A double-blind, placebo-controlled, randomized multiple dose phase 1b trial of a CDK4/6 inhibitor, TCK-276, in patients with active rheumatoid arthritis.

OBJECTIVE: The purpose of this study was to evaluate the safety, tolerability, pharmacokinetics, and efficacy (as an exploratory endpoint) of TCK-276, a novel CDK4/6 inhibitor, after multiple oral doses for 7 days in patients with active RA. METHODS: This multicentre, randomized, placebo-controlled, dose-ascending, double-blind, phase 1b, multiple-dose study included 32 patients with active RA in 4 cohorts of 8 patients (6 active and 2 matching placebo), each receiving an oral dose of TCK-276 or matching placebo for 7 days (once daily). The doses of TCK-276 were 10, 25, 75, and 175 mg/day. Safety and pharmacokinetic endpoints, and exploratory disease activity parameters for RA were assessed. RESULTS: There were no deaths, serious adverse events, notable clinically meaningful laboratory findings (including hematological changes), clinically meaningful vital sign changes, or clinically meaningful electrocardiogram or cardiac telemetry changes. TCK-276 was rapidly absorbed and the half-life time ranged approximately from 6 to 12 hours. No obvious accumulation was observed, and the increase in TCK-276 exposure was dose proportional. At day 7, DAS28-CRP responses (EULAR good or moderate responses) were observed in 40%, 80%, and 66.7% at 25, 75, and 175 mg/day TCK-276, respectively, versus 12.5% in placebo; ACR20 responses were 33.3%, 60%, and 50% respectively, versus none in placebo. CONCLUSION: TCK-276 (≤175 mg) was well tolerated with no clinically meaningful safety signals in patients with active RA. Together with the preliminary efficacy (≥25 mg/day), these data warrant further study of TCK-276 for the treatment of active RA. TRIAL REGISTRATION: ClinicalTrails.gov, NCT05437419.

Recommendations for conducting the rodent erythrocyte Pig-a assay: A report from the HESI GTTC Pig-a Workgroup.

The rodent Pig-a assay is a flow cytometric, phenotype-based method used to measure in vivo somatic cell mutation. An Organization for Economic Co-operation and Development (OECD) test guideline is currently being developed to support routine use of the assay for regulatory purposes (OECD project number 4.93). This article provides advice on best practices for designing and conducting rodent Pig-a studies in support of evaluating test substance safety, with a focus on the rat model. Various aspects of assay conduct, including laboratory proficiency, minimum number of animals per dose group, preferred treatment and blood sampling schedule, and statistical analysis are described.

Detection of In Vivo Mutation in the Hprt and Pig-a Genes of Rat Lymphocytes.

Assays for in vivo mutation are used to identify genotoxic hazards and phenotypes prone to genomic instability and cancer. The hypoxanthine guanine phosphoribosyl transferase (Hprt) gene and the phosphatidyl inositol glycan, class A (Pig-a) gene are endogenous X-linked genes that can be used as reporters of mutation in peripheral blood lymphocytes from most mammals. Here we describe methodology for measuring Hprt and Pig-a mutation in rat T-lymphocytes. The identification and selective expansion of mutant lymphocytes is based upon the phenotypic properties of Hprt- and Pig-a-deficient cells, that is, resistance to the purine analog, 6-thioguanine, or to the bacterial toxin, proaerolysin. Expanded mutants can be further analyzed by sequencing cDNA from the target transcripts for identification of small sequence alterations and by multiplex PCR analysis of genomic DNA for the detection of deletions.

Persistence of vertebral growth plate cartilage in aged cynomolgus monkeys.

Growth plates at each end of vertebral bodies play a pivotal role in longitudinal spinal growth. Epiphyseal closures are formed in adult humans. Although monkeys are frequently employed in bone and disc research, the age of epiphyseal closure has not been well documented. In this study, histological analyses of lumbar vertebral end plates and the surrounding tissue were performed in 11 normal cynomolgus monkeys aged approximately 9 to 15 years, and unclosed growth plate cartilage was detected in all the end plates. The data from this study constitute the first documentation of persistent vertebral growth plate cartilage in cynomolgus monkeys. The persistence of growth plate cartilage in cynomolgus monkeys approximately 15 years of age or younger, which differs from the complete epiphyseal closure exhibited in adult humans, may affect the biomechanical behavior of the spine. This is an important factor to consider in extrapolating the results of spine and intervertebral disc research using cynomolgus monkeys to adult humans.

Detection of In Vivo Mutation in the Pig-a Gene of Mouse Bone Marrow Erythroids.

Detection of in vivo mutation is important for evaluating the health risks associated with chemicals. The Pig-a in vivo gene mutation assay has been developed over the last decade for this purpose. Most approaches for the assay, however, measure cells with a Pig-a mutant phenotype in erythrocytes from the peripheral blood, with the mutations causing the phenotype being difficult to determine directly. This chapter describes a procedure for detecting mutations in the Pig-a gene of phenotypically mutant mouse bone marrow erythroids, the precursors of peripheral blood erythrocytes. The strategy for molecular analysis of Pig-a gene mutation includes enrichment of GPI-anchor deficient cells with a cell sorter followed by a cloning and sequencing of Pig-a cDNAs.

The rat Pig-a assay using an erythroid HIS49 antibody in a single dose study of isopropyl p-toluenesulfonate.

As part of a collaborative study in the Mammalian Mutagenicity Study group of the Japanese Environmental Mutagen Society, we evaluated the in vivo mutagenicity of isopropyl p-toluenesulfonate (IPTS) using a peripheral blood Pig-a assay in rats. Pig-a mutant frequency (MF) data was obtained for both red blood cells (RBCs) and reticulocytes (RETs) at 1, 2 and 4 weeks after a single oral administration of IPTS at doses of 125, 250, or 500mg/kg. The results of the RBC Pig-a assay demonstrated that both the 250 and 500mg/kg treatment groups showed significant increases in Pig-a MF only at 4 weeks after IPTS treatment. In comparison, the PIGRET assay showed a clear and dose-related increase in Pig-a MF at 1 week after treatment, with a continuous increase until 4 weeks after treatment observed in the highest dose group. These results indicate that the both the RBC Pig-a assay and PIGRET assay can detect in vivo IPTS mutagenicity under a single dosing protocol. In particular, the PIGRET assay, which uses magnetic enrichment to analyze greater numbers of RETs in a high-throughput manner, showed an increase in Pig-a MF earlier than the RBC Pig-a assay. The PIGRET assay is also considered to be more sensitive than the RBC Pig-a assay because it exhibits a low spontaneous Pig-a MF. For this reason, the PIGRET assay clearly identified small increases in Pig-a MF as significant at the lower doses than in the RBC Pig-a assay under the conditions in this study.

The PIGRET assay, a method for measuring Pig-a gene mutation in reticulocytes, is reliable as a short-term in vivo genotoxicity test: Summary of the MMS/JEMS-collaborative study across 16 laboratories using 24 chemicals.

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 >1×106 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.

Report on the rat Pig-a assay using an anti-rat erythroid marker HIS49 antibody in a single dose study of 1,2-dimethylhydrazine.

As part of a collaborative study in the Mammalian Mutagenicity Study (MMS) Group of the Japanese Environmental Mutagen Society (JEMS), we investigated the in vivo genotoxicity profile of 1,2-dimethylhydrazine (DMH) using a Pig-a assay in total red blood cells (RBC Pig-a assay) or a reticulocyte Pig-a assay (PIGRET assay). We also assessed the genotoxic potential of DMH using both a bone marrow micronucleus test and a liver comet assay as follow-up studies. Single administration of 25, 50, 100mg/kg DMH to male rats did not show time- or dose-related increases in Pig-a mutant frequency (MF) in either the RBC Pig-a or PIGRET assays up to 4 weeks after treatment. The bone marrow micronucleus test under the same dose levels was judged positive, while the liver comet assay was judged inconclusive due to the high number of hedgehogs. Re-evaluation of the rat liver comet assay at lower dose levels (4, 10, and 25mg/kg DMH) showed a dose-related increase in%DNA in tail. Taken together, DMH showed a positive response in both the bone marrow micronucleus test and liver comet assay, while the increases in Pig-a MF in both the RBC Pig-a and PIGRET assays could hardly be detected after single dosing. These results suggest that DMH provides different genotoxicity outcomes depending on the endpoint following acute in vivo dosing.

Prophylactic treatment with sulphonated immunoglobulin G attenuates development of mechanical allodynia-like response in mice with neuropathic pain.

Human immunoglobulin G (IgG) concentrates are immune-modulating, anti-inflammatory plasma-derived products. Clinical studies in recent years have suggested that IgG attenuates neuropathic pain. In this study, effects of sulphonated IgG on the development and maintenance of a mechanical allodynia-like response were examined in mice with neuropathic pain induced by a partial sciatic nerve ligation (PSL). When sulphonated IgG (400 or 1,000 mg/kg/day, i.p.) was administered for 5 days, from 1 day before surgery to post-operative day (POD) 3, the development of a mechanical allodynia-like response was attenuated. On the other hand, sulphonated IgG had little effect on the maintenance of a mechanical allodynia-like response when administered for 5 days, from POD 11 to POD 15, at which time a mechanical allodynia-like response had already been developed. To explore the mechanism of sulphonated IgG, the mRNA expression of inflammatory cytokines was evaluated in the injured sciatic nerve. Sulphonated IgG (1,000 mg/kg/day, i.p.) that was administered for 3 days, from 1 day before surgery to POD 1, significantly attenuated the up-regulation of tumor necrosis factor-α and monocyte chemotactic protein-1 mRNAs on POD 1. These results suggest that prophylactic treatment with sulphonated IgG attenuates the development of mechanical allodynia-like response by inhibition of inflammatory cytokine expression in mice with PSL.

The effects of long-lasting hypoglycemia on male reproductive organs in rats.

Glucose has an important role in spermatogenesis. Nevertheless there are few reports in which the effects of long-lasting hypoglycemia on male reproductive organs have been evaluated. Therefore, insulin was administered subcutaneously at 100, 200, and 400 IU/kg to male rats twice a day for one month. This treatment regimen produced plasma glucose levels that rapidly decreased after treatment, with decreased glucose levels lasting for several hours after each administration on the first and final treatment days. During the treatment period, no abnormalities in clinical signs or body weight were observed. No statistically significant differences were noted in the weights of testes, epididymides, prostates and seminal vesicles, or pituitary glands. Histopathological examination revealed that the insulin-treated animals exhibited degeneration of seminiferous tubules in the testes and exfoliation of germ cells in the lumens of epididymides as a secondary change related to the testicular lesions. The incidences of the histopathological findings were found to be proportional to insulin dose. Sperm analysis of the group receiving the highest dosage indicated that the sperm concentration tended to decrease and the incidences of sperm malformations tended to increase. Our results suggest that long-lasting hypoglycemia affects male reproductive organs in rats.

Detection of in vivo mutation in the Hprt and Pig-a genes of rat lymphocytes.

Assays for in vivo mutation are used to identify genotoxic hazards and phenotypes prone to genomic instability and cancer. The hypoxanthine guanine phosphoribosyl transferase (Hprt) gene and the phosphatidyl inositol glycan, class A (Pig-a) gene are endogenous X-linked genes that can be used as reporters of mutation in peripheral blood lymphocytes from most mammals. Here we describe methodology for measuring Hprt and Pig-a mutation in rat T-lymphocytes. The identification and selective expansion of mutant lymphocytes are based upon the phenotypic properties of Hprt- and Pig-a-deficient cells, i.e., resistance to the purine analog, 6-thioguanine, or to the bacterial toxin, proaerolysin. Expanded mutants can be further analyzed by sequencing cDNA from the target transcripts for identification of small sequence alterations and by multiplex PCR analysis of genomic DNA for the detection of deletions.

Effective use of the Pig-a gene mutation assay for mutagenicity screening: measuring CD59-deficient red blood cells in rats treated with genotoxic chemicals.

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 in vivo Pig-a gene mutation assay is useful for evaluating the genotoxicity of ionizing radiation in mice.

The in vivo Pig-a mutation assay has been adapted for measuring mutation in rats, mice, monkeys, and humans. To date, the assay has been used mainly to assess the mutagenicity of chemicals that are known to be powerful point mutagens. The assay has not been used to measure the biological effects associated with ionizing radiation. In this study, we modified the Pig-a gene mutation assay (Kimoto et al. [2011b]: Mutat Res 723:36-42) and used 3-color staining with fluorescently labeled anti-CD24, anti-TER-119, and anti-CD71 to detect the Pig-a mutant frequencies in total red blood cells (RBCs) and in reticulocytes (RETs) from X-irradiated mice. Single exposures to X-irradiation resulted in dose- and time-dependent increases in Pig-a mutant frequencies, and these subsequently declined over time returning to background frequencies. The same total amount of radiation, delivered either as a single dose or as four repeat doses at weekly intervals, increased Pig-a mutant frequencies to comparable levels, reaching maxima 2-3 weeks after the single dose or 2-3 weeks after the last of the repeat doses. These increased frequencies subsequently returned to background levels. Our results indicated that the 3-color Pig-a assay was useful for evaluating the in vivo genotoxicity of radiation.

Further development of the rat Pig-a mutation assay: measuring rat Pig-a mutant bone marrow erythroids and a high throughput assay for mutant peripheral blood reticulocytes.

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.

Manifestation of Pig-a mutant bone marrow erythroids and peripheral blood erythrocytes in mice treated with N-ethyl-N-nitrosourea: direct sequencing of Pig-a cDNA from bone marrow cells negative for GPI-anchored protein expression.

Our previous rat studies indicate that the endogenous Pig-a gene is a promising reporter of in vivo mutation and potentially useful as the basis for an in vivo genotoxicity assay. The function of the Pig-a protein in the synthesis of glycosylphosphatidyl inositol (GPI) anchors is conserved in variety of eukaryotic cells, including human and rodent cells, which implies that Pig-a mutants can be measured in a similar manner in different mammalian species. In the present study, we developed a flow cytometric Pig-a assay for rapidly measuring gene mutation in the mouse. An antibody to TER-119, a specific cell-surface marker of murine erythroid lineage, was used to identify erythrocytes in peripheral blood (PB) and erythroids in bone marrow (BM). An antibody to CD24, a GPI-anchored protein, was used to identify Pig-a mutants as CD24-negative cells. CD-1 mice were administered a single dose of 100mg/kgN-ethyl-N-nitrosourea (ENU), and PB and BM were collected at 1, 2, and 4 weeks after dosing. While the Pig-a mutant frequency (MF) in PB was increased moderately at 2 and 4 weeks after ENU dosing, the Pig-a MF in BM was strongly increased starting at 1 week after the dosing, with the elevated MF persisting for at least 4 weeks after the dosing. We also used flow cytometric sorting to isolate CD24-negative erythroids from the BM of ENU-treated mice. cDNA sequencing indicated that these cells have mutations in the Pig-a gene, with base-pair substitutions typical of ENU-induced mutation spectra. The results indicate that the Pig-a mutation assay can be adapted for measuring mutation in BM erythroids and PB of mice. Taken together, the data suggest that Pig-a mutants are fixed in the BM, where they further proliferate and differentiate; erythrocytes derived from these BM Pig-a mutants transit from the BM and accumulate in PB.

Analysis of mutations in the Pig-a gene of spleen T-cells from N-ethyl-N-nitrosourea-treated fisher 344 rats.

A rapid in vivo somatic cell gene mutation assay is being developed that measures mutation in the endogenous X-linked phosphatidylinositol glycan, class A gene (Pig-a). The assay detects Pig-a mutants by flow cytometric identification of cells deficient in glycosylphosphatidyl inositol (GPI) anchor synthesis. GPI-deficient, presumed Pig-a mutant cells also can be detected in a cloning assay that uses proaerolysin (ProAER) selection. Previously, we demonstrated that ProAER-resistant (ProAER(r) ) rat spleen T-cells have mutations in the Pig-a gene. In the present study, we report on a more complete analysis of ProAER(r) rat spleen T-cell mutants and describe a mutation spectrum for mutants isolated from rats 4 weeks after treatment with three consecutive doses of 35.6 mg/kg N-ethyl-N-nitrosourea (ENU). We identified a total of 55 independent mutations, with the largest percentage (69%) involving basepair substitution at A:T. The overall spectrum of Pig-a gene mutations was consistent with the types of DNA adducts formed by ENU and was very similar to what has been described for in vivo ENU-induced mutation spectra in other rodent reporter genes (e.g., in the endogenous Hprt gene and transgenic shuttle vectors). These data are consistent with the rat Pig-a assay detecting test-agent-induced mutational responses.

The in vivo Pig-a gene mutation assay, a potential tool for regulatory safety assessment.

The Pig-a (phosphatidylinositol glycan, Class A) gene codes for a catalytic subunit of the N-acetylglucosamine transferase complex involved in an early step of glycosylphosphatidyl inositol (GPI) cell surface anchor synthesis. Pig-a is the only gene involved in GPI anchor synthesis that is on the X-chromosome, and research into the origins of an acquired genetic disease involving GPI anchor deficiency (paroxysmal nocturnal hemoglobinuria) indicates that cells lacking GPI anchors, or GPI-anchored cell surface proteins, almost always have mutations in the Pig-a gene. These properties of the Pig-a gene and the GPI anchor system have been exploited in a series of assays for measuring in vivo gene mutation in blood cells from humans, rats, mice, and monkeys. In rats, flow cytometric measurement of Pig-a mutation in red blood cells requires microliter volumes of blood and data can be generated in hours. Spontaneous mutant frequencies are relatively low (<5 × 10(-6)) and rats treated with multiple doses of the potent mutagen, N-ethyl-N-nitrosourea, display Pig-a mutant frequencies that are close to the sum of the frequencies produced by the individual exposures. A general observation is that induced mutant frequencies are manifested earlier in reticulocytes (about 2 weeks after treatment) than in total red blood cells (about 2 months after exposure). Based on data from a limited number of test agents, the assay shows promise for regulatory applications, including integration of gene mutation measurement into repeat-dose toxicology studies.

Flow cytometric detection of Pig-A mutant red blood cells using an erythroid-specific antibody: application of the method for evaluating the in vivo genotoxicity of methylphenidate in adolescent rats.

A modified flow cytometry assay for Pig-A mutant rat red blood cells (RBCs) was developed using an antibody that positively identifies rat RBCs (monoclonal antibody HIS49). The assay was used in conjunction with a flow cytometric micronucleus (MN) assay to evaluate gene mutation and clastogenicity/aneugenicity in adolescent male and female rats treated with methylphenidate hydrochloride (MPH). Sprague-Dawley rats were treated orally with 3 mg/kg MPH (70/sex) or water (40/sex) 3 x /day on postnatal days (PNDs) 29-50. Eight additional rats (4/sex) were injected i.p. with N-ethyl-N-nitrosourea (ENU) on PND 28. Blood was collected on PNDs 29, 50, and 90, and used for determining serum MPH levels and/or conducting genotoxicity assays. On the first and last days of MPH treatment (PNDs 29 and 50), serum MPH levels averaged 21 pg/microl, well within the clinical treatment range. Relative to our previously published method (Miura et al. [2008]; Environ Mol Mutagen 49: 614-629), the HIS49 Pig-A mutation assay significantly reduced the background RBC mutant frequency; in the experiments with ENU-treated rats, the modification increased the overall sensitivity of the assay 2-3 fold. Even with the increased assay sensitivity, the 21 consecutive days of MPH treatment produced no evidence of Pig-A mutation induction (measured at PND 90); in addition, MPH treatment did not increase MN frequency (measured at PND 50). These results support the consensus view that the genotoxicity of MPH in pediatric patients reported earlier (El-Zein et al. [2005]: Cancer Lett 230: 284-291) cannot be reproduced in animal models, suggesting that MPH at clinically relevant levels may be nongenotoxic in humans.

Accumulation and persistence of Pig-A mutant peripheral red blood cells following treatment of rats with single and split doses of N-ethyl-N-nitrosourea.

We previously reported the development of an in vivo gene mutation assay using the phosphatidylinositol glycan complementation group A gene (Pig-A) as an endogenous reporter. The assay quantifies mutation in rat peripheral red blood cells (RBCs) by flow cytometric detection of cells negative for glycosylphosphatidyl inositol (GPI)-anchored protein surface markers. In this study, we examined the accumulation and persistence of Pig-A mutant RBCs in rats treated with N-ethyl-N-nitrosourea (ENU) using two dosing schedules. Male F344 rats were given single i.p. injections of 8.9, 35.6, or 142.4 mg/kg ENU or four equal weekly doses totaling 35.6 or 142.4 mg/kg ENU (8.9 mg/kgx4 or 35.6 mg/kgx4; split-dose groups). Before the treatment and through 26 weeks after the single dose or beginning the split-dose regimen, peripheral RBCs were collected and Pig-A mutant frequencies measured as RBCs negative for the GPI-anchored protein, CD59. Mean CD59-negative RBC frequencies in negative control rats ranged from 3.9 x 10(-6) to 28.7 x 10(-6) and displayed no time-related trend. With single ENU doses, CD59-negative RBC frequencies increased in a time- and dose-related manner. Maximum responses were observed beginning at 6 weeks post-treatment (57.3 x 10(-6) in the 8.9 mg/kg group; 186.9 x 10(-6) in the 35.6 mg/kg group; 759.2 x 10(-6) in the 142.4 mg/kg group), and these elevated mutant frequencies persisted to the last sampling time. In addition, splitting the dose of ENU into four weekly doses produced nearly the same mutant frequency as when given as a single dose: the maximum responses after four weekly doses of 8.9 or 35.6 mg/kg were 176.8 x 10(-6) and 683.3 x 10(-6), respectively. These results indicate that ENU-induced Pig-A mutant RBCs accumulate in a near additive fashion in rats, and once present in the peripheral blood, persist for at least 6 months. These characteristics of Pig-A mutation could be important for detecting weak mutagens by repeated or subchronic/chronic dosing protocols.

Evaluation of Macaca mulatta as a model for genotoxicity studies.

We have investigated the use of peripheral blood from the nonhuman primate (NHP) rhesus monkey (Macaca mulatta) as a model system for mutation detection. The rhesus monkey is metabolically closer to humans than most common laboratory animals, and therefore may be a relevant model for hazard identification and human risk assessment. To validate the model, conditions were determined for in vitro selection and expansion of 6-thioguanine-resistant (6-TGr) HPRT mutant and proaerolysin-resistant (ProAERr) PIG-A mutant lymphocytes from peripheral blood obtained by routine venipuncture. Also, flow cytometric methods were developed for the rapid detection of PIG-A mutant erythrocytes. The flow cytometric analysis of PIG-A mutant erythrocytes was based on enumerating cells deficient in surface markers attached to the cellular membrane via glycosylphosphatidyl inositol (GPI) anchors. Mutant cells were enumerated over an extended period of time in peripheral blood of male monkeys receiving daily doses of the electrolyte replenisher Prangtrade mark (a common carrier for oral delivery of drugs in NHPs), and in the blood of one male monkey treated with a single i.p. dose of 50mg/kg of N-ethyl-N-nitrosourea at approximately 2 years of age and another similar injection at approximately 3.5 years of age. The spontaneous PIG-A and HPRT T-cell mutant frequency (MF) was low in animals receiving Prang (0-8x10(-6)), and treatment with ENU resulted in a clearly detectable increase in the frequency of ProAERr and 6-TGr lymphocytes (up to approximately 28x10(-6) and approximately 30x10(-6), respectively). Also, the ENU-treated animal had higher frequency of GPI-deficient erythrocytes (46.5x10(-6) in the treated animal vs. 7.8+/-4.2x10(-6) in control animals). Our results indicate that the rhesus monkey can be a valuable model for the identification of agents that may impact upon human health as mutagens and that the PIG-A gene can be a useful target for detection of mutation in both white and red blood cells.