MCAT - Biochem - Glycolysis, Gluconeogenesis, and Pentose Phosphate Pathway
Cori Cycle
acidic lactic acid formed from fermentation in blood cells are delivered back to the liver to be converted to glucose for red blood cell use
1,3-BPG and PEP (1,3-Bisphosphoglycerate and posphoenolpyruvate)
high energy intermediates used to generate ATP by substrate level phosphorylation
starch
how plants store glucose branched
fructose-1,6-bisphosphatase
in the cytoplasm, reverse of PFK1 removes phosphate fructose-1,6-bisphosphate --> fuctose 6-phosphate, rate limiting step of gluconeogenesis, activated by ATP directly and glucagon indirectly, inhibited by AMP and fructose-2,6-bp directly and insulin indirectly
adaptations to high altitude (low pO₂)
increased respiration, O2 affinity, rate of glycolysis, 2,3-BPG in RBC, # hemoglobin, all normalize blood O2 levels
phosphoenolpyruvate carboxykinase (PEPCK)
induced by glucagon and cortisol occurs in cytoplasm converts: oxaloacetate +GTP --> PEP
malate
intermediate conversion of oxaloacetate which can leave mitochondria via malate-aspartate shuttle, oxidized to OAA in cytoplasm
pentose phosphate pathway (PPP)
irreversible metabolic process in the cytoplasm of cells purpose: produces NADPH and ribose 5-phosphate for nucleotide synthesis activated by insulin and NADP⁺ inhibited by NADPH part 1: irreversible: glucose 6-phosphate → ribulose 5-phosphate + NADPH uses glucose-6-phosphate dehyrdogenase (G6PD) part 2: reversible: ribose 5-phosphate → pool of sugars
Glycolysis 5
isomerase, DHAP > glyceraldehyde 3-P (DHAP can be shuttled to liver to be turned into glycerol 3-P for fat storage)
metabolism of galactose
lactose → galactose + glucose by lactase lactose hydrolyzed to galactose and glucose by lactase in duodenum > transported to liver via hepatic portal vein where phosphorylated by galactokinase to trap in cell > converted to glucose 1-phosphate by galactose-1-phosphate uridyl transferase
Glut 2
low affinity transporter on hepatocyts and pancreatic cells, captures glucose in hepatic vein after meals primarily for storage, km 15mM, glucose sensor (in beta-islet cells serves as glucose sensor for insulin release along with glucokinase) specific glucose transporter that allows glucose to leave the liver cell
storing glucose
muscles store excess glucose as glycogen liver converts glucose into fatty acids for storage via glycolysis adipose tissue requires glucose to form DHAP which is converted to glycerol phosphate to store incoming fatty acids as triacylglycerols
substrate level phosphorylation
not dependent on oxygen, only means of ATP production in anaerobic tissue
fate of NADH
of O2 present, oxidized in electron transport chain, if O2 absent, oxidized by lactate dehydrogenase
pyruvate kinase
phosphoenolpyruvate --> pyruvate, produces ATP activated by fructose 1,6-bisphosphate (feedforward activation)
Glycolysis 2
phosphoglucose isomerase, glucose 6-P > fructose 6-P
Glycolysis 7
phosphoglycerate kinase, bisphosphoglycerate + Pi > 3-phosphoglycerate, ADP > ATP
Glycolysis 8
phosphoglycerate mutase, 3-phosphoglycerate > 2-phosphoglycerate
irreversible steps in glycolysis
pyruvate glucokinase/hexokinase, PFK-1, pyruvate kinase ("How Glycolysis Pushed Forward the Process: Kinases")
glycogen synthase
rate limiting enzyme of glycogenesis, activated by insulin in liver and muscle activated by glucose-6-phosphate inhibited by epinephrine inhibited by glucagon (which phosphorylates and inactivates enzyme)
glycogen phosphorylase
rate limiting enzyme of glycogenolysis breaks bonds using Pi activated by glucagon in liver activated by epinephrine and AMP in muscles inhibited by ATP
glucose-6-phosphate dehydrogenase (G6PD)
rate-limiting enzyme of the Pentose Phosphate Pathway, activated by NADP+ and insulin and inhibited by NADPH (ribose phosphate building block of nucleic acids)
glutathione
reducing agents that can help reverse free radical formation before damage done to cells
Gluconeogenesis
reverse of glycolysis, occurs during fasting occurs in the cytoplasm and mitochondria, predominantly in the liver, promoted by epinephrine and glucagon, inhibited by insulin (used to raise blood glucose levels after glycogen used up 24 hours after fasting)
glycogen
storage form of glucose branched polymer of glucose degraded in liver and skeletal muscle
metabolism of fructose (sucrose)
sucrose → glucose + fructose using sucrase sucrose hydrolyzed by sucrase resulting in fructose and glucose > transported via hepatic portal vein and phosphorylated by fructokinase > fructose 1-phosphate cleaved by aldolase B into glyceraldehyde and DHAP
PDH cofactors
thiamine, pyrophosphate, lipoic acid, CoA, FAD and NAD+
pyruvate dehydrogenase (PDH)
transition step pyruvate→acetyl-CoA complex of enzymes that converts pyruvate to acetyl-CoA, stimulated by insulin and inhibited by acetl-CoA
Glut 4
transporter of glucose in adipose and muscle tissue, responds to glucose concentrations in peripheral blood, km of 5mM close to normal blood glucose levels, insulin stimulates movement of these transports to membrane via exocytosis mechanism (ie if insulin increases, GLUT 4 transporters on plama membrane increases)
galactokinase
traps galactose by adding phosphorus
DHAP (dihydroxyacetone phosphate)
used in hepatic and adipose tissue, formed from fructose 1,6-bisphosphate, isomerized to glycerol 3-phosphate then converted to glycerol to store incoming fatty acids as triacylglycerides
Red blood cells (erythrocytes) anerobic glycolysis
1 glucose =2 ATP 1,3-BPG → 2,3-BPG using bisphosphoglycerate mutase
3-phosphoglycerate kinase
1,3 bisphosphoglycerate --> 3-phosphoglycerate, generates ATP in substrate level phosphorylation
three fates of pyruvate
1. converted to acetyl-CoA by PDH (pyruvate dehydrogenase). insulin causes increase 2. lactate by lactate dehydrogenase, 3. converted to oxaloacetate by pyruvate carboxylase if too much acetyl-CoA (ie enter gluconeogenesis)
isoform
A slightly different version of the same protein, often specific to a given tissue ex: different isoforms of gycogen enzymes in muscles and liver
kinase
An enzyme that transfers phosphate ions from one molecule to another (from ATP)
4 glucose transporters
GLUT 1 GLUT 2 GLUT 3 GLUT 4 (GLUT 2 and 4 are located in specific cells and are highly regulated)
cell respiration net count
GLYCOLYSIS: 1 glucose→2 pyruvate in cytoplasm used 2ATP made 4ATP + 2NADH NET: 2 ATP + 2 NADH TRANSITION STEP: 2 pyruvate → 2 Acetyl-CoA used 2 NAD⁺ made 2NADH + 2 Acetyl-CoA + 2CO₂ NET: 2 NADH + 2CO₂ KREB CYCLE: in mitochondrial matrix (repeat twice due to 2 pyruvates) 2 Acetyl CoA + 4C→ 6C 6C + NAD⁺ → 5C + NADH + CO₂ 5C + NAD⁺ → 4C + NADH + CO₂ 4C + ADP → 4C + ATP 4C + NAD⁺ + FADH → 4C (rearrange) + NADH + FADH₂ NET: 2 FADH₂ + 6 NADH + 4 CO₂ + 2 ATP total made entering ETC: 4ATP + 6CO₂ +10NADH + 2FADH₂ ETC: in inner membrane of mitchondria (1 NADH=2.5 ATP, 1 FADH₂=1.5 ATP) 3 complexes pumps out H into intermembrane space protons pump back to matrix through ATP synthase makes 32 ATP 6 O₂ + H⁺ → 6 H₂O
glycolysis
Glucose → 2 pyruvate 2 ATP 2 NADH cytoplasmic pathway that converts one glucose into two pyruvates releasing energy captured in two substrate level phosphorylations, produces 2 ATP, and 2 NADH used in aerobic respiration pathway (does not occur in red blood cells, or other cells deprived of mitochondria or oxygen)
NADPH vs NADH
NADH: where NAD⁺ is electron acceptor, oxidizing agent, oxidizes other molecules, is reduced to NADH NADPH: electron donor, reducing agent, reduces other molecules and is oxidized
Glycolysis 3
PFK-1, fructose 6-P > fructose 1,6-Bis P, ATP > ADP
pyruvate carboxylase
activated by acetyl-CoA. too much acetyl-CoA produced from glycolysis causes negative feedback to pyruvate production. causes gluconeogenesis oxaloacetate (from citric acid cycle) can't leave mitochondria. convert oxoloacetate to malate, which can leave via malate-aspiratate shuttle mitochondrial enzyme activated by (1st step to bypass pyruvate kinase in gluconeogenesis)
fructose 2,6-bisphosphate
activates PFK-1, involved in the indirect activation and inhibition of PFK-1 for metabolites of glycolysis to be fed to glycogen, fatty acids, and other storage molecules, not just ATP production
hexose monophosphate shunt (HMP)
aka PPP, occurs in cytoplasm of most cells, generates NADPH and sugars for biosynthesis (derived from ribulose 5-phosphate)
Glycolysis 4
aldolase, fructose 1,6-Bis P > glyceraldehyde 3-P + DHAP (dihydroxyacetone phosphate)
glucogenic amino acids
all except leucine and lysine, can be converted into intermediated that feed into gluconeogenesis
gluconeogenesis avoiding irreversible steps in glycolysis
avoid glucokinase, PFK1 and pyruvate kinase by using: pyruvate carboxylase + PEPCK fructose-1,6-bp glucose-6-phosphatase
2,3-bisphosphoglycerate (2,3-BPG)
binds allosterically to beta-chains of hemoglobin and decreases O2 affinity, shifts dissociation curve left allowing for O2 unloading, doesn't bind to fetal hemoglobin
glycogen
branched polymer of glucose, stored in cytoplasm as granules with a protein core, branching allows greater density at periphery stored in liver for the maintenance of blood glucose levels, stored in muscles as energy reserve
glycogenolysis
breakdown of glycogen uses glycogen phosphorylase to break a-1,4 bonds and a debranching enzyme to break a-1,6 bonds
debranching enzyme
breaks a-1,6 bonds to release glucose from glycogen two enzyme complex, moves a block of oligoglucose from one branch and connects it to the chain using alpha-1,4 glucosidic links, removes branchpoint connected with alpha-1,6 glycosidic links, freeing a glucose molecule
ketogenic amino acids
can be converted into ketone bodies which can be used as an alternate fuel
Gluconeogenesis key intermediates
cannot convert aetyl-CoA to glucose convert 3 intermediates to pyruvate: 1. lactate using lactate dehydrogenase 2. alanine using alanine aminotransferase 3. glycerol 3P using glycerol-3P dehydrogenase to DHAP
insulin
causes an abundance of glucose to enter a cell and be shunted to glycolysis, aerobic respiration, fuel storage pathways
Beriberi
characterized by congestive heart failure or nerve damage, can be a result of thiamine deficiency
Wernicke-Korsakoff syndrome
characterized by difficulty walking, uncoordinated eye movements, confusion, memory disturbances, can be a result of thiamine deficiency
processes in mitochondria
citric acid cycle ETC oxidative phosphorylation beta oxidation (fatty acid metabolism)
aldolase B
cleaves fructose-1,6 bisphosphate to form glyceraldehyde and DHAP
fructose
comes from honey, fruit , and sucrose, trapped in cell by fructokinase
branching enzyme
converts a-1,4 branch to a-1,6 branch introduces alpha-1,6 glycosidic linkages into the granule as it grows, (hydrolyzes alpha-1,4 bonds to release a block of oligoglucose and binds it at a different location,"1-6 puts a branch in the mix")
aldose reductase
converts galactose --> galactitol in lens of eye
pyruvate carboxylase + PEP
converts pyruvate to PEP and avoids irreversible pyruvate kinase in glycolysis
yeast fermentation
converts pyruvate to ethanol and carbon dioxide and NAD⁺ 3C→2C + CO₂
glycogenin
core protein within glycogen granule
sucrase
duodenal brushborder enzyme
Glycolysis 9
enolase, 2-phosphoglycerate > PEP
lactate dehydrogenase
enzyme for fermentation oxidizes NADH to NAD+, replenishing the oxidized coenzyme for glyceraldehyde-3-phosphate dehydrogenase.
glucose-6-phosphatase
enzyme found in endoplasmic reticulum of liver cells, glucose 6-phosphate→ glucose GLUT transporter brings glucose back to cytoplasm uses ATP energy from B-oxidation reverse of glucokinase/hexokinase
bisphosphoglycerate mutase
enzyme located on hemoglobin that catalyzes 1,3 BPG -->2,3-BPG
epimerase
enzymes that catalyze the conversion of one sugar epimer to another (these epimers are different at exactly 1 chiral carbon)
galactose-1-phosphate uridyl transferase
epimerase, converts galactose 1-phosphate to glucose 1-phosphate (in hepatic cells)
fructokinase
fructose --> fructose 1-phosphate
phosphofructokinase-1 (PFK-1)
fuctose 6-phosphate --> fructose 1,6-bisphosphate using ATP, rate limiting enzyme, inhibited by ATP and citrate, activated by AMP (citrate intermediate in citric acid cycle, both it and ATP signal that there is enough energy present)
phosphofructokinase-2 (PFK-2)
fuctose 6-phosphate --> fructose 2,6-bisphosphate, found mostly in the liver, activated by insulin, inhibited by glucagon
other monossaccharide metabolism
galactose and fructose
glycogen storage disease
genetic deficiencies that affect glycogen metabolism enzymes are defective which can lead to accumulation or lack of glycogen
galactosemia
genetic deficiency of galactokinase or galactose-1-phosphate uridultransferase which results in cataracts from excess conversion to galactitol by aldose reductase
Glycolysis 1
glucokinase / hexokinase, glucose > glucose 6-P, ATP >ADP,
glucokinase
glucose --> glucose 6-phosphate, present in pancreatic Beta-islet cells as part of glucose sensor, phosphorylation prevent glucose from exiting via GLUT transporter, induced by insulin in hepatocytes
hexokinase
glucose --> glucose 6-phosphate, in peripheral tissues, low Km value for max velocity at low [glucose], inhibited by glucose 6-phosphate
Glycolysis 6
glyceraldehyde 3-P dehydrogenase, glyceraldehyde 3-P + Pi> 1,3-Bisphosphoglycerate, NAD+ > NADH + H
glyceraldehyde-3-phosphate dehydrogenase
glyceraldehyde 3-phosphate --> 1,3 bisphosphoglycerate, uses Pi, produces NADH which feeds into elctron transport chain
von Gierke's disease
glycogen storage disease resulting from a defect in glucose 6-phosphatase cannot finish gluconeogenesis person has low blood sugar between meals needs continuous feeding to maintain blood sugar buildup of glucose-6P leads to enlarged and damaged liver
Glycogenesis
glycogen synthesis: glucose → glucose-6-P glucose-6-P → glucose-1-P glucose-1-P + UTP → glucose + UDP glucose + UDP → glycogen (glycogenin) + UDP using glycogen synthase, branching enzyme
rate limiting enzymes
glycolysis: PFK1 fermentation: lactate dehydrogenase glycogenesis: glycogen synthase glycogenolysis: glycogen phosphorylase gluconeogenesis: fructose-1,6-bp pentose phosphate pathway: glucose-6-phosphate dehydrogenase
fermentation
without oxygen produces NAD⁺ converts pyruvate to lactate Process by which cells release energy in the absence of oxygen and oxidize NADH to NAD+ (reducing pyruvate to lactate in mammals, to ethanol in yeast)
