Your search keyword '"William J. L'Amoreaux"' showing total 5 results

1. Taurine supplementation induces hyperinsulinemia and neuronal hyperexcitability

Author

Abdeslem, El Idrissi, Francoise, Sidime, Ola, Tantawy, Dinali, Obeysekera, Don, Wisidagama, Samreen, Tariq, Irena, Jmukhadze, and William J, L'Amoreaux

Subjects

Blood Glucose, Male, Mice, Taurine, Hyperinsulinism, Dietary Supplements, Animals, Brain, Synaptic Transmission, Receptor, Insulin, Up-Regulation

Published

2015

2. Taurine 8 : Volume 1: The Nervous System, Immune System, Diabetes and the Cardiovascular System

Author

Abdeslem El Idrissi, William J. L'Amoreaux, Abdeslem El Idrissi, and William J. L'Amoreaux

Subjects

Human physiology, Life sciences, Nutrition, Biochemistry, Cardiology

Abstract

Taurine 8 represents the combined efforts of investigators on the roles of the amino acid taurine on human health and disease. The chapters covered in this book are directly derived from presentations of the contributors at the 18th International Taurine Meeting held in Marrakech, Morocco in April 2012. The purpose of this book is to disseminate current findings on taurine's contribution in several organ systems. This book covers the following topics: Taurine in the Nervous System, Taurine in the Immune System, Taurine and Diabetes, and Taurine and the Cardiovascular System. Dr. Abdeslem El Idrissi, College of Staten Island and Dr. William L'Amoreaux, College of Staten Island, were co-chairs of the Organizing Committee for the meeting. Data presented at this meeting provided compelling evidence that taurine is not only cytoprotective in cardiomyocytes, but also is a potent GABA agonist, whereby it can facilitate vasodilation of conducting arteries. Taurine conjugates, such as taurine chloramine, may protect cells from oxidative stress via increased HO-1 expression. In adult rodents, taurine has a potent effect on plasma glucose levels, likely through the release of insulin in pancreatic beta cells. As a potential neurotransmitter, taurine is known to work via the GABAergic system, but current research presented at this meeting suggest that taurine may interact with glutamate and serotonin receptors as well. Data are also presented to demonstrate the protective roles of taurine on neurons in neuroblastoma. Perhaps the most important and exciting presentation is the role of taurine and alcohol: the combination may be lethal. Data are also presented at this meeting of the potential role taurine may have as an adjuvant treatment with cisplatin in chemotherapy.

Published

2013

3. Taurine 8 : Volume 2: Nutrition and Metabolism, Protective Role, and Role in Reproduction, Development, and Differentiation

Author

Abdeslem El Idrissi, William J. L'Amoreaux, Abdeslem El Idrissi, and William J. L'Amoreaux

Subjects

Taurine, Taurine--Congresses

Abstract

Taurine 8 represents the combined efforts of investigators on the roles of the amino acid taurine on human health and disease. The chapters covered in this book are directly derived from presentations of the contributors at the 18th International Taurine Meeting held in Marrakech, Morocco in April 2012. The purpose of this book is to disseminate current findings on taurine's contribution in several organ systems. This book covers the following topics: Taurine in Nutrition and Metabolism, the Protective Role of Taurine, and the Role of Taurine in Reproduction, Development, and Differentiation. Dr. Abdeslem El Idrissi, College of Staten Island and Dr. William L'Amoreaux, College of Staten Island, were co-chairs of the Organizing Committee for the meeting. Data presented at this meeting provided compelling evidence that taurine is not only cytoprotective in cardiomyocytes, but also is a potent GABA agonist, whereby it can facilitate vasodilation of conducting arteries. Taurine conjugates, such as taurine chloramine, may protect cells from oxidative stress via increased HO-1 expression. In adult rodents, taurine has a potent effect on plasma glucose levels, likely through the release of insulin in pancreatic beta cells. As a potential neurotransmitter, taurine is known to work via the GABAergic system, but current research presented at this meeting suggest that taurine may interact with glutamate and serotonin receptors as well. Data are also presented to demonstrate the protective roles of taurine on neurons in neuroblastoma. Perhaps the most important and exciting presentation is the role of taurine and alcohol: the combination may be lethal. Data are also presented at this meeting of the potential role taurine may have as an adjuvant treatment with cisplatin in chemotherapy.

Published

2013

4. Taurine's effects on the neuroendocrine functions of pancreatic β cells

Author

Christina M, Cuttitta, Sara R, Guariglia, Abdeslem El, Idrissi, and William J, L'amoreaux

Subjects

Aniline Compounds, Mesocricetus, Glutamate Decarboxylase, Taurine, Models, Biological, Neurosecretory Systems, Cell Line, Sulfonylurea Compounds, Xanthenes, Cricetinae, Insulin-Secreting Cells, Insulin Secretion, Animals, Insulin, Calcium, Somatostatin

Abstract

Taurine plays significant physiological roles, including those involved in neurotransmission. Taurine is a potent γ-aminobutyric acid (GABA) agonist and alters cellular events via GABA(A) receptors. Alternately, taurine is transported into cells via the high affinity taurine transporter (TauT), where it may also play a regulatory role. We have previously demonstrated that treatment of Hit-T15 cells with 1 mM taurine for 24 h significantly decreases insulin and GABA levels. We have also demonstrated that chronic in vivo administration of taurine results in an up-regulation of glutamic acid decarboxylase (GAD), the key enzyme in GABA synthesis. Here, we wished to test if administration of 1 mM taurine for 24 h may increase release of another β cell neurotransmitter somatostatin (SST) and also directly impact up-regulation of GAD synthesis. Treatment with taurine did not significantly alter levels of SST (p0.05) or GAD67 (p0.05). This suggests that taurine does not directly affect SST release, nor does it directly affect GAD synthesis. Taken together with our observation that taurine does promote GABA release via large dense-core vesicles, the data suggest that taurine may alter membrane potential, which in turn would affect calcium flux. We show here that 1 mM taurine does not alter intracellular Ca(2+) concentrations from 20 to 80 s post treatment (p0.05), but does increase Ca(2+) flux between 80 and 200 s post-treatment (p0.005). This suggests that taurine may induce a biphasic response in β cells. The initial response of taurine via GABA(A) receptors hyperpolarizes β cell and sequesters Ca(2+). Subsequently, taurine may affect Ca(2+) flux in long term via interaction with K(ATP) channels.

Published

2013

5. The effects of chronic taurine supplementation on motor learning

Author

Allison, Santora, Lorenz S, Neuwirth, William J, L'Amoreaux, and Abdeslem El, Idrissi

Subjects

Male, Mice, Taurine, Movement, Rotarod Performance Test, Dietary Supplements, Reaction Time, Animals, Learning, Motor Activity, Biomechanical Phenomena

Abstract

Taurine is one of the most abundant nonprotein amino acids shown to be essential for the development, survival, and growth of vertebrate neurons. We previously demonstrated that chronic taurine supplementation during neonatal development results in changes in the GABAergic system (El Idrissi, Neurosci Lett 436:19-22, 2008). The brains of mice chronically treated with taurine have decreased levels of GABA(A)β subunits and increased expression of GAD and GABA, which contributes to hyperexcitability. This down regulation of GABA(A)receptor subunit expression and function may be due to a sustained interaction of taurine with GABA(A)receptors. This desensitization decreases the efficacy of the inhibitory synapses at the postsynaptic membrane. If changes occur in the GABAergic system as a possible compensatory mechanism due to taurine administration, then it is important to study all aspects by which taurine induces hyperexcitability and affects motor behavior. We therefore hypothesized that modification of the GABAergic system in response to taurine supplementation influences motor learning capacity in mice. To test this hypothesis, the rotarod task was employed after chronic taurine supplementation in drinking water (0.05% for 4 weeks). Control animals receiving no taurine supplementation were also tested in order to determine the difference in motor learning ability between groups. Each animal was trained on the rotarod apparatus for 7 days at an intermediate speed of 24 rpm in order to establish baseline performance. On the testing day, each animal was subjected to eight different predefined speeds (5, 8, 15, 20, 24, 31, 33, and 44 rpm). From our observations, the animals that underwent chronic taurine supplementation appeared to have a diminished motor learning capacity in comparison to control animals. The taurine-fed mice displayed minor improvements after repeated training when compared to controls. During the testing session the taurine-fed mice also exhibited a shorter latency to fall, as the task requirements became more demanding.

Published

2013