Chapter 5: Microbial Metabolism Flashcards
Central Role of ATP
During catabolism, useful energy is temporarily conserved in the “high energy bond” of ATP - adenosine triphosphate. No matter what form of energy a cell uses as its primary source, the energy is ultimately transformed and conserved as ATP - the universal currency of energy exchange in biological systems. When energy is required during anabolism, it may be spent as the high energy bond of ATP which has a value of about 8 kcal per mole. Hence, the conversion of ADP to ATP requires 8 kcal of energy, and the hydrolysis of ATP to ADP releases 8 kcal.Because of the central role of ATP in energy-generating metabolism, expect to see its involvement as a coenzyme in most energy-producing processes in cells.
What are the three types of phosphorylation reactions that generate ATP?
Substrate Level, Oxidative, and Photophosphorylation
What is substrate level phosphorylation?
ATP is formed when the substrate transfers a high energy phosphate to ADP directly.
What are some examples of Substrate Level Phosphorylation?
Glycolysis and the Krebs cycle
What is oxidative phosphorylation?
Electrons are transferred from organic compounds to electron carriers (NAD+ and FAD). Electrons are then passed through different carriers to molecules of oxygen. Each transfer results in the release of energy.
What is an example of oxidative phosphorylation?
Electron Transport Chain
What is photophosphorylation?
It occurs only in photosynthetic cells which contain light trapping pigments like chlorophyll. The process converst light energy to chemical energy (ATP and NADPH). An electron transport chain is involved. An example is photosynthesis.
What is oxidation?
The REMOVAL of electrons, producing energy.
What is reduction?
The GAINING of electrons.
Explain the significance of the REDOX tower.
The redox tower represents the range of possible reduction potentials. Oxidized/electron donors are at the top, and reduced/accepting substances are at the bottom. The farther the electrons drop, the more energy released.
What are the steps in Aerobic Respiration?
- Glycolysis (can occur with or without O2); 2. Pyruvate Oxidation; 3. Kreb’s cycle 4. Electron Transport Chain
**Glycolysis and the Krebs Cycle create a little ATP, but they mostly create the electron carriers that all meet up in step 4. The electron transport chain is where a lot of ATP is created!
What goes in and what comes out of glycolysis?
1 molecule of Glucose and NAD+ yields 2 pyruvate, 2 ATPs (because we actually produce 4, but have to use two for the process), 2 NADH (which goes to the electron transport chain to make ATP)
What goes in/what comes out of Pyruvate Oxidaion and Acetyl CoA synthesis? (happens in cytoplasm of prokaryotes)
2 Pyruvate yield: 2 acetyl CoA, 2 NADH (which go to the ETC), and 2 CO2
What goes in/what comes out of the Krebs/Citric Acid Cycle?
Acetyl CoA goes in and yields 6 NADH, 2FADH2, 2ATP, and 4 CO2
What goes in/what comes out of the Electron Transport Chain?
First off, the ETC actually takes place in the prokaryotic cell membrane. The starting material is NADH, FADH2, O2, and ATP Synthase (the turbine that BOOMS and produces ATP as it spins with the hydrogen proton gradient). The end products are 28 ATP, H2O, NAD+, and FAD+. Oxygen is the final electron acceptor.
