Browsing by Subject "Health Sciences, Pharmacology"
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Item Open Access Adolescent Response to THC: Greater Learning Impairment and Lesser Cannabinoid CB1 Receptor Desensitization in Adolescents than Adults.(2009) Moore, NicoleAdolescence is a behaviorally well-defined developmental period during which experimentation with illicit drugs such as marijuana is common. While the lasting effects of adolescent marijuana use have been studied in humans and in animal models, relatively little is known about the acute response to marijuana in adolescents. It is known that adolescent rats are more impaired by the psychoactive ingredient in marijuana, delta-9 tetrahydrocannabinol (THC), than adults in a water maze spatial learning task. However, what causes this greater sensitivity to THC-induced learning impairment is not understood. We characterized adolescent (postnatal day 30-35) and adult (postnatal day 70-75) rat cannabinoid CB1 receptor number, distribution, and functional coupling in the hippocampus, the brain which may be the site at which THC impairs spatial learning impairment. Next, we elucidated the time course of hippocampal CB1 receptor desensitization in adolescents and adults in response to daily treatment with 10 mg/kg THC. Finally, we characterized the development of tolerance to the learning impairment caused by THC in adolescent and adult rats by pre-treating them for five days with 10 mg/kg THC, and measuring learning performance in the Morris water maze. Our results indicate that agonist stimulation of the CB1 receptor in adolescent hippocampus produces less functional coupling to G proteins than adults. Also, adolescent hippocampal CB1 receptors desensitize less rapidly in response to 10 mg/kg THC treatment than those in adults. Finally, adolescent rats do not become tolerant to the learning impairment effects of 10 mg/kg THC after five days of pre-treatment, while adults do. We conclude that adolescents may be more impaired by THC than adults as a result of more slowly desensitizing hippocampal CB1 receptors, which may be due to
lesser functional CB1-G protein coupling in adolescents.
Item Open Access Adolescent Vulnerabilities to Cocaine: Assessing Locomotor and Transcriptional Responses to Acute Cocaine and Cocaine-Induced Behavioral Plasticity During Adolescence.(2008-05-27) Caster, JosephAdolescence is a critical period for drug addiction in humans. Most lifelong drug addiction is initiated during adolescence and the progression from initial drug use to the expression of addictive behaviors occurs more rapidly during adolescence than in adulthood. The purpose of this work was to examine if the adolescent brain uniquely responds to the addictive stimulant cocaine. This was accomplished by comparing the following measures in adolescent and adult male rats: locomotor responses to cocaine across a range of doses in two acute cocaine binge models, plasma cocaine and brain concentrations, locomotor responses to apomorphine, the relative magnitude of locomotor sensitization induced by a single high dose of cocaine (40 mg/kg), and cocaine-induced c-fos and zif268 expression. We determined that young adolescent (PN 28) rats had greater stereotypy responses to all doses of a repeated dose cocaine binge (15 mg/kg), the highest dose of an escalating dose binge (25 mg/kg), and low dose apomorphine. In addition to showing exaggerated acute locomotor responses to cocaine, young adolescents demonstrated a form of intrabinge sensitization that was absent in adults. Exaggerated adolescent locomotor responses could not be attributed to cocaine metabolism as we did not observe greater cocaine plasma or brain concentrations in adolescents compared to adults. A single high dose of cocaine (40 mg/kg) induced more ambulatory and stereotypy sensitization in young adolescents than adults. Further, the magnitude of the acute locomotor response to cocaine predicted the magnitude of locomotor sensitization in individual adolescents. We also showed that cocaine dose-dependently caused age-specific increases in the expression of the plasticity-associated immediate early genes c-fos and zif268: low dose (10 mg/kg) cocaine caused greater increases in striatal c-fos expression in adolescents whereas high dose (40 mg/kg) cocaine caused greater increases in striatal c-fos and zif268 expression in adults. Both doses of cocaine stimulated bigger increases in cortical zif268 expression in adults compared to adolescents. Finally, we demonstrated that the coordinated expression of striatal c-fos and zif268 develops during adolescence: there was no correlation between striatal c-fos and zif268 expression in individual adolescents but a strong correlation was seen in adults. The results of these experiments demonstrate that adolescents have unique molecular responses to acute cocaine and may help explain how adolescents show unique adaptive changes following continued cocaine use.
Item Open Access Akt, Glucose Metabolism, and the Bcl-2 Family(2010) Coloff, Jonathan LouisNormal cells require input from extrinsic growth factors to control proliferation and survival. Recent studies have demonstrated that these same extrinsic signals also regulate cellular metabolism to ensure that metabolism adequately supports the demands of cell function, proliferation, and cell survival. The PI3K/Akt pathway is downstream of many growth factors and can promote both glucose metabolism and cell survival. Aberrant activation of the PI3K/Akt pathway is common in cancer, and its activation can contribute to the growth factor independence that is a hallmark of neoplastic cells. Metabolic demand is high in stimulated and leukemic T cells, and activation of Akt can increase glucose metabolism to meet these requirements. There is great interest in targeting the unique metabolism of cancer cells for cancer therapy, thus making an understanding of the interaction of metabolism and cell death essential.
Akt is also anti-apoptotic and can inhibit cell death by regulating members of the Bcl-2 family. Interestingly, the ability of Akt to prevent cell death is inextricably linked to its metabolic function. Several recent studies have demonstrated that glucose metabolism can affect Bcl-2 to family members to promote cell survival, but the role of Akt-dependent glucose metabolism in the regulation of Bcl-2 family members is not understood. Using a model of growth factor withdrawal-induced apoptosis, we show that Akt prevents cell death by maintaining glucose metabolism to regulate the Bcl-2 family members Puma and Mcl-1, and demonstrate the importance of this pathway in the survival of stimulated T lymphocytes and leukemia.
After growth factor withdrawal, active Akt suppressed Puma induction in abundant glucose, but Puma was rapidly upregulated in glucose-deficient conditions and was necessary and sufficient to promote efficient cell death. Importantly, glucose was not uniquely required, as provision of alternative mitochondrial fuels allowed Akt to suppress Puma and maintain survival. This metabolic regulation of Puma was mediated through partially p53-dependent transcriptional induction as well as control of Puma protein stability.
In addition to inhibiting Puma expression, active Akt prevented the loss of Mcl-1 after growth factor withdrawal by sustaining Mcl-1 protein synthesis in a glucose-dependent manner. Mcl-1 was essential for preventing Bim-induced apoptosis, as Akt could not inhibit Bim induction after growth factor deprivation. Slowing of Mcl-1 synthesis by inhibiting glucose metabolism reversed Mcl-1-mediated resistance of leukemic cells to the Bcl-2 inhibitor ABT-737. Importantly, Akt and glucose-reliant Mcl-1 expression required mTOR-dependent phosphorylation of 4EBP, and treatment with mTOR inhibitors also reversed ABT-737 resistance.
Together, this study demonstrates that Akt promotes cell survival by preventing metabolic checkpoints that stimulate Puma expression and stability and inhibit Mcl-1 synthesis, advancing our understanding of the links between metabolism and cell death. These studies highlight the importance of cellular metabolism--including a potential role for the alternative sugar fructose--in cancer cell survival that may provide a mechanistic understanding to drive development of metabolism-targeted cancer therapies.
Item Open Access Development of Novel Antidote Controlled Antithrombotic Aptamers(2008-04-23) Oney, SabahThrombosis is initiated by platelets and leads to cardio-, cerebro-, and peripheral vascular disease, the leading causes of morbidity and mortality in the western world. Antiplatelet drugs have improved clinical outcomes for thrombosis patients. However, their expanded use is limited by hemorrhage at high concentrations and sub-therapeutic activity at lower doses. Thus, development of new antiplatelet agents with improved safety and efficacy is a medical priority. VWF is a multimeric plasma glycoprotein that plays a critical role in platelet-mediated thrombus formation and presents an attractive target for antiplatelet therapy. To this end, I have isolated and characterized aptamer molecules that bind to VWF with high affinity and have shown that some of these aptamer molecules could inhibit platelet activation/aggregation in vitro and in vivo. Furthermore, I designed antidote molecules that can reverse the effects of the aptamer molecules, restoring platelet function quickly and effectively. This project has yielded the first antidote controlled antiplatelet agent and may lead to significant improvements in thrombosis therapy. Thrombin is a plasma protein that plays a critical role in thrombosis. Currently, available antithrombin agents are efficacious in preventing coagulation but do not significantly affect platelet activation and aggregation, both essential components of thrombus formation. Therefore, I tested two aptamer molecules that bind to mutually exclusive exosites on thrombin and, when used together, synergistically inhibit both coagulation and platelet activation. I demonstrated that this method could potentially lead to the development of effective antithrombotic therapies. With an ever-increasing number of people taking multiple medications, the need to safely administer drugs and limit unintended side effects has never been greater. Antidote control remains the most direct means to counteract acute side effects of drugs but unfortunately it has been challenging and cost prohibitive to generate antidotes for most therapeutic agents. Therefore, I described the development of a set of antidote molecules that are capable of counteracting the effects of an entire class of therapeutic agents, i.e. aptamers, including those that I generated against VWF. I demonstrated that protein and polymer-based molecules that capture oligonucleotides can reverse the activity of aptamers in vitro and in vivo.Item Open Access Distinct Functions and Regulation of Nonmuscle Myosin II Isoforms a and B in Cell Motility(2008-04-23) Sandquist, Joshua CThe ability of cells to migrate is of fundamental importance to a diverse array of biological processes, both physiological and pathological, such as development, the immune response and cancer cell metastasis, to name a few. The process of cell movement is a complicated cycle of coordinated steps involving dynamic and precise rearrangement of the actin-myosin cytoskeleton. As a critical component of the migration machinery, the molecular motor protein nonmuscle myosin II (myosin II) has long been a subject of scientific inquiry. It is now generally accepted that the contractile forces generated by myosin II contribute directly or indirectly to every step in migration. Interestingly, three isoforms of myosin II (myosin IIA, IIB and IIC) have been identified, and although each isoform performs the same basic molecular functions, recent findings suggest that the different myosin II isoforms make unique contributions to the motile process. In this dissertation work I used RNA interference technology to specifically deplete cells of myosin IIA and IIB in order to characterize the distinct migration phenotypes associated with loss-of-function of each individual isoform. Surprisingly, I found that the two myosin II isoforms perform not only distinct but opposing functions in cell migration, with myosin IIA and IIB normally inhibiting and facilitating proper cell movement, respectively. Furthermore, using pharmacological and microscopy techniques, I investigated the cellular mechanisms allowing for isoform-specific function. My results provide evidence for at least two isoform-specific regulatory mechanisms, namely selectivity in signaling pathways and subcellular distribution. A particularly significant finding is the identification of the different assembly properties of myosin IIA and IIB as the key element responsible for directing isoform-distinct distribution. Together the data presented herein represent a considerable advance in our understanding of the distinct functions and regulation of myosin II in cell motility.
Item Open Access Pyruvate Cycling Pathways and Glucose-Stimulated Insulin Secretion in Pancreatic Beta Cells(2008-02-11) Ronnebaum, Sarah MariePancreatic β-cells secrete insulin in response to glucose. Intracellular glucose metabolism drives a cascade of events, including ATP production, calcium influx, and insulin processing, culminating in insulin granule exocytosis. However, insulin secretory mechanisms are incompletely understood. β-cells have the capacity to flow pyruvate into the TCA cycle via the anaplerotic enzyme pyruvate carboxylase to engage one of several pathways of pyruvate recycling. Previous work demonstrated that pyruvate cycling was correlated with insulin secretion, and that NADPH may be involved in granule exocytosis. We hypothesized that NADPH-producing cytosolic enzymes isocitrate dehydrogenase (ICDc) and malic enzyme (MEc) may be involved in both pyruvate cycling and insulin secretion. ICDc expression was reduced using siRNA in the INS-1 derived cell line 832/13 and in isolated rat islets, which led decreased glucose-stimulated insulin secretion (GSIS), pyruvate cycling, and NADPH. Organic acid profiling revealed that decreased pyruvate cycling was compensated by an increase in lactate and stable pyruvate levels. This work established an important role for ICDc in maintaining GSIS through pyruvate-isocitrate cycling. MEc expression was reduced using siRNA in two β-cell lines, 832/13 and 832/3, as well as isolated rat islets. MEc suppression inhibited GSIS in the 832/13 cells only, and these effects were not due to changes in pyruvate cycling, NADPH, or the organic acid profile. This suggests that in normal β-cells, MEc does not participate in pyruvate cycling. Acetyl CoA carboxylase 1 (ACC1) is essential in de novo lipogenesis, which has been implicated in GSIS by other laboratories. Chronic, but not acute, inhibition of ACC1 via siRNA reduced insulin secretion independent of lipogenesis. ACC1 siRNA decreased glucose oxidation, pyruvate cycling, and ATP:ADP, due to an unexpected decrease in glucokinase protein. This work questions the use of ACC inhibitors in obesity and diabetes therapy. In summary, these studies on ICDc, MEc, and ACC1, coupled with concurrent work in our laboratory, eliminate two potential pyruvate cycling pathways (pyruvate-malate and pyruvate-citrate) and establish that pyruvate-isocitrate cycling is the critical pathway for control of GSIS. Future work will focus on identifying the signaling intermediate generated in the pyruvate-isocitrate pathway that links to insulin granule exocytosis.Item Open Access Role of the Type III TGF-beta Receptor Cytoplasmic Domain in Breast Cancer Progression(2009) Lee, Jason DoleBreast cancer remains among the most common cancers of the developed world. Despite advances in treatment modalities, deaths due to breast cancer are the second leading cause of cancer death among women. The transforming growth factor-beta (TGF-β) pathway is an important modulator of breast cancer progression, acting in a tumor suppressing fashion in early carcinogenesis but switching in a poorly understood fashion to a promoter of cancer progression in later stages. Mutations and loss of function of TGF-β components are common across a variety of cancers. In particular, the expression of the type III TGF-β receptor (TβRIII) is decreased with cancer grade and clinical progression in prostate, lung, ovarian, and pancreatic cancers. In an effort to enhance our understanding of the biology of TGF-β on carcinogenesis, this dissertation looks at the role of TβRIII in breast cancer progression.
Through an examination of clinical specimens, loss of TβRIII was seen at both the message and protein levels with increasing tumor grade. Analysis of correlated patient outcomes showed that low TβRIII expression was predictive of a shorter time to recurrence, demonstrating clinical relevance for TβRIII expression. The contribution of TβRIII to tumor progression was further examined by examining known TGF-β functions, including proliferation, apoptosis, migration, and invasion. TβRIII had no effect on proliferation or apoptosis, but had a suppressive effect on metastasis in vivo, as mammary cancer cells stably expressing TβRIII that were orthotopically injected exhibited lower metatstatic burden and local invasion. In vitro, breast cancer cells exhibited suppression of migration and invasion in transwell assays. Finally, soluble TβRIII (sTβRIII) was shown to recapitulate the suppressive effects on invasion.
To further explore other potential mechanisms by which TβRIII may be mediating its tumor suppressive effects, I examined the contribution of the cytoplasmic domain of TβRIII, which is known to be critical in the regulation of TβRIII cell surface expression and downstream signaling. In vitro, I demonstrated that abrogation of the cytoplasmic domain attenuates the TβRIII-mediated suppression of migration and invasion. TβRIII's suppressive effects are also concomitant with loss of TGF-β signaling, as abrogation of the cytoplasmic domain failed to attenuate TGF-β signaling while the full length receptor was able to do so. In vivo, I also showed that in the absence of the cytoplasmic domain, TβRIII is unable to suppress metastasis and local invasion. Finally, a closer dissection of the cytoplasmic domain revealed that abolishing the interaction of TβRIII with the scaffolding protein GIPC also attenuated TβRIII's ability to dampen TGF-β signaling and invasion.
In sum, TβRIII was established as a prognostic marker for recurrence-free survival of breast cancer patients and as a suppressor of metastasis, migration, and invasion. Furthermore, several mechanisms contribute to TβRIII's tumor suppressive effects, namely the generation of sTβRIII and the interaction of TβRIII with GIPC. Taken together, these studies further demonstrate the importance of TGF-β signaling in cancer biology, elucidate mechanisms by which TβRIII suppresses breast carcinogenesis, and expand upon our understanding of the emerging roles of TβRIII in regulating tumor biology in general.
Item Open Access The Role of Gonadal Hormones in Mesencephalic Dopaminergic Systems(2008-08-11) Johnson, Misha LynetteDopamine regulates movement, cognition and the rewarding effects of addictive drugs. Sex differences mediated by gonadal hormones affect each of these processes. An extensive literature suggests that estrogen augments dopaminergic function. Our laboratory found that female rats exhibit increased locomotor stimulation in response to cocaine and greater cocaine-induced dopamine overflow compared to males, sex differences that emerge in early adulthood. Currently, the underlying mechanisms for these differences are poorly understood. I hypothesized that female rats would have more dopamine neurons in midbrain regions and that ovarian hormones would exert trophic effects on dopamine neurons. Immunohistochemical and stereological techniques were used to quantitate the number of cells in the SNpc and VTA of male and female rats and mice to assess: (1) if sex differences in dopamine neuron number exist and when they emerge, (2) how gonadal hormones influence dopaminergic cell number and dopamine-mediated behaviors (3) the role of specific hormone receptors in the effects on cell number (4) the possibility that dopamine neuron number is directly linked to cocaine-stimulated behavior and electrically-stimulated dopamine release and that these responses to cocaine are mediated through gonadal hormone modulation of midbrain dopamine neuron number. I discovered sex differences in midbrain dopamine neuron number; adult female rodents have more neurons in the SNpc and VTA. We also found that gonadectomy in adulthood reduced midbrain dopamine neuron number in females and increased neuron number in males, establishing the trophic effects of estrogen in the intact midbrain and possible suppressive effects of androgens. Treatment with agonists for estrogen receptor subtypes alpha and beta and androgen receptor reversed the effects of gonadectomy on cell number in females and males, respectively. In an effort to bridge cocaine-stimulated behavior and cell number in sham ovariectomized and ovariectomized females, we discovered cocaine-stimulated behavior, dopamine release and SNpc cell density were positively correlated in intact female rats, an effect that is lost with ovariectomy. This dissertation demonstrates that estrogen is critical for the maintenance of dopaminergic cell populations that enhance behavioral responses to psychostimulants in females, thereby contributing to the observed sex differences.