Effects of transferrin conjugates of artemisinin and artemisinin dimer on breast cancer cell lines.

Transferrin (Tf) conjugates of monomeric artemisinin (ART) and artemisinin dimer were synthesized. The two conjugates, ART-Tf and dimer-Tf, retained the original protein structure, and formed stable aggregates in aqueous buffer. ART-Tf induced declines in proteins involved in apoptosis (survivin), cell cycling (cyclin D1), oncogenesis (c-myelocytomatosis oncogene product (c-MYC)), and dysregulated WNT signaling (beta-catenin) in both the human prostate (DU145) and breast (MCF7) cancer cell lines. Both ART-Tf and dimer-Tf induced down-regulation of survivin, c-MYC and mutated human epidermal growth factor receptor-2 (ERBB2 or HER2) in the BT474 breast cancer cell line. To our knowledge, this is the first demonstration that an ART derivative can cause a decline of ERBB2 in a human cancer cell line. Potential mechanisms for the observed effects are presented. Both transferrin conjugates strongly inhibited the growth of BT474 cells in the same concentration range that the conjugates caused declines in the levels of ERBB2, survivin, and c-MYC, while showing essentially no toxicity towards MCF10A normal breast cells.

Effects of aromatic compounds on antennal responses and on the pheromone-binding proteins of the gypsy moth (Lymantria dispar).

Female gypsy moths emit a pheromone, (+)-disparlure, which the males follow until they locate the emitter. The male moths' antennae are covered with innervated sensory hairs, specialized in detection of the pheromone. The neurons in these sensory hairs are bathed by a solution rich in pheromone-binding protein (PBP). PBPs are soluble proteins that bind the pheromone and other odorants reversibly with variable thermodynamic and kinetic selectivity and are essential for olfactory responses. Here, we have studied the interaction between 2 gypsy moth PBPs with aromatic compounds that modulate the responses of male moth antennae to (+)-disparlure. The aromatic compounds do not elicit responses by themselves, but when administered together with pheromone, they inhibit, enhance, or prolong the electrophysiological response to the pheromone. Three interactions between the compounds and PBPs were studied: 1) the equilibrium binding of the compounds by themselves to the PBPs, 2) the equilibrium binding of the compounds in the presence of pheromone or a fluorescent reporter ligand, and 3) the effect of the compounds on the conformation of the pheromone-PBP complex. A subset of compounds causes a prolongation of the electroantennogram response, and from this study, we conclude that these compounds follow a structure-activity pattern and stabilize a particular conformer of the PBPs that appears to activate the olfactory response.

Synthesis and biological activity of conformationally restricted gypsy moth pheromone mimics.

The design and synthesis of a series of conformationally constrained mimics of gypsy moth sex pheromone, (+)-disparlure (7R,8S)-2-methyl-7,8-epoxyoctadecane, are described. The core structure of the mimics is derived from 5-(2'-hydroxyethyl)cyclopent-2-en-1-ol. Substituent optimization of the analogs was accomplished through the synthesis of mini-libraries and pure individual compounds, followed by electrophysiological experiments with male gypsy moth antennae. The electroantennogram results show that the analogs elicited weak to no antennal responses themselves. There was a clear structure-activity pattern for odorant activity, with ethyl substituents being best. Further, when puffed simultaneously with the pheromone, some of the compounds gave a significant enhancement of the antennal depolarization, indicating an additive or synergistic effect. A pure pheromone stimulus following a mixed compound/pheromone stimulus was generally not affected, with two exceptions: one compound enhanced and another inhibited a subsequent stimulus. The compounds also prolonged the stimulation of the antenna, which manifested itself in widened electroantennogram peaks. We tested the hypothesis that this prolonged stimulation may be due to the stabilization of a particular conformer of the pheromone-binding protein (PBP). Compounds that caused PBP2 to adopt a similar conformation than in the presence of pheromone also caused peak widening. This was not the case with PBP1.

Binding conformation and kinetics of two pheromone-binding proteins from the Gypsy moth Lymantria dispar with biological and nonbiological ligands.

Pheromone-binding proteins (PBPs) in insects can bind various substances and selectively deliver the message of a signal molecule to the downstream components of the olfactory system. This can be achieved either through a ligand-specific conformational change of the C-terminal peptide of the PBP or by selectively binding/releasing the ligand. PBP may also act as a scavenger to protect the sensory neurons from saturating at high ligand doses. We have compared two PBPs from the gypsy moth (PBP1 and PBP2) and their truncated forms (TPBPs), which lack the C-terminal peptide, in this study. Stopped-flow kinetics with N-phenyl-1-naphthylamine (NPN) have revealed a diffusion-controlled collisional step, between PBP and NPN, after which the NPN relocates into a hydrophobic environment. This work supports the hypothesis that binding between PBPs and ligands occurs stepwise. With the method of tryptophan fluorescence quenching, we have shown different local conformational changes around Trp 37, induced by different ligands, manifested in changes of both the steric and electronic environment around the residue. Importantly, we have noticed a significant difference in the changes induced by the biological ligand (the pheromone) and nonbiological ligands. Therefore, we hypothesize that PBP may serve a different function in each kinetic step, displaying a unique P.L conformation.

Ligand-interaction kinetics of the pheromone- binding protein from the gypsy moth, L. dispar: insights into the mechanism of binding and release.

The pheromone-binding proteins (PBPs), which exist at a high concentration in the sensillum lymph surrounding olfactory neurons, are proposed to be important in pheromone detection and discrimination in insects. Here, we present a systematic study of PBP-ligand interaction kinetics. We find that PBP2, from the gypsy moth, Lymantria dispar, associates and dissociates slowly with its biofunctional ligands, (+)- and (-)-disparlure. Tryptophan anisotropy measurements detect PBP multimers in solution as well as an increase in the multimeric state of the protein upon long exposure to ligand. We propose a kinetic model that includes monomer/multimer equilibria and a two-step binding process: (1) external binding of the pheromone assisted by the C terminus of PBP2, and (2) slow embedding of the pheromone into the internal pocket. This experimentally derived model sheds light on the potential biological function and mechanism of PBPs as ligand scavengers.