The Effect of Macrophage-secreted Factors on Preadipocyte Survival

Molgat, André

10 January 2013

Adipose tissue (AT) expansion and remodeling that maintains healthy function relies on stromal preadipocytes capable of differentiating into new adipocytes (adipogenesis). During chronic positive energy balance, a relative deficit in adipogenesis, from either a decrease in preadipocyte number or their capacity to differentiate, leads to excessive adipocyte hypertrophy and AT dysfunction. AT contains macrophages whose number and activation state is dynamically regulated with changes in AT mass. This study aims to investigate the effect of macrophage-secreted factors on preadipocyte survival. To assess the effect of macrophage-secreted factors on preadipocytes, murine 3T3-L1 preadipocytes or human primary preadipocytes were incubated with macrophage-conditioned medium (MacCM), prepared from either murine (J774A.1, RAW264.7, bone marrow-derived) or human (THP-1, monocyte-derived) macrophage models, respectively. MacCM inhibited preadipocyte apoptosis and activated pro-survival signaling in both preadipocyte models. Inhibition of PDGFR, Akt, or ERK1/2 reduced the pro-survival effect of MacCM in 3T3-L1 preadipocytes. Inhibition of reactive oxygen species (ROS) generation, or enhancement of ROS clearance, reduced MacCM-dependent 3T3-L1 preadipocyte survival. Whereas anti-inflammatory activated macrophages retained the ability to prevent preadipocyte apoptosis, pro-inflammatory activated macrophages did not. TNF-α immunoneutralization restored the survival activity of pro-inflammatory MacCM on 3T3-L1 preadipocytes. These studies reveal a novel pro-survival effect of MacCM on preadipocytes, and identify signaling molecules (PDGF, Akt, ERK1/2, and ROS) that underlie this action. Macrophage activation was found to regulate the pro-survival activity of MacCM. These in vitro cell culture studies are consistent with a model in which the extent of preadipocyte apoptosis in vivo may determine preadipocyte number and the ability of AT to expand while maintaining healthy function during chronic positive energy balance.

adipocyte

preadipocyte

metabolism

adipose tissue

fat

macrophage

inflammation

PDGF

TNFalpha

apoptosis

reactive oxygen species

platelet-derived growth factor

tumor-necrosis factor alpha

Mechanisms of Channel Arrest and Spike Arrest Underlying Metabolic Depression and the Remarkable Anoxia-tolerance of the Freshwater Western Painted Turtle (Chrysemys picta bellii)

Pamenter, Matthew

26 February 2009

Anoxia is an environmental stress that few air-breathing vertebrates can tolerate for more than a few minutes before extensive neurodegeneration occurs. Some facultative anaerobes, including the freshwater western painted turtle Chrysemys picta bellii, are able to coordinately reduce ATP demand to match reduced ATP availability during anoxia, and thus tolerate prolonged insults without apparent detriment. To reduce metabolic rate, turtle neurons undergo channel arrest and spike arrest to decrease membrane ion permeability and neuronal electrical excitability, respectively. However, although these adaptations have been documented in turtle brain, the mechanisms underlying channel and spike arrest are poorly understood. The aim of my research was to elucidate the cellular mechanisms that underlie channel and spike arrest and the neuroprotection they confer on the anoxic turtle brain. Using electrophysiological and fluorescent imaging techniques, I demonstrate for the first time that: 1) the α-amino-3-hydroxy-5-methyl-4-isoxazole propionic acid receptor (AMPAR) undergoes anoxia-mediated channel arrest; 2) delta opioid receptors (DORs), and 3) mild mitochondrial uncoupling via mitochondrial ATP-sensitive K+ channels result in an increase in cytosolic calcium concentration and subsequent channel arrest of the N-methyl-D-aspartate receptor, preventing excitotoxic calcium entry, and 4) reducing nitric oxide (NO) production; 5) the cellular concentration of reactive oxygen species (ROS) decreases with anoxia and ROS bursts do not occur during reoxygenation; and 6) spike arrest occurs in the anoxic turtle cortex, and that this is regulated by increased neuronal conductance to chloride and potassium ions due to activation of γ–amino-butyric acid receptors (GABAA and GABAB respectively), which create an inhibitory electrical shunt to dampen neuronal excitation during anoxia. These mechanisms are individually critical since blockade of DORs or GABA receptors induce excitotoxic cell death in anoxic turtle neurons. Together, spike and channel arrest significantly reduce neuronal excitability and individually provide key contributions to the turtle’s long-term neuronal survival during anoxia. Since the turtle is the most anoxia-tolerant air-breathing vertebrate identified, these results suggest that multiple mechanisms of metabolic suppression acting in concert are essential to maximizing anoxia-tolerance.

anoxia

reptile

neuroscience

ischemia

facultative anaerobe

NMDA receptor

AMPA receptor

reactive oxygen species

ischemic preconditioning

mKATP channel

GABA

delta opioid receptor

0433

Vascular KATP Channel Modulation by S-Glutathionylation: A Novel Mechanism for Cellular Response to Oxidative Stress

Yang, Yang

29 April 2011

The KATP channels play an important role in the membrane excitability and vascular tone regulation. Previous studies indicate that the function of KATP channels is disrupted in oxidative stress seen in a variety of cardiovascular diseases, while the underlying mechanism remains unclear. Here, we demonstrate S-glutathionylation to be a modulation mechanism underlying the oxidant-mediated vascular KATP channel inhibition, the molecular basis for the channel inhibition and the alleviation of the channel inhibition by vasoactive intestinal peptide (VIP). We found that an exposure of isolated mesenteric rings to H2O2 impaired the KATP channel-mediated vascular dilation. In whole-cell recordings and inside-out patches, micromolar H2O2 or diamide caused a strong inhibition of the vascular KATP channel (Kir6.1/SUR2B) in the presence, but not in the absence, of glutathione (GSH), indicating S-glutathionylation. By co-expressions of Kir6.1 or Kir6.2 with SUR2B subunits, we found that the oxidant sensitivity of the KATP channel relied on the Kir6.1 subunit. Systematic mutational analysis revealed three cysteine residues (Cys43, Cys120 and Cys176) to be important. Among them, Cys176 was prominent, contributing to >80% oxidant sensitivity. Biochemical pull-down assay with biotinylated glutathione ethyl ester (BioGEE) showed that mutations of Cys176 impaired the oxidant-induced incorporation of GSH to the Kir6.1 subunit. Simulation modeling of Kir6.1 S-glutathionylation revealed that after incorporation to residue 176, the GSH moiety occupied a space between slide helix and two transmembrane helices. This prevented the necessary conformational change of the inner helix for channel gating, and retained the channel in its closed state. VIP is a potent vasodilator, and is shown to have protective role against oxidative stress. We found that the channel was strongly augmented by VIP and the channel activation relied on PKA phosphorylation. These results therefore indicate that 1) the vascular KATP channel is strongly inhibited in oxidative stress, 2) S-glutathionylation underlies the oxidant-mediated KATP channel inhibition, 3) Cys176 in the Kir6.1 subunit is the major site for S-glutathionylation, and 4) the Kir6.1/SUR2B channel is activated in a PKA-dependent manner by VIP that has been previously shown to alleviate oxidative stress.

Kir6.1

SUR2B

ATP-sensitive K+ channels

KATP channel

Vascular tone

Oxidative stress

S-glutathionylation

Structural modeling

Protein kinase A

Vasodilators

Vasoconstrictors

Vasoactive intestinal peptide

Reactive oxygen species.

Biology, general

Mechanisms of Channel Arrest and Spike Arrest Underlying Metabolic Depression and the Remarkable Anoxia-tolerance of the Freshwater Western Painted Turtle (Chrysemys picta bellii)

Pamenter, Matthew

26 February 2009

Anoxia is an environmental stress that few air-breathing vertebrates can tolerate for more than a few minutes before extensive neurodegeneration occurs. Some facultative anaerobes, including the freshwater western painted turtle Chrysemys picta bellii, are able to coordinately reduce ATP demand to match reduced ATP availability during anoxia, and thus tolerate prolonged insults without apparent detriment. To reduce metabolic rate, turtle neurons undergo channel arrest and spike arrest to decrease membrane ion permeability and neuronal electrical excitability, respectively. However, although these adaptations have been documented in turtle brain, the mechanisms underlying channel and spike arrest are poorly understood. The aim of my research was to elucidate the cellular mechanisms that underlie channel and spike arrest and the neuroprotection they confer on the anoxic turtle brain. Using electrophysiological and fluorescent imaging techniques, I demonstrate for the first time that: 1) the α-amino-3-hydroxy-5-methyl-4-isoxazole propionic acid receptor (AMPAR) undergoes anoxia-mediated channel arrest; 2) delta opioid receptors (DORs), and 3) mild mitochondrial uncoupling via mitochondrial ATP-sensitive K+ channels result in an increase in cytosolic calcium concentration and subsequent channel arrest of the N-methyl-D-aspartate receptor, preventing excitotoxic calcium entry, and 4) reducing nitric oxide (NO) production; 5) the cellular concentration of reactive oxygen species (ROS) decreases with anoxia and ROS bursts do not occur during reoxygenation; and 6) spike arrest occurs in the anoxic turtle cortex, and that this is regulated by increased neuronal conductance to chloride and potassium ions due to activation of γ–amino-butyric acid receptors (GABAA and GABAB respectively), which create an inhibitory electrical shunt to dampen neuronal excitation during anoxia. These mechanisms are individually critical since blockade of DORs or GABA receptors induce excitotoxic cell death in anoxic turtle neurons. Together, spike and channel arrest significantly reduce neuronal excitability and individually provide key contributions to the turtle’s long-term neuronal survival during anoxia. Since the turtle is the most anoxia-tolerant air-breathing vertebrate identified, these results suggest that multiple mechanisms of metabolic suppression acting in concert are essential to maximizing anoxia-tolerance.

anoxia

reptile

neuroscience

ischemia

facultative anaerobe

NMDA receptor

AMPA receptor

reactive oxygen species

ischemic preconditioning

mKATP channel

GABA

delta opioid receptor

0433

Impact of Sunlight and Natural Organic Matter on the Fate, Transport, and Toxicity of Carbon Based Nanomaterials

Qu, Xiaolei

16 September 2013

The fast growing production of carbon based nanomaterials (CNMs) and their potential widespread use in consumer products raise concerns regarding their potential risks to human health and ecosystems. The present study investigated the role of photochemical transformation and natural organic matter (NOM) in the fate, transport, and toxicity of fullerenes and carbon nanotubes (CNTs) in natural aquatic systems, providing fundamental information for risk assessment and management. Photochemical transformation of aqueous fullerene nanoparticles (nC60) and CNTs occurs at significant rates under UVA irradiation at intensity similar to that in sunlight. The transformation processes are mediated by self-generated ROS, resulting in changes of surface structure depending on the initial surface oxidation state of CNMs. UVA irradiation leads to oxygenation of nC60 surface and decarboxylation of carboxylated multi-walled carbon nanotubes (COOH-MWNTs). The environmental transport of CNMs is significantly affected by their surface chemistry, concentration and species of electrolytes, and concentration and properties of co-existing NOM. In electrolyte solutions without NOM, the mobility of CNMs is largely decided by their surface chemistry, primarily the oxygen-containing functional groups. In NaCl solutions, UVA irradiation remarkably enhanced the mobility of nC60; conversely, it reduced nC60 stability in CaCl2 solutions. The mobility of COOH-MWNTs in NaCl solutions correlated well with the abundance of surface carboxyl groups. Humic acid, once adsorbed on the nC60 surface, can significantly enhance its stability through steric hindrance. The extent of stabilization depends on the amount and properties of humic acid adsorbed. Humic acid has limited adsorption on UVA-irradiated nC60. Soil humic acid is more efficient in stabilizing nC60 than aquatic humic acid due to its higher molecular weight. Humic acid immobilized onto the silica surface can potential enhance or hinder nC60 deposition, depending on the complex interplay of attractive and repulsive forces. MWNTs are more toxicity to bacteria, Escherichia coli, than COOH-MWNTs due to their higher bioavailability and oxidative capacity. Surface oxidation induced by •OH reduced the toxicity of MWNT while reactions with •OH have little effect on the COOH-MWNT toxicity. Antioxidants such as glutathione can effectively inhibit the antibacterial activity of MWNTs.

Relationships between Mechanical Stress and Markers of Inflammation in Diseased Human Coronary Arteries

Hallow, Karen Melissa

05 July 2007

Rupture of atherosclerotic plaque is one of the primary causes of death due to cardiovascular disease. The factors directing plaque progression to instability are poorly understood. It is well-known that arteries respond to changes in mechanical stress by remodeling, and that remodeling is mediated by the inflammatory response. Studies have shown that both mechanical stress and markers of inflammation are increased in the fibrous cap and shoulder regions of plaque, where rupture most often occurs. In this study we hypothesized that there are spatial relationships between the local mechanical environment and expression of markers of inflammation in atherosclerosis, and that these relationships are plaque-progression dependent. To test these hypotheses, we analyzed cross-sections at intervals along the length of human coronary atherosclerotic arteries. For each cross-section, a heterogeneous finite element model was developed to determine the spatial distribution of stress. In addition, novel techniques for quantifying inflammatory markers at high spatial resolution were used to determine the distributions of inflammatory markers. The distributions of stress and five markers of inflammation activated NF-kB, macrophages, MMP-1, nitrotyrosine, and microvessels - were then compared to determine whether spatial relationships exists. We demonstrated that the probability of activated NF-kB expression increases monotonically with increasing stress in all stages of plaque progression. This indicates that the relationship between mechanical stress and NF-kB activation is a player throughout the disease process. We found that the relationship between mechanical stress and macrophages is highly dependent on the state of plaque progression. In intermediate stages of progression macrophages increase with moderate stress but drop off again at very high stresses, while in the advanced stage macrophages continue to increase monotonically with stress. We found that MMP1 increases with stress in stages of progression where active remodeling is occurring, but decreases with stress in mature stable plaque. We found no relationship between mechanical stress and nitrotyrosine expression or microvessels. Taken together, these results support the role of mechanical stress in instigating and maintaining the inflammatory response, and help explain how mechanical input is able to direct the complex biological changes involved in remodeling.

Atherosclerosis

Plaque rupture

Inflammation

Nuclear factor - kappa B

Matrix metalloproteinase

Macrophages

Reactive oxygen species

Nitrotyrosine

Microvessels

Heterogeneous finite element model

Strains and stresses

Atherosclerotic plaque

Coronary heart disease

Inflammation

Assessment of Cerebellar and Hippocampal Morphology and Biochemical Parameters in the Compound Heterozygous, Tottering/leaner Mouse

Murawski, Emily M.

2009 December 1900

Due to two different mutations in the gene that encodes the a1A subunit of voltage-activated CaV 2.1 calcium ion channels, the compound heterozygous tottering/leaner (tg/tgla) mouse exhibits numerous neurological deficits. Human disorders that arise from mutations in this voltage dependent calcium channel are familial hemiplegic migraine, episodic ataxia-2, and spinocerebellar ataxia 6. The tg/tgla mouse exhibits ataxia, movement disorders and memory impairment, suggesting that both the cerebellum and hippocampus are affected. To gain greater understanding of the many neurological abnormalities that are exhibited by the 90-120 day old tg/tgla mouse the following aspects were investigated: 1) the morphology of the cerebellum and hippocampus, 2) proliferation and death in cells of the hippocampal dentate gyrus and 3) changes in basic biochemical parameters in granule cells of the cerebellum and hippocampus. This study revealed no volume abnormalities within the hippocampus of the mutant mice, but a decrease in cell density with the pyramidal layer of CA3 and the hilus of the dentate gyrus. Cell size in the CA3 region was unaffected, but cell size in the hilus of the dentate gyrus did not exhibit the gender difference seen in the wild type mouse. The cerebellum showed a decrease in volume without any decrease in cerebellar cellular density. Cell proliferation and differentiation in the subgranular zone of the hippocampal dentate gyrus remained normal. This region also revealed a decrease in cell death in the tg/tgla mice. Basal intracellular calcium levels in granule cells show no difference within the hippocampus, but an increase in the tg/tgla male cerebellum compared to the wild type male cerebellum. There was no significant difference in granule cell mitochondrial membrane potential within the wild type and mutant animals in either the hippocampus or cerebellum. The rate of reactive oxygen species (ROS) production in granule cells revealed no variation within the hippocampus or cerebellum. The amount of ROS was decreased in cerebellar granule cells, but not granule cells of the hippocampus. Inducing ROS showed no alteration in production or amount of ROS produced in the hippocampus, but did show a ceiling in the amount of ROS produced, but not rate of production, in the cerebellum.

Cerebellum

Hippocampal neurogenesis

Voltage-gated calcium ion channels

Mitochondrial membrane potential

Effects of dietary fat and fiber on the oxidative status of the small intestine and colon of rats

Sanders, Lisa Merle

16 August 2006

Colon cancer is one of the most commonly diagnosed cancers in the US, yet small intestine cancer is a rare event. While there are many similarities between these two tissues, inherent differences such as redox status, may contribute to the variation in cancer occurrence. We examined the difference in reactive oxygen species (ROS) generation, antioxidant enzyme activity and oxidative DNA damage in the small and large intestine of rats under normal conditions and following exposure to exogenous oxidative stress. Basal ROS and antioxidant enzyme activities were greater in the colon than the small intestine, and the balance of ROS to antioxidant enzymes in the colon was more pro-oxidant than in the small intestine. During oxidative stress, ROS and oxidative DNA damage were greater in the colon than the small intestine. Thus the colon responds to oxidative stress less effectively than the small intestine, possibly contributing to increased cancer incidence at this site. We next wanted to understand how diets containing a combination of fish or corn oil and pectin or cellulose may alter the redox environment of the colon. ROS, oxidative DNA damage, antioxidant enzyme activity and apoptosis were measured in colonocytes of rats fed one of four diets containing either corn oil or fish oil and cellulose or pectin. Measurements were madein rats untreated with carcinogen and rats exposed to a chemical carcinogen and radiation. In rats not treated with a carcinogen, fish oil enhanced ROS, and fish oil/pectin suppressed antioxidant enzymes as compared to corn oil/cellulose. Oxidative DNA damage was inversely related to ROS in the fish oil/pectin diet and apoptosis was enhanced relative to other diets. In carcinogen treated and irradiated rats, a similar protective effect was seen with fish oil/pectin as evidenced by a reduction in oxidative DNA damage and enhancement of apoptosis. This suggests that a diet containing fish oil/pectin may protect against colon carcinogenesis by modulation of the redox environment to promote apoptosis and minimize oxidative DNA damage.

colon cancer

apoptosis

reactive oxygen species

antioxidants

oxidative stress

glutathione

oxidative damage

radiation

animal model

small intestine

fish oil

omega 3 fatty acids

dietary fiber

Oxidative Stress In The Brain: Effects Of Hydroperoxides And Nitric Oxide On Glyceraldehyde 3-Phosphate Dehydrogenase And Phosphoinositide Cycle Enzymes

Vaidyanathan, V V

04 1900

In the aerobic cell, oxygen can be converted into a series of reactive metabolites, together called as "reactive oxygen species" (ROS). This large group include both radical and non-radical species such as superoxide anion (02"), hydroxyl radical ("0H), H202, nitric oxide (N0') and lipid hydroperoxides (LOOH). ROS are generated in very small amounts at all stages of aerobic life, and probably have a role in cellular regulation. However, their formation in excess leads to toxicity and damage to tissues. This situation, called 'oxidative stress', is responsible, atleast in part, to the pathophysioiogy of a number of disease states such as inflammation, arthritis, cancer, ageing, ischemia-reperfusion and several neurodegenerative disorders. Compared to other organs in the animal body, brain tissue is more vulnerable to oxidative stress. This is due to three major reasons; (1) brain has a high oxygen consumption (2) high content of polyunsaturated fatty acids and iron, that can promote lipid peroxidation, and (3) low levels of antioxidant enzymes such as catalase and glutathione peroxidase. The inability of neurons to regenerate also contributes to exacerbate an oxidant damage in the brain. The main objective of this investigation was to identify biochemical systems in the brain that are susceptible to ROS, on the following two issues: 1. What are the targets for the action of H2O2 and NO in the glycolytic cycle, the major route for the oxidation of glucose in brain? 2. What are the targets for the action of polyunsaturated fatty acids and their oxidative metabolites among the enzymes of phosphoinositide cycle (PI cycle), the ubiquitous signal transduction event in the brain? Using sheep brain cytosol , it was found that among the various glycolytic enzymes, only glyceraldehyde 3-phosphate dehydrogenase (GAPD) was inhibited by H2O2. The enzyme was purified to homogeneity from sheep brain and its inactivation with H202 was studied in detail. Commercial preparations of rabbit skeletal muscle GAPD was also used in this study. An unusual requirement of glutathione for the complete inactivtion of the enzyme by H2O2 was observed. The H2O2-inactivated GAPD was partially reactivated by prolonged treatment with thiol compounds. Using CD-spectral analysis, a significant change was found in the secondary structure in H2O2-treated GAPD. GAPD was inactivated by NO only in presence of high concentrations of DTT and after prolonged incubation. The N0-inactivated GAPD was partially reactivated by treatment with thiol compounds. A new activity, namely ADP-ribosylation (ADPR) emerged in the NO-treated mammalian, but not in yeast. GAPD, ADPR activity could be generated in GAPD through NO-independent treatments such as incubation with NADPH and aerobic dialysis. During NADPH treatment no loss of dehydrogenase activity occurred. Thus, it was concluded that loss of dehydrogenase activity and emergence of ADPR in NO-treated GAPD were not correlated but coincidental, and that NO treatment yielded small amounts of modified-GAPD that had ADPR activity. In the brain, onset of ischemia is characterized by a significant elevation in free fatty acid (FFA) levels, predominantly, arachidonic acid (AA). It is suggested that AA can be oxidised to its metabolites like prostaglandins and 15-hydroperoxy arachidonic acid (15-HPETE) and some of these might exert toxic effects during reperfusion. Using whole membranes or tissue slices prepared from rat brain, effects of polyunsaturated fatty acids and their oxidative metabolites on five enzymes of PI cycle namely PI synthase, PI and PIP kinases, agonist-stimulated PLC and DG kinase was studied. Hydroperoxides of linoleic- and arachidonic acids inactivated PI synthase selectively among the PI cycle enzymes. Interestingly, AA selectively stimulated DG kinase in neural membranes. Docasahexaenoic acid (DHA) a highly unsaturated fatty acid found in the brain, also stimulated DG kinase activity while saturated, mono-and di-unsaturated fatty acids were ineffective. It was concluded that AA and DHA have a role in modulating neural DG kinase. The data presented in the thesis indicate that ROS have selective targets in cells and the consequent protein modifications can be used to modulate cellular functions under normal and oxidative stress conditions.

Biochemistry

Brain - Physiology

Brain - Stress Enzymes

Reactive Oxygen Species (ROS)

Brain - Oxidative Stress

Oxidative Stress

Phosphoinositide Cycle

PT Cycle

Die Rolle der Kalzium-Calmodulin-abhängigen-Proteinkinase II δc (CaMKIIδc) bei der Radikal-vermittelten Zytotoxizität in isolierten ventrikulären Kaninchenmyozyten / The role of Calcium/Calmodulin Kinase II δc (CaMKIIδc) at ROS- (radical oxygen species) induced Cytotoxicity in isolated ventrikular Rabbitcardiomyocytes

Ruff, Hanna Maria

22 June 2010

No description available.

610 Medizin, Gesundheit

Medicine

CaMKII

später Natriumstrom

Sauerstoffradikale

Herzinsuffizienz

intrazelluläres Kalzium

radicals

reactive oxygen species

late sodium current

heart failure

calcium (cellular)

CaMKII

44.85 Kardiologie

MED 411 Kardiologie