Microglia/macrophage-derived inflammatory mediators galectin-3 and quinolinic acid are elevated in cerebrospinal fluid from newborn infants after birth asphyxia.

Activation of microglia/macrophages is important in neonatal hypoxic-ischemic (HI) brain injury. Based on experimental studies, we identified macrophage/microglia-derived mediators with potential neurotoxic effects after neonatal HI and examined them in cerebrospinal fluid (CSF) from newborn infants after birth asphyxia. Galectin-3 is a novel inflammatory mediator produced by microglia/macrophages. Galectin-3 is chemotactic for inflammatory cells and activates nicotinamide adenine dinucleotide phosphate (NADPH) oxidase resulting in production and release of reactive oxygen species (ROS). Matrix metalloproteinase-9 (MMP-9) is a tissue-degrading protease expressed by activated microglia in the immature brain after HI. Both galectin-3 and MMP-9 contribute to brain injury in animal models for neonatal HI. Quinolinic acid (QUIN) is a neurotoxic N-methyl-D-aspartate (NMDA) receptor agonist also produced by activated microglia/macrophages. Galectin-3 and MMP-9 were measured by ELISA and QUIN by mass spectrometry. Asphyxiated infants (n=20) had higher levels of galectin-3 (mean (SEM) 2.64 (0.43) ng/mL) and QUIN (335.42 (58.9) nM) than controls (n=15) (1.36 (0.46) ng/mL and 116.56 (16.46) nM, respectively), p<0.05 and p<0.01. Infants with septic infections (n=10) did not differ from controls. Asphyxiated infants with abnormal outcome had higher levels of galectin-3 (3.96 (0.67) ng/mL) than those with normal outcome (1.76 (0.32) ng/mL), p=0.02, and the difference remained significant in the clinically relevant group of infants with moderate encephalopathy. MMP-9 was detected in few infants with no difference between groups. The potentially neurotoxic macrophage/microglia-derived mediators galectin-3 and QUIN are increased in CSF after birth asphyxia and could serve as markers and may contribute to injury.

Identification of a battery of tests for drug candidate evaluation in the SMNDelta7 neonate model of spinal muscular atrophy.

Spinal muscular atrophy (SMA) is characterized by selective loss of alpha-motor neurons and is caused by homozygous loss or mutation in the survival motor neuron (SMN1) gene. Loss of SMN1 is partially compensated by the copy gene, SMN2. Currently, there are no specific treatments for SMA. Key features of SMA are modeled in mice by deletion of murine Smn, and insertion of both full length human SMN2 gene and the major aberrant splice isoform of the SMN2 gene (SMNDelta7; [Le, T.T., Pham, L.T., Butchbach, M.E., Zhang, H.L., Monani, U.R., Coovert, D.D., Gavrilina, T.O., Xing, L., Bassell, G.J., and Burghes, A.H. 2005. SMNDelta7, the major product of the centromeric survival motor neuron (SMN2) gene, extends survival in mice with spinal muscular atrophy and associates with full-length SMN. Hum Mol Genet 14: 845-857]). The present study identified moderate-throughput, quantitative behavioral tests in neonatal SMN2(+/+);SMNDelta7(+/+);Smn(-/-) mice. It also addresses methodological approaches and common interpretational challenges in a neonatal model with motor deficiencies and frequent deaths. Animals were assessed daily for body weight and survival, and every other day for neonatal well-being indices and tests of motor function such as performance on the hind-limb suspension test (a.k.a. tube test) and geotaxis. The tube test is a novel non-invasive motor function test specifically designed for neonatal rodents. We found progressive deterioration in SMA model mice for most measures studied particularly body weight, survival, body temperature and motor function with differences appearing as early as P3. Power analysis showed that body weight, survival, righting reflex, geotaxis and tube test had highest predictive power for drug efficacy studies. This multi-functional component battery of tests provides a rapid and efficient means to identify, evaluate and develop candidate therapies as a prelude to human clinical trials.

4-chloro-3-hydroxyanthranilate reduces local quinolinic acid synthesis, improves functional recovery, and preserves white matter after spinal cord injury.

Inflammatory processes within the central nervous system (CNS) contribute significantly to the pathogenesis of a broad range of neurologic diseases, including spinal cord injury (SCI). One mechanism by which immune activation causes neurologic symptoms and tissue injury is via the production of neurotoxins by activated macrophages and microglia. In the present study, the role of the endogenous tryptophan metabolite and neurotoxin quinolinic acid (QUIN) in secondary pathology following traumatic SCI was investigated. Adult Hartley guinea pigs were injured by lateral compression of the spinal cord at the 12th thoracic segment (T12). QUIN had accumulated at the site of injury on day 12 post-injury in proportion to the severity of functional neurologic deficits (as assessed by the cutaneus trunci muscle reflex and motor function score at 5 h post-injury). Systemic administration of the 3-hydroxyanthranilate-3,4-dioxygenase (3-HAD) inhibitor, 4-chloro-3-hydroxyanthranilate (4Cl-3HAA; approximately 100 mg/kg every 12 h, beginning 5 h after injury) attenuated local QUIN production and reduced QUIN accumulation at the site of injury by approximately 50% at day 12, without enhanced accumulations of the neuroprotective metabolite kynurenic acid (KYNA). The severity of secondary functional deficits was also reduced by 4Cl-3HAA. In toluidine blue-stained spinal cord sections, the area of surviving intact white matter at the injury site was increased by approximately 100% in the 4Cl-3HAA-treated group. Sparing of both axons and myelin contributed to this increase. These results support the conclusion that QUIN accumulations at the site of injury contribute to secondary functional deficits and tissue damage following SCI.

Cerebrospinal fluid and serum markers of inflammation in autism.

Systemic immune abnormalities have no known relevance to brain dysfunction in autism. In order to find evidence for neuroinflammation, we compared levels of sensitive indicators of immune activation: quinolinic acid, neopterin, and biopterin, as well as multiple cytokines and cytokine receptors, in cerebrospinal fluid and serum from children with autism, to control subjects with other neurologic disorders. In cerebrospinal fluid from 12 children with autism, quinolinic acid (P = 0.037) and neopterin (P = 0.003) were decreased, and biopterin (P = 0.040) was elevated, compared with control subjects. In sera from 35 persons with autism, among cytokines, only tumor necrosis factor receptor II was elevated compared with controls (P < 0.02). Decreased quinolinic acid and neopterin in cerebrospinal fluid are paradoxical and suggest dysmaturation of metabolic pathways and absence of concurrent infection, respectively, in autism. Alternatively, they may be produced by microglia but remain localized and not expressed in cerebrospinal fluid.

Assessment of the macrophage marker quinolinic acid in cerebrospinal fluid after pediatric traumatic brain injury: insight into the timing and severity of injury in child abuse.

This study measured quinolinic acid (QUIN), a macrophage-microglia derived neurotoxin, in the cerebrospinal fluid (CSF) of children after non-inflicted and inflicted traumatic brain injury (nTBI, iTBI), and correlated QUIN concentrations with age, mechanism of injury (nTBi vs. iTBI), Glasgow Coma Scale (GCS) score and 6-month Glasgow Outcome Score. One hundred fifty-two CSF samples were collected from 51 children with severe TBI (GCS < or = 8). CSF was collected at the time an intraventricular catheter was placed and daily thereafter. QUIN concentration was measured by gas chromatography-mass spectroscopy. Patients ranged in age from 2 months to 16 years. Eleven children (22%) had iTBI. Initial and peak CSF QUIN concentrations were higher in patients with iTBI versus nTBI after adjusting for time after injury and GCS. Despite the lack of a history of trauma in 82% of children with iTBI, 100% had a peak QUIN concentration of >100 nM. There was a significant increase in the CSF concentrations of QUIN following severe nTBI and iTBI in children. Higher initial and peak QUIN concentrations after iTBI may be due to severity of injury, young age, and/or delay in seeking medical care, which allows for increased secondary injury.

Antibiotic-mediated release of tumour necrosis factor alpha and norharman in patients with hospital-acquired pneumonia and septic encephalopathy.

OBJECTIVE: To investigate antibiotic-mediated release of tumour necrosis factor (TNF)-alpha and norharman in patients with hospital-acquired pneumonia with and without additional septic encephalopathy. DESIGN: Prospective observational study with a retrospective post hoc analysis. SETTING: Surgical intensive care unit (ICU) at a university hospital. PATIENTS: Thirty-seven patients were consecutively included (9 patients with hospital-acquired pneumonia, 11 patients with hospital-acquired pneumonia and septic encephalopathy, 17 control patients) in the study. Pneumonia was defined according to the criteria of the American Thoracic Society. INTERVENTIONS: Patients received cephalosporins for antibiotic treatment of hospital-acquired pneumonia. Blood samples were taken before, immediately after and 4 h after application of cephalosporins. MEASUREMENTS AND RESULTS: Of the pneumonia patients, 55% developed septic encephalopathy. ICU stay, complications and mortality were significantly increased. An increased release of TNF-alpha was immediately seen in all pneumonia patients after antibiotics compared to controls, whereas the level did not differ between patients with and without septic encephalopathy. Norharman was significantly increased in pneumonia patients 4 h after antibiotic treatment, in tendency more enhanced in the pneumonia patients without encephalopathy. CONCLUSIONS: Patients with hospital-acquired pneumonia and septic encephalopathy had a significantly longer ICU stay with higher mortality rate compared to patients with hospital-acquired pneumonia alone. Antibiotic-mediated TNF-alpha release may induce the kynurenine pathway. TNF-alpha activates indolamine-2,3-dioxygenase with neurotoxic quinolinic acid as the end product. Norharman seems to counteract this mechanism and seems to play a role in neuroprotection. The worse outcome of patients with encephalopathy expresses the need to investigate protective factors and mechanisms.

Prediction of clinical drug efficacy by classification of drug-induced genomic expression profiles in vitro.

Assays of drug action typically evaluate biochemical activity. However, accurately matching therapeutic efficacy with biochemical activity is a challenge. High-content cellular assays seek to bridge this gap by capturing broad information about the cellular physiology of drug action. Here, we present a method of predicting the general therapeutic classes into which various psychoactive drugs fall, based on high-content statistical categorization of gene expression profiles induced by these drugs. When we used the classification tree and random forest supervised classification algorithms to analyze microarray data, we derived general "efficacy profiles" of biomarker gene expression that correlate with anti-depressant, antipsychotic and opioid drug action on primary human neurons in vitro. These profiles were used as predictive models to classify naïve in vitro drug treatments with 83.3% (random forest) and 88.9% (classification tree) accuracy. Thus, the detailed information contained in genomic expression data is sufficient to match the physiological effect of a novel drug at the cellular level with its clinical relevance. This capacity to identify therapeutic efficacy on the basis of gene expression signatures in vitro has potential utility in drug discovery and drug target validation.

Neopterin and quinolinic acid are surrogate measures of disease activity in the juvenile idiopathic inflammatory myopathies.

OBJECTIVE: We evaluated the utility of neopterin and quinolinic acid (QUIN) as surrogate measures of disease activity in juvenile idiopathic inflammatory myopathies (IIMs). METHODS: Plasma and first morning void urine samples were measured for neopterin and QUIN using commercial ELISA, HPLC, or gas chromatography-mass spectrometry in 45 juvenile IIM patients and 79 healthy controls. Myositis disease activity assessments were obtained. RESULTS: Plasma and urine neopterin and QUIN concentrations were increased in juvenile IIM patients compared with healthy controls (P <0.017). Urine neopterin and QUIN highly correlated with each other (r(s) = 0.73; P <0.0001). Urine neopterin and QUIN correlated moderately with myositis disease activity assessments, including physician and parent global activity assessments, muscle strength testing, functional assessments (Childhood Myositis Assessment Scale, Childhood Health Assessment Questionnaire), skin global activity, and edema on magnetic resonance imaging (r(s) = 0.42-0.62; P <0.05), but generally not with muscle-associated enzymes in serum. Urine neopterin or QUIN, in combination with either serum lactate dehydrogenase (LD) or aspartate aminotransferase (AST), significantly predicted global disease activity (R(2) =0.40-0.56; P <0.002), and both were more sensitive to change than these serum enzymes (standardized response means, -0.41 to -0.48). CONCLUSIONS: Urinary neopterin and QUIN are candidate measures of disease activity in juvenile IIM patients and add significantly to the prediction of global disease activity in combination with serum LD or AST values. Measurement of these markers in first morning void urine specimens appears to be as good as, or possibly better than, measurements of their concentrations in plasma.

Cerebrospinal fluid glutamine, tryptophan, and tryptophan metabolite concentrations in dogs with portosystemic shunts.

OBJECTIVE: To determine whether glutamine (GLN), tryptophan (TRP), and tryptophan metabolite concentrations are higher in cerebralspinal fluid (CSF) dogs with naturally occurring portosystemic shunts (PSS), compared with control dogs. ANIMALS: 11 dogs with confirmed PSS and 12 control dogs fed low- and high-protein diets. PROCEDURE: Cerebrospinal fluid and blood samples were collected from all dogs. Serum and CSF concentrations of GLN, alanine, serine, TRP, 5-hydroxyindoleacetic acid (5-HIAA), and quinolinic acid (QUIN) were measured. RESULTS: Cerebrospinal fluid concentrations of GLN, TRP, and 5-HIAA were significantly higher in PSS dogs, compared with control dogs fed high- or low-protein diets. Cerebrospinal fluid QUIN concentration was significantly higher in PSS dogs, compared with control dogs fed the low-protein diet. Serum QUIN concentration was significantly lower in PSS dogs, compared with control dogs fed either high- or low-protein diets. CONCLUSIONS AND CLINICAL RELEVANCE: An increase in CNS GLN concentration is associated with high CSF concentrations of TRP and TRP metabolites in dogs with PSS. High CSF 5-HIAA concentrations indicate an increased flux of TRP through the CNS serotonin metabolic pathway, whereas high CSF QUIN concentrations indicate an increased metabolism of TRP through the indolamine-2,3-dioxygenase pathway. The high CSF QUIN concentrations in the face of low serum QUIN concentrations in dogs with PSS indicates that QUIN production from TRP is occurring in the CNS. High concentrations of QUIN and other TRP metabolites in the CNS may contribute to neurologic abnormalities found in dogs with PSS and hepatic encephalopathy.

Effects of systemic and central nervous system localized inflammation on the contributions of metabolic precursors to the L-kynurenine and quinolinic acid pools in brain.

L-Kynurenine and quinolinic acid are neuroactive L-tryptophan-kynurenine pathway metabolites of potential importance in pathogenesis and treatment of neurologic disease. To identify precursors of these metabolites in brain, [(2)H(3) ]-L-kynurenine was infused subcutaneously by osmotic pump into three groups of gerbils: controls, CNS-localized immune-activated, and systemically immune-activated. The specific activity of L-kynurenine and quinolinate in blood, brain and systemic tissues at equilibrium was then quantified by mass spectrometry and the results applied to a model of metabolism to differentiate the relative contributions of various metabolic precursors. In control gerbils, 22% of L-kynurenine in brain was derived via local synthesis from L-tryptophan/formylkynurenine versus 78% from L-kynurenine from blood. Quinolinate in brain was derived from several sources, including: local tissue L-tryptophan/formylkynurenine (10%), blood L-kynurenine (35%), blood 3-hydroxykynurenine/3-hydroxyanthranilate (7%), and blood quinolinate (48%). After systemic immune-activation, however, L-kynurenine in brain was derived exclusively from blood, whereas quinolinate in brain was derived from three sources: blood L-kynurenine (52%), blood 3-hydroxykynurenine or 3-hydroxyanthranilate (8%), and blood quinolinate (40%). During CNS-localized immune activation, > 98% of both L-kynurenine and quinolinate were derived via local synthesis in brain. Thus, immune activation and its site determine the sources from which L-kynurenine and quinolinate are synthesized in brain. Successful therapeutic modulation of their concentrations must take into account the metabolic and compartment sources.

LC/MS analysis of NAD biosynthesis using stable isotope pyridine precursors.

A liquid chromatographic-electrospray ionization ion trap mass spectrometry (LC/MS) method has been developed to measure the biosynthetic incorporation of specific precursors into NAD. The stable isotope-labeled precursors tryptophan, quinolinic acid, nicotinic acid, and nicotinamide were added to the media of human liver tumor cells (SK-HEP) grown in culture. The cells were harvested, the NAD was extracted, and the ratio of labeled to unlabeled NAD was measured using the newly developed LC/MS assay. The quantity of NAD formed from each precursor relative to an internal standard (fully labeled 13C, 15N-labeled NAD prepared from baker's yeast) was measured. The detection limit (signal-to-noise ratio 5:1) of the LC/MS method was 37 fmol (25 pg) of NAD and was linear from 20.0 ng to 25 pg. All reported NAD levels were normalized relative to cellular protein measurements. At 50 microM precursor concentrations, nicotinamide was the dominant precursor and NAD levels in the cell rose well above normal levels. Other precursors were minimally incorporated. The same methods were applied to NAD biosynthesized by macrophages derived from peripheral blood monocytes. However, the NAD concentration in macrophages was about 5% of that in SK-HEP cells and the incorporation of stable isotope-labeled substrates remained below measurable levels.