Term
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Definition
synthesizng glucose from non-carbohydrate precursors |
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Term
what are some examples of non-carbohydrate precursors used in gluconeogenesis? |
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Definition
pyruvate, alanine (by transamination), lactate (by LDH, lactate dehydrogenase), propionate, glycerol, (important in starved state), and gluconeogenic amino acids, (anything that feeds into the pyruvate/TCA cycle such as aspartate) |
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Term
what tissues perform gluconeogenesis? |
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Definition
liver, (major, kidney, and small intestine epithelia, (minor) |
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Term
what is the purpose of gluconeogenesis? |
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Definition
supporting the plasma glucose level |
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Term
what are the enzymes of the 3 irreversible steps that gluconeogenesis needs to bypass in re-tracking glycolysis? |
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Definition
pyruvate kinase, PFK-1, and gluokinase |
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Term
where does glycolysis take place? |
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Definition
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Term
how many net ATP are generated in glycolysis? |
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Definition
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Term
how many steps/enzymes are there in glycolysis, how many are reversible? |
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Definition
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Term
what is the first enzyme/step/barrier that must be overcome in gluconeogenesis? |
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Definition
pyruvate -> PEP, (PK catalyzed step in glycolysis) - requires several steps |
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Term
how is pyruvate converted to oxaloacetate in the first step of gluconeogenesis? |
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Definition
first the pyruvate must be brought into the mitochondria from the cytosol. once there, pyruvate carboxylase adds a bicarbonate using ATP and biotin as a cofactor. 3C molecule - 4C |
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Term
what else can oxaloacetate be used for, other than gluconeogenesis? |
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Definition
addition back into the TCA cycle to make citrate. |
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Term
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Definition
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Term
what are the two ways that oxaloacetate can be made into PEP? how often does the body use either process? |
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Definition
in the mitochondria or in the cytosol. each happens about 50% of the time |
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Term
how is oxaloacetate made into PEP in the mitochondria? |
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Definition
mitochondrial PEP carboxykinase uses a GTP to convert oxaloacetate into PEP, giving off a CO2 |
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Term
how is oxaloacetate made into PEP in the cytosol? |
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Definition
there is no oxaloacetate transporter from the mitochondria to the cytosol, so oxaloacetate has to be converted to malate, transported,converted back to oxaloacetate, then converted to PEP by cytosolic PEP carboxykinase, using 1 GTP, and giving off a CO2. (transamination to aspartate instead of malate is also possible) |
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Term
what energy molecules/enzymes are needed to get pyruvate to PEP? |
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Definition
ATP, (pyruvate carboxylase), and GTP, (PEP carboxykinase) |
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Term
in comparison to glycolysis, which gives 2 pyruvates, and one enzyme producing net 1 ATP each, gluconeogenesis uses 2 enzymes 2x to create 2 PEPs, how many ATP/GTP does this require |
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Definition
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Term
what is one benefit of using malate in the process of converting OAA -> PEP? |
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Definition
OAA to malate makes NADH -> NAD+ in the mitochondria, and malate to OAA in the cytosol makes NAD+ -> NADH, bringing more reducing equivalents to the cytosol which will be helpful later |
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Term
what rxns need biotin? what is an example? |
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Definition
carboxylation rxns, such as pyruvate -> oxaloacetate |
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Term
what molecules allosterically activate pyruvate carboxylase? why is this helpful? |
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Definition
acetyl CoA, and other acyl CoAs. one reason for this is acetyl CoA and pyruvate are both substrates of the TCA cycle, which requires oxaloacetate to make citrate, (start of TCA). acetyl CoAs need OAA in the process of breaking down fats |
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Term
what is the next 2 steps/barriers/enzymes to overcome in gluconeogenesis after pyruvate kinase? |
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Definition
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Term
how is the glycolytic PFK-1 step overcome in gluconeogenesis? |
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Definition
PFK-1 uses an ATP to make F6P -> F1,6bisP. so in gluconeogenesis, fructose 1,6-bisphosphatase uses a water and takes off a Pi, (no energy involved) |
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Term
how is the glycolytic hexokinase step overcome in gluconeogenesis? |
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Definition
hexokinase uses an ATP to convert glucose to G6P, so glucose 6 phosphatase takes the Pi off using a water, (no energy involved) |
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Term
which 2 amino acids are completely ketogenic? |
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Definition
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Term
what does it mean that almost all the amino acids are gluconeogenic? |
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Definition
glucose is very important |
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Term
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Definition
RBCs, (and to some extent muscles) produce lactate, (pyruvate -> lactate by LDH, using one NADH) for the 2 ATP from glycolysis. the lactate is then brought back to to the liver and can be used in gluconeogenesis |
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Term
what is the alanine cycle? |
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Definition
the alanine cycle is muscle running glycolysis and then transaminating the pyruvate to alanine, this is used to either save an NADH that the cori cycle would have used, or to transport N back to the liver. alanine can then be either transaminated to pyruvate in the liver and run through gluconeogenesis, or excreted as urea |
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Term
where does the energy driving gluconeogenesis come from? |
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Definition
fatty acid catabolism, (acetyl CoA) |
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Term
what are the 2 major products from beta-oxidation, (fatty acids catabolism)? |
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Definition
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Term
what do the products of beta oxidation do in terms of regulating gluconeogenesis, (in terms of the pyruvate kinase step of glycolysis)? |
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Definition
NADH and acetyl CoA both inhibit pyruvate dehydrogenase, (tells liver to stop making more acetyl CoA, b/c now its coming from fats), and acetyl CoA activates pyruvate carboxylase. |
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Term
what does pyruvate dehydrogenase do? |
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Definition
catalyzes the conversion of pyruvate to acetyl CoA |
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Term
what does pyruvate carboxylase do? is it inducible? |
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Definition
catalyzes conversion of pyruvate to oxaloacetate. it is inducible by glucagon. |
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Term
what does pyruvate kinase do? |
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Definition
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Term
what ratio of insulin/glucagon correlates with gluconeogenesis? |
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Definition
low insulin/high glucagon |
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Term
how does the higher level of glucagon regulate gluconeogenesis, (in terms of the pyruvate kinase step of glycolysis)? |
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Definition
glucagon stops pyruvate kinase from making more pyruvate from PEP, (futile cycle). glucagon also activates AND INDUCES PEP carboxykinase, which catalyzes the conversion of oxaloacetate to PEP |
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Term
how does glucagon regulate the PFK step of glycolysis in gluconeogenesis in terms of covalent modification? |
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Definition
glucagon activates a kinase that phosphorylates PFK-2 and fructose 2,6 bisphosphatase. this inactivates PFK-2, which then cannot make F2,6bisP, (allosteric activator of PFK-1). also, this activates fructose 2,6 bisphosphatase, which changes F2,6bisP -> F6P. thus, glucagon favors gluconeogenesis |
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Term
how does insulin regulate the PFK step of glycolysis in gluconeogenesis in terms of covalent modification? |
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Definition
insulin activates a phosphatase that dephosphorylates PFK2 and F2,6,bisPase. this activates PFK2, allowing it to make F2,6 bisP and inactivates F2,6 bisPase, (stopping conversion of F6P -> F2,6,bisP). thus, insulin favors glycolysis |
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Term
what enzymes are inducible by glucagon? |
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Definition
PEP-CK, F1,6bisphosphatase, and G6phosphatase |
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Term
how does glucagon regulate the PFK step of glycolysis in gluconeogenesis in terms of enzyme induction? |
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Definition
glucagon can induce PEP-CK, the enzyme that catalyzes the conversion of OAA -> PEP |
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Term
how does glucagon affect glucokinase? how does this further the purpose of gluconeogenesis? |
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Definition
it activates it's translocation into the nucleus, and therefore when glucose is produced it can go into the bloodstream from the liver w/out risk of it being brought into glycolysis |
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Term
what ratio of ATP to AMP allosterically activates gluconeogenesis? where does the ATP come from? |
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Definition
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