Efficient regioselective chemical modifications of maltotriose: an easy access to oligosaccharidic scaffold

Regioselective chlorination of fully unprotected maltotriose has given in high yield 1^I,2^I-III,3^I-III,4^III-octa-O-acetyl-6^I-III-trichloro-6^I-III-trideoxymaltotriose. Moreover, regioselective ditritylation of methyl β-maltotrioside has provided the two regioselectively C₆-disubstituted trisaccharides. Selective deprotection of these new compounds gives the corresponding diol and halogenated analogues, respectively, in good yield. All compounds have been completely characterized and the substitution pattern in the oligosaccharidic sequence has been elucidated. A new family of amphiphilic carbohydrates, namely the 6-deoxy-6-alkylthiomaltotriose derivatives, bearing either two or three thioalkyl hydrophobic chains, respectively, has been synthesized. Critical micellar concentration (CMC) values as well as the antimicrobial properties have been evaluated for amphiphilic compounds.     

Design,Synthesis and Anticancer Evaluation of New Substituted Thiophene-Quinoline Derivatives

A series of new isoxazolyl, triazolyl and phenyl based 3-thiophen-2-yl-quinoline derivatives were synthesized adopting click chemistry approach. In addition, the synthesis of new useful synthon, (2-chloroquinolin-3-yl) (thiophen-2-yl) methanol, is reported. The obtained compounds were characterized by spectral data analysis and evaluated for their anticancer activity. All the derivatives were subjected to in vitro MTT cytotoxicity screening assay against a panel of four different human cancer cell lines, liver (HepG-2), colon (HCT-116), human cervical cancer (HeLa) and breast (MCF-7). Out of a library of 17 compounds, two compounds have been identified as potent and selective cytotoxic agents against HeLa and MCF-7 cell lines. SAR studies for such hybridized analogues were investigated and phenyl derivatives were proved to be more potent than isoxazole and triazole derivatives. Furthermore, the promising compounds were selected for in vitro inhibition of EGFR-TK and Topo II enzymes. Also, they were subjected to cell cycle arrest analysis and apoptosis assay on MCF-7 cells. Our recent finding highlights these thiophene-quinoline analogues as a promising class of compounds for further studies concerning new anticancer therapies.     

Water-soluble polysaccharides as carriers of paramagnetic contrast agents for magnetic resonance imaging: synthesis and relaxation properties.

Water-soluble, carbohydrate-based, paramagnetic metal chelate derivatives have been investigated as potential organ-selective contrast media for magnetic resonance imaging (m.r.i.). The in vitro proton spin-lattice relaxation properties of compounds with different paramagnetic metals, chelating agents, and carbohydrate matrixes have been studied. Typically, these complexes were 60-260% more efficient proton-relaxation agents than the corresponding low-molecular-weight metal chelates at 10 MHz, but less efficient than the corresponding protein derivatives. As expected, carbohydrates that contained manganese or gadolinium were more effective relaxation agents than iron, copper, erbium, or nickel derivatives.     

Monosaccharides and monosaccharide derivatives in human seminal plasma

Gas chromatography—mass spectrometry with an on-line data system was used to identify monosaccharides and monosaccharide derivatives in human seminal plasma. The carbohydrates were converted into the methoxime—trimethylsilyl derivatives before separation in open tubular glass capillary columns coated with SE-30. Twenty-one different compounds were detected in the seminal fluid, of which twelve have not been recognized before. Seventeen of the monosaccharides have previously been identified in urine. Similar patterns of sugars were found both in fertile and infertile individuals, including one with azoospermia. The compounds identified are, with the possible exception of -ribose, present as free monosaccharides at the time of ejaculation, and they do not seem to be preformed by spermatozoa.     

Glycosyltransferases involved in the biosynthesis of biologically active natural products that contain oligosaccharides

A unique characteristic of carbohydrates is their structural diversity which is greater than that of many other classes of biological compounds. Carbohydrate-containing natural products show many different biological activities and some of them have been developed as drugs for medical use. The biosynthesis of carbohydrate-containing natural products is catalysed by glycosyltransferases. In this review we will present information on the function of glycosyltransferases involved in the biosynthesis of oligosaccharide antibiotics focusing especially on urdamycins and landomycins, two angucycline antibiotics with interesting antitumor activities. We will also discuss the use of glycosyltransferases in combinatorial biosynthesis to generate new "hybrid" antibiotics.     

Synthesis and discovery of potent carbonic anhydrase,acetylcholinesterase, butyrylcholinesterase,and α‐glycosidase enzymes inhibitors: The novel N,N′‐bis‐cyanomethylamine and alkoxymethylamine derivatives

During this investigation, N,N′‐bis‐azidomethylamines, N,N′‐bis‐cyanomethylamine, new alkoxymethylamine and chiral derivatives, which are considered to be a new generation of multifunctional compounds, were synthesized, functional properties were investigated, and anticholinergic and antidiabetic properties of those compounds were studied through the laboratory tests, and it was approved that they contain physiologically active compounds rather than analogues. Novel N‐bis‐cyanomethylamine and alkoxymethylamine derivatives were effective inhibitors of the α‐glycosidase, cytosolic carbonic anhydrase I and II isoforms, butyrylcholinesterase (BChE), and acetylcholinesterase (AChE) with K_i values in the range of 0.15–13.31 nM for α‐glycosidase, 2.77–15.30 nM for human carbonic anhydrase isoenzymes I (hCA I), 3.12–21.90 nM for human carbonic anhydrase isoenzymes II (hCA II), 23.33–73.23 nM for AChE, and 3.84–48.41 nM for BChE, respectively. Indeed, the inhibition of these metabolic enzymes has been considered as a promising factor for pharmacologic intervention in a diversity of disturbances.     

Osmoadaptation mechanisms in prokaryotes: distribution of compatible solutes

Microorganisms respond to osmotic stress mostly by accumulating compatible solutes, either by uptake from the medium or by de novo synthesis. These osmotically active molecules preserve the positive turgor pressure required for cell division. The diversity of compatible solutes is large but falls into a few major chemical categories; they are usually small organic molecules such as amino acids or their derivatives, and carbohydrates or their derivatives. Some are widely distributed in nature while others seem to be exclusively present in specific groups of organisms. This review discusses the diversity and distribution of known classes of compatible solutes found in prokaryotes as well as the increasing knowledge of the genes and pathways involved in their synthesis. The alternative roles of some archetypal compatible solutes not subject to osmoregulatory constraints are also discussed.     

Derivatization of carbohydrates for analysis by chromatography; electrophoresis and mass spectrometry

Carbohydrates display a large diversity of structures and their analysis presents many obstacles as the result of properties such as isomeric diversity, existence of branched structures and the lack of chromophores or fluorophores. Consequently, many analytical approaches depend on the application of chemical modifications such as hydrolysis or derivative formation. This review covers various aspects of derivatization that are used for such approaches as improving thermal stability and volatility for gas-phase analyses, introduction of fluorophores for optical detectors, introduction of charge for mass spectral analyses and attachment of bioaffinity tags for bioactivity studies. Reducing carbohydrates contain, in addition to multiple hydroxyl groups, several other sites for derivatization such as the single anomeric site that has been used in numerous methods for attaching various property-enhancing tags. Other sites are restricted to specific carbohydrates but include carboxy groups in sialic acids and amino groups in glycosylamines. All of these groups have been the targets of derivatization and this review attempts to summarise the main methods used for these various functional groups.     

Designed potent multivalent chemoattractants for Escherichia coli.

Bacterial chemotactic responses are initiated when certain small molecules (i.e., carbohydrates, amino acids) interact with bacterial chemoreceptors. Although bacterial chemotaxis has been the subject of intense investigations, few have explored the influence of attractant structure on signal generation and chemotaxis. Previously, we found that polymers bearing multiple copies of galactose interact with the chemoreceptor Trg via the periplasmic binding protein glucose/galactose binding protein (GGBP). These synthetic multivalent ligands were potent agonists of Escherichia coli chemotaxis. Here, we report on the development of a second generation of multivalent attractants that possess increased chemotactic activities. Strikingly, the new ligands can alter bacterial behavior at concentrations 10-fold lower than those required with the original displays; thus, they are some of the most potent synthetic chemoattractants known. The potency depends on the number of galactose moieties attached to the oligomer backbone and the length of the linker tethering these carbohydrates. Our investigations reveal the plasticity of GGBP; it can bind and mediate responses to several carbohydrates and carbohydrate derivatives. These attributes of GGBP may underlie the ability of bacteria to sense a variety of ligands with relatively few receptors. Our results provide insight into the design and development of compounds that can modulate bacterial chemotaxis and pathogenicity.     

A universal protocol for photochemical covalent immobilization of intact carbohydrates for the preparation of carbohydrate microarrays

A universal photochemical method has been established for the immobilization of intact carbohydrates and their analogues, and for the fabrication of carbohydrate microarrays. The method features the use of perfluorophenyl azide (PFPA)-modified substrates and the photochemical reaction of surface azido groups with printed carbohydrates. Various aldoses, ketoses, nonreducing sugars such as alditols, and their derivatives can be directly arrayed on the PFPA-modified chips. The lectin-recognition ability of arrayed mannose, glucose, and their oligo- and polysaccharides were confirmed using surface plasmon resonance imaging and laser-induced fluorescence imaging.     

1,5-Anhydro-D-fructose; a versatile chiral building block: biochemistry and chemistry

There is a steadily increasing need to expand sustainable resources, and carbohydrates are anticipated to play an important role in this respect, both for bulk and fine chemical preparation. The enzyme alpha-(1-->4)-glucan lyase degrades starch to 1,5-anhydro-D-fructose. This compound, which has three different functional properties, a prochiral center together with a permanent pyran ring, renders it a potential chiral building block for the synthesis of valuable and potentially biologically active compounds. 1,5-Anhydro-D-fructose is found in natural materials as a degradation product of alpha-(1-->4)-glucans. The occurrence of lyases and the metabolism of 1,5-anhydro-D-fructose are reviewed in the biological part of this article. In the chemical part, the elucidated structure of 1,5-anhydro-D-fructose will be presented together with simple stereoselective conversions into hydroxy/amino 1,5-anhydro hexitols and a nojirimycin analogue. Synthesis of 6-O-acylated derivatives of 1,5-anhydro-D-fructose substituted with long fatty acid residues is carried out using commercially available enzymes. Those reactions lead to compounds with potential emulsifying properties. The use of protected derivatives of 1,5-anhydro-D-fructose for the synthesis of natural products is likewise reviewed. The potential utilization of this chemical building block is far from being exhausted. Since 1,5-anhydro-D-fructose now is accessible in larger amounts through a simple-enzyme catalyzed degradation of starch by alpha-(1-->4)-glucan lyase, the application of 1,5-anhydro-D-fructose may be considered a valuable contribution to the utilization of carbohydrates as the most abundant resource of sustainable raw materials.     

The continuing search for antitumor agents from higher plants

Plant secondary metabolites and their semi-synthetic derivatives continue to play an important role in anticancer drug therapy. In this short review, selected single chemical entity antineoplastic agents from higher plants that are currently in clinical trials as cancer chemotherapy drug candidates are described. These compounds are representative of a wide structural diversity. In addition, the approaches taken toward the discovery of anticancer agents from tropical plants in the laboratory of the authors are summarized. The successful clinical utilization of cancer chemotherapeutic agents from higher plants has been evident for about half a century, and, when considered with the promising pipeline of new plant-derived compounds now in clinical trials, this augurs well for the continuation of drug discovery research efforts to elucidate additional candidate substances of this type.     

Protozoan parasite-specific carbohydrate structures

The carbohydrate moieties displayed by pathogenic protozoan parasites exhibit many unusual structural features and their expression is often developmentally regulated. These unique structures suggest a specific relationship between such carbohydrates and parasite pathogenicity. Studies of infected humans indicate that immune responses to protozoan parasites are elicited by glycan determinants on cell-surface or secreted molecules. Infections by protozoa are a major worldwide health problem, and no vaccines or efficacious treatments exist to date. Recent progress has been made in elucidating the structure and function of carbohydrates displayed by major protozoan parasites that infect man. These structures can be used as prototypes for the chemical or combined chemo-enzymatic synthesis of new compounds for diagnosis and vaccine development, or as inhibitors specifically designed to target parasite glycan biosynthesis.     

Antiobesity designed multiple ligands: Synthesis of pyrazole fatty acid amides and evaluation as hypophagic agents

Searching for new antiobesity agents, a new series of fatty acid amide derivatives of 1,5-diarylpyrazole have been synthesized as dual peroxisome proliferator activated receptor alpha (PPARalpha)/cannabinoid receptor ligands. The compounds have been evaluated in vivo and in vitro as PPARalpha activators and as cannabinoids in two tests of the mouse tetrad. In vivo, food intake studies have been performed with all the compounds. No significant cannabinoid activity has been found but some compounds behaved as potent PPARalpha activators. Several compounds showed anorexigenic properties reducing food intake in rats.     

Chalcone derivatives and their antibacterial activities: Current development

The increase in antibiotic resistance due to various factors has encouraged the look for novel compounds which are active against multidrug-resistant pathogens. In this framework, chalcone-based compounds showed a diversity of pharmacological properties, and its derivatives possess a high degree of structural diversity, and it is helpful for the discovery of new therapeutic agents. The growing resistance to antibiotics worldwide has endangered their efficacy. This has led to a surging interest in the discovery of new antibacterial agents. Thus, there is an urgent need for new antibacterial drug candidates with increased strength, new targets, low cost, superior pharmacokinetic properties, and minimum side effects. The present review concluded and focuses on the recent developments in the area of medicinal chemistry to explore the diverse chemical structures of potent antibacterial agents and also describes its structure-activity relationships studies. The various synthetic structures leading to this class of neutral protective compound is common and additional structural optimization is promising for potential drug discovery and development.     

18 Possible extraterrestrial life: a quantum-chemical look on the silicon analogs of carbon biomolecules

The uniqueness of life on our planet has been an important topic of discussion in scientific literature for many decades. The most particular findings are in the fields of the structure of biomolecules and the mechanisms of their conformational and chemical transfers since they underlie all the biospheric processes of our planet. The compounds based on carbon are the subject of study of organic chemistry, which has an appropriate thoroughly developed classification of such substances; a number of approaches have been proposed for the analysis of composition and structure of the organic compounds, and a theoretical basis has been created, which describes the character of various chemical bonds involving carbon atoms. At the same time, since quite a while, there is a widely discussed hypothesis (Alison, 1968) concerning the possibility of existence of compounds, which are similar to organic, but are based on silicon atoms. Even in interstellar medium, among all the diversity of molecules detected, 84 are based on carbon, and 8 on silicon (Lazio, 2000), including four hybrid types, i.e. containing both silicon and carbon. According to approximate evaluations, the contents ratio of carbon to silicon in the space equals to 10:1, though the Earth’s crust consists of 87% of silicon in the form of oxides. In the Periodic Table, silicon is situated in the same group IV, like carbon. These two elements are largely similar in the structure of their valent electronic shells, and their noteworthy that previously it was stated (Lazio, 2000) that silicon-containing compounds are not as diverse in structure as carbon compounds. Despite having higher mass and radius, the atoms of silicon form double and triple covalent bonds (Wang et al., 2008). Therefore, the issue concerning the existence of silicon structures similar to carbon biomolecules, as well as the question of hypothetical “biochemical” processes involving non-carbonic analogs of aminoacids, carbohydrates, proteins, lipids, and other biomolecules, is still a matter of discussion in scientific and popular science literature. It is particularly notable that the modern methods of computational chemistry allow carrying out the estimating calculations of the structure and dynamics of such compounds, which is quite similar to the known approaches of substance modeling de novo in drug design. For instance, first by calculations (Nagase, Kudo, & Aoki, 1985), and later on experimentally (Abersfelder, White, Rzepa, & Scheschkewitz, 2010), aromaticity of cyclic carbohydrate-like derivatives of silicon was studied. In the present study, we used quantum-chemical semiempirical PM3 and ab initio B3LYP/6-311G(d,p) level of theory to investigate the peculiarities of several structural and thermodynamic parameters of molecules, which can be assumed as complete silicon analogs of carbonic L-amino acids and other biomolecules, so-called bricks of life: carbohydrates, nitrogenous bases, fatty acids, as well as vitamins and caffeine. The quantum-mechanical calculations that we made displayed that the molecules of silicon amino acids possess higher thermodynamic stability compared to carbon analogs. Thereby, silicon amino acids have a similar conformation freedom, increased values of dipole moment, as well as more pronounced electron-donor characteristics. Silicon analogs of carbohydrates, fatty acids, and nitrogenous bases are as well considered as heavier thermodynamically stable compounds, having special features in 3D-organization and worth further experimental study. The present work also deals with the question of the existence and stability of “alpha-helices” composed of silicon amino acids, because in the molecules of Si-analogs of aspartate and glutamate, we have discovered effective formation of intramolecular hydrogen bond (due to the side chain), which is highly important for Pauling–Corey alpha helix formation in natural L-amino acids (Kondratyev, Kabanov, & Komarov, 2010). Our estimations show that an “alpha helix” composed of 10 silicon alanine analogs is more stable in isolated state than a linear form of such macromolecule, which was not observed for a molecule of the same composition having a carbon backbone.     

Caffeic acid derivatives isolated from the aerial parts of Galinsoga parviflora and their effect on inhibiting oxidative burst in human neutrophils

Four new caffeoyl -glucaric and -altraric acid derivatives along with eleven known compounds were isolated from aerial parts of Galinsonga parviflora. Their structures were elucidated by high-resolution spectroscopic studies. The four new compounds were determined as being 2,3,4,5-tetracaffeoylglucaric acid (1), 2,4,5-tricaffeoylglucaric acid (2), 2,3,4- or 3,4,5-tricaffeoylaltraric acid (3) and 2,3(4,5)-dicaffeoylaltraric acid (4). A reliable criterion for the determination of the linkage position of caffeic acids moieties in glucaric acid derivatives has been proposed, on the basis of detailed analysis of the respective J-couplings, including substitution and solvent influence on the observed values. All hexaric acids derivatives appeared as inhibitors of reactive oxygen species production by stimulated neutrophils.     

Synthesis,nitric oxide release,and α-glucosidase inhibition of nitric oxide donating apigenin and chrysin derivatives

α-Glucosidase (AG) play crucial roles in the digestion of carbohydrates. Inhibitors of α-glucosidase (AGIs) are promising candidates for the development of anti-diabetic drugs. Here, five series of apigenin and chrysin nitric oxide (NO)-donating derivatives were synthesised and evaluated for their AG inhibitory activity and NO releasing capacity in vitro. Except for 9a–c, twelve compounds showed remarkable inhibitory activity against α-glucosidase, with potency being better than that of acarbose and 1-deoxynojirimycin. All organic nitrate derivatives released low concentrations of NO in the presence of l-cysteine. Structure activity relationship studies indicated that 5-OH, hydrophobic coupling chain, and carbonyl groups of the coupling chain could enhance the inhibitory activity. Apigenin and chrysin derivatives therefore represents a new class of promising compounds that can inhibit α-glucosidase activity and supply moderate NO for preventing the development of diabetic complications.     

Synthesis and biological validation of novel pyrazole derivatives with anticancer activity guided by 3D-QSAR analysis

Using literature data on anticancer activity of pyrazole derivatives, 3D-QSAR models were developed and 3D-QSAR analysis was performed. The 3D-QSAR analysis enabled identification of molecular properties that have the highest impact on antitumor activity against lung cancer cells. The results of 3D-QSAR analysis were taken into account while new compounds were designed. Obtained 3D-QSAR models were used for prediction of activity of new compounds. In this way, design of new compounds was guided by 3D-QSAR analysis which was performed on literature data. Ten new pyrazole derivatives were synthesised and their antitumor activities against A549 and NCIH23 lung cancer cells were validated. In order to obtain full profile of anticancer activity, cells viability (MTS) assays were combined with cell proliferation (BrdU) assays which measure actively dividing cells in treated sample. Experimental measurements showed good agreement between predicted and measured activities for majority of compounds. Also, anticancer activities of new pyrazole derivatives pointed to the chemical groups that can be useful in designing antitumor molecules. Substitution of hydrazine linker with rigid, 1,2,4-oxadiazole moiety resulted in compound 10, which has low (if any) cytotoxic activity and high potential cytostatic activity. Therefore, compound 10 presents a good starting point for design of new, more potent and safer anticancer therapeutics.     

Determination of desmosine, isodesmosine, and other amino acids by liquid chromatography with electrochemical detection following precolumn derivatization with naphthalenedialdehyde/cyanide

Naphthalenedialdehyde (NDA) in the presence of cyanide (CN) reacts with primary amines to produce fluorescent cyano[f]benzoisoindole (CBI) derivatives. These derivatives have been shown to be substantially more stable than the corresponding o-phthalaldehyde derivatives. However, one drawback of this method is that compounds derivatized at more than one site exhibit quenching, precluding the use of fluorescence detection. The CBI derivatives have been found to be electroactive and are oxidized at a modest oxidation potential (+750 mV). Electrochemical detection is especially useful for the analysis of compounds containing more than one primary amine site because the response is not attenuated as it is in fluorescence detection. Desmosine and isodesmosine were of particular interest because of their importance in elastic fiber and the lack of highly sensitive HPLC methods for the determination of these compounds. Both of these compounds react with NDA/CN to produce electrochemically active derivatives. The combination of derivatization with NDA/CN and electrochemical detection was found to be linear over three orders of magnitude. Detection limits for CBI-lysine and CBI-desmosine were 100 fmol at a S/N of 2. Amino acids in elastin were quantitated using this method. The results correlate well with what has been reported previously in the literature. A significant advantage of the use of liquid chromatography with electrochemical detection with precolumn derivatization with NDA/CN for the analysis of desmosine and isodesmosine is that they can be separated and quantitated individually using this method. In addition, the unique voltammetry of multiderivatized CBI-amino acids can be used to verify peak purity.