RESUMO
We show that crystal-field calculations for C_{1} point-group symmetry are possible, and that such calculations can be performed with sufficient accuracy to have substantial utility for rare-earth based quantum information applications. In particular, we perform crystal-field fitting for a C_{1}-symmetry site in ^{167}Er^{3+}:Y_{2}SiO_{5}. The calculation simultaneously includes site-selective spectroscopic data up to 20 000 cm^{-1}, rotational Zeeman data, and ground- and excited-state hyperfine structure determined from high-resolution Raman-heterodyne spectroscopy on the 1.5 µm telecom transition. We achieve an agreement of better than 50 MHz for assigned hyperfine transitions. The success of this analysis opens the possibility of systematically evaluating the coherence properties, as well as transition energies and intensities, of any rare-earth ion doped into Y_{2}SiO_{5}.
RESUMO
The serum opacity factor (SOF) is a group A streptococcal protein that induces opacity of mammalian serum. The serum opacity factor 22 gene (sof22) from an M type 22 strain was cloned from an EMBL4 library by screening for plaques exhibiting serum opacity activity. DNA sequencing yielded an open reading frame of 3,075 bp. Its deduced amino acid sequence predicts a protein of 1,025 residues with a molecular weight of 112,735, a size that approximates that of the SOF22 protein isolated from both the original streptococcal strain and Escherichia coli harboring the cloned sof22 gene. The molecule is composed of three domains: an N-terminal domain responsible for the opacity reaction (opacity domain), a repeat domain with fibronectin-binding (Fn-binding) activity, and a C-terminal cell attachment domain. The C-terminal end of SOF22 is characterized by a hexameric LPXTGX motif, an adjacent hydrophobic region, and a charged C terminus, which are the hallmarks of cell-bound surface proteins found on nearly all gram-positive bacteria. Immediately upstream of this cell anchor region, SOF22 contains four tandem repeat sequence blocks, flanked by prolinerich segments. The repeats share up to 50% identity with a repeated motif found in other group A streptococcal Fn-binding proteins and exhibit Fn-binding activity, as shown by subcloning experiments. According to deletion analysis, the opacity domain is confined to the region N terminal to the repeat segment. Thus, SOF22 is unique among the known Fn-binding proteins from gram-positive bacteria in containing an independent module with a defined function in its N-terminal portion. Southern blot analysis with a probe from this N-terminal region indicates that the opacity domain of SOF varies extensively among different SOF-producing M types.
