How do you solve this problem? The ΔG°’ for the hydrolysis of ATP to ADP +...

Many metabolic reactions are coupled reaction. Such as the first step in glycolysis drawn below: Glucose...

Many metabolic reactions are coupled reaction. Such as the first step in glycolysis drawn below: Glucose + Pi ↔ glucose-6-phosphate + H2O a. The ΔG°’ is 14 kJ•mol-1. What is the ratio of [G6P]/[glucose][Pi] at equilibrium at 25°C? b. The above reaction is coupled to the hydrolysis of ATP. In muscle cells at 37°C, the steady-state ratio of [ATP]/[ADP] is 12 & the ΔG°’ for ATP hydrolysis is -30.5 kJ•mol-1. Assuming that glucose and G6P achieve equilibrium values in muscle...

It’s demanding to measure the standard free-energy change associated with the hydrolysis of ATP because the...

It’s demanding to measure the standard free-energy change associated with the hydrolysis of ATP because the minute amount of ATP remaining at equilibrium is difficult to measure accurately. The value of ΔG'º can be calculated indirectly, however, from the equilibrium constants of two other reactions (the first of which should look familiar) that have less favorable equilibrium constants: glucose-6-phosphate + H2O à glucose + Pi                    Keq'=270 ATP + glucose à ADP + glucose-6-phosphate   Keq'=890 Using this information, calculate ΔG'º for...

The standard free energy change for ATP hydrolysis is -30.5 kJ/mol. Therefore, the free energy change...

The standard free energy change for ATP hydrolysis is -30.5 kJ/mol. Therefore, the free energy change for this reaction in a cell in which the concentration of ATP, ADP, and Pi are 3.1 mM, 2.2 mM and 6.8 mM, respectively, and assuming a physiologically relevant temperature (37 °C), is: Answer -44.25 kJ/mol explain

The glycolytic reaction glyceraldehyde 3-phosphate + Pi → 1,3-bisposphoglycerate has a ΔG°′ of +6.3 kJ/mol. In...

The glycolytic reaction glyceraldehyde 3-phosphate + Pi → 1,3-bisposphoglycerate has a ΔG°′ of +6.3 kJ/mol. In cells however, it is coupled to the subsequent reaction: 1,3- bisposphoglycerate + ADP → ATP + 3-phosphoglycerate which for which G°’= –18.5 kJ/mol Calculate the free energy change for these two reactions if they are coupled together. This was also given if helpful: Abbreviations for cofactors such as NADH, ATP etc. are sufficient unless the specific structure for that molecule is requested. Otherwise use...

Adenosine Tri-Phosphate (ATP) is a compound that provides energy for biochemical reactions in the body during...

Adenosine Tri-Phosphate (ATP) is a compound that provides energy for biochemical reactions in the body during hydrolysis. For hydrolysis of ATP at 37 ° C, ΔH (rxn) ° = -20 kJ / mol and ΔS (rxn) ° = +35 J / K.mol. Assuming that all of these thermodynamic properties are independent of temperature, take into account the temperature at which the equilibrium constant (K) for ATP hydrolysis becomes greater than 1

For the uncoupled and coupled reactions glucose + phosphate → glucose-6-phosphate, ΔG°' = +13.8 kJ/mol glucose...

For the uncoupled and coupled reactions glucose + phosphate → glucose-6-phosphate, ΔG°' = +13.8 kJ/mol glucose + ATP → glucose-6-phosphate + ADP, ΔG°' = -16.7 kJ/mol By how much does coupling to ATP increase the apparent equilibrium constant for the formation of glucose-6-phosphate? Given R = 8.315 J/mol · K. T = 298 K. a) 1.2 times b) 2.2 × 105 times c) 2.2 × 108 times d) 4.5 × 10-6 times

1) Creatine phosphate is produced by creatine kinase which transfers a phosphate group from ATP to...

1) Creatine phosphate is produced by creatine kinase which transfers a phosphate group from ATP to creatine to generate ADP and creatine phosphate. Calculate the ΔG°’ for the coupled reaction. (I calculated it to be -12.5 kJ/mol but I am not sure if this is right) 2) Calculate the ΔG for the reaction described above. The concentrations of creatine phosphate, creatine and ADP are 0.020 mM and the concentrations of the orthophosphate ion and ATP are 20 mM. Temperature is...

The molecular process that makes muscle contraction possible is that ATP binds to myosin, which releases...

The molecular process that makes muscle contraction possible is that ATP binds to myosin, which releases the energy needed to make the muscle contract. In this problem, we will examine the quantities of energy involved in this process. Part 1 The reaction of ATP hydrolysis catalyzed by myosin (M) occurs in several steps*: M + ATP → M·ATP M·ATP → M·ADP·Pi M·ADP·Pi → M·ADP + Pi (aq) M·ADP → M + ADP * T. Kodama & R.C. Woledge, "Enthalpy Changes...

1.Suppose that two proteins, A and B, can associate with each other to form a complex.  ...

1.Suppose that two proteins, A and B, can associate with each other to form a complex.   You measure the dissociation constant at several different temperatures and find that as you heat up the sample, the Kd decreases. Does this mean that binding of A and B becomes more favorable or less favorable as the temperature increases? 2.Calculate the ΔG for ATP hydrolysis in a cell in which the [ATP]/[ADP] ratio had climbed to 100_1, while the Pi concentration remained at...

1 In the absence of oxygen, cells consume glucose at a high, steady rate. When oxygen...

1 In the absence of oxygen, cells consume glucose at a high, steady rate. When oxygen is added, glucose consumption drops precipitously and is then maintained at the lower rate. Why is glucose consumed at a high rate in the absence of oxygen and at a low rate in its presence? 2 In the following diagram showing the distribution of thermal energy in a population of substrate molecules, the energy thresholds indicated by numbers represent ... Energy per molecule Number...