Background:It is not known whether a -blocker, metoprolol, induces physiological responses through -arrestins in vivo. Results: Long-term administration of metoprolol induced cardiac fibrosis in wild type but not -arrestin2-or GRK5 knock-out mice. Conclusion: Metoprolol induced cardiac fibrosis in a G protein-independent and GRK5/-arrestin2-dependent manner. Significance: Our study provides a physiological significance of -arrestin-mediated biased signaling pathway by a -blocker in vivo.
Recent studies indicate that the Pig-a assay is a promising tool for evaluating in vivo mutagenicity. We have developed novel rat Pig-a assays that facilitate measuring mutant frequencies in two early arising populations of blood cells, bone marrow erythroids (BMEs) and peripheral blood (PB) reticulocytes (RETs). In these assays, bone marrow cells of erythroid origin and PB red blood cells (RBCs) were identified using an antibody against rat erythroid-specific marker HIS49. In addition, RETs were selectivity enriched from PB using magnetic separation of cells positive for CD71, a transferrin receptor expressed on the surface of BMEs and RETs, but not on the surface of mature RBCs. With magnetic enrichment, more than 1 x 10(6) CD71-positive RETs could be evaluated by flow cytometry for Pig-a mutant frequency within 5 to 8 min. CD59-deficient RET and BME frequencies of more than 100 x 10(-6) and 80 x 10(-6) were detected 1 week after treating rats with 40 mg/kg N-ethyl-N-nitrosourea; by comparison, the frequency of CD59-deficient total RBCs in these rats was 13.2 x 10(-6). The frequency of spontaneous Pig-a mutant RETs and BMEs was less than 5 x 10(-6) and 15 x 10(-6), respectively. Since approximately 98% of nucleated cells in the BME fraction were erythroblasts, it should be possible to use BMEs to determine the spectrum of CD59-deficient Pig-a mutations in cells of erythroid lineage. Conducting concurrent Pig-a assays on RETs and BMEs may be useful for evaluating the in vivo mutagenicity of chemicals, especially when prolonged mutant manifestation is not feasible or when the confirmation of mutation induction is necessary.
The in vivo mutation assay using the X-linked phosphatidylinositol glycan class A gene (Pig-a in rodents, PIG-A in humans) is a promising tool for evaluating the mutagenicity of chemicals. Approaches for measuring Pig-a mutant cells have focused on peripheral red blood cells (RBCs) and reticulocytes (RETs) from rodents. The recently developed PIGRET assay is capable of screening >1×10 RETs for Pig-a mutants by concentrating RETs in whole blood prior to flow cytometric analysis. Additionally, due to the characteristics of erythropoiesis, the PIGRET assay can potentially detect increases in Pig-a mutant frequency (MF) sooner after exposure compared with a Pig-a assay targeting total RBCs (RBC Pig-a assay). In order to test the merits and limitations of the PIGRET assay as a short-term genotoxicity test, an interlaboratory trial involving 16 laboratories was organized by the Mammalian Mutagenicity Study Group of the Japanese Environmental Mutagenicity Society (MMS/JEMS). First, the technical proficiency of the laboratories and transferability of the assay were confirmed by performing both the PIGRET and RBC Pig-a assays on rats treated with single doses of N-nitroso-N-ethylurea. Next, the collaborating laboratories used the PIGRET and RBC Pig-a assays to assess the mutagenicity of a total of 24 chemicals in rats, using a single treatment design and mutant analysis at 1, 2, and 4 weeks after the treatment. Thirteen chemicals produced positive responses in the PIGRET assay; three of these chemicals were not detected in the RBC Pig-a assay. Twelve chemicals induced an increase in RET Pig-a MF beginning 1 week after dosing, while only 3 chemicals positive for RBC Pig-a MF produced positive responses 1 week after dosing. Based on these results, we conclude that the PIGRET assay is useful as a short-term test for in vivo mutation using a single-dose protocol.
-The Pig-a gene mutation assay using perpherial blood erythrocytes is being investigated as a screening tool for assessing mutagenicity in vivo. In this study, we evaluated two distinct approaches for performing the Pig-a assay in rats. We used antibodies to CD45 or the erythroid marker HIS49 to identify red blood cells (RBCs), and then monitored the kinetics of Pig-a mutant frequency, as measured by the frequency of CD59-deficient RBCs, in rats treated with the genotoxic chemicals, N-ethyl-N-nitrosourea, cyclophosphamide, 4-nitroquinoline-1-oxide, and ethylmethanesulfonate. In some instances, micronucleus frequency also was measured in the same animals. Time-and dose-related increases in Pig-a mutant frequency were found in all the chemical-treated groups, except for the groups treated with cyclophosphamide, which was a potent inducer of micronuclei. The two different approaches we employed were comparable for measuring induced mutant frequencies, but our historical data showed that the mean background frequencies for the CD45/CD59 method and the HIS49/CD59 method were 12.7 × 10 -6 and 5.5 ×10 -6 , respectively. The relatively low, stable background mutant frequency associated with the HIS49/CD59 method indicates that it may have greater power for discriminating weak induced responses. These results suggest that the HIS49/CD59 method is a promising tool for measuring Pig-a mutant RBCs. In addition, differences in their manifestation kinetics and in their relative sensitivity for detecting different test compounds suggest that the combination of the Pig-a assay and the micronucleus assay may be effective in identifying in vivo genotoxicity.
The
Pig-a
assay, a promising tool for evaluating in vivo genotoxicity, is based on flow cytometric enumeration of red blood cells (RBCs) that are deficient in glycosylphosphatidylinositol anchor protein. Various approaches for measuring
Pig-a
mutant cells have been developed, particularly focusing on measuring mutants in peripheral RBCs and reticulocytes (RETs). The
Pig-a
assay on concentrated RETs—the PIGRET assay—has the potential to detect genotoxicity in the early stages of a study. To verify the potential and usefulness of the PIGRET assay for short-term testing, we conducted an interlaboratory trial involving 16 laboratories organized by the Mammalian Mutagenicity Study Group of the Japanese Environmental Mutagen Society (MMS/JEMS). The collaborating laboratories assessed the mutagenicity of a total of 24 chemicals in rats using a single-treatment design and standard protocols for conducting the
Pig-a
assay on total RBCs (the RBC
Pig-a
assay) and the PIGRET assay. Here, we describe the standard protocol for the RBC
Pig-a
assay in detail.
The peripheral blood Pig-a assay is now recognized as one of genetic toxicology test to detect the in vivo mutagenic potential of chemical. A previous report on interlaboratry trial by Japanese research group has shown that the rat Pig-a assay with an antibody binds to an erythroid marker is transferable and reproducible. By using this approach, we evaluated the capability of the Pig-a assay protocol to integrate into the general toxicity studies (single or repeated dose study). Both Pig-a assay in total red blood cells (RBC Pig-a assay) and Pig-a assay in reticulocytes (PIGRET assay) were performed before and at days 8, 15 and 29 following single or 28-daily treatments of cyclophosphamide (CP). The difference in the kinetics of increase in Pig-a mutant frequency (MF) between total red blood cell (RBC) and reticulocyte (RET) was found in the single dose study; RET Pig-a MF was temporary increased at days 8 and 15, while RBC Pig-a MF was increased only at day 15. In the repeated dose study, the RET Pig-a MF was increased in the high dose group at day 29, though it was the result under the conditional statistical analysis which excluded one outlier in the control group. The manuscript by Dertinger et al, also showed the increase of Pig-a MFs in both RBCs and RETs, suggesting that the Piga assay for the repeated dose study is feasible to detect the mutagenicity of CP. Taken together, the increase of Pig-a MF was detectable under the both single and 28-day repeated dose study with CP. These results suggest that the Pig-a assay approaches are practical in the general toxicity studies. In addition, the PIGRET assay is an advantageous method at the point that the increase in mutant cells is more detectable at an early stage compared with the RBC Pig-a assay. It is thought that this phenomenon is based on the differentiation stage of an erythroid lineage.
The PIGRET assay is one of the Pig-a assays targeting reticulocytes (RETs), an in vivo genotoxicity evaluation method using flow cytometry with endogenous reporter glycosylphosphatidylinositol anchor protein. The PIGRET assay with RETs selectively enriched with anti-CD71 antibodies has several desirable features: high-throughput assay system, low background frequency of mutant cells, and early detection of mutation. To verify the potential and usefulness of the PIGRET assay for short-term testing, an interlaboratory trial involving 16 laboratories organized by the Mammalian Mutagenicity Study Group of the Japanese Environmental Mutagen and Genome Society was conducted. The collaborating laboratories assessed the mutagenicities of a total of 24 chemicals in rats using a single-treatment design and standard protocols for conducting the Pig-a assay on the total red blood cell assay and the PIGRET assay. Here the standard protocol for the PIGRET assay was described in detail.
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