Teodoro Bottiglieri Ph.D.

Vasudevan, A., T. Bottiglieri, K. M. Tecson, M. Sathyamoorthy, J. M. Schussler, C. E. Velasco, L. R. Lopez, C. Swift, M. Peterson, J. Bennett-Firmin, R. Schiffmann and P. A. McCullough (2017). “Residual thromboxane activity and oxidative stress: Influence on mortality in patients with stable coronary artery disease.” Coron Artery Dis 28(4): 287-293.

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BACKGROUND: Aspirin use is effective in the prevention of cardiovascular disease; however, not all patients are equally responsive to aspirin. Oxidative stress reflected by F2-isoprostane [8-iso-prostaglandin-F2alpha (8-IsoPGF2alpha)] is a potential mechanism of failure of aspirin to adequately inhibit cyclooxygenase-1. The objective was to examine the relation between all-cause mortality and the concentrations of urinary 11-dehydro thromboxane B2 (11dhTxB2) and 8-IsoPGF2alpha in patients with stable coronary artery disease (CAD). METHODS: The data for this analysis are from a prospective study in which patients were categorized into four groups based on the median values of 11dhTxB2 and 8-IsoPGF2alpha. RESULTS: There were 447 patients included in this analysis with a median (range) age of 66 (37-91) years. The median (range) values of 11dhTxB2 and 8-IsoPGF2alpha were 1404.1 (344.2-68296.1) and 1477.9 (356.7-19256.3), respectively. A total of 67 (14.9%) patients died over a median follow-up of 1149 days. The reference group for the Cox proportional hazards survival analysis was patients with values of 11dhTxB2 and 8-IsoPGF2alpha below their corresponding medians. Adjusting for the age and sex, patients with values of 11dhTxB2 greater than the median had a significantly higher risk of mortality when compared with the reference group (high 11dhTxB2 and low 8-IsoPGF2alphaadj: hazard ratio: 3.2, 95% confidence interval: 1.6-6.6, P=0.002; high 11dhTxB2 and 8-IsoPGF2alphaadj: hazard ratio: 3.6, 95% confidence interval: 1.8-7.3, P<0.001). The findings were similar when we adjusted for the comorbidities of cancer, kidney function, and ejection fraction. CONCLUSION: We found that 11dhTxB2 appears to be a better prognostic marker for mortality as compared with 8-IsoPGF2alpha, suggesting aspirin resistance itself is a stronger independent determinant of death in CAD patients treated with aspirin.

Dayal, S., G. L. Baumbach, E. Arning, T. Bottiglieri, F. M. Faraci and S. R. Lentz (2017). “Deficiency of superoxide dismutase promotes cerebral vascular hypertrophy and vascular dysfunction in hyperhomocysteinemia.” PLoS One 12(4): e0175732.

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There is an emerging consensus that hyperhomocysteinemia is an independent risk factor for cerebral vascular disease and that homocysteine-lowering therapy protects from ischemic stroke. However, the mechanisms by which hyperhomocysteinemia produces abnormalities of cerebral vascular structure and function remain largely undefined. Our objective in this study was to define the mechanistic role of superoxide in hyperhomocysteinemia-induced cerebral vascular dysfunction and hypertrophy. Unlike previous studies, our experimental design included a genetic approach to alter superoxide levels by using superoxide dismutase 1 (SOD1)-deficient mice fed a high methionine/low folate diet to produce hyperhomocysteinemia. In wild-type mice, the hyperhomocysteinemic diet caused elevated superoxide levels and impaired responses to endothelium-dependent vasodilators in cerebral arterioles, and SOD1 deficiency compounded the severity of these effects. The cross-sectional area of the pial arteriolar wall was markedly increased in mice with SOD1 deficiency, and the hyperhomocysteinemic diet sensitized SOD1-deficient mice to this hypertrophic effect. Analysis of individual components of the vascular wall demonstrated a significant increase in the content of smooth muscle and elastin. We conclude that superoxide is a key driver of both cerebral vascular hypertrophy and vasomotor dysfunction in this model of dietary hyperhomocysteinemia. These findings provide insight into the mechanisms by which hyperhomocysteinemia promotes cerebral vascular disease and ischemic stroke.

Roffman, J. L., L. J. Petruzzi, A. S. Tanner, H. E. Brown, H. Eryilmaz, N. F. Ho, M. Giegold, N. J. Silverstein, T. Bottiglieri, D. S. Manoach, J. W. Smoller, D. C. Henderson and D. C. Goff (2017). “Biochemical, physiological and clinical effects of l-methylfolate in schizophrenia: a randomized controlled trial.” Mol Psychiatry: 2017 Mar [Epub ahead of print].

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Folic acid supplementation confers modest benefit in schizophrenia, but its effectiveness is influenced by common genetic variants in the folate pathway that hinder conversion to its active form. We examined physiological and clinical effects of l-methylfolate, the fully reduced and bioactive form of folate, in schizophrenia. In this randomized, double-blind trial, outpatients with schizophrenia (n=55) received l-methylfolate 15 mg or placebo for 12 weeks. Patients were maintained on stable doses of antipsychotic medications. The pre-defined primary outcome was change in plasma methylfolate at 12 weeks. Secondary outcomes included change in symptoms (Positive and Negative Syndrome Scale (PANSS), Scale for Assessment of Negative Symptoms, Calgary Depression Scale for Schizophrenia), cognition (Measurement and Treatment Research to Improve Cognition in Schizophrenia composite) and three complementary magnetic resonance imaging measures (working memory-related activation, resting connectivity, cortical thickness). Primary, mixed model, intent-to-treat analyses covaried for six genetic variants in the folate pathway previously associated with symptom severity and/or response to folate supplementation. Analyses were repeated without covariates to evaluate dependence on genotype. Compared with placebo, l-methylfolate increased plasma methylfolate levels (d=1.00, P=0.0009) and improved PANSS Total (d=0.61, P=0.03) as well as PANSS Negative and General Psychopathology subscales. Although PANSS Total and General Psychopathology changes were influenced by genotype, significant PANSS Negative changes occurred regardless of genotype. No treatment differences were seen in other symptom rating scales or cognitive composite scores. Patients receiving l-methylfolate exhibited convergent changes in ventromedial prefrontal physiology, including increased task-induced deactivation, altered limbic connectivity and increased cortical thickness. In conclusion, l-methylfolate supplementation was associated with salutary physiological changes and selective symptomatic improvement in this study of schizophrenia patients, warranting larger clinical trials.

Vogel, K. R., E. Arning, T. Bottiglieri and K. M. Gibson (2017). “Multicompartment analysis of protein-restricted phenylketonuric mice reveals amino acid imbalances in brain.” J Inherit Metab Dis 40(2): 227-235.

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BACKGROUND: The mainstay of therapy for phenylketonuria (PKU) remains dietary protein restriction. Developmental and neurocognitive outcomes for patients, however, remain suboptimal. We tested the hypothesis that mice with PKU receiving protein-restricted diets would reveal disruptions of brain amino acids that shed light on these neurocognitive deficits. METHOD: Phenylalanine hydroxylase-deficient (PKU) mice and parallel controls (both wild-type and heterozygous) were fed custom diets containing 18, 6, and 4 % protein for 3 weeks, after which tissues (brain, liver, sera) were collected for amino acid analysis profiling. RESULTS: Phenylalanine (phe) was increased in all tissues (p < 0.0001) of PKU mice and improved with protein restriction. In sera, decreased tyrosine (p < 0.01) was corrected (defined as not significantly different from the level in control mice receiving 18 % chow) with protein restriction, whereas protein restriction significantly increased many other amino acids. A similar trend for increased amino acid levels with protein restriction was also observed in liver. In brain, the effects of protein restriction on large neutral amino acids (LNAAs) were variable, with some deficit correction (threonine, methionine, glutamine) and no correction of tyrosine under any dietary paradigm. Protein restriction (4 % diet) in PKU mice significantly decreased lysine, arginine, taurine, glutamate, asparagine, and serine which had been comparable to control mice under 18 % protein intake. CONCLUSION: Depletion of taurine, glutamate, and serine in the brain of PKU mice with dietary protein restriction may provide new insight into neurocognitive deficits of PKU.

Belik, J., Y. Shifrin, E. Arning, T. Bottiglieri, J. Pan, M. C. Daigneault and E. Allen-Vercoe (2017). “Intestinal microbiota as a tetrahydrobiopterin exogenous source in hph-1 mice.” Sci Rep 7: 39854.

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Tetrahydrobiopterin (BH4) is a cofactor of a number of regulatory enzymes. Although there are no known BH4 exogenous sources, the tissue content of this biopterin increases with age in GTP cyclohydrolase 1-deficient hyperphenylalaninemia-1 (hph-1) mice. Since certain bacteria are known to generate BH4, we hypothesize that generation of this biopterin by the intestinal microbiota contributes to its tissue increase in hph-1 adult mice. The goal of this study was to comparatively evaluate hph-1 mice and wild-type C57Bl/6 controls for the presence of intestinal BH4-producing bacteria. Newborn and adult mice fecal material was screened for 6-pyruvoyltetrahydropterin synthase (PTPS-2) an enzyme only present in BH4-generating bacteria. Adult, but not newborn, wild-type control and hph-1 mouse fecal material contained PTPS-2 mRNA indicative of the presence of BH4-generating bacteria. Utilizing chemostat-cultured human fecal bacteria, we identified the PTPS-2-producing bacteria as belonging to the Actinobacteria phylum. We further confirmed that at least two PTPS-2-producing species, Aldercreutzia equolifaciens and Microbacterium schleiferi, generate BH4 and are present in hph-1 fecal material. In conclusion, intestinal Actinobacteria generate BH4. This finding has important translational significance, since manipulation of the intestinal flora in individuals with congenital biopterin deficiency may allow for an increase in total body BH4 content.