Silencing of quinolinic acid phosphoribosyl transferase (QPT) gene for enhanced production of scopolamine in hairy root culture of Duboisia leichhardtii.

Scopolamine is a pharmaceutically important tropane alkaloid which is used therapeutically in the form of an anesthetic and antispasmodic drug. The present study demonstrates enhanced scopolamine production from transgenic hairy root clones of Duboisia leichhardtii wherein the expression of quinolinate phosphoribosyl transferase (QPT) gene was silenced using the QPT-RNAi construct under the control of CaMV 35 S promoter. The RNAi hairy roots clones viz. P4, P7, P8, and P12 showed the enhanced synthesis of scopolamine with significant inhibition of nicotine biosynthesis. Optimization of culture duration in combination with methyl jasmonate elicitor in different concentrations (50 µM-200 µM) was carried out. Maximum synthesis of scopolamine had obtained from HR clones P7 (8.84 ± 0.117 mg/gm) on the 30th day of cultivation. Conspicuously, elicitation with wound-associated hormone methyl jasmonate enhanced the yield of scopolamine 2.2 fold (19.344 ± 0.275 mg/gm) compared to the culture lacking the elicitor. The transgenic hairy roots cultures established with RNAi mediated silencing of quinolinate phosphoribosyl transferase gene provides an alternative approach to increase the yield of scopolamine in fulfilling the demand of this secondary metabolite.

Hypothesis kynurenic and quinolinic acids: The main players of the kynurenine pathway and opponents in inflammatory disease.

I hypothesize that the intermediates of the kynurenine (Kyn) pathway (KP) of tryptophan (Trp) degradation kynurenic acid (KA) and quinolinic acid (QA) play opposite roles in inflammatory diseases, with KA being antiinflammatory and QA being immunosuppressant. Darlington et al. have demonstrated a decrease in the ratio of plasma 3-hydroxyanthranilic acid to anthranilic acid ([3-HAA]/[AA]) in many inflammatory conditions and proposed that this decrease either reflects inflammatory disease or is an antiinflammatory response. I argue in favour of the latter possibility and provide evidence that KA is responsible for the decrease in this ratio by increasing AA formation from Kyn through activation of the kynureninase reaction. Immunosuppression has been attributed to some Kyn metabolites tested at concentrations far greater than could occur in microenvironments. So far, only QA has been shown using immunohistochemistry to reach immunosuppressive levels. Future immune studies of the KP should focus on QA as the potentially main microenvironmentally measurable immunosuppressant and should include KA as an antiinflammatory metabolite.

Ischemic Stroke and Kynurenines: Medicinal Chemistry Aspects.

Ischemic stroke is one of the leading causes of mortality and permanent disability in developed countries. Stroke induces massive glutamate release, which in turn causes N-Methyl-D-aspartate (NMDA) receptor over-excitation and thus, calcium overload in neurons leading to cell death via apoptotic cascades. The kynurenine pathway is a complex enzymatic cascade of tryptophan catabolism, generating various neuroactive metabolites. One metabolite, kynurenic acid (KYNA), is a potent endogenous NMDA glutamate receptor antagonist, making it a possible therapeutic tool to decrease excitotoxicity and neuroinflammation. Recently, clinical investigations have shown that during the acute phase of ischemic stroke, kynurenine pathway is activated and peripheral levels of metabolites correlated with worse outcome. In this review, we set out to summarize the current literature on the connection of the kynurenine pathway and ischemic stroke and set a course for future investigations and potential drug development.

nadA and nadB of Shigella flexneri 5a are antivirulence loci responsible for the synthesis of quinolinate, a small molecule inhibitor of Shigella pathogenicity.

The evolution of bacterial pathogens from commensal organisms involves virulence gene acquisition followed by pathoadaptation to the new host, including inactivation of antivirulence loci (AVL). AVL are core ancestral genes whose expression is incompatible with the pathogenic lifestyle. Previous studies identified cadA (encoding lysine decarboxylase) as an AVL of Shigella spp. In this study, AVL of Shigella were identified by examining a phenotypic difference from its non-pathogenic ancestor, Escherichia coli. Unlike most E. coli strains, Shigella spp. are nicotinic acid auxotrophs, the pathway for the de novo synthesis of NAD being uniformly defective. In Shigella flexneri, this defect is due to alterations in the nadA and/or nadB genes encoding the enzyme complex that converts L-aspartate to quinolinate, a precursor to NAD synthesis. Quinolinate was found to inhibit invasion and cell-to-cell spread of Sh. flexneri 5a and its ability to induce polymorphonuclear neutrophil transepithelial migration. Virulence of other Shigella species was also inhibited by quinolinate. Introduction of functional nadA and nadB genes from E. coli K-12 into Sh. flexneri 5a restored its ability to synthesize quinolinate but also resulted in strong attenuation of virulence in this strain. The results define nadA and nadB as AVL in Shigella and validate the concept of pathoadaptive evolution of bacteria from commensal ancestors by inactivation of AVL. They also suggest that studies focusing on this form of bacterial evolution can identify novel inhibitors of virulence in other bacterial pathogens.

Mechanism of partial agonism at NMDA receptors for a conformationally restricted glutamate analog.

The NMDA ionotropic glutamate receptor is ubiquitous in mammalian central neurons. Because partial agonists bind to the same site as glutamate but induce less channel activation, these compounds provide an opportunity to probe the mechanism of activation of NMDA-type glutamate receptors. Molecular dynamics simulations and site-directed mutagenesis demonstrate that the partial agonist homoquinolinate interacts differently with binding pocket residues than glutamate. Homoquinolinate and glutamate induce distinct changes in the binding pocket, and the binding pocket exhibits significantly more motion with homoquinolinate bound than with glutamate. Patch-clamp recording demonstrates that single-channel activity induced by glutamate or by homoquinolinate has identical single-channel current amplitude and mean open-channel duration but that homoquinolinate slows activation of channel opening relative to glutamate. We hypothesize that agonist-induced conformational changes in the binding pocket control the efficacy of a subunit-specific activation step that precedes the concerted global change in the receptor-channel complex associated with ion channel opening.

The nadA gene of Pseudomonas fluorescens PGPR strain 267.1.

An insertion mutant of Pseudomonas fluorescens PGPR strain 267.1 was found to be auxotrophic for niacin (nicotinic acid) and could not synthesize quinolinic acid. The Tn5 interrupted gene was cloned and sequenced. The cloned fragment contained an open reading frame, nadA, capable of encoding a 359-amino-acid protein (39.0 kDa) with substantial identity to various bacterial quinolinate synthetases. The nadA gene complemented quinolinic acid synthesis deficiency and niacin auxotrophy of the P. fluorescens 106 P nadA mutant.

N-Methyl-D-aspartate receptor subtype-selectivity of homoquinolinate: an electrophysiological and radioligand binding study using both native and recombinant receptors.

Homoquinolinate, a derivative of the endogenous NMDA agonist, quinolinate, has been shown to display higher affinity for Xenopus oocytes expressing NR2A- and NR2B-containing receptors, compared to NR2C- and NR2D-containing receptors, whilst autoradiographical experiments subsequently showed that [3H]homoquinolinate labelled a subpopulation of NMDA receptors in rat brain sections, with a similar distribution to NR2B-containing receptors. In this study, we have shown that NMDA-specific [3H]homoquinolinate binding to rat brain membranes comprised 44% of total binding with a Bmax value of 5.73 pmol/mg protein, which was inhibited by NMDA with Ki=0.867 micro m. However, NMDA-specific [3H]homoquinolinate binding was not observed for a number of human recombinant NMDA receptors investigated, suggesting that there are subtle differences between the binding sites of recombinant and native receptors. Electrophysiological experiments revealed that homoquinolinate activated human recombinant NR1a/NR2A, NR1a/NR2B and NR1a/NR2A/NR2B receptors with EC50 values of 25.2, 13.8 and 9.04 micro m, respectively, with intrinsic activities of 148, 93.3 and 125%, respectively, compared to glutamate (=100%). In contrast to an autoradiographical study, these radioligand binding and electrophysiological experiments suggest that homoquinolinate is not highly selective for NR2B-containing receptors.

[3H]homoquinolinate binds to a subpopulation of NMDA receptors and to a novel binding site.

NMDA receptors mediate several important functions in the CNS; however, little is known about the pharmacology, biochemistry, and function of distinct NMDA receptor subtypes in brain tissue. To facilitate the study of native NMDA receptor subpopulations, we have determined the radioligand binding properties of [3H]homoquinolinate, a potential subtype-selective ligand. Using quantitative receptor autoradiography, NMDA-specific [3H]homoquinolinate binding selectively labeled brain regions expressing NR2B mRNA (layers I-III of cerebral cortex, striatum, hippocampus, and septum). NMDA-specific [3H]homoquinolinate binding was low in brain regions that express NR2C and NR2D mRNA (cerebellar granular cell layer, NR2C; glomerular layer of olfactory bulb, NR2C/NR2D; and midline thalamic nuclei, NR2D). In forebrain, the pattern of NMDA-specific [3H]homoquinolinate binding paralleled NR2B and not NR2A distribution. In addition to NMDA-displaceable binding, there was a subpopulation of [3H]homoquinolinate binding sites in the forebrain, cerebellum, and choroid plexus that was not displaced by NMDA or L-glutamate. In contrast, we found that the derivative of homoquinolinate, 2-carboxy-3-carboxymethylquinoline, markedly inhibited the NMDA-insensitive binding of [3H]homoquinolinate without inhibiting the NMDA-sensitive population. [3H]Homoquinolinate may be useful for selectively characterizing NR2B-containing NMDA receptors in a preparation containing multiple receptor subtypes and for characterizing a novel binding site of unknown function.

Hippocampal quinolinic acid concentrations in epileptogenesis in rats.

AIM: To study the changes of hippocampal quinolinic acid (QA) concentrations during acute and chronic seizures induced by ip injection of kainic acid (KA, 12 mg kg-1) in rats. METHODS: The extraction and measurement of QA in the hippocampus were performed using a gas chromatography-mass spectrometry method. RESULTS: When acute seizures were fully established 3 h after KA injection, no significant changes of hippocampal QA were found. During chronic seizures observed on d 30 after KA injection, there was even a 55 +/- 8% significant decrease. When neither acute nor chronic seizures were detectable but astroglial proliferation in the hippocampus and secondary neuronal degeneration in extrahippocampal regions became gradually prominent 2 d and 7 d after KA injection, there were 56 +/- 13% and 156 +/- 13% dramatic increases of hippocampal QA concentrations, respectively. CONCLUSION: The increase of hippocampal QA hardly plays any key role in the initiation of KA-induced seizures but may contribute to astroglial proliferation and neuronal degeneration by activation of N-methyl-D-aspartate receptors.

[Biochemical studies on AIDS dementia complex--possible contribution of quinolinic acid during brain damage].

AIDS dementia complex (ADC) is a complex, progressive neuropsychiatric syndrome seen in 60-70% of the patients with AIDS. The structural and functional changes associated with ADC may be the result of a variety of indirect mechanisms mediated via activated brain cells or/and virus that produce neurotoxins including N-methyl-D-aspartate receptor agonist (eg, quinolinic acid, glutamate), cytokines, gp 120 and nitric oxide. The level of the neurotoxin and kynurenine pathway metabolite, quinolinic acid, is increased in the brain and CSF of HIV-1-infected patients, and is correlated with quantitative measures of neurologic impairment. Importantly, increased CSF and brain levels of QUIN also occur in other inflammatory neurologic diseases (bacterial, viral, fungal and parasitic infections, meningitis, autoimmune diseases and septicemia), independent of HIV-1 infection. Therefore, QUIN and other neuroactive kynurenine pathway metabolites may be final common mediators of neurologic dysfunction in a broad spectrum of inflammatory neurologic diseases. Conversion of L-tryptophan to QUIN has also been demonstrated in vitro in both brain tissue following macrophage infiltration, and in macrophages stimulated by interferon-gamma or HIV infection. Macrophages in vitro have a high capacity to synthesize QUIN following exposure to interferon-gamma, tumor necrosis factor-alpha, IL-1 beta and IL-6, compared to cells derived from other tissues. Notably, the concentrations achieved in the macrophage incubates exceeded the levels found in the CNS of HIV-1-infected patients, and exceeded the concentrations shown to be neurotoxic in vitro. We hypothesize that increased kynurenine pathway metabolism following inflammation reflects the presence of macrophages and other reactive cell populations at the site of brain infection. Strategies to attenuate the neurotoxic effects of kynurenines, such as inhibitors of kynurenine pathway metabolism and cytokine antibodies may offer new approaches to therapy.

Neuropharmacology of quinolinic and kynurenic acids.

In a little more than 10 years, the kynurenine metabolites of tryptophan have emerged from their former position as biochemical curiosities, to occupy a prominent position in research on the causes and treatment of several major CNS disorders. The pathway includes two compounds, quinolinic acid and kynurenic acid, which are remarkably specific in their pharmacological profiles: one is a selective agonist at receptors sensitive to NMDA, whereas the other is a selective antagonist at low concentrations at the strychnine-resistant glycine modulatory site associated with the NMDA receptor. It has been argued that these agents cannot be of physiological or pathological relevance because their normal extracellular concentrations, in the nanomolar range, are at least 3 orders of magnitude lower than those required to act at NMDA receptors. This is a facile argument, however, that ignores at least two possibilities. One is that both quinolinate and kynurenate may be present in very high concentrations locally at some sites in the brain that cannot be reflected in mean extracellular levels. Similar considerations apply to many neuroactive agents in the CNS. The fact that both compounds appear to be synthesised in, and thus emerge from, glial cells that are well recognised as enjoying a close physical and chemical relationship with some neurones in which the intercellular space may be severely restricted may support such a view. Certainly the realisation that NMDA receptors may not be fully saturated functionally with glycine would be consistent with the possibility that even quite low concentrations of kynurenate could maintain a partial antagonism at the glycine receptor. A second possibility is that there may be a subpopulation of NMDA receptors (or, indeed, for a quite different amino acid) that possesses a glycine modulatory site with a much lower sensitivity to glycine or higher sensitivity to kynurenate, making it more susceptible to fluctuations of endogenous kynurenine levels. Whatever the specific nature of their physiological roles, the presence of an endogenous selective agonist and antagonist acting at NMDA receptors must continue to present exciting possibilities for understanding the pathological basis of several CNS disorders as well as developing new therapeutic approaches. An imbalance in the production or removal of either of these substances would be expected to have profound implications for brain function, especially if that imbalance were present chronically.(ABSTRACT TRUNCATED AT 400 WORDS)

Virus isolation and quinolinic acid in primary and chronic simian immunodeficiency virus infection.

OBJECTIVE: In this 2.5-year study of simian immunodeficiency virus (SIVsm) infection in rhesus monkeys, quinolinic acid (QUIN) levels and virus isolation determinations were made in serial cerebrospinal fluid (CSF) and blood samples to evaluate the relationship between these parameters over the course of infection. METHODS: Eight rhesus monkeys were inoculated in the saphenous vein with SIVsm. Four animals were maintained as uninoculated controls. CSF and blood samples were obtained every 1-4 weeks over the course of study. SIV isolation was determined in H9 cells for the CSF and in primary rhesus lymphocyte co-cultures for peripheral blood mononuclear cells (PBMC). QUIN was quantitated in CSF and serum by electron-capture negative chemical ionization gas chromatography mass spectrometry. RESULTS: All SIV-inoculated animals became CSF and PBMC isolation-positive by 1-3 weeks post-inoculation. Control animals remained SIV-negative. One SIV-positive animal was humanely euthanized at 2 weeks post-inoculation. The three SIV-inoculated animals that were CSF isolation-negative after the fifth week post-inoculation maintained CSF QUIN values < 100 nM, remained CSF and PBMC isolation-negative, and clinically healthy in the chronic course of disease. In contrast, the four SIV-inoculated animals that were CSF isolation-positive 6-8 weeks post-inoculation had CSF QUIN levels as high as 153-565 nM during the second month post-inoculation and remained CSF virus isolation-negative, persistently PBMC isolation-positive, and experienced clinical symptoms of SIV in the chronic course of disease. Three of these four animals have succumbed to SIV infection. DISCUSSION: Initial QUIN responses and viral isolation status in the first month post-inoculation were consistent among SIV-inoculated animals with CSF and serum QUIN values significantly higher than those of controls. A divergence within the SIV-inoculated group of animals became apparent within the second month of primary SIV infection and was maintained throughout the course of infection. Persistent PBMC viral isolation and marked elevations of QUIN were linked to symptomatic disease and a poor prognosis for survival. Predominantly negative PBMC viral isolation and slight, but significant, elevations of QUIN were linked to asymptomatic disease with a favorable prognosis for survival.

[The presence of quinolinic acid in the structures of the rat brain]. / Issledovanie nalichiia khinolinovoi kisloty v strukturakh golovnogo mozga.

The brain tissue extracts from chronically alcoholized (15% ethanol intake for more than 18 months) rats were studied by mass spectrometry. The mass spectra for the striatum of control and alcohol-consuming rats were identical, while those for the hippocampus showed a significant difference: a great increase in the intensity of peaks typical of mass spectra for quinolinic acid.

Poliovirus induces indoleamine-2,3-dioxygenase and quinolinic acid synthesis in macaque brain.

Accumulation of the neurotoxin quinolinic acid within the brain occurs in a broad spectrum of patients with inflammatory neurologic disease and may be of neuropathologic significance. The production of quinolinic acid was postulated to reflect local induction of indoleamine 2,3-dioxygenase by cytokines in reactive cells and inflammatory cell infiltrates within the central nervous system. To test this hypothesis, macaques received an intraspinal injection of poliovirus as a model of localized inflammatory neurologic disease. Seventeen days later, spinal cord indoleamine 2,3-dioxygenase activity and quinolinic acid concentrations in spinal cord and cerebrospinal fluid were both increased in proportion to the degree of inflammatory responses and neurologic damage in the spinal cord, as well as the severity of motor paralysis. The absolute concentrations of quinolinic acid achieved in spinal cord and cerebrospinal fluid exceeded levels reported to kill spinal cord neurons in vitro. Smaller increases in indoleamine 2,3-dioxygenase activity and quinolinic acid concentrations also occurred in parietal cortex, a poliovirus target area. In frontal cortex, which is not a target for poliovirus, indoleamine 2,3-dioxygenase was not affected. A monoclonal antibody to human indoleamine 2,3-dioxygenase was used to visualize indoleamine 2,3-dioxygenase predominantly in grey matter of poliovirus-infected spinal cord, in conjunction with local inflammatory lesions. Macrophage/monocytes in vitro synthesized [13C6]quinolinic acid from [13C6]L-tryptophan, particularly when stimulated by interferon-gamma. Spinal cord slices from poliovirus-inoculated macaques in vitro also converted [13C6]L-tryptophan to [13C6]quinolinic acid. We conclude that local synthesis of quinolinic acid from L-tryptophan within the central nervous system follows the induction of indoleamine-2,3-dioxygenase, particularly within macrophage/microglia. In view of this link between immune stimulation and the synthesis of neurotoxic amounts of quinolinic acid, we propose that attenuation of local inflammation, strategies to reduce the synthesis of neuroactive kynurenine pathway metabolites, or drugs that interfere with the neurotoxicity of quinolinic acid offer new approaches to therapy in inflammatory neurologic disease.

[Kynurenine and its metabolites in nervous system diseases]. / Kinurenin és metabolitjai idegrendszeri betegségekben.

Kynurenine is a metabolite of the tryptophan-nicotine-amide-adenine-dinucleotide pathway. Recent preclinical and clinical data suggest that kynurenine and its metabolites (kynurenic acid, quinolinic acid) may play important role in the pathogenesis of neurological and other disorders (Huntington's disease, epilepsy, hypoxia, ulcus, hepatic and infectious diseases). Experimental data and theoretical considerations suggest that modification of kynurenine metabolism and influence of the concentrations of kynurenine metabolites may be useful therapeutic strategies in treatment of several disorders. This review is a summary of the pathobiochemical mechanisms and possible therapeutic strategies.

Human macrophages convert L-tryptophan into the neurotoxin quinolinic acid.

Substantial increases in the concentrations of the excitotoxin and N-methyl-D-aspartate-receptor agonist quinolinic acid (QUIN) occur in human patients and non-human primates with inflammatory diseases. Such increases were postulated to be secondary to induction of indoleamine 2,3-dioxygenase in inflammatory cells, particularly macrophages, by interferon-gamma. To test this hypothesis, human peripheral-blood macrophages were incubated with L-[13C6]tryptophan in the absence or presence of interferon-gamma. [13C6]QUIN was quantified by gas chromatography and electron-capture negative-chemical-ionization mass spectrometry. [13C6]QUIN was detected in the incubation medium of both unstimulated and stimulated cultures. Exposure to interferon-gamma substantially increased the accumulation of [13C6]QUIN in a dose- and time-dependent manner. The QUIN concentrations achieved exceeded those reported in both cerebrospinal fluid and blood of patients and of non-human primates with inflammatory diseases. Macrophages stimulated with interferon-gamma may be an important source of accelerated L-tryptophan conversion into QUIN in inflammatory diseases.

Neuroactive kynurenines in Lyme borreliosis.

Although neurologic dysfunction occurs frequently in patients with Lyme borreliosis, it is rarely possible to demonstrate the causative organism within the neuraxis. This discordance could arise if neurologic symptoms were actually due to soluble neuromodulators produced in response to infection. Since immune stimulation is associated with the production of quinolinic acid (QUIN), an excitotoxin and N-methyl-D-aspartate (NMDA) agonist, we measured levels of CSF and serum QUIN, and lymphokines. Samples were obtained from 16 patients with CNS Borrelia burgdorferi infection, eight patients with Lyme encephalopathy (confusion without intra-CNS inflammation), and 45 controls. CSF QUIN was substantially elevated in patients with CNS Lyme and correlated strongly with CSF leukocytosis. In patients with encephalopathy, serum QUIN was elevated with corresponding increments in CSF QUIN. Lymphokine concentrations were not consistently elevated. We conclude that CSF QUIN is significantly elevated in B burgdorferi infection--dramatically in patients with CNS inflammation, less in encephalopathy. The presence of this known agonist of NMDA synaptic function--a receptor involved in learning, memory, and synaptic plasticity--may contribute to the neurologic and cognitive deficits seen in many Lyme disease patients.

Modulation of quinolinic and kynurenic acid content in the rat brain: effects of endotoxins and nicotinylalanine.

Quinolinic acid, an endogenous excitotoxin, and kynurenic acid, an antagonist of excitatory amino acid receptors, are believed to be synthesized from tryptophan after the opening of the indole ring. They were measured in the rat brain and other organs using gas chromatography-mass spectrometry or HPLC. The enzyme indoleamine 2,3-dioxygenase, capable of cleaving the indole ring of tryptophan, was induced by administering bacterial endotoxins to rats, which significantly increased the brain content of both quinolinic and kynurenic acids. Nicotinylalanine, an analogue of kynurenine, inhibited this endotoxin-induced accumulation of quinolinic acid while potentiating the accumulation of kynurenic acid. The possibility of significantly increasing brain concentrations of kynurenic acid without a concomitant increase in quinolinic acid may provide a useful approach for studying the role of these electrophysiologically active tryptophan metabolites in brain function and preventing the possible toxic actions of abnormal synthesis of quinolinic acid.