Your search keyword '"Salmon, Adam B."' showing total 20 results

1. Mouse models used to test the role of reactive oxygen species in aging and age-related chronic diseases.

Author

Nguyen, Hoang Van M., Ran, Qitao, Salmon, Adam B., Bumsoo, Ahn, Chiao, Ying Ann, Bhaskaran, Shylesh, and Richardson, Arlan

Subjects

*ALZHEIMER'S disease, *TRANSGENIC mice, *KNOCKOUT mice, *LABORATORY mice, *REACTIVE oxygen species

Abstract

With the development of the technology to generate transgenic and knockout mice in the 1990s, investigators had a powerful tool to directly test the impact of altering a specific gene on a biological process or disease. Over the past three decades, investigators have used transgenic and knockout mouse models, which have altered expression of antioxidant genes, to test the role of oxidative stress/damage in aging and age-related diseases. In this comprehensive review, we describe the studies using transgenic and knockout mouse models to test the role of oxidative stress/damage in aging (longevity) and three age-related diseases, e.g., sarcopenia, cardiac aging, and Alzheimer's Disease. While longevity was consistently altered only by one transgenic and one knockout mouse model as predicted by the Oxidative Stress Theory of Aging, the incidence/progression of the three age-related diseases (especially Alzheimer's disease) were robustly impacted when the expression of various antioxidant genes was altered using transgenic and knockout mouse models. [Display omitted] • Overexpressing or knocking out most antioxidant genes had little effect on lifespan. • Lifespan was altered by deleting Sod1 or overexpressing catalase in mitochondria. • Overexpressing or knocking out antioxidant genes impacted Alzheimer's disease. • Overexpressing or knocking out antioxidant genes protected heart from stress. • Knocking out antioxidant genes accelerated sarcopenia. [ABSTRACT FROM AUTHOR]

Published

2024

2. MsrA Overexpression Targeted to the Mitochondria, but Not Cytosol, Preserves Insulin Sensitivity in Diet-Induced Obese Mice.

Author

Hunnicut, JennaLynn, Liu, Yuhong, Richardson, Arlan, and Salmon, Adam B.

Subjects

CYTOSOL, MITOCHONDRIAL DNA, GENE expression, GENE targeting, OBESITY, INSULIN resistance, LABORATORY mice

Abstract

There is growing evidence that oxidative stress plays an integral role in the processes by which obesity causes type 2 diabetes. We previously identified that mice lacking the protein oxidation repair enzyme methionine sulfoxide reductase A (MsrA) are particularly prone to obesity-induced insulin resistance suggesting an unrecognized role for this protein in metabolic regulation. The goals of this study were to test whether increasing the expression of MsrA in mice can protect against obesity-induced metabolic dysfunction and to elucidate the potential underlying mechanisms. Mice with increased levels of MsrA in the mitochondria (TgMito MsrA) or in the cytosol (TgCyto MsrA) were fed a high fat/high sugar diet and parameters of glucose homeostasis were monitored. Mitochondrial content, markers of mitochondrial proteostasis and mitochondrial energy utilization were assessed. TgMito MsrA, but not TgCyto MsrA, mice remain insulin sensitive after high fat feeding, though these mice are not protected from obesity. This metabolically healthy obese phenotype of TgMito MsrA mice is not associated with changes in mitochondrial number or biogenesis or with a reduction of proteostatic stress in the mitochondria. However, our data suggest that increased mitochondrial MsrA can alter metabolic homeostasis under diet-induced obesity by activating AMPK signaling, thereby defining a potential mechanism by which this genetic alteration can prevent insulin resistance without affecting obesity. Our data suggest that identification of targets that maintain and regulate the integrity of the mitochondrial proteome, particular against oxidative damage, may play essential roles in the protection against metabolic disease. [ABSTRACT FROM AUTHOR]

Published

2015

3. Altered metabolism and resistance to obesity in long-lived mice producing reduced levels of IGF-I.

Author

Salmon, Adam B., Lerner, Chad, Yuji Ikeno, Perrine, Susan M. Motch, McCarter, Roger, and Sell, Christian

Subjects

*SOMATOMEDIN C, *GLUCOSE metabolism, *OBESITY, *INSULIN resistance, *HIGH-fat diet, *GLUCONEOGENESIS, *LONGEVITY, *LABORATORY mice

Abstract

The extension of lifespan due to reduced insulin-like growth factor 1 (IGF-I) signaling in mice has been proposed to be mediated through alterations in metabolism. Previously, we showed that mice homozygous for an insertion in the Igf1 allele have reduced levels of IGF-I, are smaller, and have an extension of maximum lifespan. Here, we tested whether this specific reduction of IGF-I alters glucose metabolism both on normal rodent chow and in response to high-fat feeding. We found that female IGF-I-deficient mice were lean on a standard rodent diet but paradoxically displayed an insulin-resistant phenotype. However, these mice gained significantly less weight than normal controls when placed on a high-fat diet. In control animals, insulin response was significantly impaired by high-fat feeding, whereas IGF-I-deficient mice showed a much smaller shift in insulin response after high-fat feeding. Gluconeogenesis was also elevated in the IGF-I-deficient mice relative to controls on both normal and high-fat diet. An analysis of metabolism and respiratory quotient over 24 h indicated that the IGF-I-deficient mice preferentially utilized fatty acids as an energy source when placed on a high-fat diet. These results indicate that reduction in the circulating and tissue IGF-I levels can produce a metabolic phenotype in female mice that increases peripheral insulin resistance but renders animals resistant to the deleterious effects of high-fat feeding. [ABSTRACT FROM AUTHOR]

Published

2015

4. Rapamycin and Dietary Restriction Induce Metabolically Distinctive Changes in Mouse Liver.

Author

Zhen Yu, Rong Wang, Fok, Wilson C., Coles, Alexander, Salmon, Adam B., and Pérez, Viviana I.

Subjects

RAPAMYCIN, METABOLITES, SIRTUINS, GROWTH factors, FATTY acids, LABORATORY mice

Abstract

Dietary restriction (DR) is the gold standard intervention used to delay aging, and much recent research has focused on the identification of possible DR mimetics. Energy sensing pathways, including insulin/IGF1 signaling, sirtuins, and mammalian Target of Rapamycin (mTOR), have been proposed as pathways involved in the antiaging actions of DR, and compounds that affect these pathways have been suggested to act as DR mimetics, including metformin (insulin/IGF1 signaling), resveratrol (sirtuins), and rapamycin (mTOR). Rapamycin is a promising DR mimetic because it significantly increases both health span and life span in mice. Unfortunately, rapamycin also leads to some negative effects, foremost among which is the induction of insulin resistance, potentially limiting its translation into humans. To begin clarifying the mechanism(s) involved in insulin resistance induced by rapamycin, we compared several aspects of liver metabolism in mice treated with DR or rapamycin for 6 months. Our data suggest that although both DR and rapamycin inhibit lipo-genesis, activate lipolysis, and increased serum levels of nonesterified fatty acids, only DR further activates β-oxidation of the fatty acids leading to the production of ketone bodies. [ABSTRACT FROM AUTHOR]

Published

2015

5. Revisiting an age-old question regarding oxidative stress.

Author

Edrey, Yael H. and Salmon, Adam B.

Subjects

*OXIDATIVE stress, *AGING prevention, *ANTIOXIDANTS, *ENVIRONMENTAL impact analysis, *BIOACCUMULATION, *LABORATORY mice

Abstract

Abstract: Significant advances in maintaining health throughout life can be made through a clear understanding of the fundamental mechanisms that regulate aging. The Oxidative Stress Theory of Aging (OSTA) is probably the most well studied mechanistic theory of aging and suggests that the rate of aging is controlled by accumulation of oxidative damage. To directly test the OSTA, aging has been measured in several lines of mice with genetic alterations in the expression of enzymatic antioxidants. Under its strictest interpretation, these studies do not support the OSTA, as modulation of antioxidant expression does not generally affect mouse life span. However, the incidence of many age-related diseases and pathologies is altered in these models, suggesting that oxidative stress does significantly influence some aspects of the aging process. Further, oxidative stress may affect aging in disparate patterns among tissues or under various environmental conditions. In this review, we summarize the current literature regarding aging in antioxidant mutant mice and offer several interpretations of their support of the OSTA. [Copyright &y& Elsevier]

Published

2014

6. Rapamycin-mediated lifespan increase in mice is dose and sex dependent and metabolically distinct from dietary restriction.

Author

Miller, Richard A., Harrison, David E., Astle, Clinton M., Fernandez, Elizabeth, Flurkey, Kevin, Han, Melissa, Javors, Martin A., Li, Xinna, Nadon, Nancy L., Nelson, James F., Pletcher, Scott, Salmon, Adam B., Sharp, Zelton Dave, Van Roekel, Sabrina, Winkleman, Lynn, and Strong, Randy

Subjects

RAPAMYCIN, LIFE spans, LABORATORY mice, DIETARY supplements, DRUG dosage, MTOR protein, ENZYME inhibitors

Abstract

Rapamycin, an inhibitor of m TOR kinase, increased median lifespan of genetically heterogeneous mice by 23% (males) to 26% (females) when tested at a dose threefold higher than that used in our previous studies; maximal longevity was also increased in both sexes. Rapamycin increased lifespan more in females than in males at each dose evaluated, perhaps reflecting sexual dimorphism in blood levels of this drug. Some of the endocrine and metabolic changes seen in diet-restricted mice are not seen in mice exposed to rapamycin, and the pattern of expression of hepatic genes involved in xenobiotic metabolism is also quite distinct in rapamycin-treated and diet-restricted mice, suggesting that these two interventions for extending mouse lifespan differ in many respects. [ABSTRACT FROM AUTHOR]

Published

2014

7. Mice Producing Reduced Levels of Insulin-Like Growth Factor Type 1 Display an Increase in Maximum, but not Mean, Life Span.

Author

Lorenzini, Antonello, Salmon, Adam B., Lerner, Chad, Torres, Claudio, Ikeno, Yuji, Motch, Susan, McCarter, Roger, and Sell, Christian

Subjects

*SOMATOMEDIN C, *INSULIN, *METABOLISM, *OBESITY, *GLUCONEOGENESIS, *LABORATORY mice, *LIFE spans, *NEUROENDOCRINOLOGY

Abstract

Reduced signaling through the IGF type 1 (IGF-1) receptor increases life span in multiple invertebrate organisms. Studies on mammalian longevity suggest that reducing levels of IGF-1 may also increase life span. However, the data are conflicting and complicated by the physiology of the mammalian neuroendocrine system. We have performed life-span analysis on mice homozygous for an insertion in the Igf1 gene. These mice produce reduced levels of IGF-1 and display a phenotype consistent with a significant decrease in IGF-1. Life-span analysis was carried out at three independent locations. Although the life-span data varied between sites, the maximum life span of the IGF-1-deficient mice was significantly increased and age-specific mortality rates were reduced in the IGF-1-deficient mice; however, mean life span did not differ except at one site, where mean life span was increased in female IGF-1-deficient animals. Early life mortality was noted in one cohort of IGF-1-deficient mice. The results are consistent with a significant role for IGF-1 in the modulation of life span but contrast with the published life-span data for the hypopituitary Ames and Snell dwarf mice and growth hormone receptor null mice, indicating that a reduction in IGF-1 alone is insufficient to increase both mean and maximal life span in mice. [ABSTRACT FROM PUBLISHER]

Published

2014

8. Mice Fed Rapamycin Have an Increase in Lifespan Associated with Major Changes in the Liver Transcriptome.

Author

Fok, Wilson C., Chen, Yidong, Bokov, Alex, Zhang, Yiqiang, Salmon, Adam B., Diaz, Vivian, Javors, Martin, Wood 3rd, William H., Zhang, Yongqing, Becker, Kevin G., Pérez, Viviana I., and Richardson, Arlan

Subjects

RAPAMYCIN, LIFE spans, MORTALITY, LABORATORY mice, LONGEVITY, ANIMAL nutrition, GENETIC transcription

Abstract

Rapamycin was found to increase (11% to 16%) the lifespan of male and female C57BL/6J mice most likely by reducing the increase in the hazard for mortality (i.e., the rate of aging) term in the Gompertz mortality analysis. To identify the pathways that could be responsible for rapamycin's longevity effect, we analyzed the transcriptome of liver from 25-month-old male and female mice fed rapamycin starting at 4 months of age. Few changes (<300 transcripts) were observed in transcriptome of rapamycin-fed males; however, a large number of transcripts (>4,500) changed significantly in females. Using multidimensional scaling and heatmap analyses, the male mice fed rapamycin were found to segregate into two groups: one group that is almost identical to control males (Rapa-1) and a second group (Rapa-2) that shows a change in gene expression (>4,000 transcripts) with more than 60% of the genes shared with female mice fed Rapa. Using ingenuity pathway analysis, 13 pathways were significantly altered in both Rapa-2 males and rapamycin-fed females with mitochondrial function as the most significantly changed pathway. Our findings show that rapamycin has a major effect on the transcriptome and point to several pathways that would likely impact the longevity. [ABSTRACT FROM AUTHOR]

Published

2014

9. Short-Term Treatment With Rapamycin and Dietary Restriction Have Overlapping and Distinctive Effects in Young Mice.

Author

Fok, Wilson C., Zhang, Yiqiang, Salmon, Adam B., Bhattacharya, Arunabh, Gunda, Rakesh, Jones, Dean, Ward, Walter, Fisher, Kathleen, Richardson, Arlan, and Pérez, Viviana I.

Subjects

RAPAMYCIN, LOW-calorie diet, LABORATORY mice, LIFE spans, LONGEVITY, AGING, THERAPEUTICS

Abstract

Because rapamycin, an inhibitor of the nutrient sensor mammalian target of rapamycin, and dietary restriction both increase life span of mice, it has been hypothesized that they act through similar mechanisms. To test this hypothesis, we compared various biological parameters in dietary restriction mice (40% food restriction) and mice fed rapamycin (14 ppm). Both treatments led to a significant reduction in mammalian target of rapamycin signaling and a corresponding increase in autophagy. However, we observed striking differences in fat mass, insulin sensitivity, and expression of cell cycle and sirtuin genes in mice fed rapamycin compared with dietary restriction. Thus, although both treatments lead to significant downregulation of mammalian target of rapamycin signaling, these two manipulations have quite different effects on other physiological functions suggesting that they might increase life span through a common pathway as well as pathways that are altered differently by dietary restriction and rapamycin. [ABSTRACT FROM PUBLISHER]

Published

2013

10. Update on the oxidative stress theory of aging: Does oxidative stress play a role in aging or healthy aging?

Author

Salmon, Adam B., Richardson, Arlan, and Pérez, Viviana I.

Subjects

*OXIDATIVE stress, *CELLULAR aging, *CELL death, *LABORATORY mice, *ANTIOXIDANTS, *LIFE spans

Abstract

Abstract: The oxidative stress theory of aging predicts that manipulations that alter oxidative stress/damage will alter aging. The gold standard for determining whether aging is altered is life span, i.e., does altering oxidative stress/damage change life span? Mice with genetic manipulations in their antioxidant defense system designed to directly address this prediction have, with few exceptions, shown no change in life span. However, when these transgenic/knockout mice are tested using models that develop various types of age-related pathology, they show alterations in progression and/or severity of pathology as predicted by the oxidative stress theory: increased oxidative stress accelerates pathology and reduced oxidative stress retards pathology. These contradictory observations might mean that (a) oxidative stress plays a very limited, if any, role in aging but a major role in health span and/or (b) the role that oxidative stress plays in aging depends on environment. In environments with minimal stress, as expected under optimal husbandry, oxidative damage plays little role in aging. However, under chronic stress, including pathological phenotypes that diminish optimal health, oxidative stress/damage plays a major role in aging. Under these conditions, enhanced antioxidant defenses exert an “antiaging” action, leading to changes in life span, age-related pathology, and physiological function as predicted by the oxidative stress theory of aging. [Copyright &y& Elsevier]

Published

2010

11. Lack of methionine sulfoxide reductase A in mice increases sensitivity to oxidative stress but does not diminish life span.

Author

Salmon, Adam B., Pérez, Viviana I., Bokov, Alex, Jernigan, Amanda, Geumsoo Kim, Hang Zhao, Levine, Rodney L., and Richardson, Arlan

Subjects

*METHIONINE, *OXIDATIVE stress, *LIFE spans, *SULFUR amino acids, *GENETICS of aging, *PARAQUAT, *FIBROBLASTS, *LABORATORY mice

Abstract

Methionine sulfoxide reductase A (MsrA) repairs oxidized methionine residues within proteins and may also function as a general antioxidant. Previous reports have suggested that modulation of MsrA in mice and mammalian cell culture can affect the accumulation of oxidized proteins and may regulate resistance to oxidative stress. Thus, under the oxidative stress theory of aging, these results would predict that MsrA regulates the aging process in mammals. We show here that MsrA-/- mice are more susceptible to oxidative stress induced by paraquat. Skin-derived fibroblasts do not express MsrA, but fibroblasts cultured from MsrA-/- mice were, nevertheless, also more susceptible to killing by various oxidative stresses. In contrast to previous reports, we find no evidence for neuromuscular dysfunction in MsrA-/- mice in either young adult or in older animals. Most important, we found no difference between MsrA-/- and control mice in either their median or maximum life span. Thus, our results show that MsrA regulates sensitivity to oxidative stress in mice but has no effect on aging, as determined by life span. [ABSTRACT FROM AUTHOR]

Published

2009

12. Mechanisms of stress resistance in Snell dwarf mouse fibroblasts: Enhanced antioxidant and DNA base excision repair capacity, but no differences in mitochondrial metabolism

Author

Page, Melissa M., Salmon, Adam B., Leiser, Scott F., Robb, Ellen L., Brown, Melanie F., Miller, Richard A., and Stuart, Jeffrey A.

Subjects

*ANTIOXIDANTS, *DNA ligases, *OXIDATIVE stress, *LABORATORY mice, *FIBROBLASTS, *MITOCHONDRIA, *METABOLISM, *PEROXIDASE

Abstract

Abstract: Dermal fibroblasts from long-lived Snell dwarf mice can withstand a variety of oxidative and non-oxidative stressors compared to normal littermate controls. Here, we report differences in the levels and activities of intracellular antioxidant and DNA repair enzymes between normal and Snell dwarf mice fibroblasts cultured under a variety of conditions, including: 3% and 20% ambient O2; the presence and absence of serum; and the addition of an exogenous oxidative stress. The only significant difference between normal and dwarf cells cultured in complete medium, at 20% O2, was an approximately 40% elevation of glutathione peroxidase (GPx) activity in the mutant cells. Serum deprivation elicited increases in GPx in both genotypes, but these activities remained higher in dwarf mouse cells. Dwarf mouse cells deprived of serum and challenged with exposure to paraquat or hydrogen peroxide showed a generally greater upregulation of catalase and DNA base excision repair enzymes. As these toxins can interact with mitochondria to increase mitochondrial ROS production, we explored whether there were differences in mitochondrial metabolism between normal and dwarf mouse cells. However, neither mitochondrial content nor the apparent mitochondrial membrane potential differed between genotypes. Overall, the results suggest that superior hydrogen peroxide metabolism and a marginally greater DNA base excision repair capacity contribute to the stress resistance phenotype of Snell dwarf mouse fibroblasts. [Copyright &y& Elsevier]

Published

2009

13. Cells From Long-Lived Mutant Mice Exhibit Enhanced Repair of Ultraviolet Lesions.

Author

Salmon, Adam B., Ljungman, Mats, and Miller, Richard A.

Subjects

*FIBROBLASTS, *CELLS, *ULTRAVIOLET radiation, *LONGEVITY, *LABORATORY mice

Abstract

Fibroblasts isolated from long-lived hypopituitary dwarf mice are resistant to many cell stresses, including ultraviolet (UV) light and methyl methane sulfonate (MMS), which induce cell death by producing DNA damage. Here we report that cells from Snell dwarf mice recover more rapidly than controls from the inhibition of RNA synthesis induced by UV damage. Recovery of messenger RNA (mRNA) synthesis in particular is more rapid in dwarf cells, suggesting enhanced repair of the actively transcribing genes in dwarf-derived cells. At early time points, there was no difference in the repair of cyclobutane pyrimidine dimers (CPD) or 6-4 photoproducts (6-4PP) in the whole genome, nor was there any significant difference in the repair of UV lesions in specific genes. However, at later time points we found that more lesions had been removed from the genome of dwarf-derived cells. We have also found that cells from dwarf mice express higher levels of the nucleotide excision repair proteins XPC and CSA, suggesting a causal link to enhanced DNA repair. Overall, these data suggest a mechanism for the UV resistance of Snell dwarf-derived fibroblasts that could contribute to the delay of aging and neoplasia in these mice. [ABSTRACT FROM AUTHOR]

Published

2008

14. Fibroblasts From Naked Mole-Rats Are Resistant to Multiple Forms of Cell Injury, But Sensitive to Peroxide, Ultraviolet Light, and Endoplasmic Reticulum Stress.

Author

Salmon, Adam B., Sadighi Akha, Amir A., Buffenstein, Rochelle, and Miller, Richard A.

Subjects

*FIBROBLASTS, *LABORATORY mice, *PEROXIDES, *ULTRAVIOLET radiation, *ENDOPLASMIC reticulum, *OXIDATION

Abstract

Fibroblasts from long-lived mutant mice are resistant to many forms of lethal injury as well as to the metabolic effects of rotenone and low-glucose medium. Here we evaluated fibroblasts from young adult naked mole-rats (NMR; Heterocephalus glaber), a rodent species in which maximal longevity exceeds 28 years. Compared to mouse cells, NMR cells were resistant to cadmium, methyl methanesulfonate, paraquat, heat, and low-glucose medium, consistent with the idea that cellular resistance to stress may contribute to disease resistance and longevity. Surprisingly, NMR cells were more sensitive than mouse cells to H2O2, ultraviolet (UV) light, and rotenone. NMR cells, like cells from Snell dwarf mice, were more sensitive to tunicamycin and thapsigargin, which interfere with the function of the endoplasmic reticulum (ER stress). The sensitivity of both Snell dwarf and NMR cells to ER stress suggests that alterations in the unfolded protein response might modulate cell survival and aging rate. [ABSTRACT FROM AUTHOR]

Published

2008

15. Skin-derived fibroblasts from long-lived species are resistant to some, but not all, lethal stresses and to the mitochondrial inhibitor rotenone.

Author

Harper, James M., Salmon, Adam B., Leiser, Scott F., Galecki, Andrzej T., and Miller, Richard A.

Subjects

*FIBROBLASTS, *CELL lines, *SKIN biopsy, *LABORATORY mice, *REGRESSION analysis

Abstract

Fibroblast cell lines were developed from skin biopsies of eight species of wild-trapped rodents, one species of bat, and a group of genetically heterogeneous laboratory mice. Each cell line was tested in vitro for their resistance to six varieties of lethal stress, as well as for resistance to the nonlethal metabolic effects of the mitochondrial inhibitor rotenone and of culture at very low glucose levels. Standard linear regression of species-specific lifespan against each species mean stress resistance showed that longevity was associated with resistance to death induced by cadmium and hydrogen peroxide, as well as with resistance to rotenone inhibition. A multilevel regression method supported these associations, and suggested a similar association for resistance to heat stress. Regressions for resistance to cadmium, peroxide, heat, and rotenone remained significant after various statistical adjustments for body weight. In contrast, cells from longer-lived species did not show significantly greater resistance to ultraviolet light, paraquat, or the DNA alkylating agent methylmethanesulfonate. There was a strong correlation between species longevity and resistance to the metabolic effects of low-glucose medium among the rodent cell lines, but this test did not distinguish mice and rats from the much longer-lived little brown bat. These results are consistent with the idea that evolution of long-lived species may require development of cellular resistance to several forms of lethal injury, and provide justification for evaluation of similar properties in a much wider range of mammals and bird species. [ABSTRACT FROM AUTHOR]

Published

2007

16. Metabolic effects of intra-abdominal fat in GHRKO mice.

Author

Masternak, Michal M., Bartke, Andrzej, Wang, Feiya, Spong, Adam, Gesing, Adam, Fang, Yimin, Salmon, Adam B., Hughes, Larry F., Liberati, Teresa, Boparai, Ravneet, Kopchick, John J., and Westbrook, Reyhan

Subjects

SOMATOTROPIN receptors, OBESITY, INSULIN, METABOLISM, ADIPONECTIN, BODY temperature, LABORATORY mice

Abstract

Summary Mice with targeted deletion of the growth hormone receptor (GHRKO mice) are growth hormone (GH) resistant, small, obese, hypoinsulinemic, highly insulin sensitive and remarkably long-lived. To elucidate the unexpected coexistence of adiposity with improved insulin sensitivity and extended longevity, we examined effects of surgical removal of visceral (epididymal and perinephric) fat on metabolic traits related to insulin signaling and longevity. Comparison of results obtained in GHRKO mice and in normal animals from the same strain revealed disparate effects of visceral fat removal (VFR) on insulin and glucose tolerance, adiponectin levels, accumulation of ectopic fat, phosphorylation of insulin signaling intermediates, body temperature, and respiratory quotient (RQ). Overall, VFR produced the expected improvements in insulin sensitivity and reduced body temperature and RQ in normal mice and had opposite effects in GHRKO mice. Some of the examined parameters were altered by VFR in opposite directions in GHRKO and normal mice, and others were affected in only one genotype or exhibited significant genotype × treatment interactions. Functional differences between visceral fat of GHRKO and normal mice were confirmed by measurements of adipokine secretion, lipolysis, and expression of genes related to fat metabolism. We conclude that in the absence of GH signaling, the secretory activity of visceral fat is profoundly altered and unexpectedly promotes enhanced insulin sensitivity. The apparent beneficial effects of visceral fat in GHRKO mice may also explain why reducing adiposity by calorie restriction fails to improve insulin signaling or further extend longevity in these animals. [ABSTRACT FROM AUTHOR]

Published

2012

17. Heightened Induction of Proapoptotic Signals in Response to Endoplasmic Reticulum Stress in Primary Fibroblasts from a Mouse Model of Longevity.

Author

Sadighi Akha, Amir A., Harper, James M., Salmon, Adam B., Schroeder, Bethany A., Tyra, Heather M., Rutkowski, D. Thomas, and Miller, Richard A.

Subjects

*ENDOPLASMIC reticulum, *FIBROBLASTS, *CAENORHABDITIS elegans, *PHOSPHORYLATION, *APOPTOSIS, *LABORATORY mice

Abstract

Previous work from our laboratory has shown that primary fibroblasts from long-lived Snell dwarf mice display a higher sensitivity to the lethal effects of endoplasmic reticulum (ER) stressors, such as thapsigargin, than cells from normal mice. Here we show that thapsigargin induces higher expression of CHOP, enhanced cleavage of caspase-12, higher caspase-3 activity, and increased phosphorylation of c-JUN, all indicators of enhanced apoptosis, in dwarf fibroblasts. Dwarf and normal fibroblasts show no genotypic difference in up-regulating BiP, GRP94, and ERp72 proteins after exposure to thapsigargin. However, dwarf fibroblasts express lower basal levels of a number of putative XBP1 target genes including Armet, Edem1, Erdj3, p58IPK and Sec61a1, as well as Ire1a itself. Furthermore, when exposed to thapsigargin, dwarf fibroblasts display attenuated splicing of Xbp1, but similar phosphorylation of eIF2a, in comparison to normal fibroblasts. These data support the notion that IRE1/XBP1 signaling is set at a lower level in dwarf fibroblasts. Diminished Xbp1 splicing in dwarf-derived fibroblasts may tilt the balance between prosurvival and proapoptotic signals in favor of apoptosis, thereby leading to higher induction of proapoptotic signals in these cells and ultimately their increased sensitivity to ER stressors. These results, together with recent findings in Caenorhabditis elegans daf-2 mutants, point to a potential interplay between insulin/IGF-1 signals and unfolded protein response signaling. [ABSTRACT FROM AUTHOR]

Published

2011

18. The paradoxical role of thioredoxin on oxidative stress and aging.

Author

Cunningham, Geneva M., Roman, Madeline G., Flores, Lisa C., Hubbard, Gene B., Salmon, Adam B., Zhang, Yiqiang, Gelfond, Jonathan, and Ikeno, Yuji

Subjects

*CYTOSOL, *THIOREDOXIN, *OXIDATIVE stress, *GENETIC overexpression, *AGING, *LABORATORY mice, *PHYSIOLOGY

Abstract

In spite of intensive study, there is still controversy about the free radical or oxidative stress theory of aging, particularly in mammals. Our laboratory has conducted the first detailed studies on the role of thioredoxin (Trx) in the cytosol (Trx1) and in mitochondria (Trx2) on oxidative stress and aging using unique mouse models either overexpressing or down-regulating Trx1 or Trx2. The results generated from our lab and others indicate that: (1) oxidative stress and subsequent changes in signaling pathways could have different pathophysiological impacts at different stages of life; (2) changes in redox-sensitive signaling controlled by levels of oxidative stress and redox state could play more important roles in pathophysiology than accumulation of oxidative damage; (3) changes in oxidative stress and redox state in different cellular compartments (cytosol, mitochondria, or nucleus) could play different roles in pathophysiology during aging, and their combined effects show more impact on aging than changes in either oxidative stress or redox state alone; and (4) the roles of oxidative stress and redox state could have different pathophysiological consequences in different organs/tissues/cells or pathophysiological conditions. To critically test the role of oxidative stress on aging and investigate changes in redox-sensitive signaling pathways, further study is required. [ABSTRACT FROM AUTHOR]

Published

2015

19. Obesity-induced oxidative stress, accelerated functional decline with age and increased mortality in mice.

Author

Zhang, Yiqiang, Fischer, Kathleen E., Soto, Vanessa, Liu, Yuhong, Sosnowska, Danuta, Richardson, Arlan, and Salmon, Adam B.

Subjects

*OBESITY complications, *OXIDATIVE stress, *METABOLIC syndrome, *MORTALITY, *GRIP strength, *LABORATORY mice

Abstract

Obesity is a serious chronic disease that increases the risk of numerous co-morbidities including metabolic syndrome, cardiovascular disease and cancer as well as increases risk of mortality, leading some to suggest this condition represents accelerated aging. Obesity is associated with significant increases in oxidative stress in vivo and, despite the well-explored relationship between oxidative stress and aging, the role this plays in the increased mortality of obese subjects remains an unanswered question. Here, we addressed this by undertaking a comprehensive, longitudinal study of a group of high fat-fed obese mice and assessed both their changes in oxidative stress and in their performance in physiological assays known to decline with aging. In female C57BL/6J mice fed a high-fat diet starting in adulthood, mortality was significantly increased as was oxidative damage in vivo . High fat-feeding significantly accelerated the decline in performance in several assays, including activity, gait, and rotarod. However, we also found that obesity had little effect on other markers of function and actually improved performance in grip strength, a marker of muscular function. Together, this first comprehensive assessment of longitudinal, functional changes in high fat-fed mice suggests that obesity may induce segmental acceleration of some of the aging process. [ABSTRACT FROM AUTHOR]

Published

2015

20. Oxidative stress and diabetes: What can we learn about insulin resistance from antioxidant mutant mouse models?

Author

Styskal, JennaLynn, Van Remmen, Holly, Richardson, Arlan, and Salmon, Adam B.

Subjects

*OXIDATIVE stress, *DIABETES, *OBESITY, *METABOLIC disorders, *GENETIC mutation, *LABORATORY mice, ANIMAL models of insulin resistance

Abstract

Abstract: The development of metabolic dysfunctions like diabetes and insulin resistance in mammals is regulated by a myriad of factors. Oxidative stress seems to play a central role in this process as recent evidence shows a general increase in oxidative damage and a decrease in oxidative defense associated with several metabolic diseases. These changes in oxidative stress can be directly correlated with increased fat accumulation, obesity, and consumption of high-calorie/high-fat diets. Modulation of oxidant protection through either genetic mutation or treatment with antioxidants can significantly alter oxidative stress resistance and accumulation of oxidative damage in laboratory rodents. Antioxidant mutant mice have previously been utilized to examine the role of oxidative stress in other disease models, but have been relatively unexplored as models to study the regulation of glucose metabolism. In this review, we will discuss the evidence for oxidative stress as a primary mechanism linking obesity and metabolic disorders and whether alteration of antioxidant status in laboratory rodents can significantly alter the development of insulin resistance or diabetes. [Copyright &y& Elsevier]

Published

2012