The annexins: spatial and temporal coordination of signaling events during cellular stress

Annexins are a family of structurally related, Ca2+-sensitive proteins that bind to negatively charged phospholipids and establish specific interactions with other lipids and lipid microdomains. They are present in all eukaryotic cells and share a common folding motif, the "annexin core", which incorporates Ca2+- and membrane-binding sites. Annexins participate in a variety of intracellular processes, ranging from the regulation of membrane dynamics to cell migration, proliferation, and apoptosis. Here we focus on the role of annexins in cellular signaling during stress. A chronic stress response triggers the activation of different intracellular pathways, resulting in profound changes in Ca2+ and pH homeostasis and the production of lipid second messengers. We review the latest data on how these changes are sensed by the annexins, which have the ability to simultaneously interact with specific lipid and protein moieties at the plasma membrane, contributing to stress adaptation via regulation of various signaling pathways.

Epothilone analogues with benzimidazole and quinoline side chains: chemical synthesis, antiproliferative activity, and interactions with tubulin

A series of epothilone B and D analogues bearing isomeric quinoline or functionalized benzimidazole side chains has been prepared by chemical synthesis in a highly convergent manner. All analogues have been found to interact with the tubulin/microtubule system and to inhibit human cancer cell proliferation in vitro, albeit with different potencies (IC(50) values between 1 and 150 nM). The affinity of quinoline-based epothilone B and D analogues for stabilized microtubules clearly depends on the position of the N-atom in the quinoline system, while the induction of tubulin polymerization in vitro appears to be less sensitive to N-positioning. The potent inhibition of human cancer cell growth by epothilone analogues bearing functionalized benzimidazole side chains suggests that these systems might be conjugated with tumor-targeting moieties to form tumor-targeted prodrugs.

Supramolecular Organization of Heptapyrenotide Oligomers—An in Depth Investigation by Molecular Dynamics Simulations

We present a molecular modeling study based on ab initio and classical molecular dynamics calculations, for the investigation of the tridimensional structure and supramolecular assembly formation of heptapyrenotide oligomers in water solution. Our calculations show that free oligomers self-assemble in helical structures characterized by an inner core formed by π- stacked pyrene units, and external grooves formed by the linker moieties. The coiling of the linkers has high ordering, dominated by hydrogen-bond interactions among the phosphate and amide groups. Our models support a mechanism of longitudinal supramolecular oligomerization based on interstrand pyrene intercalation. Only a minimal number of pyrene units intercalate at one end, favoring formation of very extended longitudinal chains, as also detected by AFM experiment. Our results provide a structural explanation of the mechanism of chirality amplification in 1:1 mixtures of standard heptapyrenotides and modified oligomers with covalently linked deoxycytidine, based on selective molecular recognition and binding of the nucleotide to the groove of the left-wound helix.

Gas-phase Dissociation of homo-DNA Oligonucleotides

Synthetic modified oligonucleotides are of interest for diagnostic and therapeutic applications, as their biological stability, pairing selectivity, and binding strength can be considerably increased by the incorporation of unnatural structural elements. Homo-DNA is an oligonucleotide homologue based on dideoxy-hexopyranosyl sugar moieties, which follows the Watson-Crick A-T and G-C base pairing system, but does not hybridize with complementary natural DNA and RNA. Homo-DNA has found application as a bioorthogonal element in templated chemistry applications. The gas-phase dissociation of homo-DNA has been investigated by ESI-MS/MS and MALDI-MS/MS, and mechanistic aspects of its gas-phase dissociation are discussed. Experiments revealed a charge state dependent preference for the loss of nucleobases, which are released either as neutrals or as anions. In contrast to DNA, nucleobase loss from homo-DNA was found to be decoupled from backbone cleavage, thus resulting in stable products. This renders an additional stage of ion activation necessary in order to generate sequence-defining fragment ions. Upon MS(3) of the primary base-loss ion, homo-DNA was found to exhibit unspecific backbone dissociation resulting in a balanced distribution of all fragment ion series.

Two-dimensional assembly and local redox-activity of molecular hybrid structures in an electrochemical environment

The self-assembly and redox-properties of two viologen derivatives, N-hexyl-N-(6-thiohexyl)-4,4-bipyridinium bromide (HS-6V6-H) and N,N-bis(6-thiohexyl)-4,4-bipyridinium bromide (HS-6V6-SH), immobilized on Au(111)-(1x1) macro-electrodes were investigated by cyclic voltammetry, surface enhanced infrared spectroscopy (SEIRAS) and in situ scanning tunneling microscopy (STM). Depending on the assembly conditions one could distinguish three different types of adlayers for both viologens: a low coverage disordered and an ordered striped phase of flat oriented molecules as well as a high coverage monolayer composed of tilted viologen moieties. Both molecules, HS-6V6-H and HS-6V6-SH, were successfully immobilized on Au(poly) nano-electrodes, which gave a well-defined redox-response in the lower pA–current range. An in situ STM configuration was employed to explore electron transport properties of single molecule junctions Au(T)|HS-6V6-SH(HS-6V6-H)|Au(S). The observed sigmoidal potential dependence, measured at variable substrate potential ES and at constant bias voltage (ET–ES), was attributed to electronic structure changes of the viologen moiety during the one-electron reduction/re-oxidation process V2+ V+. Tunneling experiments in asymmetric, STM-based junctions Au(T)-S-6V6-H|Au(S) revealed current (iT)–voltage (ET) curves with a maximum located at the equilibrium potential of the redox-process V2+ V+. The experimental iT–ET characteristics of the HS-6V6-H–modified tunneling junction were tentatively attributed to a sequential two-step electron transfer mechanism.

Electron transport through catechol-functionalized molecular rods

The charge transport properties of a catechol-type dithiol-terminated oligo-phenylene-ethynylene was investigated by cyclic voltammetry (CV) and by the scanning tunnelling microscopy break junction technique (STM-BJ). Single molecule charge transport experiments demonstrated the existence of high and low conductance regions. The junction conductance is rather weakly dependent on the redox state of the bridging molecule. However, a distinct dependence of junction formation probability and of relative stretching distances of the catechol- and quinone-type molecular junctions is observed. Substitution of the central catechol ring with alkoxy-moieties and the combination with a topological analysis of possible π-electron pathways through the respective molecular skeletons lead to a working hypothesis, which could rationalize the experimentally observed conductance characteristics of the redox-active nanojunctions.

Role of amylase, mucin, IgA and albumin on salivary protein buffering capacity: a pilot study

It has been suggested that proteins serve as major salivary buffers below pH5. It remains unclear, however, which salivary proteins are responsible for these buffering properties. The aim of this pilot study was to evaluate the correlation between salivary concentration of total protein, amylase, mucin, immunoglobulin A (IgA), albumin and total salivary protein buffering capacity at a pH range of 4-5. In addition, the buffering capacity and the number of carboxylic acid moieties of single proteins were assessed. Stimulated saliva samples were collected at 9:00, 13:00 and 17:00 from 4 healthy volunteers on 3 successive days. The buffering capacities were measured for total salivary protein or for specific proteins. Also, the concentration of total protein, amylase, mucin, IgA and albumin were analysed. Within the limits of the current study, it was found that salivary protein buffering capacity was highly positively correlated with total protein, amylase and IgA concentrations. A weak correlation was observed for both albumin and mucin individually. Furthermore, the results suggest that amylase contributed to 35 percent of the salivary protein buffering capacity in the pH range of 4-5.

Combinatorial chromophore assembly inside a DNA four-way junction

In 1964 first proposed by Robin Holliday as a mechanistic model to solve the mystery of how genetic information is exchanged in yeast, the DNA four-way junction or Holliday junction (HJ) was proofed to be the key in- termediate in homologous recombination and became an important tool in the field of DNA origami, computation and nanomachines. Herein we use the assembly of four modified nucleic acid strands into the planar square conformation of this higher order DNA structure to demonstrate in a proof of principle manner the cumulative effect of pyrene moieties interacting inside the junction.[1][2]

Guineensine is a novel inhibitor of endocannabinoid uptake showing cannabimimetic behavioral effects in BALB/c mice

High-content screening led to the identification of the N-isobutylamide guineensine from Piper nigrum as novel nanomolar inhibitor (EC50 = 290 nM) of cellular uptake of the endocannabinoid anandamide (AEA). Noteworthy, guineensine did not inhibit endocannabinoid degrading enzymes fatty acid amide hydrolase (FAAH) or monoacylglycerol lipase (MAGL) nor interact with cannabinoid receptors or fatty acid binding protein 5 (FABP5), a major cytoplasmic AEA carrier. Activity-based protein profiling showed no inhibition of serine hydrolases. Guineensine also inhibited the cellular uptake of 2-arachidonoylglycerol (2-AG). Preliminary structure–activity relationships between natural guineensine analogs indicate the importance of the alkyl chain length interconnecting the pharmacophoric isobutylamide and benzodioxol moieties for AEA cellular uptake inhibition. Guineensine dose-dependently induced cannabimimetic effects in BALB/c mice shown by strong catalepsy, hypothermia, reduced locomotion and analgesia. The catalepsy and analgesia were blocked by the CB1 receptor antagonist rimonabant (SR141716A). Guineensine is a novel plant natural product which specifically inhibits endocannabinoid uptake in different cell lines independent of FAAH. Its scaffold may be useful to identify yet unknown targets involved in endocannabinoid transport.

Quantitative 1H-magnetic resonance spectroscopy of human brain: Influence of composition and parameterization of the basis set in linear combination model-fitting

Localized short-echo-time (1)H-MR spectra of human brain contain contributions of many low-molecular-weight metabolites and baseline contributions of macromolecules. Two approaches to model such spectra are compared and the data acquisition sequence, optimized for reproducibility, is presented. Modeling relies on prior knowledge constraints and linear combination of metabolite spectra. Investigated was what can be gained by basis parameterization, i.e., description of basis spectra as sums of parametric lineshapes. Effects of basis composition and addition of experimentally measured macromolecular baselines were investigated also. Both fitting methods yielded quantitatively similar values, model deviations, error estimates, and reproducibility in the evaluation of 64 spectra of human gray and white matter from 40 subjects. Major advantages of parameterized basis functions are the possibilities to evaluate fitting parameters separately, to treat subgroup spectra as independent moieties, and to incorporate deviations from straightforward metabolite models. It was found that most of the 22 basis metabolites used may provide meaningful data when comparing patient cohorts. In individual spectra, sums of closely related metabolites are often more meaningful. Inclusion of a macromolecular basis component leads to relatively small, but significantly different tissue content for most metabolites. It provides a means to quantitate baseline contributions that may contain crucial clinical information.

Synthesis and properties of heterobifunctional photoaffinity reagents for the identification and isolation of receptors

A method employing isotopically- and photoaffinity-labeled probes and polyclonal and monoclonal antibody to the probes for the identification, isolation and recovery of protein receptors is described. Antibody was raised against N-(3-(p-azido-m-($\sp{125}$I) -iodophenyl)) propionate (AIPP) coupled to and photolyzed to BSA. The antibodies specifically bound AIPP-derivatized proteins. An isolation system was developed utilizing this probe and two antigenically identical reversible analogues. N-(3-((p-azido-m-($\sp{125}$I) -iodo-phenyl)propionyl)amidoethyl-1,3-dithiopropionyl) succinimide (Reversible $\sp{125}$I-AIPPS) reacts with primary amines and N-(((3-p-azido-m-($\sp{125}$I) -iodophenyl)propionyl)amidoethyl)dithiopyridine ($\sp{125}$I-AIPP-PDA) reacts with reduced thiols. The applicability of the system was established by derivatizing known ligands (Transferrin and Interferon-alpha) with one of the probes. The ligand-probe was then allowed to interact with its receptor by incubation with SS5 lymphoma cells and cross-linked by photolysis at 300 nm. The photolyzed ligand/probe/receptor preparation was then recovered with AIPP antibody. Utilization of N-(3-((p-azido-m-($\sp{125}$I) -iodo-phenyl-propionyl)-amidoethyl-1,3-dithiopropionyl) succinimide (Reversible $\sp{125}$I-AIPPS) allowed the components of the photolyzed complex to be separated by treatment with 2-mercaptoethanol in the SDS-PAGE solubilization buffer. Ligand and receptor labeling were then assessed by Coomassie staining and autoradiography. Results of receptor assays suggest that $\sp{125}$I-AIPP was, indeed, transferred to moieties that represent the receptors for both Transferrin and Interferon-alpha. ^

Tumor cell-associated epitopes recognized by lymphokine-activated killers (LAK)

Interleukin-2 activated lymphocytes, designated lymphokine-activated killers (LAK), acquire the unique capacity to express potent cytologic activity against a broad spectrum of abnormal and/or transformed NK-sensitive and NK-resistant target cells while sparing normal cell types. Investigations into the target spectra exhibited by cloned effector cells indicate that LAK cells express a polyspecific recognition mechanism that identifies an undefined class of cell surface-associated molecules expressed on susceptible targets. This report extends our previous investigations into the biochemical nature of these molecules by characterizing the functional role of two tumor cell-surface-associated epitopes implicated in conferring target cells with susceptibility to LAK-mediated cytotoxicity. The first moiety is implicated in the formation of effector/target cell conjugates. This binding ligand is preferentially expressed on tumor cells relative to LAK-resistant PBL target cells, sensitive to trypsin treatment, resistant to functional inactivation by heat- and detergent-induced conformational changes, and does not require N-linked glycosylation to maintain binding activity. In contrast, a carbohydrate-associated epitope represents the second tumor-associated molecule required for target cell susceptibility to LAK cells. Specifically, N-linked glyoprotein synthesis represents an absolute requirement for post-trypsin recovery of target cell susceptibility. The minimal N-linked oligosaccharide residue capable of restoring this second signal has been identified as a high mannose structure. Although ultimately required for tumor cell susceptibility, as measured in $\sp{51}$Cr-release assays, this N-glycan-associated molecule is not required for the differential tumor cell binding expressed by LAK cells. Furthermore, N-glycan expression is not adequate in itself to confer target cell susceptibility. Additional categories of cell surface components have been investigated, including O-linked oligosaccharides, and glycosaminoglycans, without identifying additional moieties relevant to target cell recognition. Collectively, these data suggest that tumor cell recognition by LAK cells is dependent on cell surface presentation of two epitopes: a trypsin-sensitive molecule that participates in the initial conjugate formation and an N-glycan-associated moiety that is involved in a post-binding event required for target cell killing. ^

Cytochrome P-450 reductase FAD binding domain: Cloning, enzymatic activity and flavin binding characterization

The Mixed Function Oxidase System metabolizes a wide range of biochemicals including drugs, pesticides and steroids. Cytochrome P450 reductase is a key enzymatic component of this system, supplying reducing equivalents from NADPH to cytochrome P450. The electrons are shuttled through reductase via two flavin moieties: FAD and FMN. Although the exact mechanism of flavins action is not known, the enzymatic features of reductase greatly depleted of either FMN of FAD have been characterized. Additionally, flavin location within reductase has been proposed by homology and chemical modification studies. This study seeks to extend the flavin depletion analysis in a more controlled system by eliminating the proposed FMN binding domain with recombinant DNA techniques and biochemical analysis. Two P450 reductase cDNA clones containing only the FMN and NADPH binding domain were isolated, expressed and the protein products purified and analysed. This study confirms the proposed FAD binding site, role of FAD in electron shuttling pathway and provides new methods to study the FAD binding domain. ^

PLASMA MEMBRANE GLYCOPROTEINS OF RAT HEPATOCELLULAR CARCINOMA CELLS

Previous investigations have demonstrated qualitative differences in the plasma membrane glycoproteins of normal and malignant rat liver cells. The present investigations were designed to identify and characterize the spectrum of glycoproteins present on the surface of Novikoff and AS-30D hepatocellular carcinoma cells. Three cell-surface radiolabeling techniques were employed to tag specifically the plasma membrane glycoproteins: lactoperoxidase catalyzed iodination, specific for tyrosine residues; galactose oxidase/NaB{('3)H}(,4), specific for galactosyl residues; and NaIO(,4)/NaB{('3)H}(,4), specific for sialic acids. The glycoproteins were resolved by one- and two-dimensional gel electrophoresis and visualized by fluorography or autoradiography. It was found that these glycoproteins are a complex population of molecules. The complexity of this system is reflected not only in the number of individual components that can be detected (> 25), but in the charge heterogeneity of individual glycoproteins due to variable sialic acid content. Certain glycoproteins behaved anamolously on SDS-polyacrylamide gel electrophoresis; the apparent molecular weight decreasing with increasing acrylamide concentrations suggesting a high % carbohydrate. Cell-surface radiolabeling techniques were employed in combination with lectin affinity chromatography, using lectins of different saccharide specificity, to analyze the saccharide determinants present on the spectrum of cell-surface molecules. It was also found that particular glycoproteins differed in their lability to protease or neuraminidase digestion and in their extractability by non-ionic detergents. From these studies, detailed models of the plasma membrane of Novikoff and AS-30D cells were constructed which incorporates information concerning the structure and accessibility of heterosaccharide and peptide moieties, the relationship of the glycolipids, and the interaction of particular glycoproteins with the lipid bilayer. These investigations provide basic information concerning the molecular composition and properties of the plasma membrane of glycoproteins of malignant rat liver cells and lay the groundwork for future comparison to normal hepatocytes. ^

PREPARATION AND CHARACTERIZATION OF COVALENTLY LINKED ENZYME-ANTIBODY CONJUGATES AND THEIR USE IN MEASURING MINUTE QUANTITIES OF PROTEIN ANTIGENS

The discovery and characterization of oncofetal proteins have led to significant advances in early cancer diagnosis and therapeutic monitoring of patients undergoing cancer chemotherapy. These tumor-associated antigens are presently measured by sensitive, specific immunoassay techniques based on the detection of minute amounts of labeled antigen or antibody incorporated into immune complexes, which must be isolated from free antigen and antibody.^ Since there are several disadvantages with using radioisotopes, the most common immunolabel, one major objective was to prepare covalently coupled enzyme-antibody conjugates and evaluate their use as a practical alternative to radiolabeled immune reagents. An improved technique for the production of enzyme-antibody conjugates was developed that involves oxidizing the carbohydrate moieties on a glycoprotein enzyme, then introducing antibody in the presence of polyethylene glycol (PEG). Covalent enzyme-antibody conjugates involving alkaline phosphatase and amyloglucosidase were produced and characterized.^ In order to increase the sensitivity of detecting the amyloglucosidase-antibody conjugate, an enzyme cycling assay was developed that measures glucose, the product of maltose cleavage by amyloglucosidase, in the picomole range. The increased sensitivity obtained by combined usage of the amyloglucosidase-antibody conjugate and enzyme cycling assay was then compared to that of conventional enzyme immunoassay (EIA).^ For immune complex isolation, polystyrene tubes and protein A-bearing Staphylococcus aureus were evaluated as solid phase matrices, upon which antibodies can be immobilized. A sandwich-type EIA, using antibody-coated S. aureus, was developed that measures human albumin (HSA) in the nanogram range. The assay, using an alkaline phosphatase-anti-HSA conjugate, was applied to the determination of HSA in human urine and evaluated extensively for its clinical applicability.^ Finally, in view of the clinical significance of alpha-fetoprotein (AFP) as an oncofetal antigen and the difficulty with its purification for use as an immunogen and assay standard, a chemical purification protocol was developed that resulted in a high yield of immunochemically pure AFP. ^