Consider the fructose-1,6-bisphosphatase reaction. Calculate the free energy change if the ratio of the concentrations of...
Consider the fructose-1,6-bisphosphatase reaction... Thank you!!! Consider the fructose-1,6-bisphosphatase reaction. Calculate the free energy change if the ratio of the concentrations of the products to the concentrations of the reactants is 20.9 and the temperature is 37.0°C? AG for the reaction is -16.7 kJ/mol. AG= kJ/mol
Consider the malate dehydrogenase reaction from the citric acid cycle. Given the listed concentrations, calculate the free energy change for this reaction at energy change for this reaction at 37.0 ∘ C (310 K). Δ G ∘ ′ for the reaction is + 29.7 kJ/mol . Assume that the reaction occurs at pH 7. thank you Consider the malate dehydrogenase reaction from the citric acid cycle. Given the listed concentrations, calculate the free energy change for this reaction at energy...
Calculate the standard change in Gibbs free energy, AGixn , for the given reaction at 25.0 °C. Consult the table of thermodynamic properties for standard Gibbs free energy of formation values. NH,CI() = NH(aq) + Cl(aq) AGxn = -7.7 kJ/mol Determine the concentration of NH(aq) if the change in Gibbs free energy, AGrxn , for the reaction is –9.53 kJ/mol. [NH] = 0.72 Consider a general reaction enzyme A(aq) = B(aq) The AG® of the reaction is -4.880 kJ mol-....
Consider the malate dehydrogenase reaction from the citric acid cycle. Given the listed concentrations, calculate the free energy change for this reaction at energy change for this reaction at 37.0°C (310 K), AG'' for the reaction is +29.7 kJ/mol. Assume that the reaction occurs at pH 7. (malate) = 1.33 mm [oxaloacetate] = 0.200 mm [NAD) - 440 mm [NADH) - 180 mM AG: 36.9 KJ-mol-
Consider the malate dehydrogenase reaction from the citric acid cycle. Given the listed concentrations, calculate the free energy change for this reaction at energy change for this reaction at 37.0°C (310 K). AG' for the reaction is +29.7 kJ/mol. Assume that the reaction occurs at pH 7. [malate) = 1.43 mm [oxaloacetate) = 0.150 mM [NAD+] = 220 mm [NADH] = 88 mm kJ.mol-1 AG:
Question 1 (1 pt): In glycolysis, fructose 1,6-bisphosphate is converted to two products with a standard free-energy change (AG) of 23.8 kJ/mol. Under what conditions encountered in a normal cell will the free-energy change (AG) be negative, enabling the reaction to proceed spontaneously to the right? Under standard conditions, enough energy is released to drive the reaction to the right. a. b. The reaction will not go to the right under any conditions because AGo is positive. When there is...
QUESTION 19 In glycolysis, fructose 1,6-bisphosphate is converted to two products with a ∆G'° of 23.8 kJ/mol. Under what conditions encountered in a normal cell will the free-energy change (∆G) be negative, enabling the reaction to proceed spontaneously to the right? A. Under standard conditions, energy is released to drive the reaction to the right, B. the reaction will not go to the right spontaneously under any conditions because the ∆G'° is positive, C. the reaction will proceed spontaneously to...
and Q. Many metabolites are maintained at steady-state concentrations that are far from equilibrium. A comparison of K the mass-action ratio, can determine whether a metabolic reaction is far from equilibrium. The equation for this equilibrium is, fructose 6-phosphate + ATP fructose 1,6-bisphosphate + ADP Calculate for this reaction at T = 25.0°C. AG = -14.2 kJ/mol K Calculate the mass-action ratio, Q. from the approximate physiological concentrations for rat heart tissue shown in the table. Q Metabolite fructose 6-phosphate...
Calculate standard free energy change using AG values. Consider the reaction 2CO2(g) + 3H2(g) C2H2() + 4H2O(g) Use standard free energies of formation to calculate the standard free energy change for this reaction at 25°C. AG9rxn = kJ/mol
Calculate standard free energy change using AGvalues. Consider the reaction 2NH3(g) + 3N2O(g)—>4N2(g) + 3H2O(g) Use standard free energies of formation to calculate the standard free energy change for this reaction at 25°C. AG° kJ/mol