natural propensities of individual amino acid residues towards enabling stabilization of the helical turn and offer far better structural organization to this cause. Chapter 5: Synthesis of shortest HBS-constrained 310 and - helical peptide analogues The unique versatility of the novel covalent propyl linker surrogate for the peptide H-bond is exhibited by its ability to constrain dipeptides in 310-helix like structures. This is the first and the only HBS model that can achieve this synthetic target as the synthetic protocol allows the conservation of both the residues as is in the constrained helical turn. Similarly, the trapping of a pentapeptide in a C-terminal extended rare and unstable -helix like cyclic structure using the current HBS linker is achieved. Considering the high entropic cost for cyclizing such a long 16-membered chain into a constrained structure, this again exhibits the versatility of the currently developed HBS design and the currently developed synthetic methodology. Chapter 6: First design and synthesis of novel H-bond surrogate constrained parallel β-sheet mimics H-bonding interactions stabilize another prevalently observed secondary structure, other than helical structures, namely the -sheets. The parallel -sheets that almost qualify for super secondary structures due to the high contact orders in them are thought to mimic in models, unlike the easier antiparallel -sheets. Here we replace the inter-strand peptide H-bond between parallel -strands to create excised templates as parallel -sheet nucleators. The propyl linker acts as a dynamic linker in these models and the two amino groups are protected with bulky sulphonamides, in order to provide Thorpe-Ingold effect to the peptide chain. The protocol for synthesizing these models has been described and the different analogues that are synthesized thus have been described. This is the first instance of synthesis of parallel -sheet mimics using the covalent surrogates for the peptide H-bond.

Peptidomimics

Peptide - Novel Covalent Surrogate

Novel H-Bond Surrogate

Cyclic α-Helical Mimics

Peptide Mimics

Helical Turn Mimics

Organic Chemistry

Implementation of the MIMICS packet switch

Ratliff, James R

January 2010

Typescript (photocopy). / Digitized by Kansas Correctional Industries

Operating systems (Computers)

MIMICS (Computer program)

Studies on the Effects of Paraben Mixtures on MCF-7 Breast Cancer Cells in Culture

Webber, Kristie Elmslie

January 2013

Parabens are the esters of p-hydroxybenzoic acid and are commonly used as preservatives in personal care products, pharmaceutical preparations and cosmetics. Recently parabens have been found to be estrogenic, bringing into question if exposure to them is adversely affecting human health. Given exposure to multiple xenoestrogens is constant; research has been carried out to determine what effect combinations of xenoestrogens might have on human and environmental health. Parabens are almost always present in combinations in formulae as this increases their antimicrobial activity, so it is important to know what the effect of this is. The main aim of this study was to determine what the effect of combining methylparaben and butylparaben together has on the proliferation of MCF-7 breast cancer cells, which proliferate in the presence of estrogen. This study was carried out by exposing MCF-7 breast cancer cells to combinations of methylparaben and butylparaben and measuring cell proliferation by counting cells using a cytometer. The results show that butylparaben caused a greater increase in cell proliferation compared to methylparaben. When methylparaben and butylparaben were combined together, the resulting cell proliferation was greater than the cell proliferation produced by either methylparaben or butylparaben alone at a concentration twice the amount of either paraben concentration contained within the mixture. These results were analysed using Analysis of Variance, which determined the combination treatments were statistically different from the single treatments according to Fishers method. This suggests that there is a synergistic effect produced when methylparaben and butylparaben are combined together, however large variation and dose dependent discrepancies means this result is uncertain and further studies need to be carried out.

parabens

xenoestrogens

xenoestrogen combinations

estrogen mimics

Exploring Galvanic Replacement as a Method to Engineer Peroxidase-mimics Nanoparticles

MaGloire, Kuryn T

01 January 2019

Peroxidase enzymes are of critical importance within the scientific community for their applications in biosensing assays. In a living system, natural peroxidases function as catalysts in the oxidation of peroxide (e.g., H2O2) - a harmful byproduct of aerobic processes and convert them into harmless compounds. Such an ability allows peroxidases to serve as labels in biosensing assays, where they are conjugated to antibodies and accurately produce a detection signal by catalyzing substrates. However, due to intrinsic limitations, namely instability, Peroxidase made of proteins substantially inhibit broader applications. Alternatively, nanoparticles produced from noble metals have been found to exhibit peroxidase-like abilities and, therefore, can be used as synthetic enzymes with the potential to replace their natural counterparts. Given that the stability of most peroxidase mimics is already much better than their natural counterparts, in this field, the principal challenge has been creating substantial improvements to the catalytic efficiency of the mimics. This study sought to create a cage-like nanostructure ( denoted as nanocages) consisting of two platinum group metals. This experiment uses Galvanic replacement as a mechanism to hollow all Nanocages formed. Galvanic replacement has been primarily demonstrated using coinage metals ( Ex. Ag and Au). This experiment seeks to show that this process is viable for other Nobel metals, as well. In particular, palladium cubes were used as scaffolds or sacrificed templates to induce the reaction with a precursor containing a secondary Nobel metal (Platinum, Rhodium, or Ruthenium). Once viable samples where produced and checked via TEM ( Transmission Electron microscope), the peroxidase-like activity was compared to the activity of a non-hollowed nanostructure of the same material composition using TMB colorimetric assay.

Galvanic Replacement

Nanocages

Peroxidase mimics

nanoparticles

nanocube

Exploring Key Orientations of Small Molecules to Disrupt Protein-protein Interactions

Ko, Eunhwa

2012 May 1900

Protein-protein interactions (PPIs) are attractive targets because of their therapeutic potential. One approach to design small molecules that can disrupt the PPIs is to use structural information of proteins. With this approach, triazole-based peptidomimetics that mimic beta-turn hot-spot regions in neurotrophins were synthesized. The monovalent mimics were assembled into bivalent mimics via a combinatorial method. Three different bivalent mimics were prepared for different studies. Bivalent mimics with long-linkers bound to TrkA or TrkC receptor and showed partial antagonism for the receptors. Other mimics were conjugated with cytotoxic compounds and they were used for TrkC targeted drug delivery. The last group of bivalent mimics previously showed targeted delivery effects for pancreatic cancer cells. In this study, we synthesized Eu-chelated bivalent mimics to perform a competitive binding assay for pancreatic cancer cells. Previous research in our group focused on design of secondary structures' mimics on rigid scaffolds as "minimalist mimics." We sought to establish structural design criteria for the minimalist mimics, and we wanted to propose that sets of such compounds could mimic local pairs of amino acids in any secondary structures as "universal peptidomimetics." Thus, we designed five compounds, such as oxazoline-, pyrrole-, dyine- "kinked" and "linear" bistrizole-based peptidomimetics, and performed molecular modelings, DFT calculations, and QMD for them to validate our hypothesis. On the concepts of "minimalist mimics" and "universal peptidomimetics," we developed the C alpha ? C beta vector matching program to evaluate preferred orientations of C alpha - C beta coordinates for secondary structures. We applied the program to omegatides and pyrrolinone-pyrrolidine oligomers. The compounds matched better with strands than for helices. We expanded the C alpha ? C beta vector matching idea to a method that ranks preferred conformations of small molecules on any combination of three interface side-chains in all structurally characterized PPIs. We developed a PDB mining program (explores key orientation, EKO) to do this, and EKO applied to pyrrolinone-pyrrolidine oligomers to find targets. EKO found several interesting targets, such as AICAR Tfase, GAPDH, and HIV-1 protease. HIV-1 dimerization inhibition and Zhang-Poorman kinetic assays were performed to validate our hypothesis, and the results showed that pyrrolinone-pyrrolidine derivatives inhibited HIV-1 dimerization.

Explores Key Orientation

Universal Peptidomimetics

minimalist mimics

protein-protein interactions

TrkC

targeted drug delivery

triazole-based beta-turn mimics

bivalent mimics

Synthesis Of Carbasugars And Other Related Structural Motifs

Talukdar, Pinaki

05 1900

Recent years have witnessed a great deal of interest in the design and synthesis of small molecules, which can mimic complex carbohydrates of vital importance in various life processes. Carbasugars constitute one such class of molecules among several others, in which ring oxygen of sugar is replaced by a methylene unit. Several approaches have been reported in the literature for the synthesis of carbasugars emanating both from carbohydrate and non-carbohydrate sources. While the carbohydrate-based approaches require extensive prote'ction-deprotection maneuver, the non-carbohydrate-based approaches generally have problems of diastereoselection and introduction of chirality. In the context of synthesis of carbasugars, we envisaged that a suitable derivative of i bicyclo[2.2.1]heptane (norbornyl system), could serve as a carbasugar equivalent provided the inherent cyclohexane ring could be disengaged through a tactical cleavage of C1-C7 or C4-C7 bonds. In the present thesis entitled "Synthesis of carbasugars and other structurally related motifs", we have established the carbasugar-norbornyl system equivalence by using 7-* oxobicyclo[2.2.1]hept~5-en-2~yl acetate as precursor . While the tactical cleavage of C1-C7 bond was employed in the synthesis of carbasugars, the C4-G7 bond cleavage provided access to a new class of carbasugars i.e. "confused" carbasugars* The quest for stronger and specific inhibitors of glycosidases led us to synthesize a diverse array of polyoxygenated compounds in this new family of carbasugars. The thesis has been organized under five main sections: I. Introduction, II. Results & Discussion, III. Experimental, IV. Spectra, and V. References where we have narrated our I synthetic efforts with suitable literature citations.

Organic Chemistry

Carbasugars

Carbasugar-norbornyl System Equivalence

Carbohydrate Mimics

Novel inhibitors of dihydrodipicolinate synthase

2014 January 1900

Dihydrodipicolinate synthase (DHDPS) catalyzes the first committed step of L-lysine and meso-diaminopimelate biosynthesis, which is the condensation of (S)-aspartate-β-semialdehyde (ASA) and pyruvate into dihydrodipicolinate via an unstable heterocyclic intermediate, (4S)-hydroxy-2,3,4,5-tetrahydro-(2S)-dipicolinic acid. DHDPS has been an attractive antibiotic target because L-lysine and meso-diaminopimelate are cross-linking components between peptidoglycan heteropolysaccharide chains in bacterial cell walls. Studies revealed that mutant auxotrophs for diaminopimelate undergo lysis in the absence of diaminopimelate in the medium; therefore the assumption is that strong inhibition of DHDPS would result in disruption of meso-diaminopimelate and L-lysine biosynthesis in bacteria and would stop or decrease bacterial growth (eventually leading to bacterial death). In this work, the DHDPS inhibitor design is focused on the allosteric site of the enzyme. It was proposed that a compound mimicking binding of two L-lysine molecules at the allosteric site at the enzyme’s dimer-dimer interface would be a more potent inhibitor than the natural allosteric inhibitor of this enzyme, L-lysine. This inhibitor (R,R-bislysine) was synthesized as a racemic mixture, which was then separated with the aid of chiral HPLC. The mechanism of feedback inhibition of DHDPS from Campylobacter jejuni with its natural allosteric modulator, L-lysine, and its synthetic mimic, R,R-bislysine, is studied in detail. It is found that L-lysine is a partial uncompetitive inhibitor with respect to pyruvate and a partial mixed inhibitor with respect to ASA. R,R-bislysine is a mixed partial inhibitor with respect to pyruvate and a noncompetitive partial inhibitor with respect to ASA, with an inhibition constant of 200 nM. Kinetic evaluation of each DHDPS mutants (Y110F, H56A, H56N, H59A and H59N) has revealed amino acids responsible for the inhibitory effect of L-lysine, R,R-bislysine, and we have found that R,R-bislysine is a strong submicromolar inhibitor of Y110F, H56A, H56N and H59N.

Dihydrodipicolinate synthase

Lysine inhibition

Cooperativity

Lysine mimics

Bislysine