Novel, cell-penetrating molecular transporters with flexible backbones and permanently charged side-chains.

Various cell-penetrating peptides have been discovered recently that can translocate across plasma membranes and can even carry large cargo molecules into the cells. Because under physiological conditions most of these peptides carry considerable positive charges due to the presence of basic amino acids such as arginine, we decided to investigate whether molecular transporters composed of permanently charged side-chains also possess such cell penetrating ability. Arginine-rich oligomers that have a backbone with increased flexibility due to incorporation of non-alpha-amino acids (epsilon-aminocaproic acid) have been found to be effective molecular transporters. Here, we report the preparation of analogue structures by replacing the arginine residues with the quaternary form of a novel redox amino acid (Nys(+)) that contain a trigonelline moiety; it has already been shown possible to replace the original basic amino acid side-chain of neuropeptides without significant activity-loss due to the sufficiently close steric and electronic analogy between the new Nys(+) and the original side-chains (in their protonated form, e.g., Arg(+), Lys(+)). A nonamer analogue showed transporter activity resulting in increased cellular uptake in human carcinoma (HeLa) cells.

The effects of parasite-derived immune-suppressive factors on the cellular innate immune and autoimmune responses of Drosophila melanogaster.

Immune-suppressive factors (ISFs) introduced into larvae of Drosophila melanogaster during infection by virulent endoparasitic wasps effectively block the innate immune response mediated by blood cells (hemocytes) but have little influence on the autoimmune response made by a tumor strain in which the blood cells manifest a similar response but instead target and destroy endogenous tissues. Quantitative hemocyte analyses indicate that ISFs interfere with the immune effector responses downstream of nonself recognition, hemocyte activation and differentiation, because these responses were manifested by tumor hosts, in which the parasitoids developed. The data suggest that once activated to encapsulate aberrant tissues, the target specificity of the autoimmune-activated hemocytes, and the genetic program underlying tumor formation, cannot be blocked by parasitoid-derived ISFs, which effectively inhibit identical hemocyte-mediated responses during parasitization.

Conformational study of linear and cyclic peptides corresponding to the 276-284 epitope region of HSV gD-1.

The results of conformational analysis of linear and cyclic peptides from the 276SALLEDPVG(284) sequence of glycoprotein D of Herpes simplex virus are presented. The epitope peptides were synthesized by SPPS and on resin cyclization was applied for preparation of cyclic compounds. Circular dichroism spectroscopy, Fourier-transform infrared spectroscopy and nuclear magnetic resonance (NMR) were used to determine of the solution structure of both linear and cyclic peptides. The results indicated that the cyclopeptides containing the core of the epitope (DPVG) as a part of the cycle have more stable beta-turn structure than the linear peptides or the cyclic analogues, where the core motif is not a part of the cycle. NMR study of H-SALLc(EDPVGK)-NH(2) confirm presence of a type I beta-turn structure which includes the DPVG epitope core.

Effect of D-amino acid substitution in a mucin 2 epitope on mucin-specific monoclonal antibody recognition.

We have studied the influence of D-amino acid substitution in the flanking region on the antibody recognition of the 19TGTQ22 epitope core in the tandem repeat of mucin 2 (MUC2) glycoprotein. Analogue peptides corresponding to the optimal epitope sequence (16PTPTGTQ22) have been prepared by the replacement of single or multiple L-amino acid residues at the N-terminal part of the molecule. According to previous studies, this portion of the all-L 16PTPTGTQ22 peptide possesses a beta-turn secondary structure important for efficient monoclonal antibody interaction. The binding properties of sequentially modified peptides (pTPTGTQ, ptPTGTQ, ptpTGTQ, and ptptGTQ) have been analyzed by a MUC2 glycoprotein specific monoclonal antibody (MAb 996) using RIA inhibition assay and characterized by IC50 values. At the same time, we have investigated the secondary structure of the compounds by circular dichroism and Fourier transform infrared spectroscopy in solution. Our data showed that the presence of D-amino acid residue(s) at position(s) 16P, 16PT17, or 16PTP18 resulted in gradually decreasing antibody binding, but the replacement of the L-Thr at position 19 almost abolished activity. Parallel with this reduction, changes in the conformer population have been detected. The propensity of the pTPTGTQ peptide to adopt folded, most probably beta-turn, structure in water can be in correlation with its essentially preserved antibody recognition. After further substitution, the peptide still contained beta- and/or gamma-turn folded secondary structural elements. The conformation of peptide ptptGTQ could be characterized mostly by semiextended (polyproline II) and probably classic gamma-turn conformers built up from D residues.

Iron, metalloenzymes and cytotoxic reactions.

There is considerable evidence implicating iron and other redox-active transition metals as progenitors of reactive intermediates of oxygen (ROI), molecules which lead to oxidative stress and contribute to various neurodegenerative processes. An important aspect of such metal-mediated damage to biomolecules is the site-specific nature of such pathological activity. Iron sequestering molecules, such as ferritin, transferrin, lactotransferrin, melanotransferrin, hemosiderin and heme can serve as cytoprotectants against metal-mediated oxidant damage. Metalloenzymes also constitute an important group of iron sequestering molecules. Metalloenzyme-catalyzed reactions in which metal ions at the enzyme active site undergo redox-cycling in association with O2 are site-specific in nature, and may represent a potential source of ROI-mediated damage to biomolecules. Dysregulation of brain iron and alterations in the levels of metalloenzymes involved in reactions with O2 derived molecules can contribute to neuronal damage. Iron may increase the cytotoxicity of neuronal dopamine by increasing its rate of oxidation to quinones and semiquinones, thereby reducing the level of this neurotransmitter. Interestingly, dopamine also may play an important role in the maintenance of transition-metal homeostasis as an iron chelator, since it can form both catecholate and hydroxamate groups, molecules employed by many microorganisms to sequester iron.

Hydroxyl radical formation via iron-mediated Fenton chemistry is inhibited by methylated catechols.

The differing effects of O-methylated catecholamines and their dihydroxyphenyl precursors on the production of *OH were quantified using a previously established specific salicylate hydroxylation assay in conjunction with a sensitive electrochemical detection system. The production of *OH by the Fenton reaction was diminished significantly by O-methylated catecholamines (O-methyldopa, O-methyldopamine, O-methyltyrosine, and N-acetyl-O-methyldopamine), whereas radical production was augmented by dihydroxyphenyls (DOPA, dopamine, and N-acetyldopamine), including those with methylated side chains (N-methyldopamine and alpha-methyldopa). Monohydroxyphenyls such as octopamine, tyramine, tyrosine, and alpha-methyltyrosine had little or no effect on radical production. These data show that a methyl group positioned on the side chain of a catecholamine does not alter its pro-oxidant behavior, while a methyl group positioned on the aromatic ring renders the catecholamine sterically or kinetically unfavorable for coordination with transition metals, thus preventing the promotion of Fenton chemistry. These results highlight the importance of O-methylation in forming catechols that are less reactive than their dihydroxyphenyl precursors. Thus, factors regulating the methylation of brain catecholamines may play a crucial role in mediating neuronal integrity during aging and in the pathogenesis of certain neurodegenerative disorders. Competitive side-chain methylation reactions may sustain or perpetuate some dihydroxyphenyls, creating an oxidatively less favorable environment for cells than would result from compounds formed by O-methylation.

Comparative studies of enhanced iron-mediated production of hydroxyl radical by glutathione, cysteine, ascorbic acid, and selected catechols.

A sensitive electrochemical detection system was employed together with a specific salicylate hydroxylation assay to comparatively assess the effects of various substances on the iron-mediated generation of the hydroxyl radical (.OH). Hydroxyl radical production was found to be enhanced significantly by reduced glutathione, cysteine, ascorbic acid, and selected catechols, but not by mannitol, melatonin or tyramine. The data showed that over the range of concentrations examined, the augmented effects were linearly proportional to the amount of added reductant for a given amount of iron in the system. The pro-oxidant activity of thiols and ascorbate reduced and recycled iron providing both hydrogen peroxide (H2O2) and catalytic ferrous ions for augmented .OH production by the Fenton reaction. The enhanced production of .OH by catechols resulted from their oxidation either by molecular oxygen or ferric ions, with the accompanying formation of semiquinones, superoxide anion and H2O2. These data caution against therapeutic applications of thiols and ascorbate for ameliorating oxy-radical-induced tissue damage in environments where free redox-active metal ions may be present to function both as foci for site-specific peroxidative activity, and as catalysts to promote the pro-oxidant properties of certain endogenous reductants, thereby elevating rather than diminishing .OH levels.

Hydrogen peroxide generation associated with the oxidations of the eumelanin precursors 5,6-dihydroxyindole and 5,6-dihydroxyindole-2-carboxylic acid.

The ability of iron chelates to promote hydroxyl radical (.OH) formation from hydrogen peroxide (H2O2) via Fenton chemistry was exploited to detect H2O2 produced during the oxidations of the eumelanin precursors 5,6-dihydroxyindole (DHI) and 5,6-dihydroxyindole-2-carboxylic acid (DHICA). H2O2 generation during the autooxidations of DHI and DHICA was confirmed on the basis of the electrochemical detection of three hydroxylation products of salicylate [2,3 and 2,5-dihydroxybenzoic acid (DHBA) and catechol], which was used as an .OH indicator. The oxidations of both 5,6-dihydroxyindoles were augmented by tyrosinase and peroxidase without the addition of H2O2. The partial inhibitions by catalase of the auto-oxidations and tyrosinase- and peroxidase-mediated oxidations of DHI and DHICA provide additional evidence of an endogenous origin of H2O2 during the final stages of eumelanogenesis. The mechanism proposed for the formation of H2O2 involves the semiquinones of DHI and DHICA in the univalent transfer of electrons to molecular oxygen. The observations described in this study support previous reports suggesting that factors modulating the levels of H2O2 in melanocytes and melanoma cells play critical roles in directing the course of melanogenesis and influencing the potential cytotoxicity of the biosynthetic pathways.

The effects of glutathione and ascorbic acid on the oxidations of 6-hydroxydopa and 6-hydroxydopamine.

The interactions of ascorbic acid (AA) and reduced glutathione (GSH) in the oxidations of the catecholaminergic neurotoxins 6-hydroxydopa (TOPA) and 6-hydroxydopamine (6-OHDA) were investigated by both high performance liquid chromatography with electrochemical detection (HPLC-ED) and spectrometric methods. These comparative studies showed TOPA and 6-OHDA to be extremely unstable, with 100% of the trihydroxyphenyls oxidized within 0.5 min at physiological pH in potassium phosphate buffer. Neither AA nor GSH was found capable of significantly impeding the oxidations of these trihydroxyphenyls, or of regenerating these substances by reducing back their oxidation products, even though such a redox exchange mechanism was demonstrated for AA and the dihydroxyphenyl dopamine. Although ineffective in keeping TOPA and 6-OHDA as reduced molecules, GSH may nevertheless influence the neurotoxicity of trihydroxyphenyls by interacting with their oxidation products forming glutathionyl conjugates, thereby switching the reaction pathway away from potentially toxic eumelanin precursors and toward the production of pheomelanin. Electrochemical analyses established the formation of two oxidation products derived from each trihydroxyphenyl, one detected at -100 mV and the other at +700 mV. AA had no effect on either oxidation product, whereas GSH significantly decreased the levels of both oxidation products. The component detected at +700 mV is the cyclized, reduced leukochrome. The identity of the component detected at -100 mV was not established, but it is considered to be either the p-quinone or the cyclized, oxidized aminochrome.

Frequency of Lewis group substances in patients with cancer of stomach.

Authors examined the frequency of Lewis group substances in red blood cells (RBC) and saliva of 293 patients with cancer of stomach, and of 760 healthy volunteers. Lewis (a-b-) substances on RBC surfaces were significantly more frequent in patients with cancer of stomach compared to normal controls. Most patients with cancer of stomach who had Lewis (a-b-) type red blood cells had Lewis-a and Lewis-b substances in their saliva. The deficiency of Lea substance and the loss or weakening of Leb antigen on RBCs may be a prognostic and diagnostic indicator in patients with cancer of stomach.