Roberta A. Mittelstaedt

Effect of chronic caloric restriction on hepatic enzymes of intermediary metabolism in the male Fischer 344 rat

It is well established that caloric restriction extends life span and significantly retards the rate of occurrence of most age-associated degenerative disease processes. A paucity of data exists relative to the mechanisms by which caloric restriction accomplishes these events. We have examined the effect of caloric restriction in rats on several hepatic enzymes of intermediary metabolism. The activities of glycolytic and supporting enzymes including lactate dehydrogenase, pyruvate kinase, sorbitol dehydrogenase, and alcohol dehydrogenase were all decreased in response to caloric restriction. Fructose 1-phosphate aldolase and creatine phosphokinase were not altered. Likewise, enzymes associated with lipid metabolism (malic enzyme and glycerokinase) were reduced (fatty acid synthetase was reduced, but not to a statistically significant degree). Activities of enzymes supporting gluconeogenesis (glutamate oxaloacetate transaminase, tyrosine aminotransferase, glutamate pyruvate transaminase, glutamate dehydrogenase, amino acid oxidase, malate dehydrogenase, and glucose 6-phosphatase) were either unchanged or increased significantly by caloric restriction. Glucagon levels were decreased. Comparisons between young ad libitum fed and older calorically restricted rats revealed similar but not identical metabolic activity. These results suggest that caloric restriction produces an effect on intermediary metabolism, favoring the role of glucagon and glucose synthesis; but limiting the role of insulin and glucose catabolism in the liver. The former observation provides for the efficient support of peripheral tissues and the latter a level of energy production necessary only for self maintenance. Limited lipid metabolism suggests decreased potential for fatty acid epoxide formation and free radical damage to cellular macromolecules. Additionally, caloric restriction may delay the progressive age associated changes in the activities of some of the enzymes investigated.

Genotoxicity of silver nanoparticles evaluated using the Ames test and in vitro micronucleus assay

Silver nanoparticles (AgNPs) have antimicrobial properties, which have contributed to their widespread use in consumer products. A current issue regarding nanomaterials is the extent to which existing genotoxicity assays are useful for evaluating the risks associated with their use. In this study, the genotoxicity of 5 nm AgNPs was assessed using two standard genotoxicity assays, the Salmonella reverse mutation assay (Ames test) and the in vitro micronucleus assay. Using the preincubation version of the Ames assay, Salmonella strains TA102, TA100, TA1537, TA98, and TA1535 were treated with 0.15-76.8 μg/plate of the AgNPs. Toxicity limited the doses that could be assayed to 2.4-38.4 μg/plate; no increases in mutant frequency over the vehicle control were found for the concentrations that could be assayed. Human lymphoblastoid TK6 cells were treated with 10-30 μg/ml AgNPs, and additional cells were treated with water and 0.73 gy X-rays as vehicle and positive controls. Micronucleus frequency was increased by the AgNP treatment in a dose-dependent manner. At a concentration of 30 μg/ml (with 45.4% relative population doubling), AgNPs induced a significant, 3.17-fold increase with a net increase of 1.60% in micronucleus frequency over the vehicle control, a weak positive response by our criteria. These results demonstrate that the 5 nm AgNP are genotoxic in TK6 cells. Also, the data suggest that the in vitro micronucleus assay may be more appropriate than the Ames test for evaluating the genotoxicity of the AgNPs.

Development of an in vivo gene mutation assay using the endogenous Pig-A gene: II. Selection of Pig-A mutant rat spleen T-cells with proaerolysin and sequencing Pig-A cDNA from the mutants†‡

We previously reported that rat spleen T‐cells and peripheral red blood cells that are deficient in glycosylphosphatidylinositol (GPI) synthesis [presumed mutants for the phosphatidylinositol glycan complementation group A gene (Pig‐A)] could be detected by flow cytometry (FCM) as cells negative for GPI‐linked markers (CD48 and CD59, respectively). To establish this procedure as a rapid in vivo gene mutation assay, we have examined the Pig‐A gene of GPI‐deficient rat spleen T‐cells for DNA sequence alterations. Splenocytes were isolated from male F344 rats, primed with ionomycin and phorbol‐12‐myristate‐13‐acetate, and seeded at limiting‐dilution into 96‐well plates. To select for GPI‐deficient T‐cells, the cells were cultured for 10 days in a medium containing rat T‐STIM® and 2 nM proaerolysin (ProAER). The frequency of ProAER‐resistant (ProAERr) spleen T‐cells from control rats ranged from 1.3 × 10−6 to 4.8 × 10−6, while administration of three doses of 40 mg/kg N‐ethyl‐N‐nitrosourea increased the frequency of ProAERr T‐cells 100‐fold at 4 weeks after dosing. FCM analysis of the cells in ProAERr clones revealed that they were CD48‐negative, and thus presumably GPI‐deficient. Sequencing of Pig‐A cDNA from six ProAERr clones indicated that they all contained alterations in the Pig‐A protein coding sequence; five had base pair substitutions and one had multiple exons deleted. These results indicate that GPI‐deficient spleen T‐cells are Pig‐A gene mutants and support the use of FCM analysis of GPI‐deficient cells as a rapid assay for measuring in vivo gene mutation. Environ. Mol. Mutagen., 2008. Published 2008 Wiley‐Liss, Inc.

The genotoxicity of acrylamide and glycidamide in big blue rats.

Acrylamide (AA), a mutagen and rodent carcinogen, recently has been detected in fried and baked starchy foods, a finding that has prompted renewed interest in its potential for toxicity in humans. In the present study, we exposed Big Blue rats to the equivalent of approximately 5 and 10 mg/kg body weight/day of AA or its epoxide metabolite glycidamide (GA) via the drinking water, an AA treatment regimen comparable to those used to produce cancer in rats. After 2 months of dosing, the rats were euthanized and blood was taken for the micronucleus assay; spleens for the lymphocyte Hprt mutant assay; and liver, thyroid, bone marrow, testis (from males), and mammary gland (females) for the cII mutant assay. Neither AA nor GA increased the frequency of micronucleated reticulocytes. In contrast, both compounds produced small (approximately twofold to threefold above background) but significant increases in lymphocyte Hprt mutant frequency (MF, p < 0.05), with the increases having dose-related linear trends (p < 0.05 to p < 0.001). Neither compound increased the cII MF in testis, mammary gland (tumor target tissues), or liver (nontarget tissue), while both compounds induced weak positive increases in bone marrow (nontarget tissue) and thyroid (target tissue). Although the genotoxicity in tumor target tissue was weak, in combination with the responses in surrogate tissues, the results are consistent with AA being a gene mutagen in the rat via metabolism to GA.

Genotoxicity of furan in Big Blue rats.

Furan is a multispecies liver carcinogen whose cancer mode of action (MOA) is unclear. A major metabolite of furan is a direct acting mutagen; however, it is not known if genotoxicity is a key step in the tumors that result from exposure to furan. In order to address this question, transgenic Big Blue rats were treated by gavage five times a week for 8 weeks with two concentrations of furan used in cancer bioassays (2 and 8mg/kg), and with two higher concentrations (16 and 30mg/kg). Peripheral blood samples taken 24h after the 5th dose (1 week of dosing) were used to assay for micronucleus (MN) frequency in normochromatic erythrocytes (NCEs) and reticulocytes (RETs), and Pig-a gene mutation in total red blood cells (RBCs). 24h after the last dose of the 8-week treatment schedule, the rats were euthanized, and their tissues were used to perform NCE and RET MN assays, the Pig-a RBC assay, Pig-a and Hprt lymphocyte gene mutation assays, the liver cII transgene mutation assay, and the liver Comet assay. The responses in the MN assays conducted at both sampling times, and all the gene mutation assays, were uniformly negative; however, the Comet assay was positive for the induction of liver DNA damage. As the positive responses in the Comet assay were seen only with doses in excess of the cancer bioassay doses, and at least one of these doses (30mg/kg) produced toxicity in the liver, the overall findings from the study are consistent with furan having a predominantly nongenotoxic MOA for cancer.

Comparative analysis of micronuclei and DNA damage induced by Ochratoxin A in two mammalian cell lines

The fungal toxin, Ochratoxin A (OTA), is a common contaminant in human food and animal feed. The present study evaluated micronucleus (MN) induction by OTA in comparison with its ability to induce cytotoxicity and DNA damage in two mammalian cell lines, CHO-K1-BH(4) Chinese hamster ovary cells and TK6 human lymphoblastoid cells. Micronuclei were evaluated by flow cytometry, cytotoxicity was estimated by relative population doubling (RPD), while direct DNA damage and oxidative DNA damage were measured with the Comet assay, performed without and with digestion by formamidopyrimidine-DNA glycosylase (fpg). For the MN and cytotoxicity measurements, the cell lines were treated for 24h (CHO cells) or 27h (TK6 cells) with 5-25μM OTA in the absence of exogenous metabolic activation. The OTA treatments resulted in concentration-responsive increases in cytotoxicity, with higher concentrations of the agent being more cytotoxic in CHO cells than TK6 cells. 15μM OTA produced positive responses for MN induction and hypodiploid events (a measure of aneugenicity) in both cell lines; this concentration of OTA also produced cytotoxicity near to the recommended limit for the assay (45±5% RPD). A time course assay with TK6 cells indicated that at least 4h of OTA treatment were required to produce a positive MN response. For the Comet assay DNA damage assessments, the cell lines were treated with 5-50μM OTA for 4h. Direct DNA damage was detected in TK6 cells, but not CHO cells, while concentration-related increases in fpg-sensitive sites were detected for both cell lines. The consistent association of oxidative DNA damage with OTA exposure suggests its involvement in producing OTA-induced clastogenicity and aneugenicity; however, based on its detection in TK6 cells direct DNA damage could be involved in any human risk posed by OTA exposure.

Comparison of the types of mutations induced by 7,12-dimethylbenz[a]anthracene in the lacI and hprt genes of Big Blue rats.

An important question regarding the use of transgenic reporter genes to detect mutation in rodents is how the types of mutations recovered in transgenes compare with the types of mutations found in the endogenous genes. In this study, we examined mutations induced by 7,12‐dimethylbenz‐[a]anthracene in the lacI transgene and the endogenous hprt gene of lymphocytes from Big Blue® rats and in the hprt gene of lymphocytes from non‐transgenic Fischer 344 rats. The overall mutation profiles found in these genes were remarkably similar: the majority of mutations were base pair substitutions, with the most common mutation being A:T → T:A transversion. Differences were found for the mutational profiles endogenous gene and transgene with respect to the location of the mutations and the orientation of basepair substitutions in the DNA strands. In most cases, these differences could be explained by the nature of the target genes. The results support the use of the lacI transgene for detecting in vivo mutation. Environ. Mol. Mutagen. 31:149–156, 1998 Published 1998 Wiley‐Liss, Inc. This article is a US Government work and, as such, is in the public domain in the United States of America.

In vivo genotoxicity of furan in F344 rats at cancer bioassay doses

Furan, a potent rodent liver carcinogen, is found in many cooked food items and thus represents a human cancer risk. Mechanisms for furan carcinogenicity were investigated in male F344 rats using the in vivo Comet and micronucleus assays, combined with analysis of histopathological and gene expression changes. In addition, formamidopyrimidine DNA glycosylase (Fpg) and endonuclease III (EndoIII)-sensitive DNA damage was monitored as a measure of oxidative DNA damage. Rats were treated by gavage on four consecutive days with 2, 4, and 8mg/kg bw furan, doses that were tumorigenic in 2-year cancer bioassays, and with two higher doses, 12 and 16mg/kg. Rats were killed 3h after the last dose, a time established as producing maximum levels of DNA damage in livers of furan-treated rats. Liver Comet assays indicated that both DNA strand breaks and oxidized purines and pyrimidines increased in a near-linear dose-responsive fashion, with statistically significant increases detected at cancer bioassay doses. No DNA damage was detected in bone marrow, a non-target tissue for cancer, and peripheral blood micronucleus assays were negative. Histopathological evaluation of liver from furan-exposed animals produced evidence of inflammation, single-cell necrosis, apoptosis, and cell proliferation. In addition, genes related to apoptosis, cell-cycle checkpoints, and DNA-repair were expressed at a slightly lower level in the furan-treated livers. Although a mixed mode of action involving direct DNA binding cannot be ruled out, the data suggest that furan induces cancer in rat livers mainly through a secondary genotoxic mechanism involving oxidative stress, accompanied by inflammation, cell proliferation, and toxicity.

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.

Comparison of mutant frequencies and types of mutations induced by thiotepa in the endogenous Hprt gene and transgenic lacI gene of Big Blue® rats

The utility of the lacI transgene of Big Blue rats as a reporter of in vivo mutation was evaluated by comparing the frequency and types of mutations induced by thiotepa in the transgene and the endogenous Hprt gene. Transgenic rats were given i.p. injections of 1.4 mg/kg of thiotepa three times per week over a period of 4 weeks (a total dose of 16.8 mg/kg); 1 week after the last injection, mutation assays were performed on spleen lymphocytes isolated from the animals. Thiotepa treatment increased the lacI mutant frequency from 34.8 +/- 4.1 x 10(-6) in control animals to 140.9 +/- 64.8 x 10(-6) (p = 0.0020) and the Hprt mutant frequency from 3.5 +/- 1.5 x 10(-6) to 41.1 +/- 23.2 x 10(-6) (p = 0.0028). Sequence analysis of lacI mutant DNA and Hprt mutant cDNA produced similar overall mutation patterns: G:C-->T:A transversion was the most common base pair substitution (32% of independent mutations in the lacI gene and 28% of Hprt mutations), and deletions and insertions accounted for 34% of mutations in the lacI gene and 28% in the Hprt gene. The majority of thiotepa-induced base pair substitutions in the Hprt gene occurred with the mutated purine on the non-transcribed DNA strand, while no strand-related bias was found for mutations in the lacI gene. Substitutions at G:C base pairs in the lacI gene, but not in the Hprt gene, were found disproportionately in CpG sites. In addition, multiplex polymerase chain reaction analysis of genomic DNA from the Hprt mutants indicated that 34% had relatively large deletions; none of these deletions was detected by the cDNA analysis. The results indicate that the frequency of thiotepa-induced mutants in Big Blue rats was 2.8-fold greater in the lacI gene than in the Hprt gene. Although the Hprt gene recovered a fraction of large deletions not found among the lacI mutants, the effects of transcription-coupled DNA repair in the Hprt gene and the targeting of base pair substitutions to G:C base pairs in CpG sites may have contributed to the higher mutant frequencies induced by thiotepa in the lacI transgene compared with the Hprt gene.