1. Production of amino acids
2. Production of vitamins
3. To encourage gluconeogenesis
4. Production of ATP and releasing pairs of hydrogen atoms
To encourage gluconeogenesis
1. CO2 forms carbonate rocks
2. CO2 is a buffer
3. CO2 is converted in photosynthesis to carbohydrates
4. CO2
CO2 is converted in photosynthesis to carbohydrates
1. Pyruvic acid to succinic acid
2. Pyruvic acid to lactic acid
3. Pyruvic acid to malic acid
4. None of these
Pyruvic acid to succinic acid
1. Kerbs's cycle
2. Glycolysis
3. ETS chain
4. Photophosphorylation
Glycolysis
1. Citric acid
2. Oxaloacetic acid
3. ATP
4. NADH2
Oxaloacetic acid
1. Carbon
2. Iron
3. Zinc
4. Oxygen
Iron
1. CO2
2. N2
3. O2
4. H2
O2
1. More of the ATP in a normal cell is formed by oxidative phosphorylation via the electron transport chain than by substrate level phosphorylation
2. In eukaryotes,the formation of ATP by oxidative phosphorylation requires that the inner mitochondrial membrane remains intact
3. NAD is a carrier molecule that travels down the electron transport chain to release ATP during oxidative phosphorylation
4. In eukaryotes,the electron transport chain and the enzymes of the citric acid cycle are located in mitochonidria whereas the enzymes of glycolysis are located in the cytoplasm
NAD is a carrier molecule that travels down the electron transport chain to release ATP during oxidative phosphorylation
1. Oxidized
2. Reduced
3. Broken into one carbon fragment
4. Isomerized
Reduced
1. Same as in glycolysis
2. Less than glycolsis
3. More than glycolysis
4. Much lesser than glycolysis
More than glycolysis