Obesity associated colon tumorigenesis: An assessment of tumor phenotype

Saxena, Swati

January 2006

Colon cancer and obesity are two significant and related pathological states with multiple etiological factors. In this dissertation, it was hypothesized that tumor growth is accelerated in the altered state of obesity due to their resistance towards tumor necrosis factor-alpha (TNF-alpha) mediated cytotoxicity. Physiologically elevated TNF-alpha in an obese state induces increased nuclear transcription factor-kB (NF-kB) activity, known to transcribe genes crucial to cell survival. Insulin resistance, oxidative stress, and a pro-inflammatory environment are few of the biological consequences of TNF-alpha and NF-kB pathway activation, and further contribute to disease progression. <br /><br /> Three major studies were conducted to investigate phenotypical changes in obesity associated tumors. Firstly, characteristics of the TNF-alpha resistant phenotype were preliminarily assessed by evaluating the effects of exogenous TNF-alpha treatment to HT-29 cells. Elevated levels of NF-kB in response to exogenous TNF-alpha gave an indication that this pathway is critical for cell survival. Furthermore, upregulation of TNF-alpha receptor 2 (TNFR2) suggested another strategy by which the cells were utilizing exogenous TNF-alpha for a survival advantage. Inhibition of NF-kB via St. John?s Wort treatment demonstrated that HT-29 cells may be sensitized towards TNF-alpha mediated cytotoxicity. <br /><br /> Zucker obese (Zk-Ob), Zucker lean (Zk-Ln), and Sprague Dawley (SD) animal models were used to assess tumor phenotype <em>in vivo</em>. Remarkable physiological differences between genotypes were observed. Zk-Ob rats had significantly higher body and organ weights as well as plasma TNF- alpha, insulin, leptin, and oxidative markers than Zk-Ln and SD animals. Tumor incidence and multiplicity were also notably higher in Zk-Ob rats. Protein analyses demonstrated increased levels of TNF-alpha, TNFR2, NF-kB, IkB kinase beta (IKKbeta), insulin receptor (IR), insulin like growth factor-I-receptor (IGF-IR), and mitogen activated protein kinase (MAPK) in Zk-Ob tumors than Zk-Ln counterparts. In all groups, tumors generally had higher protein expression than surrounding, normal appearing colonic mucosa. It is well known that these molecules are involved in signaling pathways that influence and co-operate with each other in rendering growth autonomy to tumor tissue. <br /><br /> A higher number of lesions in the distal than proximal colon in Zk-Ob rats was observed, supporting the emerging concept that genotype/physiological state of the host affects development and distribution of tumors. Thus, a third study was conducted to explore differences between distal and proximal tumor phenotype. Results demonstrated that expression of TNFR2, NF-kB, IR, IGF-IR, and MAPK p44 were significantly higher in distal than proximal tumors. This observation suggested that development of tumors in different regions of the colon varied under the same physiological conditions. Moreover, phenotype of distal tumors appeared to be upregulating survival pathways in comparison to proximal lesions, possibly explaining the higher tumor incidence in the distal colon. <br /><br /> Research documented in this thesis supported the hypothesis that the physiological status of the host intricately affects tumor phenotype. In particular, the TNF-alpha resistant phenotype was most prominent in Zk-Ob tumors, and appeared to be associated with upregulation of multiple signaling pathways cooperating towards tumorigenesis.

Biology

colon cancer

obesity

tumor phenotype

TNF-alpha

NF-kB

Zucker animal model

Obesity associated colon tumorigenesis: An assessment of tumor phenotype

Saxena, Swati

January 2006

Colon cancer and obesity are two significant and related pathological states with multiple etiological factors. In this dissertation, it was hypothesized that tumor growth is accelerated in the altered state of obesity due to their resistance towards tumor necrosis factor-alpha (TNF-alpha) mediated cytotoxicity. Physiologically elevated TNF-alpha in an obese state induces increased nuclear transcription factor-kB (NF-kB) activity, known to transcribe genes crucial to cell survival. Insulin resistance, oxidative stress, and a pro-inflammatory environment are few of the biological consequences of TNF-alpha and NF-kB pathway activation, and further contribute to disease progression. <br /><br /> Three major studies were conducted to investigate phenotypical changes in obesity associated tumors. Firstly, characteristics of the TNF-alpha resistant phenotype were preliminarily assessed by evaluating the effects of exogenous TNF-alpha treatment to HT-29 cells. Elevated levels of NF-kB in response to exogenous TNF-alpha gave an indication that this pathway is critical for cell survival. Furthermore, upregulation of TNF-alpha receptor 2 (TNFR2) suggested another strategy by which the cells were utilizing exogenous TNF-alpha for a survival advantage. Inhibition of NF-kB via St. John?s Wort treatment demonstrated that HT-29 cells may be sensitized towards TNF-alpha mediated cytotoxicity. <br /><br /> Zucker obese (Zk-Ob), Zucker lean (Zk-Ln), and Sprague Dawley (SD) animal models were used to assess tumor phenotype <em>in vivo</em>. Remarkable physiological differences between genotypes were observed. Zk-Ob rats had significantly higher body and organ weights as well as plasma TNF- alpha, insulin, leptin, and oxidative markers than Zk-Ln and SD animals. Tumor incidence and multiplicity were also notably higher in Zk-Ob rats. Protein analyses demonstrated increased levels of TNF-alpha, TNFR2, NF-kB, IkB kinase beta (IKKbeta), insulin receptor (IR), insulin like growth factor-I-receptor (IGF-IR), and mitogen activated protein kinase (MAPK) in Zk-Ob tumors than Zk-Ln counterparts. In all groups, tumors generally had higher protein expression than surrounding, normal appearing colonic mucosa. It is well known that these molecules are involved in signaling pathways that influence and co-operate with each other in rendering growth autonomy to tumor tissue. <br /><br /> A higher number of lesions in the distal than proximal colon in Zk-Ob rats was observed, supporting the emerging concept that genotype/physiological state of the host affects development and distribution of tumors. Thus, a third study was conducted to explore differences between distal and proximal tumor phenotype. Results demonstrated that expression of TNFR2, NF-kB, IR, IGF-IR, and MAPK p44 were significantly higher in distal than proximal tumors. This observation suggested that development of tumors in different regions of the colon varied under the same physiological conditions. Moreover, phenotype of distal tumors appeared to be upregulating survival pathways in comparison to proximal lesions, possibly explaining the higher tumor incidence in the distal colon. <br /><br /> Research documented in this thesis supported the hypothesis that the physiological status of the host intricately affects tumor phenotype. In particular, the TNF-alpha resistant phenotype was most prominent in Zk-Ob tumors, and appeared to be associated with upregulation of multiple signaling pathways cooperating towards tumorigenesis.

Biology

colon cancer

obesity

tumor phenotype

TNF-alpha

NF-kB

Zucker animal model

Stroke-induced stem cells proliferation in normal versus diabetic mice and pharmacological regulation / Stroke-inducerad stamcells proliferation i normala kontra diabetiska möss och famakologisk reglering

Fadhel, Zainab

January 2015

Introduction: Stroke is caused from the occlusion of any cerebral artery leading to cerebral ischemia, brain damage and consequent neurological impairments and disability. The primary causes of mortality in western populations is stroke. Diabetes type 2 is a high risk factor for stroke. Stroke leads to an observable increase of neural stem cell proliferation in the subventricular zone and enhances neurogenesis in the adult rodent and human brain which suggest a mechanism contributing to stroke recovery. Neurogenesis in type 2 diabetes patients is impaired. However, whether stroke-induced neurogenesis is impaired in diabetes has not been studied. Exendin-4 is a drug for clinical treatment of type 2 diabetes which has been shown to have neuroprotective properties in animal studies. However whether Exendine-4 leads to increased neurogenesis after  stroke in the diabetic brain has not been previously studied.  Aims: The specific aims of this project were to determine whether stroke-induced stem cell proliferation is impacted by diabetes in the mouse, and if Exendine-4 regulates stroke-induced stem cell proliferation in normal and diabetic mice. Material and Methods: Aged obese/type 2 diabetic mice were subjected to stroke. The Exendin-4 treatment was started 1.5 hours thereafter. Treatment was continued for one week before animals were sacrificed. Brains were isolated and the neurons were immunostained using the specific proliferation marker Ki67. Neural stem cell proliferation was quantified by counting Ki67+ cells in the ipsilateral (subventricular zone in stroke hemisphere).The estimation was assessed by stereological counts of proliferating stem cell in the subventricular zone.  Results: The number of proliferating stem cell after stroke was statistically significantly higher in the normal mice versus diabetic mice. The effect was present in both sides (control and stroke) of the subventricular zone. Exendine-4 treatment induced statistically significant increased of  stem cell proliferation in normal mice but not in diabetic mice.   Conclusions: The result of this study shows that type 2 diabetes decreased the proliferation of neural stem cell in the subventricular zone and that Exendin-4 enhanced the subventricular proliferation in a preclinical model of clinical relevance. The data suggest that the Exendin-4 treatment could be administered to normal patients suffering from stroke in the ambulance or in the emergency room although more studies are needed.

Stroke

diabetes

GLP-1

Exendin-4

neurogenesis

stem cell proliferation

animal model

mouse

Temporal deregulation of genes and microRNAs in neurons during prion-induced neurodegeneration

Majer, Anna

18 June 2010

Prion diseases are fatal and incurable neurodegenerative diseases that share many pathological similarities to other neurodegenerative diseases such as Alzheimer’s or Parkinson’s disease. One of the earliest pathological signs commonly detected in all of these diseases is the dysfunction followed by loss of neuronal synapses, spines and eventually dendrites that collectively contribute to disruption of normal brain function. These pathologies tend to progressively accumulate within the brain tissue such that extensive damage typically precedes clinical symptom manifestation and ultimate death of neurons. Clearly, understanding the molecular processes responsible for these pathologies could uncover critical pathway(s) that are responsible for propagating this brain damage and could therefore be exploited for therapy development. However, molecular mechanisms implicated in this early pathology remain unidentified. To address this gap in knowledge, this thesis describes a transcriptional approach coupled with specific isolation of neuronal-enriched tissue which was used to help delineate cellular pathways involved in prion-induced neurodegeneration. Profiling cell bodies of CA1 hippocampal neurons known to be affected during early prion disease revealed temporal alteration in both gene and microRNA (gene regulators) expression throughout disease. On a gene expression level, changes in transcript expression during preclinical disease were reminiscent of an activity-dependent neuroprotective gene signature previously described in the literature. These neuroprotective genes were induced during preclinical disease, diminished as disease progressed and were abolished at clinical disease. In support of this process, upregulation of the phosphorylated form of the neuroprotective transcription factor CREB was detected during preclinical disease in these neurons. Furthermore, several genes known to be induced by CREB were also upregulated at preclinical disease in prion-infected mice. Interestingly, expression of numerous deregulated microRNAs paralleled the neuroprotective gene signature of which several are known to remodel neuronal spines and dendrites. To determine whether other preclinically induced microRNAs were also capable of remodeling neuronal structures, gain-of-function studies were performed in primary mouse hippocampal neurons for the uncharacterized miR-26a-5p. Neurons over-expressing miR-26a-5p had enhanced spine density and dendrite arborization, similar to other preclinically-induced microRNAs. Together, these data suggests that CA1 hippocampal neurons induce a neuroprotective transcriptional signature that is evident early in the course of disease within CA1 hippocampal neurons and is abolished by clinical disease. Reestablishment of key molecules that can induce this neuroprotective signature at a time when these genes begin to dissipate could prolong prion disease onset and delay clinical symptom manifestation. / October 2015

prions

microRNA

neurodegeneration

gene expression

neurons

hippocampus

laser capture microdissection

preclinical

clinical

neuroprotection

animal model

NMDAR

EXPERIMENTAL-COMPUTATIONAL ANALYSIS OF VIGILANCE DYNAMICS FOR APPLICATIONS IN SLEEP AND EPILEPSY

Yaghouby, Farid

01 January 2015

Epilepsy is a neurological disorder characterized by recurrent seizures. Sleep problems can cooccur with epilepsy, and adversely affect seizure diagnosis and treatment. In fact, the relationship between sleep and seizures in individuals with epilepsy is a complex one. Seizures disturb sleep and sleep deprivation aggravates seizures. Antiepileptic drugs may also impair sleep quality at the cost of controlling seizures. In general, particular vigilance states may inhibit or facilitate seizure generation, and changes in vigilance state can affect the predictability of seizures. A clear understanding of sleep-seizure interactions will therefore benefit epilepsy care providers and improve quality of life in patients. Notable progress in neuroscience research—and particularly sleep and epilepsy—has been achieved through experimentation on animals. Experimental models of epilepsy provide us with the opportunity to explore or even manipulate the sleep-seizure relationship in order to decipher different aspects of their interactions. Important in this process is the development of techniques for modeling and tracking sleep dynamics using electrophysiological measurements. In this dissertation experimental and computational approaches are proposed for modeling vigilance dynamics and their utility demonstrated in nonepileptic control mice. The general framework of hidden Markov models is used to automatically model and track sleep state and dynamics from electrophysiological as well as novel motion measurements. In addition, a closed-loop sensory stimulation technique is proposed that, in conjunction with this model, provides the means to concurrently track and modulate 3 vigilance dynamics in animals. The feasibility of the proposed techniques for modeling and altering sleep are demonstrated for experimental applications related to epilepsy. Finally, preliminary data from a mouse model of temporal lobe epilepsy are employed to suggest applications of these techniques and directions for future research. The methodologies developed here have clear implications the design of intelligent neuromodulation strategies for clinical epilepsy therapy.

Sleep

Epilepsy

Vigilance dynamics

Hidden Markov model

EEG

Animal model

Behavioral Neurobiology

Bioelectrical and neuroengineering

Signal Processing

Trace amine associated receptors : a new target for medications in drug addiction

Cotter, Rachel

January 2012

The abuse of stimulant drugs, such as methamphetamine (METH), has become a major source of public concern in New Zealand. Specific medications for treating METH addiction are not available at present. The newly discovered trace amine- associated receptor 1 (TAAR1) constitutes a novel receptor target for medication development in neuropsychiatry. TAAR1 regulates monoamine systems in the brain, especially dopamine, and is activated directly by psychomotor stimulants, including METH. This study examined the effects of the newly developed TAAR1 partial agonist, RO5203648, in rat models of METH abuse. In experiment 1 rats were administered different doses of RO5203648 (0, 1.67, 5mg/kg i.p.) followed by METH (0, 0.75, 2mg/kg i.p.). Locomotor activity was monitored via automated video tracking system in an open field. The results revealed that RO5203648 dose- dependently reduced acute METH-induced stimulation and prevented long-term sensitization following chronic exposure. Paradoxically, in experiment 2, RO5203648 and METH treatment increased c-Fos protein expression in the nucleus accumbens and dorsal striatum. In experiment 3 rats were trained to consistently self-administer METH (0.5mg/kg/infusion) and were then pre-treated with RO5203648 (0, 3, 10mg/kg i.p.). The data showed that RO5203648 drastically reduced METH intake. Next, RO5203648 was substituted (0.25, 0.5, 1.0 mg/kg/infusion) for METH in the same paradigm. Remarkably, RO5203648 exhibited no reinforcing efficacy compared with METH. Taken together, these observations showed that RO5203648 is able to attenuate METH-related behaviours, including locomotor stimulation, sensitization and self-administration, and highlight the great potential of TAAR1-based medications for the treatment of METH addiction.

Drug Addiction

Methamphetamine

Medication

Trace Amine Associated Receptor 1

animal model

Pathophysiological, Inflammatory and Haemostatic Responses to Various Endotoxaemic Patterns : An Experimental Study in the Pig

Lipcsey, Miklós

January 2006

Septic shock is frequently seen in intensive care units and is associated with significant mortality. Endotoxin – a major mediator of the pathophysiologic responses – is released during lysis of Gram-negative bacteria. These responses can be mimicked in the endotoxaemic pig. This thesis focuses on the following topics: the inflammatory and pathophysiological responses to various endotoxin doses and infusion patterns; covariations between endotoxin induced inflammatory and pathophysiological responses; whether the biological effects of endotoxin can be modulated by clopidogrel and whether tobramycin or ceftazidime reduce plasma cytokine levels. Endotoxin induced linear log-log cytokine and F2-isoprostane responses. Leukocyte and platelet responses, pulmonary compliance, circulatory variables as well as indicators of plasma leakage and hypoperfusion exhibited log-linear responses to the endotoxin dose. Biological responses to endotoxaemia such as inflammation, hypotension, hypoperfusion and organ dysfunction were more expressed when the organism was exposed to endotoxin at a higher rate. These results may facilitate the possibility to choose relevant endotoxin administration, when experiments are set up in order to evaluate certain responses to endotoxaemia. Correlation studies between cytokines, leukocytes, platelets and the endotoxin dose were in agreement with the well-known ability of endotoxin to induce cytokine expression and to activate both primary haemostasis and leukocytes. Free radical mediated lipid peroxidation and COX-mediated inflammation correlated to cytokine expression and organ dysfunction in endotoxaemic shock. Endotoxaemic pigs pretreated with clopidogrel, exhibited a trend towards less expressed deterioration of renal function, although blocking of ADP-induced primary haemostasis is not a key mediator of endotoxin induced deterioration of renal function. Tobramycin did not neutralise the biological effects of endotoxin or the plasma levels of endotoxin, suggesting that these antibiotics do not bind to endotoxin. Reduction in IL-6 was greater in pigs treated with ceftazidime and tobramycin as compared with those given saline, indicating a possible anti-inflammatory effect of both antibiotics.

Anaesthesiology and intensive care

sepsis

animal model

cytokines

isoprostanes

endotoxic shock

pig

Anestesiologi och intensivvård

SLEEP REGULATION IN THE STOP-NULL MOUSE MODEL OF SCHIZOPHRENIA

Profitt, Maxine

13 February 2014

Sleep disturbances are common in patients with schizophrenia. Mice lacking the cytoskeletal-associated protein Stable Tubule Only Polypeptide (STOP) display cognitive, behavioural and neurobiological deficits that mimic those seen in schizophrenia, but there is little evidence of sleep changes in these mice. To investigate their sleep patterns, electroencephalogram (EEG) and electromyogram were recorded under a 12:12 light:dark cycle in adult male STOP-null (KO; n=7) and wild-type (WT; n=8) mice, during a 24 h baseline period, followed by 6 h of sleep deprivation, and a 24 h recovery period. In the baseline period, KO mice spent more time awake and less time in non-rapid eye movement (NREM) and REM sleep compared to WT mice. Particularly in the dark phase, KO mice had more wake and NREM sleep episodes, and shorter NREM and REM sleep episodes relative to WT mice. Following sleep deprivation, during the first 12 h of recovery (i.e. dark phase), both groups showed similar increases in NREM and REM sleep amounts and NREM EEG delta power relative to corresponding baseline periods. These findings indicate that the STOP-null mice sleep less and their sleep is more fragmented compared to WT mice. These features are consistent with the sleep abnormalities found in individuals with schizophrenia.

Knock Out

Animal Model

Sleep Regulation

Schizophrenia

STOP Null Mouse

Sleep Patterns

INSIGHTS INTO THE ROLE OF INFLAMMATION IN COLITIS-ASSOCIATED CANCER: TARGETING TUMOR NECROSIS FACTOR RECEPTORS

Stillie, RoseMarie

17 November 2011

Inflammatory bowel diseases (IBD) are associated with an elevated risk of colorectal cancer that increases with disease duration and severity. Tumor necrosis factor (TNF) is a major therapeutic target in IBD, but long-term anti-TNF therapy is associated with increased risks of infection and lymphoma, therefore we asked whether TNF signaling through its receptors TNFR1 and TNFR2 could impact colitis and colitis-associated cancer (CAC). In acute dextran sulphate sodium (DSS)-colitis, no major inflammatory differences were found between wildtype (WT), TNFR1- and TNFR2-deficient mice, with the exception of reduced macrophage infiltration into inflamed tissue in TNFR1-/- mice. Chronic colitis and tumor development was assessed in these mice using the carcinogen azoxymethane and 4 cycles of DSS. TNFR1-/- mice were protected against colorectal tumor development compared to WT and TNFR2-/- mice, while inflammation was similar between strains. Hematopoietic TNFR1 deficiency resulted in reduced inflammation and tumor incidence, while stromal/epithelial TNFR1 deficiency reduced indices of cancer without affecting inflammation. 8-OHDG was significantly lower in TNFR1-/- mice compared to other strains, suggesting that TNF could contribute to oxidative stress within the colon. Mice lacking leukocyte NADPH oxidase were protected against clinical illness and CAC despite similar histological inflammation, indicating that inflammation-associated oxidative stress can play a role in CAC. In conclusion, TNF signaling through TNFR1 contributes significantly to the development of colorectal cancer in a model of CAC in a manner that involves both stromal/epithelial and hematopoietic TNFR1. This is significant because anti-TNF therapies may be effective at reducing CAC in the absence of a clinical reduction of IBD symptoms.

Colitis

cancer

inflammatory bowel disease

animal model of colitis

tumor necrosis factor

NADPH oxidase

Role of Glucagon-like Peptide-2 and Elemental Formula in Short Bowel Syndrome – Using Neonatal Piglets as an Animal Model

Hua, Zheng

Unknown Date

No description available.

short bowel syndrome

elemental formula

glucagon-like peptide-2

animal model