[Development of effective detection method for Coxiella burnetii in mayonnaise by real-time PCR and investigation of C. burnetii contamination in commercial mayonnaise in Tokyo].

A PCR method for the effective detection of Coxiella burnetii in commercially available mayonnaise was developed. Sample preparations were isolated from 50 g portions of each mayonnaise product by four successive extraction steps in phosphate buffer with 2.0 M NaCl. These extracts were then centrifuged at 20,000 x g for 60 min. DNA was isolated from the solution containing the precipitate with a commercial kit, and amplified quantitatively using real-time PCR that targeted the com1 region of C. burnetii. The recoveries of C. burnetii from 2 kinds of commercial mayonnaise specimens, with a baseline control of 1 x 10(7) particles of the Nine Mile phase II strain, were 85.0 +/- 6.0% and 72.0 +/- 0.4%, respectively. The determination limit of this method was 500 C. burnetii particles per 50 g of mayonnaise. The DNA specimens isolated from 50 different commercial mayonnaise samples sold in Tokyo using this method were amplified using both nested PCR and real-time PCR. No contamination by C. burnetii was detected in any of the mayonnaise samples.

[Investigation of Coxiella burnetii contamination in commercial milk and PCR method for the detection of C. burnetii in egg].

A total of 244 milk samples collected from supermarkets in Tokyo were examined for contamination with Coxiella burnetii. C. burnetii DNA was detected in 131 (53.7%) of the samples by nested PCR. PCR-positive samples were injected into immunosuppressed A/J strain mice. Of the 22 PCR-positive milk samples tested, none resulted in isolation of C. burnetii from the mice. Heat-treatment was sufficient to inactivate C. burnetii in commercial milk. In addition, a PCR detection method for C. burnetii in chicken egg was developed. Egg yolk was added to an equal volume of 1 mol/L of NaCl phosphate buffer and homogenized for removal of protein and lipid. After centrifugal separation, the supernatant was removed, and template DNA in the precipitate was extracted using SDS, proteinase K and NaI. Using such prepared samples, 3.2 x 10(1) C. burnetii particles in 1 g of egg yolk could be detected by nested PCR. All of 200 chicken egg samples collected from supermarkets in Tokyo were negative for C. burnetii by the nested PCR method.

RGS8 expression in developing cerebellar Purkinje cells.

The regulators of G protein signaling (RGS) proteins modulate heterotrimeric G protein signaling. RGS8 belongs to B/R4 subfamily of RGS proteins and is specifically expressed in Purkinje cells of adult cerebellum. Here, to examine the expression of RGS8 mRNA in developing cerebellum, we performed in situ hybridization. Apparent signals for expression of RGS8 mRNA were first detected on day 9 after birth, then RGS8 mRNA expression in Purkinje cells increased up to day 21, and its levels decreased to some extent in adult Purkinje cells. We also studied the expression of RGS7, which is expressed in Golgi cells in the granule cell layer of adult cerebellum. The expression of RGS7 mRNA was recognized in 7 day neonatal cerebellum. When examined with anti-RGS8 antibody, the RGS8 protein was already excluded from nucleus on day 9, and was distributed in cell body and dendrites in differentiating Purkinje cells of 14 day neonates.

Distribution of regulator of G protein signaling 8 (RGS8) protein in the cerebellum.

The regulator of G protein signaling (RGS) proteins modulate heterotrimeric G protein signaling. RGS8 was identified as a brain-specific RGS protein of 180 amino acids. Biochemical studies indicated that RGS8 binds to Galphao and Galphai3, and that it functions as a GTPase-activating protein (GAP) for Galpha subunits. Physiological investigations demonstrated that RGS8 is not a simple negative regulator, but accelerates the G-protein-coupled responses. In situ hybridization analysis showed a highly dense expression of RGS8 mRNA in Purkinje cells of the cerebellum in rat brain. When the cellular distribution of RGS8 was examined in non-neural cells transfected with RGS8 cDNA, the protein was found to be concentrated in nuclei. Further, co-expression of constitutively active Galphao resulted in the translocation of RGS8 protein to the plasma membrane. The cellular distribution of the RGS8 protein in cerebellar Pukinje cells was also studied in detail. It was shown that the protein is excluded from the nuclei and distributed in the cell body and dendrites except the axons of Purkinje cells. Thus, it is evident that there is a novel mechanism controlling the distribution of RGS8 protein in cerebellar Purkinje cells.

Alternative splicing of RGS8 gene determines inhibitory function of receptor type-specific Gq signaling.

The regulators of G protein signaling (RGS) proteins modulate heterotrimeric G protein signaling. RGS8 is a brain-specific RGS protein of 180 aa. Here we identified a short isoform of RGS8, RGS8S, that arises by alternative splicing. RGS8S cDNA encodes a N terminus of 7 aa instead of amino acids 1-9 of RGS8 and 10-180 of RGS8. The subcellular distribution of RGS8 and RGS8S did not differ significantly in transfected cells. RGS8S accelerated, not as efficiently as RGS8, the turning on and off of Gi/o-mediated modulation of G protein-gated inwardly rectifying K(+) channels in Xenopus oocytes. We next examined the effects of RGS8 and RGS8S on Gq-mediated signaling. RGS8 decreased the amplitude of the response upon activation of m1 muscarinic or substance P receptors, but did not remarkably inhibit signaling from m3 muscarinic receptors. In contrast, RGS8S showed much less inhibition of the response of either of these Gq-coupled receptors. By quantitative analysis of the inhibitory effect and the protein expression level, we confirmed that the difference of inhibitory effect is caused by both the qualitative difference between RGS8 and RGS8S and the quantitative difference of the protein expression level. We also confirmed that the receptor-type specificity of inhibition is not caused by the difference of the expression level of the receptors. In summary, we showed that 9 aa in the N terminus of RGS8 contribute to the function to inhibit Gq-coupled signaling in a receptor type-specific manner and that the regulatory function of RGS8S is especially diminished on Gq-coupled responses.