Kellie L.K. Tamashiro

Cloned mice have an obese phenotype not transmitted to their offspring.

Mammalian cloning using somatic cells has been accomplished successfully in several species, and its potential basic, clinical and therapeutic applications are being pursued on many fronts. Determining the long-term effects of cloning on offspring is crucial for consideration of future application of the technique. Although full-term development of animals cloned from adult somatic cells has been reported, problems in the resulting progeny indicate that the cloning procedure may not produce animals that are phenotypically identical to their cell donor. We used a mouse model to take advantage of its short generation time and lifespan. Here we report that the increased body weight of cloned B6C3F1 female mice reflects an increase of body fat in addition to a larger body size, and that these mice share many characteristics consistent with obesity. We also show that the obese phenotype is not transmitted to offspring generated by mating male and female cloned mice.

Cloning of mice to six generations

Mice have been cloned by nuclear transfer into enucleated oocytes, and here we describe the reiterative cloning of mice to four and six generations in two independent lines. Successive generations showed no signs of prematureageing, as judged by gross behaviouralparameters, and there was no evidence of shortening of telomeres at the ends of chromosomes, normally an indicator of cellular senescence — in fact, these appeared to increase slightly in length. This increase is surprising, given that the number of mitotic divisions greatly exceeds that of sexually produced animals and that any deleterious effects of cloning might be expected to be amplified in sequentially cloned mice. Our results offer a new approach to the study of organismal ageing.

Prenatal Stress or High-Fat Diet Increases Susceptibility to Diet-Induced Obesity in Rat Offspring

OBJECTIVE Perturbations to the prenatal environment have been associated with the development of adult chronic disease, findings that gave rise to the “Barker Hypothesis” or the “developmental origins of adult disease” concept. In this study, we used an animal model to determine the metabolic consequences of maternal prenatal stress and high-fat feeding on the developing offspring. RESEARCH DESIGN AND METHODS Pregnant female Sprague-Dawley rats were maintained on standard chow or 60% high-fat diet throughout gestation and lactation. Half of each group were exposed to a novel variable stress paradigm during the 3rd week of gestation, whereas control dams were left undisturbed. Body weight, body composition, glucose tolerance, and endocrine parameters were measured in offspring through early adulthood. RESULTS Male and female pups from dams that experienced prenatal stress and/or were on a high-fat diet weighed more beginning on postnatal day 7 compared with standard chow–control pups. Access to high-fat diet at weaning increased the body weight effect through early adulthood and was attributable to greater adiposity. Pups weaned onto standard chow diet showed no significant difference in glucose clearance or insulin secretion. However, pups weaned onto high-fat diet had impaired glucose tolerance if their dams were on a high-fat diet, experienced prenatal stress, or both. CONCLUSIONS Our data demonstrate that prenatal stress and/or high-fat diet during the intrauterine or postnatal environment affects offspring in a manner that increases their susceptibility to diet-induced obesity and leads to secondary adverse metabolic consequences.

Neuroprotective role of Sirt1 in mammalian models of Huntington's disease through activation of multiple Sirt1 targets

Huntingtons disease is a fatal neurodegenerative disorder caused by an expanded polyglutamine repeat in huntingtin (HTT) protein. We previously showed that calorie restriction ameliorated Huntingtons disease pathogenesis and slowed disease progression in mice that model Huntingtons disease (Huntingtons disease mice). We now report that overexpression of sirtuin 1 (Sirt1), a mediator of the beneficial metabolic effects of calorie restriction, protects neurons against mutant HTT toxicity, whereas reduction of Sirt1 exacerbates mutant HTT toxicity. Overexpression of Sirt1 improves motor function, reduces brain atrophy and attenuates mutant-HTT–mediated metabolic abnormalities in Huntingtons disease mice. Further mechanistic studies suggested that Sirt1 prevents the mutant-HTT–induced decline in brain-derived neurotrophic factor (BDNF) concentrations and the signaling of its receptor, TrkB, and restores dopamine- and cAMP-regulated phosphoprotein, 32 kDa (DARPP32) concentrations in the striatum. Sirt1 deacetylase activity is required for Sirt1-mediated neuroprotection in Huntingtons disease cell models. Notably, we show that mutant HTT interacts with Sirt1 and inhibits Sirt1 deacetylase activity, which results in hyperacetylation of Sirt1 substrates such as forkhead box O3A (Foxo3a), thereby inhibiting its pro-survival function. Overexpression of Sirt1 counteracts the mutant-HTT–induced deacetylase deficit, enhances the deacetylation of Foxo3a and facilitates cell survival. These findings show a neuroprotective role for Sirt1 in mammalian Huntingtons disease models and open new avenues for the development of neuroprotective strategies in Huntingtons disease.

Social stress: From rodents to primates

Social stress is associated with development of many psychological and physiological disturbances in humans. Animal models are needed to determine the etiology of these diseases and to develop rational clinical therapies to treat those afflicted. Rodent and non-human primate models of social stress have been developed to address these needs and contribute in complementary ways to the understanding of social stress. In this review, we provide an overview of common rodent and non-human primate models of social stress used in the laboratory with a focus on social hierarchy models. The implications of the current findings on understanding of the development of stress-related disease will also be discussed.

Leptin activates hypothalamic acetyl-CoA carboxylase to inhibit food intake

Hypothalamic fatty acid metabolism has recently been implicated in the controls of food intake and energy homeostasis. We report that intracerebroventricular (ICV) injection of leptin, concomitant with inhibiting AMP-activated kinase (AMPK), activates acetyl-CoA carboxylase (ACC), the key regulatory enzyme in fatty acid biosynthesis, in the arcuate nucleus (Arc) and paraventricular nucleus (PVN) in the hypothalamus. Arc overexpression of constitutively active AMPK prevents the Arc ACC activation in response to ICV leptin, supporting the hypothesis that AMPK lies upstream of ACC in leptins Arc intracellular signaling pathway. Inhibiting hypothalamic ACC with 5-tetradecyloxy-2-furoic acid, a specific ACC inhibitor, blocks leptin-mediated decreases in food intake, body weight, and mRNA level of the orexigenic neuropeptide NPY. These results show that hypothalamic ACC activation makes an important contribution to leptins anorectic effects. Furthermore, we find that ICV leptin up-regulates the level of malonyl-CoA (the intermediate of fatty acid biosynthesis) specifically in the Arc and increases the level of palmitoyl-CoA (a major product of fatty acid biosynthesis) specifically in the PVN. The rises of both levels are blocked by 5-tetradecyloxy-2-furoic acid along with the blockade of leptin-mediated hypophagia. These data suggest malonyl-CoA as a downstream mediator of ACC in leptins signaling pathway in the Arc and imply that palmitoyl-CoA, instead of malonyl-CoA, could be an effector in relaying ACC signaling in the PVN. Together, these findings highlight site-specific impacts of hypothalamic ACC activation in leptins anorectic signaling cascade.

Nrf2 mediates cancer protection but not prolongevity induced by caloric restriction

Caloric restriction (CR) is the most potent intervention known to both protect against carcinogenesis and extend lifespan in laboratory animals. A variety of anticarcinogens and CR mimetics induce and activate the NF-E2-related factor 2 (Nrf2) pathway. Nrf2, in turn, induces a number of antioxidative and carcinogen-detoxifying enzymes. Thus, Nrf2 offers a promising target for anticarcinogenesis and antiaging interventions. We used Nrf2-disrupted (KO) mice to examine its role on the biological effects of CR. Here, we show that Nrf2 is responsible for most of the anticarcinogenic effects of CR, but is dispensable for increased insulin sensitivity and lifespan extension. Nrf2-deficient mice developed tumors more readily in response to carcinogen exposure than did WT mice, and CR was ineffective in suppressing tumors in the KO mice. However, CR extended lifespan and increased insulin sensitivity similarly in KO and WT mice. These findings identify a molecular pathway that dissociates the prolongevity and anticarcinogenic effects of CR.

Chronic Corticosterone Exposure Increases Expression and Decreases Deoxyribonucleic Acid Methylation of Fkbp5 in Mice

There is evidence for hypercortisolemia playing a role in the generation of psychiatric symptoms and for epigenetic variation within hypothalamic-pituitary-adrenal (HPA) axis genes mediating behavioral changes. We tested the hypothesis that expression changes would be induced in Fkbp5 and other HPA axis genes by chronic exposure to corticosterone and that these changes would occur through the epigenetic mechanism of loss or gain of DNA methylation (DNAm). We administered corticosterone (CORT) to C57BL/6J mice via their drinking water for 4 wk and tested for behavioral and physiological changes and changes in gene expression levels using RNA extracted from hippocampus, hypothalamus, and blood for the following HPA genes: Fkbp5, Nr3c1, Hsp90, Crh, and Crhr1. The CORT mice exhibited anxiety-like behavior in the elevated plus maze test. Chronic exposure to CORT also caused a significant decrease in the hippocampal and blood mRNA levels of Nr3c1 and a decrease in Hsp90 in blood and caused an increase in Fkbp5 for all tissues. Differences were seen in Fkbp5 methylation in hippocampus and hypothalamus. To isolate a single-cell type, we followed up with an HT-22 mouse hippocampal neuronal cell line exposed to CORT. After 7 d, we observed a 2.4-fold increase in Fkbp5 expression and a decrease in DNAm. In the CORT-treated mice, we also observed changes in blood DNAm in Fkbp5. Our results suggest DNAm plays a role in mediating effects of glucocorticoid exposure on Fkbp5 function, with potential consequences for behavior.

Postnatal Growth and Behavioral Development of Mice Cloned from Adult Cumulus Cells

Abstract Since the first successful cloning of mammals from adult somatic cells, there has been no examination of the learning or behavior of cloned offspring. The possibility of adverse effects on animals produced through adult somatic cell cloning is high because many natural biological processes are bypassed and DNA from adult cells, which presumably contain mutations, are used. In this study, we compared cloned mice produced by microinjection transfer of cumulus cell nuclei into enucleated oocytes, to control mice that were specifically generated to eliminate confounding factors that are unique to our cloning procedure. Postnatal weight gain of clones was significantly greater than that of controls. Preweaning development observations revealed that first appearance or performance of 3 out of 10 measures was delayed in cloned mice; however, results of subsequent tests of learning and memory, activity level, and motor skills were comparable for both groups. Together, these data suggest that nuclear transfer of adult somatic cell nuclei to produce cloned mice may delay the appearance of a few developmental milestones but it does not adversely affect the overall postnatal behavior of mice. In addition, this procedure may cause late onset of significantly increased body weight in cloned offspring, the cause or causes of which are being further examined.

REPEATED EXPOSURE TO SOCIAL STRESS HAS LONG-TERM EFFECTS ON INDIRECT MARKERS OF DOPAMINERGIC ACTIVITY IN BRAIN REGIONS ASSOCIATED WITH MOTIVATED BEHAVIOR

The visible burrow system (VBS) is a chronic social stress paradigm in which a dominance hierarchy forms among male rats housed with females. Males in the VBS undergo behavioral and physiological changes thought to be manifestations of chronic social stress. Since it is unclear whether chronic social stress affects motivation and reward behavior, brain areas related to these regions were examined. Long-term effects of a single or repeated VBS exposure on mesolimbic subregions were investigated by exposing rats to the VBS either once (one cycle of VBS housing and recovery) or repeatedly (three cycles). Behavior in the VBS was observed and rats were classified as dominants or subordinates. Subordinates were further sub-classified on the basis of stress hormone (corticosterone) response to an acute stressor (i.e. restraint stress). Normal responders were categorized as stress-responsive subordinates (SRS) and animals with a blunted hypothalamic-pituitary-adrenal axis response were designated as non-responsive subordinates (NRS). Controls males were pair-housed with a single female during VBS periods and alone during recovery. Lowered enkephalin-mRNA levels were observed in the nucleus accumbens (Acb) after single VBS exposure in SRS and repeated VBS exposure both subordinate groups (i.e. SRS + NRS) compared with controls. Decreased dopamine transporter density was detected after single VBS exposure in the dorsolateral caudate putamen (DLCPu) of NRS and after repeated VBS exposure in the Acb of NRS compared with controls. Dopamine D2 receptor density was elevated after single VBS exposure in the Acb of both subordinate groups (SRS + NRS) and after repeated VBS exposure in the DLCPu, dorsomedial CPu, and Acb of NRS compared with controls. No changes in dopamine D1 receptor binding were observed in any group. These results suggest that long-term changes in dopamine activity in mesolimbic structures persist after repeated exposures to chronic social stress and may provide insight into the neurochemical basis of depressive illness and subsequent comorbidity with drug abuse vulnerability.