Water Quality Assessment of Shatt Al-Arab River, Southern Iraq Using NSF-WQI

Three stations were selected on Shatt Al-Arab River, which is distinguished by its fresh water that is used for drinking, agriculture and industry. The first station is located in the north of Basrah Province in Al-Shafy, the second in the province center in Al-Salhiya and the third one to the south in the Sahel Region, during the period from October 2019 until September 2020. The study aimed to assess the quality of Shatt Al-Arab River water by using the NSF-WQI guide and its suitability for various uses as it represents an easy and efficient method of evaluation. Seven factors were used in the study: dissolved oxygen, biochemical oxygen demand, reactive phosphate, potential of Hydrogen, total dissolved solids, nitrates and water temperature. The results showed that the water quality index values varied between 110-122, as Shatt Al-Arab River water is generally classified as poor water. The second station recorded the highest (122) value for the index, while the first station recorded the lowest value (110).

Effects of altered pyruvate dehydrogenase activity on contracting skeletal muscle bioenergetics

During aerobic exercise (>65% of maximum oxygen consumption), the primary source of acetyl-CoA to fuel oxidative ATP synthesis in muscle is the pyruvate dehydrogenase (PDH) reaction. This study investigated how regulation of PDH activity affects muscle energetics by determining whether activation of PDH with dichloroacetate (DCA) alters the dynamics of the phosphate potential of rat gastrocnemius muscle during contraction. Twitch contractions were induced in vivo over a broad range of intensities to sample submaximal and maximal aerobic workloads. Muscle phosphorus metabolites were measured in vivo before and after DCA treatment by phosphorus nuclear magnetic resonance spectroscopy. At rest, DCA increased PDH activation compared with control (90 ± 12% vs. 23 ± 3%, P < 0.05), with parallel decreases in inorganic phosphate (Pi) of 17% (1.4 ± 0.2 vs. 1.7 ± 0.1 mM, P < 0.05) and an increase in the free energy of ATP hydrolysis (ΔGATP) (−66.2 ± 0.3 vs. −65.6 ± 0.2 kJ/mol, P < 0.05). During stimulation DCA increased steady-state phosphocreatine (PCr) and the magnitude of ΔGATP, with concomitant reduction in Pi and ADP concentrations. These effects were not due to kinetic alterations in PCr hydrolysis, resynthesis, or glycolytic ATP production and altered the flow-force relationship between mitochondrial ATP synthesis rate and ΔGATP. DCA had no significant effect at 1.0- to 2.0-Hz stimulation because physiological mechanisms at these high stimulation levels cause maximal activation of PDH. These data support a role of PDH activation in the regulation of the energetic steady state by altering the phosphate potential (ΔGATP) at rest and during contraction.

Metabolic and ionic coupling factors in amino acid-stimulated insulin release in pancreatic β-HC9 cells

Fuel stimulation of insulin secretion from pancreatic β-cells is thought to be mediated by metabolic coupling factors that are generated by energized mitochondria, including protons, adenine nucleotides, and perhaps certain amino acids (AA), as for instance aspartate, glutamate, or glutamine (Q). The goal of the present study was to evaluate the role of such factors when insulin release (IR) is stimulated by glucose or AA, alone or combined, using 31P, 23Na and 1H NMR technology, respirometry, and biochemical analysis to study the metabolic events that occur in continuously superfused mouse β-HC9 cells contained in agarose beads and enhanced by the phosphodiesterase inhibitor IBMX. Exposing β-HC9 cells to high glucose or 3.5 mM of a physiological mixture of 18 AA (AAM) plus 2 mM glutamine caused a marked stimulation of insulin secretion associated with increased oxygen consumption, cAMP release, and phosphorylation potential as evidenced by higher phosphocreatine and lower Pi peak areas of 31P NMR spectra. Diazoxide blocked stimulation of IR completely, suggesting involvement of ATP-dependent potassium (KATP) channels in this process. However, levels of MgATP and MgADP concentrations, which regulate channel activity, changed only slowly and little, whereas the rate of insulin release increased fast and very markedly. The involvement of other candidate coupling factors was therefore considered. High glucose or AAM + Q increased pHi. The availability of temporal pH profiles allowed the precise computation of the phosphate potential (ATP/Pi × ADP) in fuel-stimulated IR. Intracellular Na+ levels were greatly elevated by AAM + Q. However, glutamine alone or together with 2-amino-2-norbornanecarboxylic acid (which activates glutamate dehydrogenase) decreased β-cell Na levels. Stimulation of β-cells by glucose in the presence of AAM + Q (0.5 mM) was associated with rising cellular concentrations of glutamate and glutamine and strikingly lower aspartate levels. Methionine sulfoximine, an inhibitor of glutamine synthetase, blocked the glucose enhancement of AMM + Q-induced IR and associated changes in glutamine and aspartate but did not prevent the accumulation of glutamate. The results of this study demonstrate again that an increased phosphate potential and a functional KATP channel are essential for metabolic coupling during fuel-stimulated insulin release but illustrate that determining the identity and relative importance of all participating coupling factors and second messengers remains a challenge largely unmet.

Effect of a glucokinase inhibitor on energy production and insulin release in pancreatic islets

Glucokinase has exclusively high control strength on glucose usage in the pancreatic beta-cell. However, glucokinase also has extraordinarily high control strength on insulin secretion, which is linked to the phosphate potential, [ATP]/([ADP][Pi]) (F.M. Matschinsky, Y.Liang, P. Kesavan, L. Wang, P. Froguel, G. Velho, D. Cohen, M.A. Permutt, Y. Tanizawa, T.L. Jetton, K. Niswender, and M.A. Magnuson. J. Clin. Invest. 92: 2092-2098, 1993). We propose that the ATP produced via the tricarboxylic acid cycle is approximately constant, irrespective of the glucose level. Furthermore, the component of ATP production that is derived from glycolysis and glycolytically derived NADH, which is shuttled into the mitochondria, is a critical signal controlling the ionic events leading to insulin secretion, as suggested previously (M. J. MacDonald. Diabetes 39: 1461-1466, 1990 and I.D. Dukes, M.S. McIntyre, R.J. Mertz, L.H. Philipson, M.W. Roe, B. Spencer, and J.F. Worley III. J. Biol. Chem. 269: 10979-10982, 1994). To test this hypothesis, glucose usage, oxidation, and insulin secretion were measured in cultured rat islets over a wide range of concentrations of glucose and mannoheptulose, an inhibitor of glucokinase. These data were fit to a mathematical model that predicts that glucokinase will govern the rate of glucose usage and ATP production and will also have a strong, but not complete, control over the rate of glucose oxidation, the phosphate potential, and insulin release. Mannoheptulose caused an inhibition of all three fluxes. The estimates of the mechanistic parameters of the model [maximal velocity (Vmax) and Michaelis constant for glucokinase, Vmax for hexokinase and glucose transport, and the inhibition constant of mannoheptulose to glucokinase] were similar to those obtained in vitro. Thus the data are consistent with a model in which the primary importance of glycolysis in transducing the glucose signal into changes of the phosphate potential imparts to glucokinase a high control strength on glucose-induced insulin secretion.