What is the ∆G for the hydrolysis of ATP under cellular conditions where: ​[ATP] = 3...

For the hydrolysis of ATP to ADP + ℗i, the free-energy change is -7.3 kcal/mol under...

For the hydrolysis of ATP to ADP + ℗i, the free-energy change is -7.3 kcal/mol under standard conditions (1 M concentration of both reactants and products). In the cellular environment, however, the free-energy change is about -13 kcal/mol. What can we conclude about the free-energy change for the formation of ATP from ADP and ℗i under cellular conditions?

Now for some calculations. ATP formation is a nonspontaneous process. It requires energy input. Under standard...

Now for some calculations. ATP formation is a nonspontaneous process. It requires energy input. Under standard state conditions the delta Go’ is ~30 kJ/mol. If the best available measures in a particular tissue indicate cellular levels of ATP= 2.5 mM, ADP = 0.6 mM and Pi =0.2 mM, what value will you report as the delta G naught’ for ATP synthesis? Show all work

The standard Gibbs free energy change for hydrolysis or pure ATP to pure ADP is -31KJ/mol....

The standard Gibbs free energy change for hydrolysis or pure ATP to pure ADP is -31KJ/mol. The reaction is written ATP = ADP +Pi. What is the Gibbs energy of reaction in an environment at 37 C in which the ATP, ADP, and Pi concentrations are all 1mmol/L or 1 µmol/L?

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

How do you solve this problem? The ΔG°’ for the hydrolysis of ATP to ADP + Pi is approximately -31 kJ/mole. What is the equilibrium constant for this reactions (R = 8.314 J/ °mol) at the cellular temperature of 37°C? Now, I know the answer is Keq = 1.7 x 10^5 but I have no idea how to get there. PLEASE HELP!

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

Cellular ATP hydrolysis does not always release exactly the same amount of energy. Provide a thermodynamic...

Cellular ATP hydrolysis does not always release exactly the same amount of energy. Provide a thermodynamic explanation for this observation. (hint, do your reading in Cell Bio by the numbers!) In the conditions of a muscle cell recovering from severe exercise, would you expect the hydrolysis of one mole of ATP molecule to produce MORE or LESS energy? Circle one and explain your reasoning.

Given the following concentrations typically found in a resting muscle cell, what is the free energy...

Given the following concentrations typically found in a resting muscle cell, what is the free energy change from hydrolysis of ATP to ADP at 25 °C?      ATP = 4 mM      ADP = 9 uM      Pi = 4 mM

The energy released is -151 kJ/mol. This energy can be converted into the synthesis of ATP...

The energy released is -151 kJ/mol. This energy can be converted into the synthesis of ATP at an efficiency of 0.7 (70% of the energy released is captured in ATP synthesis) and the oxidation of 1 succinate leads to the phosphorylation of 2 equivalents of ATP. Under these conditions, what is the maximum ratio of [ATP]/[ADP] attainable by oxidative phosphorylation when [Pi] = 1 mM? (Assume the free energy needed for ATP synthesis is +30.5 kJ/mol)

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...

Standard Free Energy of Hydrolysis, ∆ G o', of some organophosphate compounds (phosphate isreleased as one...

Standard Free Energy of Hydrolysis, ∆ G o', of some organophosphate compounds (phosphate isreleased as one of the products of hydrolysis)                                     Compound kJ/mol phosphoenolpyruvate -61.9 carbamyl phosphate -51.4 creatine phosphate -43.1 acetyl phosphate -42.2 ATP (to ADP) -30.5 Glucose-1-phosphate -20.9 Glucose-6-phosphate -13.8 Glycerol-3-phosphate -9.2 Use the table in the above table to calculate the ∆G o' (in kJ/mol) for the following reaction: ATP +  glucose --------> ADP  +  glucose-6-phosphate