MOLECULAR AND BIOCHEMICAL CHARACTERIZATION OF OLEATE- AND GLYCEROL-3-PHOSPHATE-REGULATED SIGNALING IN PLANTS

Mandal, Mihir Kumar

01 January 2012

Oleic acid (18:1), a monounsaturated fatty acid (FA), is synthesized upon desaturation of stearic acid (18:0) and this reaction is catalyzed by the plastidal enzyme stearoyl-acyl carrier protein-desaturase (SACPD). A mutation in the SSI2/FAB2 encoded SACPD lowers 18:1 levels, which correlates with induction of various resistance (R) genes and increased resistance to pathogens. Genetic and molecular studies have identified several suppressors of ssi2 which restore altered defense signaling either by normalizing 18:1 levels or by affecting function(s) of a downstream component. Characterization of one such ssi2 suppressor mutant showed that it is required downstream of low 18:1-mediated constitutive signaling and partially restores altered defense signaling in the ssi2 mutant. Molecular and genetic studies showed that the second site mutation was in the Nitric Oxide Associated (NOA) 1 gene, which is thought to participate in NO biosynthesis. Consistent with this result, ssi2 plants accumulated high levels of NO and showed an altered transcriptional profile of NO-responsive genes. Interestingly, the partial defense phenotypes observed in ssi2 noa1 plants were completely restored by an additional mutation in either of the two nitrate reductases NIA1 or NIA2. This suggested that NOA1 and NIA proteins participated in NO biosynthesis in an additive manner. Biochemical studies showed that 18:1 physically bound NOA1, in turn leading to its degradation in a protease-dependent manner. In concurrence, overexpression of NOA1 did not promote NO-derived defense signaling in wild-type plants unless 18:1 levels were lowered. Subcellular localization showed that NOA1 and the 18:1-synthesizing SSI2 were present in close proximity within the nucleoids of chloroplasts. Indeed, pathogen- or low 18:1- induced accumulation of NO was primarily detected in the chloroplasts and their nucleoids. Together, these data suggested that 18:1 levels regulate NO synthesis and thereby NO-mediated retrograde signaling between the nucleoids and the nucleus. Since cellular pools of glycerol-3-phosphate (G3P) regulate 18:1 levels, I next analyzed the relationship between G3P and 18:1. Interestingly, unlike 18:1, an increased G3P pool was associated with enhanced systemic immunity in Arabidopsis. This was consistent with G3P-mediated transcriptional reprogramming in the distal tissues. To determine mechanism(s) underlying G3P-conferred systemic immunity, I analyzed the interaction between G3P and a lipid transfer protein (LTP), DIR1. In addition, I monitored localization of DIR1 in both Arabidopsis as well as tobacco. Contrary to its predicted apoplastic localization, DIR1 localized to endoplasmic reticulum and plasmodesmata. The symplastic localization of DIR1 was confirmed using several different assays, including co-localization with plasmodesmatal-localizing protein, plasmolysis and protoplast-based assays. Translocation assays showed that G3P increased DIR1 levels and translocated DIR1 to distal tissues. Together, these results showed that G3P and DIR1 are present in the symplast and their coordinated transport into distal tissues is likely essential for systemic immunity. In conclusion, this work showed that low 18:1-mediated signaling is mediated via NO, synthesis of which is likely initiated in the plastidal nucleoids. In addition, my work shows that G3P functions as an independent signal during systemic signaling by mediating translocation of the lipid transfer protein, DIR1.

Oleic acid

Glycerol 3 phosphate

Nitric oxide

Nucleoid

Lipid transfer protein

Plant Pathology

Plant Sciences

Nitric oxide signalling in the basolateral complex of the amygdala: an extension of NMDA receptor activation during Pavlovian fear conditioning and expression

Overeem, Kathie

January 2006

N-methyl-D-asparate (NMDA) receptors located within the basolateral complex of the amygdala are required for the consolidation and expression of Pavlovian conditioned fear. The events downstream of receptor activation that mediate these processes are not well defined. An intermediate step that may be of significance is the synthesis of the gas nitric oxide (NO). Nitric oxide is synthesised as a result of NMDA receptor activation and acts as an unconventional neurotransmitter freely diffusing across cell membranes interacting with its targets in a non-synaptic manner. The targets of NO include cellular components that play significant roles during the consolidation of conditioned fear and the neurotransmission associated with its expression. This implies that NO may be an important intermediary of NMDA receptor activation and both these processes. The current study sought to examine this possibility using fear potentiated startle to examine the expression of learned fear. Three experiments were conducted, fifty rats received intra-BSC microinfusions of the global nitric oxide synthase inhibitor L-NAME either prior to fear conditioning, fear testing, or examination of the shock sensitization of the acoustic startle affect. The results indicated that NO was indeed required for both the consolidation and expression of learned fear, whereas it was not required for shock enhanced startle responding. This study provides new information about the sub-cellular basis of conditioned fear, and highlights the pivotal role played by NO in processes associated with conditioned fear.

Nitric oxide

Pavlovian Fear conditioning

Fear expression

Amygdala

Nitric Oxide Signaling through Soluble Guanylate Cyclase

Hu, Xiaohui

January 2008

Soluble guanylyl/guanylate cyclase (sGC), the primary receptor for nitric oxide (NO), is a heme containing heterodimeric enzyme involved in numerous physiological events in animals. The small molecule YC-1 stimulates sGC, but the mechanism behind and the location of binding are unknown. I have developed a prokaryotic expression system for insect ( <italic>Manduca sexta</italic>) sGC. The recombinant holoenzyme, like its mammalian counterpart, is responsive to NO, CO and YC-1, displaying a 175-fold increase in activity on binding. Truncated constructs containing the N-terminal two-thirds of both subunits (msGC-NT) were designed to facilitate expression. With the highly pure material, we investigated NO and CO binding, reaction kinetics and regulation. Binding of NO to msGC-NT heme forms a six-coordinate intermediate followed by release of the proximal histidine to yield a five-coordinate nitrosyl complex. The conversion rate is insensitive to nucleotides, YC-1 and changes in NO concentration up to ~30 micromolar. In contrast, NO release from msGC-NT is biphasic in the absence of YC-1, while binding of YC-1 eliminates the fast phase but has little effect on the slower phase. CO binding to msGC-NT is also regulated by YC-1. The CO release rate is reduced by YC-1 while the on rate remains unchanged, which leads to an ~50-fold increase in binding affinity. YC-1 binding leads to a substantial geminate recombination of CO to msGC-NT upon photolysis. Our data are consistent with a model for allosteric activation in which (1) YC-1 binds away from the catalytic site and (2) sGC undergoes a conformational switch between two states of an open and a closed heme pocket. The final catalysis results from the integration of the influence of numerous allosteric effectors on the equilibrium between these two states.<italic>S </italic>-nitrosoglutathione (GSNO) exists <italic>in vivo </italic> and plays important roles in NO signaling. We have developed a model cell line, in which inducible NO synthase and human sGC genes were included. GSNO stimulation of sGC has been investigated using recombinant insect and human enzymes. GSNO can activate sGC as efficiently as gaseous NO, but apparently with a distinct mechanism. GSNO or endogenous NO could <italic>S </italic>-nitrosylate sGC, which might regulate the enzyme function.

cGMP

kinetics

ligand-recptor interaction

nitric oxide

signaling

soluble guanylate cyclase

Role of Angiotensin II, Glutamate, Nitric Oxide and an Aldosterone-ouabain Pathway in the PVN in Salt-induced Pressor Responses in Rats

Gabor, Alexander

13 June 2012

High salt intake contributes to the development of hypertension in salt-sensitive humans and animals and the mechanistic causes are poorly understood. In Dahl salt-sensitive (S) but not salt-resistant (R) rats, high salt diet increases cerebrospinal fluid (CSF) [Na+] and activates an aldosterone-mineralocorticoid receptor-epithelial sodium channel-endogenous ouabain (MR-ENaC-EO) neuromodulatory pathway in the brain that enhances the activity of sympatho-excitatory angiotensinergic and glutamatergic pathways, leading to an increase in sympathetic nerve activity (SNA) and blood pressure (BP). We hypothesize that high salt diet in Dahl S rats enhances Ang II release in the paraventricular nucleus (PVN), causing a decrease in local nitric oxide (NO) action and an increase in local glutamate release thereby elevating SNA, BP and heart rate (HR). The present study evaluated the effects of agonists or blockers of MR, ENaC, EO, nitric oxide synthase (NOS) or glutamate and AT1-receptors on the BP and HR responses to acute infusions of Na+ rich aCSF, intracerebroventricularly (icv), or in the PVN of Dahl S, R or Wistar rats or to high salt diet in Dahl S and R rats. In Wistar rats, aldosterone in the PVN enhanced the BP and HR responses to infusion of Na+ rich aCSF in the PVN, but not in the CSF, and only the enhancement was prevented by blockers of MR, ENaC and EO in the PVN. AT1-receptor blockers in the PVN fully blocked the enhancement by aldosterone and the responses to infusion of Na+ rich aCSF icv, or in the PVN. Na+ rich aCSF in the PVN caused larger increases in BP and HR in Dahl S vs. R rats and the responses to Na+ were fully blocked by an AT1-receptor blocker in the PVN. BP and HR responses to a NOS blocker in the PVN were the same, but L-NAME enhanced Na+ effects more in Dahl R than S rats. High salt diet attenuated increases in BP from L-NAME in the PVN of Dahl S but not R rats. AT1 and glutamate receptor blockers candesartan and kynurenate in the PVN decreased BP in Dahl S but not R rats on high salt diet. At the peak BP response to candesartan, kynurenate in the PVN further decreased BP whereas candesartan did not further decrease BP at the peak BP response to kynurenate. Our findings indicate that both an acute increase in CSF [Na+] and high salt intake in Dahl S rats increases AT1-receptor activation and decreases NO action in the PVN thereby contributing to the pressor responses to Na+ and presumably, to dietary salt-induced hypertension. The increased BP response to AT1-receptor activation in the PVN of Dahl S is mediated by enhanced local glutamate receptor activation. An MR-ENaC-EO pathway in the PVN can be functionally active and further studies need to assess its role in Dahl S rats on high salt intake.

Aldosterone

Ouabain

angiotensin II

glutamate

nitric oxide

paraventricular nucleus

hypertension

Dahl salt sensitive rat

Circulating Progenitor Cell Therapeutic Potential Impaired by Endothelial Dysfunction and Rescued by a Collagen Matrix

Marier, Jenelle

26 July 2012

Angiogenic cell therapy is currently being developed as a treatment for coronary artery disease (CAD); however, endothelial dysfunction (ED), commonly found in patients with CAD, impairs the ability for revascularization to occur. We hypothesized that culture on a collagen matrix will improve survival and function of circulating progenitor cells (CPCs) isolated from a mouse model of ED. Overall, ED decreased the expression of endothelial markers in CPCs and impaired their function, compared to normal mice. Culture of CPCs from ED mice on collagen was able to increase cell marker expression, and improve migration and adhesion potential, compared to CPCs on fibronectin. Nitric oxide production was reduced for CPCs on collagen for the ED group; however, CPCs on collagen had better viability under conditions of serum deprivation and hypoxia, compared to fibronectin. This study suggests that a collagen matrix may improve the function of therapeutic CPCs that have been exposed to ED.

coronary artery disease

circulating progenitor cells

endothelial dysfunction

nitric oxide

collagen matrix

Differential Activation of Nitrergic Neurons in the Dorsal Raphe Nucleus of Acute Restraint Stressed Male Rats

Nichols, India S

13 December 2016

The Dorsal Raphe Nucleus (DRN) is a complex brain region that has been implicated in disorders such as anxiety and depression. The DRN is divided into subregions through its rostrocaudal and mediolateral axis. It has been reported that after a single restraint session there is differential spatial activation of nitric oxide synthase (NOS) across the DRN. The temporal profile of NOS activity during acute stress is not known but it is important because duration of acute stress is associated with different general responses. In this report rats were restrained for 1, 3, or 6 hours and nicotinamide adenine phosphate diaphorase (NADPH-d) was stained as an index to NOS activity to determine the spatio-temporal profile of NOS throughout a 6 hour restraint. Astrocyte reactivity was also measured to determine whether NOS activation correlated with GFAP expression since astrocytes react to neural activity and store and release l-arginine, the precursor for nitric oxide production. The results showed that the DRN had a dynamic response to acute restraint stress, most notably in the caudal lateral wings where activation increased after 3 hours of restraint (p = > 0.001) but neuron count decreased after 6 hours (p = 0.040). Astrocytes did not correlate with NOS activation but they showed spatio-temporal differences as well whereas they were more active in the rostral half of the DRN. In conclusion, the present study suggests that NOS produced in the DRN may have a role in prolonged exposure to acute stress and that subregions show differential NOS activation.

stress

nitric oxide

synthase

dorsal raphe nucleus

NADPH-d

Biology

Neuroscience and Neurobiology

Nitric oxide : a chemical effector of pathogenesis in Magnaporthe oryzae

Johnson, Jasper R. P.

January 2011

Research detailed in this thesis investigated the generation of Nitric Oxide (NO) and its role in the pathogenesis of the rice blast fungus Magnaporthe oryzae. Two putative nitric oxide synthase genes and single copy nitrate and nitrite reductase genes were cloned as potential sources of NO in M. oryzae. Single and double gene disrupted mutants were generated and their phenotypes assessed. Detection of NO is problematic. Herein, a fluorescent plate reader assay was developed, exploiting the NO sensitive dye DAR-4M AM and the NO scavenger PTIO, to compare wildtype NO generation with the mutant strains. All strains were assessed for infection-related development on an artificial surface inductive to appressorium formation and maturation in the wildtype strain. Appressorium formation in the presence of PTIO and the NO donor DETANONOate was recorded for all strains on this surface. The pathogenicity of the wildtype and mutant strains were assessed, in terms of their ability to infect rice and barley plants. Finally, the capacity of each strain to metabolise nitrogen was evaluated to confirm the disruption of the nitrate and nitrite reductase genes. Collectively, the data demonstrate that the plate reader assay provides robust evidence for the generation of NO in M. oryzae. However, none of the various mutant strains showed a reduction in NO emission during germling morphogenesis. However, they exhibited significantly different infection-related development on an inductive artificial surface as compared with the wildtype strain. Moreover, exogenous application of PTIO to the wildtype strain provided evidence for NO and its involvement in germination and appressorium development. No significant differences in the infection of rice and barley leaves were observed between the wildtype and mutant strains, indicating their disrupted genes are dispensable for pathogenesis. The nitrate and nitrite reductase genes were found to be essential for nitrate assimilation. In summary, this work provides the most robust evidence for the generation of NO in fungi to-date, but the molecular mechanism underpinning the generation of NO in M. oryzae remains elusive.

572

The role of plasma and vascular tetrahydrobiopterin in vascular disease states

Cunnington, Colin

January 2011

The endothelial nitric oxide synthase (eNOS) co-factor tetrahydrobiopterin (BH4) has been shown to play a pivotal role in maintaining endothelial function in experimental vascular disease models. In BH4-deficient states, eNOS becomes enzymatically ‘uncoupled’, generating reactive oxygen species instead of nitric oxide, thus promoting endothelial dysfunction. In humans with coronary artery disease (CAD), higher vascular BH4 levels have been shown to be associated with improved endothelial function, and genetic variation in endogenous BH4 synthesis has implicated a causal role. Accordingly, BH4 has been proposed as a potential therapeutic target in vascular disease states. The work in this thesis aims to further elucidate the roles of exogenous and endogenous BH4 in humans. In a randomised, placebo-controlled clinical trial of oral BH4 therapy in patients with CAD, exogenous BH4 had no effect on endothelial function or vascular oxidative stress. Subsequent pharmacokinetic and pharmacodynamic analysis revealed that oral BH4 significantly augmented BH4 levels in plasma and in venous tissue (but not in arterial tissue), but also increased levels of the oxidation product dihydrobiopterin (BH2), which lacks eNOS cofactor activity. Thus, there was a null effect on overall biopterin redox status. To further understand the mechanics of exogenous BH4 oxidation, ex vivo studies of human blood and vascular tissue demonstrated that exogenous BH4 is very rapidly oxidised to BH2; co-administration with an antioxidant had only a modest effect on preventing BH4 oxidation in blood, with no beneficial effect on biopterin redox state in the vasculature. Finally, using a “Mendelian randomisation” approach, I studied the effects of a haplotype of GCH1 (the gene encoding the rate limiting enzyme in BH4 synthesis) on endogenous BH4 bioavailability and vascular function in healthy individuals. In patients with CAD, this haplotype has been associated with decreased BH4 bioavailability and eNOS uncoupling, however in healthy individuals the haplotype exerted no significant effect, likely due to reduced inflammatory stimulation of GCH1.

616.12306

Assessment Of Surface-CatalyzedReaction Products From HighTemperature Materials In Plasmas

Allen, Luke Daniel

01 January 2016

Current simulations of atmospheric entry into both Mars and Earth atmospheres for the design of thermal protections systems (TPS) typically invoke conservative assumptions regarding surface-catalyzed recombination and the amount of energy deposited on the surface. The need to invoke such assumptions derives in part from lack of adequate experimental data on gas-surface interactions at trajectory relevant conditions. Addressing this issue, the University of Vermont's Plasma Test and Diagnostics Laboratory has done extensive work to measure atomic specie consumption by measuring the concentration gradient over various material surfaces. This thesis extends this work by attempting to directly diagnose molecular species production in air plasmas. A series of spectral models for the A-X and B-X systems of nitric oxide (NO), and the B-X system of boron monoxide (BO) have been developed. These models aim to predict line positions and strengths for the respective molecules in a way that is best suited for the diagnostic needs of the UVM facility. From the NO models, laser induced fluorescence strategies have been adapted with the intent of characterizing the relative quantity and thermodynamic state of NO produced bysurface-catalyzed recombination, while the BO model adds a diagnostic tool for the testing of diboride-based TPS materials. Boundary layer surveys of atomic nitrogen and NO have been carried out over water-cooled copper and nickel surfaces in air/argon plasmas. Translation temperatures and relative number densities throughout the boundary layer are reported. Additional tests were also conducted over a water-cooled copper surface to detect evidence of highly non-equilibrium effects in the form of excess population in elevated vibrational levels of the A-X system of NO. The tests showed that near the sample surface there is a much greater population in the v'' = 1ground state than is predicted by a Boltzmann distribution.

air plasma

Laser Induced Fluorescence

nitric oxide

spectroscopy

surface recombination

Aerospace Engineering

Mechanical Engineering

THE INFLUENCES OF MATRIX METALLOPROTEINASE-1 EXPRESSION ON GLIOBLASTOMA PATHOLOGY

Pullen, Nicholas

30 March 2010

Glioblastoma multiforme (GBM) is an aggressive central nervous system (CNS) cancer characterized by enhanced tumor cell motility, pernicious invasion into the normal brain, extensive tumor-induced angiogenesis, and adaptive resistance to current therapeutic paradigms. One of the difficulties associated with GBM is the ability of the tumor cells to infiltrate normal CNS tissue. Neurosurgeons can remove the primary tumor mass, but peripheral cells that are inaccessible will ultimately result in a secondary lesion that can lead to death. The matrix metalloproteinases (MMP) are well known for their abilities to facilitate processes of cellular motility and invasion through their clearance of extracellular matrix (ECM). A specific member of this family, MMP-1, is not observed in normal brain, yet its expression is a common characteristic of GBM. The various causes of MMP-1 expression, and its consequences in GBM cells are unknown. As such, functional studies were conducted related to the induction of MMP-1 expression via another molecule intrinsic to GBM, nitric oxide (NO). The exposure of GBM cell lines to nanomolar concentrations of NO produced significant inductions of MMP-1 expression and GBM cell motility. The specific removal of MMP-1 with siRNA elicited an abrogation of NO-stimulated motility, suggesting a pathological contribution by this enzyme. Furthermore, recent accumulating evidence suggests that MMP-1 contributes to tumor cell survival and related angiogenesis in other cancer settings. To investigate these capabilities in GBM, cell lines were stably engineered to have either MMP-1 over-expression or knock-down. Both tumor formation and size were significantly reduced with MMP-1 knock-down and significantly increased with over-expression. In a model of GBM cell-induced angiogenesis, the presence of MMP-1 contributed to an angiogenic phenotype. Further angiogenesis studies revealed a significant recruitment of host endothelium to the tumor interstitium in vivo. Proteomic studies suggest that one mechanism by which MMP-1 could influence angiogenesis is through the easement of the anti-angiogenic tissue inhibitor of metalloproteinases-4 (TIMP-4), since the removal of MMP-1 elicits a significant increase in TIMP-4 detection. Altogether, these functional data present MMP-1 as a promising target for future therapeutic investigation, because it is unique to the GBM environment and contributes to key overlapping GBM pathologies.

glioblastoma multiforme

matrix metalloproteinase

nitric oxide

Anatomy

Medicine and Health Sciences

Nervous System