Dynamically Spontaneous Symmetry Breaking and Masses of Lightest Nonet Scalar Mesons as Composite Higgs Bosons

Based on the (approximate) chiral symmetry of QCD Lagrangian and the bound state assumption of effective meson fields, a nonlinearly realized effective chiral Lagrangian for meson fields is obtained from integrating out the quark fields by using the new finite regularization method. As the new method preserves the symmetry principles of the original theory and meanwhile keeps the finite quadratic term given by a physically meaningful characteristic energy scale $M_c$, it then leads to a dynamically spontaneous symmetry breaking in the effective chiral field theory. The gap equations are obtained as the conditions of minimal effective potential in the effective theory. The instanton effects are included via the induced interactions discovered by 't Hooft and found to play an important role in obtaining the physical solutions for the gap equations. The lightest nonet scalar mesons($\sigma$, $f_0$, $a_0$ and $\kappa$) appearing as the chiral partners of the nonet pseudoscalar mesons are found to be composite Higgs bosons with masses below the chiral symmetry breaking scale $\Lambda_{\chi} \sim 1.2$ GeV. In particular, the mass of the singlet scalar (or the $\sigma$) is found to be $m_{\sigma} \simeq 677$ MeV.Comment: 15 pages, Revtex, published version, Eur. Phys. J. C (2004) (DOI) 10.1140/epjcd/s2004-01-001-

Study of Electron Transfer through the Reductase Domain of Neuronal Nitric Oxide Synthase and Development of Bacterial Nitric Oxide Synthase Inhibitors

Crystal structure of neuronal Nitric Oxide Synthase reductase (nNOSr) implies that large-scale domain motion is essential for electron transfer. However, the details are not well understood. To address this, we generated a functioning “Cys-lite” version of nNOSr and then replaced the nNOSr Glu816 and Arg1229 residues with Cys in the FMN and FAD domains (CL5SS) in order to allow cross-domain disulfide bond formation under pH 9 or to cross-linking using bis-maleimides. Cross-linked CL5SS exhibited a =95% decrease in cytochrome c reductase activity and reduction of the disulfide bond restored the activities. The results demonstrate that a conformational equilibrium involving FMN domains motion is essential for the electron transfer. A graded lengthening of the bis-maleimide cross-linkers was associated with an increase in activity, thus helping to define the distance constraints for domain opening. Stopped-flow kinetic studies showed cross-linking did not negatively affect the hydride transfer and interflavin electron but severally impaired the electron efflux from the FMN domain to its redox partner. How these findings impact our understanding of the nNOS catalytic cycle and details are discussed. Staphylococcus aureus nitric oxide synthase (saNOS) helps S. aureus to maintain its antibiotics resistance, making saNOS a drug target. However, in vitro determination of saNOS inhibitor potency by activity assay is challenging because saNOS lacks an attached reductase. Herein, we employ the following approaches to optimize the in vitro assessment of NO synthesis by saNOS (1) B. subtillis flavodoxin YkuN and B. subtillis flavodoxin reductase FLDR were adopted as reductase partners for saNOS; (2) PEGylated-oxyhemoglobin was used for the direct capture of NO; (3) a 96-well plate format was used to increase the assay throughput. Our results showed that PEGylation of oxyHb minimizes the futile redox cycling within the flavoprotein and ensured effective electron transfer from produced NO to oxyHb. Nitric oxide produced by saNOS and cell cytosol was successfully detected by our assays. We also tested the inhibitory potency of six compounds derived from trimethoprim. They were confirmed to be H4F competitor with IC50 varying from 1 µM to 1 mM. The most potent inhibitor UCP111F26M is very specific to saNOS. Details of this inhibitor are discussed

Schwinger boson mean field theory of the Heisenberg Ferrimagnetic Spin Chain

The Schwinger boson mean field theory is applied to the quantum ferrimagnetic Heisenberg chain. There is a ferrimagnetic long range order in the ground state. We observe two branches of the low lying excitation and calculate the spin reduction, the gap of the antiferromagnetic branch, and the spin fluctuation at $T=0K$. These results agree with the established numerical results quite well. At finite temperatures, the long range order is destroyed because of the disappearance of the Bose condensation. The thermodynamic observables, such as the free energy, magnetic susceptibility, specific heat, and the spin correlation at $T>0K$, are calculated. The $T\chi_{uni}$ has a minimum at intermediate temperatures and the spin correlation length behaves as $T^{-1}$ at low temperatures. These qualitatively agree with the numerical results and the difference is small at low temperatures.Comment: 15 pages, 5 figures. Accepted by Phys. Rev.