Localized and delocalized bound states of the main isotopologue 48O3 and of 18O-enriched 50O3 isotopomers of the ozone molecule near the dissociation threshold.

Knowledge of highly excited rovibrational states of ozone isotopologues is of key importance for modelling the dynamics of exchange reactions, for understanding longstanding problems related to isotopic anomalies of the ozone formation, and for analyses of extra-sensitive laser spectral experiments currently in progress. This work is devoted to new theoretical study of high-energy states for the main isotopologue 48O3 = 16O16O16O and for the family of 18O-enriched isotopomers 50O3 = {16O16O18O, 16O18O16O, 18O16O16O} of the ozone molecule considered using a full-symmetry approach. Energies and wave functions of bound states near the dissociation threshold are computed in hyperspherical coordinates accounting for the permutation symmetry of three identical nuclei in 48O3 and of two identical nuclei in 50O3, using the most accurate potential energy surface available now. The obtained vibrational band centers agree with observed ones with the root-mean-squares deviation of about 1 cm-1, making the results appropriate for assignments and analyses of future experimental spectra. The levels delocalized between the three potential wells of ozone isomers are computed and analyzed. The states situated deep in the three (for 48O3) or two (for 50O3) equivalent potential wells have similar energies with negligible splitting. However, the states situated just below the potential barriers separating the wells, are split due to the tunneling between the wells resulting in the splitting of rovibrational sub-bands. We evaluate the amplitudes of the corresponding effects and consider possible perturbations in vibration-rotation bands due to interactions between three potential wells. Theoretical predictions for the splitting of observable band centers are provided for the first time.

The Role of Ozone Vibrational Resonances in the Isotope Exchange Reaction 16O16O + 18O → 18O16O + 16O: The Time-Dependent Picture.

We consider the time-dependent dynamics of the isotope exchange reaction in collisions between an oxygen molecule and an oxygen atom: 16O16O + 18O → 16O18O + 16O. A theoretical approach using the multiconfiguration time-dependent Hartree method was employed to model the time evolution of the reaction. Two potential surfaces available in the literature were used in the calculations, and the results obtained with the two surfaces are compared with each other as well as with results of a previous theoretical time-independent approach. A good agreement for the reaction probabilities with the previous theoretical results is found. Comparing the results obtained using two potential energy surfaces allows us to understand the role of the reef/shoulder-like feature in the minimum energy path of the reaction in the isotope exchange process. Also, it was found that the distribution of final products of the reaction is highly anisotropic, which agrees with experimental observations and, at the same time, suggests that the family of approximated statistical approaches, assuming a randomized distribution over final exit channels, is not applicable to this case.

Versican isoforms modulate expression and function of nicotinic acetylcholine receptors.

Versican is a chondroitin sulfate proteoglycan whose isoforms are differentially expressed, but little is known of their functions in the neuronal system. Here we show that isoforms of versican play different roles in neuronal differentiation and neurite outgrowth. Expression of versican V1 isoform in PC12 cells induced complete neuronal differentiation and increased the expression of nicotinic acetylcholine receptor in NGF-independent manners. The V1-induced neuronal differentiation was different from the NGF-induced differentiation, showing a specific profile of nAChR subunit expression and distinct kinetics of receptor-gated channel activity. Our results have implications for understanding how versican regulates neuronal development, function and repair.

The ability of versican to simultaneously cause apoptotic resistance and sensitivity.

Expression of the extracellular matrix proteoglycan versican is associated with more than 10 types of cancers, often being secreted by stromal cells in response to tumor signals. Previous work in our lab has shown that overexpression of the V1 versican isoform in cultured fibroblasts (V1 cells) increases both proliferation and apoptotic resistance. We show here that V1 cells induced tumor formation in nude mice and that, in keeping with previously shown apoptotic resistance, V1 cells have down-regulated Fas mRNA and protein levels. Unexpectedly, however, V1 cells were found to be sensitized to a wide range of cytotoxic agents. This combination of selective apoptotic resistance and sensitivity is often seen in cancer cells. V1 cells were also shown to have high resting levels of p53 and murine double minute-2 proteins, correlating with apoptotic sensitivity. Treatment with UV radiation induced p21 expression in vector-transfected cells but not in V1 cells. As p21 induces cell cycle arrest and inhibits apoptosis, its loss in V1 cells, coupled with high resting levels of proapoptotic p53, may be at least partially involved in their premature death following cytotoxic treatment. This study further supports the importance of versican in cancer cell biology and the complexity of apoptosis regulation.

PG-M/versican binds to P-selectin glycoprotein ligand-1 and mediates leukocyte aggregation.

P-selectin glycoprotein ligand-1 (PSGL-1), a glycoprotein expressed on the cell surface of leukocytes, binds to selectins and mediates leukocyte rolling on the vascular endothelium. Here we report that PSGL-1 binds to the C-terminal (G3 domain) of the extracellular proteoglycan PG-M/versican. Cells transfected with PSGL-1 or a shorter form containing the binding site, or cells expressing endogenous PSGL-1 aggregate in the presence of versican or G3 product. The aggregation appears to be induced by G3 multimers that bind to PSGL-1 and form a network. Endogenous versican and/or G3-containing fragments also bind to PSGL-1 in human plasma. Removal of the endogenous G3-containing fragments reduces the effect of plasma on leukocyte aggregation. Finally, the roles of G3-containing fragments in leukocyte aggregation were confirmed in a mouse model. Taken together, our results strongly support a physiologically relevant role for PSGL-1/versican binding and may have implications in the immunoresponse.