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Do microbes create energy from nutrients?
- No energy is never created nor destroyed, only moved around.
- They extract energy that is already present in the bonds of the nutrients.
What is a Oxidation-reduction (redox) reaction?
It is a reaction that salvages electrons (and the energy associated with them) released from the breaking of nutrient bonds.
What is ATP?
How energy is banked.
What happens in a Oxidation reaction?
Oxidation is the removal of electrons from a molecule, and is always coupled with a Reduction reaction.
What happens in a reduction reaction?
Reduction is the gaining of electrons, and are always coupled with Oxidation.
What is a dehydration reaction?
- This is the removal of hydrogen atoms.
- Biological oxidation reactions are often dehydration reactions.
NAD+ + 2H++2e- = NADH+H+
This is energy extracted in the form of electrons
What is the high energy of the cell?
- ATP has "high energy" or unstable bonds which allows the energy to be released quickly and easily
What are the mechanisms of ATP generation?
- Substrate-level phosphorylation
- Oxidative phosphorylation
What is substrate-level phosphorylation
Generation of ATP when a high energy phosphate is transferred directly to ADP from a phosphorylated substrate.
What is Oxidative phosphorylation
Electrons are transferred from organic compunds through a series of electron carriers to O2 or other oxidized inorganic or organic molecules.
What is photophosphorylation
This occurs in photosynthetic cells, the light causes chlorophyll to give up electrons
How do microbes generate energy?
- By the oxidation of..
In what ways to microbes catabolise carbohydrates?
- Cellular respiration
Both start with Glycolysis
What are the components of cellular respiration?
- Intermediate step
- TCA cycle (Kreb's cycle)
- Electron Transport Chain
What is Glycolysis?
Glucose is oxidized to pyruvic acid with ATP and NADH produced
What is the Intermediate step?
Pyruvic acid is converted to acetyle-CoA with NADH produced
What is the TCA/Kreb's cycle?
Acetyl CoA is oxidized to CO2 with ATP, NADH and HADH2 produced
What is the electron transport chain
NADH and HADH2 are oxidized through a series of redox reactions and a considerable amount of ATP is produced
How many steps are in glycolysis?
- Used simultaneously with glycolysis (several intermediates can reenter glycolysis)
- Breakdown of 5-carbon sugars(pentoses) as well as glucose
- Produces important intermediates in the synthesis of, Cucleic acids, glucose from Co2 and certian amino acids
- Produces NADPH for anabolic reaction
- Yealds only 1 atp per glucose
- Bacteria can metabolize glucose without glycolysis or pentose phosphate pathway.
- Produces 2 NADPH and 1 ATP/glucose
- Used by obligate aerobes such as Pseudomonas Spp.
What happens after glycolysis
- After glucose is broken down to pyruvic acid, it can be channeled into either Fermentaion or
- Cellular respiration.
- Aerobic respiration or anaerobic respiration
What is arobic respiration
- Tricarboxylic acid (TCA) cycle
- Kreb's cycle or citric acid cycle
- A large amount of potential energy stored in acetyl CoA is released by a series of redox reactions that transfer electrons to the electron carrier coenzymes (NAD+ and FAD)
- Used in the intermediate step
- Pyruvic acid is converted to a 2-carbon compound (decarboxylation)
- The 2 carbon acetle group then combines with Coenzyme A through a high energy bond
- NAD+ is reduced to NADH
Summary of Glycolysis
- Glucose is split and oxidized through a ten step pathway to two molecules of pyruvic acid
- Net gain of 2 ATP molecules, 4 from energy phase(by substrate level phosphorylation) mins 2 from preparatory phase
- 2 NADH molecules produced (will be used to make more ATP)
- Pyruvic acid can now undergo either Fermentation or respiration
Recap of Glycolysis, Intermediate Step, and Kreb's Cycle
- Pathway # of Steps Energy used Energy Gained Energy forms
- Glycolysis 10 2 ATP 4 ATP, 2 NADH ATP, NADH
- Intermediate 1 0 2 NADH NADH
- Kreb's 9 0 2 ATP, 6NADH, 2 FADH ATP, NADH, FADH
Per per glucose molecule