Design, synthesis and evaluation of biomimetic affinity ligands for elastases

A low-molecular-weight biomimetic affinity ligand selective for binding elastase has been designed and synthesized. The ligand was based on mimicking part of the interaction between a natural inhibitor, turkey ovomucoid inhibitor and elastase, and modelled from the X-ray crystallographic structure of the enzyme-inhibitor complex. Limited solid-phase combinatorial chemistry was used to synthesize 12 variants of the lead ligand using the triazine moiety as the scaffold for assembly. The ligand library was screened for its ability to bind elastase and trypsin, and two ligands were studied further. Ligand C4/6 [2-alanyl-alanyl-4-tryptamino-6-(alpha-lysyl)-s-triazine] was found to bind porcine pancreatic elastase, but not trypsin, with a dissociation constant of 6 x 10(-5) M and a binding capacity of 21 mg elastase per ml gel. The adsorbent was used to purify elastase from a crude extract of porcine pancreas. Immobilized ligand C4/5 6 [2-alanyl-alanyl-4-tyramino-6-(alpha-lysyl)-s-triazine] was similarly chosen for optimal binding of elastase from cod and used to purify the enzyme from a crude extract of cod pyloric caeca. Ligand C4/6 was subsequently synthesized in solution and its structure verified by 1H-NMR.     

Chemical synthesis of biomimetic forms

The biogenic origin of the first traces of life is often based on the morphological analysis of microfossils. However life-like forms can also be obtained via chemical synthesis from purely inorganic precursors. Many examples can be found in literature that are mainly based on aqueous solution chemistry. Osmotic growth of gelatinous precipitates is observed during the formation of “chemical gardens”. Point defects in surfactant mesophases lead to mesoporous silica with curved shapes. The oriented attachment of nanocrystals via hydrophilic polymers leads to mesocrystals that exhibit a large variety of unusual shapes.     

Design and synthesis of new vancomycin derivatives

A set of vancomycin derivatives with lipid chain attached via a glyceric acid linker was designed and synthesized. A concise synthesis towards these derivatives was developed and the IC₅₀s of these new lipoglycopeptides were tested. Some of them showed very potent activity against both vancomycin sensitive and resistant strains.     

Electroconductive materials as biomimetic platforms for tissue regeneration

In many diseases, tissue regeneration is compromised and/or insufficient to restore tissue/organ function. Therefore, novel regenerative therapies are being developed to enhance resident and transplanted cell proliferation and functional differentiation. Numerous biomaterials engineered to include nanocomponents have emerged as promising candidates to fulfil the need of mimicking the properties of the healthy extracellular matrix. This is particularly important for tissues that require electroconductive support to achieve optimal cellular function, such as muscles and neurons. In this review, we summarize and discuss the current state-of-the-art for electroconductive materials in tissue regeneration, with particular emphasis on materials containing nanocomponents.     

Design and synthesis of new types of oligonucleopeptides

Summary Design and synthesis of oligonucleopeptides (ONPs), structural analogues of oligonucleotides, where the phosphodiester backbone is substituted by a peptide chain, are described. Oligonucleopeptides, in which the number of ordinary bonds between the nucleobases is six and the number of bonds between the backbone and nucleobase is two or four were constructed using two different approaches. The first way is based on incorporation of thyminylalanine residues into the peptide chain alternatively with glycine residues. Experimental studies of the stability of oligonucleotide-oligonucleopeptide complexes as well as model estimations of their potential surfaces indicated the low DNA binding efficiency of this type of reagents. The second approach consists of synthesis of ω-ornithine peptides followed by modification of the backbone with thyminylacetaldehyde attached to an α-amino function of ornithine residues through Schiff bases. ONPs were synthesized using the solid-phase method.     

Design and synthesis of new types of oligonucleopeptides

Design and synthesis of oligonucleopeptides (ONPs),structural analogues of oligonucleotides, where the phosphodiester backbone is substituted by a peptidechain, are described. Oligonucleopeptides, in whichthe number of ordinary bonds between the nucleobasesis six and the number of bonds between the backboneand nucleobase is two or four were constructed usingtwo different approaches. The first way is based onincorporation of thyminylalanine residues into the peptidechain alternatively with glycine residues.Experimental studies of the stability ofoligonucleotide–oligonucleopeptide complexes as wellas model estimations of their potential surfacesindicated the low DNA binding efficiency of this typeof reagents. The second approach consists of synthesis of-ornithine peptides followed by modification of thebackbone with thyminylacetaldehyde attached to an-amino function of ornithine residues through Schiffbases. ONPs were synthesized using the solid-phase method.     

Design and synthesis of new adamantyl-substituted antileishmanial ether phospholipids

A series of new 2-[3-(2-alkyloxy-ethyl)-adamantan-1-yl]-ethoxy substituted ether phospholipids was synthesized and their antileishmanial activity was evaluated against Leishmania infantum amastigotes. The majority of the new analogues were significantly less cytotoxic than miltefosine while, antiparasitic activity depended on the length of the 2-alkyloxy substituent. The most potent compounds were {2-[[[3-(2-hexyloxy-ethyl)-adamant-1-yl]-ethoxy]hydroxyphosphinyloxy]ethyl}-Ν,Ν,Ν-trimethyl-ammonium inner salt (5b) and {2-[[[3-(2-octyloxy-ethyl)-adamant-1-yl]-ethoxy]hydroxyphosphinyloxy]ethyl}-Ν,Ν,Ν-trimethyl-ammonium inner salt (5c).     

Design and synthesis of new models for diiron biosites

In order to mimic dinuclear active sites of some non-heme diiron proteins, ten new polydentate and potentially dinucleating ligands have been synthesized. Each ligand contains a carboxylate moiety designed to bridge two metal atoms. These central carboxylate moieties are derived from substituted benzoic acids that in turn are linked to terminal nitrogen or oxygen donors by spacers so that framework-type polydentate ligands similar to the polypeptide frames in diiron metallobiosites are formed. Reaction of these ligands with Fe(ClO4)3 x 9H2O leads to ferric mu-oxo-mu-carboxylato iron complexes of the general formulas [Fe2O(L)2(H2O)2](ClO4)2 and [Fe2O(L)(BzO)](ClO4)2 (L = ligand), containing one or two immobilized bridging carboxylates, respectively. While X-ray crystallography shows that some of these complexes are dimers or network polymers in the solid state, electrospray ionization mass spectrometry (ESMS) and spectroscopic data (UV-Vis, NMR, Móssbauer) indicate that they dissociate to monomeric Fe2O units in dilute CH3CN solutions.     

Design and an efficient synthesis of new thiorotenone derivatives

A series of novel 4-aryl-thiopyrano[3,4-b]pyran-5-one derivatives were synthesized through an efficient one-pot three-component reaction under solvent-free conditions. This work provides a new series of derivatives of thiorotenone with potential biological activity for biomedical screening.     

Design and synthesis of new piperidone grafted acetylcholinesterase inhibitors

Alzheimer’s disease (AD) is a neurodegenerative disorder affecting 35 million people worldwide. A common strategy to improve the well-being of AD patients consists on the inhibition of acetylcholinesterase with the concomitant increase of the neurotransmitter acetylcholine at cholinergic synapses. Two series of unreported N-benzylpiperidines 5(a–h) and thiazolopyrimidines 9(a–q) molecules were synthesized and evaluated in vitro for their acetylcholinesterase (AChE) inhibitory activities. Among the newly synthesized compounds, 5h, 9h, 9j, and 9p displayed higher AChE enzyme inhibitory activities than the standard drug, galantamine, with IC₅₀ values of 0.83, 0.98, and 0.73 μM, respectively. Cytotoxicity studies of 5h, 9h, 9j, 9n and 9p on human neuroblastoma cells SH-SY5Y, showed no toxicity up to 40 μM concentration. Molecular docking simulations of the active compounds 5h and 9p disclosed the crucial role of π-π-stacking in their binding interaction to the active site AChE enzyme. The presented compounds have potential as AChE inhibitors and potential AD drugs.     

A biomimetic approach towards synthesis of zinc oxide nanoparticles

Using natural processes as inspiration, the present study demonstrates a positive correlation between zinc metal tolerance ability of a soil fungus and its potential for the synthesis of zinc oxide (ZnO) nanoparticles. A total of 19 fungal cultures were isolated from the rhizospheric soils of plants naturally growing at a zinc mine area in India and identified on the genus, respectively the species level. Aspergillus aeneus isolate NJP12 has been shown to have a high zinc metal tolerance ability and a potential for extracellular synthesis of ZnO nanoparticles under ambient conditions. UV–visible spectroscopy, Fourier transform infrared spectroscopy, X-ray diffraction analysis, transmission electron microscopy, and energy dispersive spectroscopy studies further confirmed the crystallinity, morphology, and composition of synthesized ZnO nanoparticles. The results revealed the synthesis of spherical nanoparticles coated with protein molecules which served as stabilizing agents. Investigations on the role of fungal extracellular proteins in the synthesis of nanoparticles indicated that the process is nonenzymatic but involves amino acids present in the protein chains.     

Facile biomimetic synthesis of costunolide-1,10-epoxide,santamarin and reynosin

Reaction of costunolide with peracids yields costunolide-1,10-epoxide which undergoes ready cyclization to santamarin and reynosin.     

Microtubule architecture: inspiration for novel carbon nanotube-based biomimetic materials

Microtubules are self-assembling biological nanotubes that are essential for cell motility, cell division and intracellular trafficking. Microtubules have outstanding mechanical properties, combining high resilience and stiffness. Such a combination allows microtubules to accomplish multiple cellular functions and makes them interesting for material sciences. We review recent experiments that elucidate the relationship between molecular architecture and mechanics in microtubules and examine analogies and differences between microtubules and carbon nanotubes, which are their closest equivalent in nanotechnology. We suggest that a long-term goal in bionanotechnology should be mimicking the properties of microtubules and microtubule bundles to produce new functional nanomaterials.     

Design and synthesis of new substrates of HtrA2 protease

HtrA2 belongs to the HtrA (high temperature requirement A) family of ATP-independent serine proteases. The primary function of HtrA2 includes maintaining the mitochondria homeostasis, cell death (by apoptosis, necrosis, or anoikis), and contribution to the cell signaling. Several recent reports have shown involvement of HtrA2 in development of cancer and neurodegenerative disorders. Here, we describe the profiling of HtrA2 protease substrate specificity via the combinatorial chemistry approach that led to the selection of novel intramolecularly quenched substrates. For all synthesized compounds, the highest HtrA2-mediated hydrolysis efficiency and selectivity among tested HtrA family members was observed for ABZ-Ile-Met-Thr-Abu-Tyr-Met-Phe-Tyr(3-NO₂)-NH₂, which displayed a specificity constant k_cat/K_M value of 14,535 M⁻¹ s⁻¹.     

Design and synthesis of new antimalarial agents from 4-aminoquinoline

This study describes the synthesis of new 4-aminoquinoline derivatives and evaluation of their activity against a chloroquine sensitive strain of P. falciparum in vitro and chloroquine resistant N-67 strain of P. yoelii in vivo. All the analogues were found to form strong complex with hematin and inhibit the beta-hematin formation in vitro. These results suggest that these compounds act on heme polymerization target.     

Design, synthesis, and antitumor activity of new bis-aminomethylnaphthalenes

A new series of bis-aminomethylnaphthalenes were synthesized in satisfactory overall yield, through a simple synthetic strategy using reductive amination. The DNA binding properties of these compounds have been examined and compared to those of reference drugs using an UV spectroscopy method. The compounds were evaluated for their in vitro anticancer activity and some of them were studied in vivo. Compound 15 exhibited remarkable antitumor activity and represents a novel template for anticancer chemotherapy and can serve as a new lead compound.     

Design and synthesis of new tetrahydroquinolines derivatives as CETP inhibitors

This letter describes the discovery and SAR optimization of tetrazoyl tetrahydroquinoline derivatives as potent CETP inhibitors. Compound 6m exhibited robust HDL-c increase in hCETP/hApoA1 double transgenic model and favorable pharmacokinetic properties.     

Methionine ligation strategy in the biomimetic synthesis of parathyroid hormones

In biological systems, both proteolysis and aminolysis of amide bonds produce activated intermediates through acyl transfer reactions either inter- or intramolecularly. Protein splicing is an illustrative example that proceeds through a series of catalyzed acyl transfer reactions and culminates at an O- or S-acyl intermediate. This intermediate leads to an uncatalyzed acyl migration to form an amide bond in the spliced product. A ligation method mimicking the uncatalyzed final steps in protein splicing has been developed utilizing the acyl transfer amide-bond feature for the blockwise coupling of unprotected, free peptide segments at methionine (Met). The latent thiol moiety of Met can be exploited using homocysteine at the α-amino terminal position of a free peptide for transthioesterification with another free peptide containing an α-thioester to give an S-acyl intermediate. A subsequent, proximity-driven S- to N-acyl migration of this acyl intermediate spontaneously rearranges to form a homocysteinyl amide bond. S-methylation with excess p-nitrobenezensulfonate yields Met at the ligation site. The methionine ligation is selective and orthogonal, and is usually completed within 4 h when performed at slightly basic pH and under strongly reductive conditions. No side reactions due to acylation were observed with any other α-amines of both peptide segments as seen in the synthesis of parathyroid hormone peptides. Furthermore, cyclic peptide can also be obtained through the same strategy by placing both homocysteine at the amino terminus and the thioester at the carboxyl terminus in an unprotected peptide precursor. These biomimetic ligation strategies hold promise for engineering novel peptides and proteins. © 1998 John Wiley & Sons, Inc. Biopoly 46: 319–327, 1998     

A biomimetic domino reaction for the concise synthesis of capreomycidine and epicapreomycidine

The non-proteinogenic amino acids capreomycidine and epicapreomycidine are constituents of antibiotically active natural products, but the synthesis of these unusual cyclic guanidine derivatives is challenging. The biosynthesis of capreomycidine has therefore been employed as a guideline to develop a concise biomimetic synthesis of both epimeric amino acids. The resulting domino-guanidinylation-aza-Michael-addition reaction provides the most convenient access to these amino acids in racemic form. Attempts to dissect the domino reaction into two separate transformations for a stereocontrolled version of this synthetic approach have also been made. The synthesized didehydro-arginine derivatives with urethane-protected guanidine moieties did not undergo the aza-Michael-addition anymore. These results may have wider implications for the 1,4-addition of guanidines to α,β-unsaturated carbonyl compounds, particularly to didehydro amino acids.