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Studied by 19 peopleNoteStudied by 66 peopleNoteStudied by 100 peopleNoteStudied by 6 peopleNoteStudied by 18 peopleNoteStudied by 68 people
IAS13
IAS13: Glucose metabolism
common dietary carbohydrates
outline basic digestion and absorptions of common sugars
compare and contrast between anaerobic glycolysis and aerobic cellular respiration
recognize the networks of glucose metabolism
relate metabolic concepts to clinical connections
Dietary carbohydrates
empirical formular: (CH2O)n, n >= 3
α-glucose: starch (amylose, amylopectin), glycogen
β-glucose: cellulose
→ affects angle of bonds formed, 3D molecular structure
starch: major carbohydrate in diet
glycogen: one of the fuel molecules in body stores
glucose: common monomer
lactose (β-1,4 between galactose, glucose)
sucrose (α-1,2 between glucose, fructose)
Glucose metabolism degradation by α-amylases
amylose (linked by α-1,4 glycosidic bonds) → maltotriose + maltose + glucose
amylopectin (branched chain of glucose subunits linked by α-1,6, glycosidic bonds) → α-limit dextrin (α-1,6 + α-1,4)/isomaltose (disaccharide linked by α-1,6) (spatially branching enables more efficient packaging of polymers) glycosidase activities in glycoproteins:
glucoamylase (oligosaccharides): release glucose from α-1,4 linked glucosyl residues
sucrase-isomaltose complex: cleave sucrose, α-1,4, α-1,6 linked glucosyl residues
trehalose: cleave trehalose (α-1,1 glucose-glucose, found in insects, algae, mushrooms)
lactase-glucosylceramidase (β glycosidase complex): cleave β-1,4 between galactose and glucose in lactose → small intestinal disaccharidases
Processing from exogenous supply
→ salivary α-amylase cleave some α-1,4 bonds in amylose chain → hydrolase enzymes absorbed on mucosal cells to convert dietary carbohydrates into free monosaccharides → undigested carbohydrates in ileum (fermented by bacteria) enters colon, egested
Intestinal villi
α-1,4 bonds in amylose cleaved by pancreatic α-amylase to release glucose
glycosidases (small intestinal disaccharidases) attached to membrane in brush border of enterocytes
monosaccharides transporters in intestinal absorptive cells
SGLT (sodium-glucose linked transporters): (brush border) active transport, co-transports glucose or galactose with Na ion down Na concentration gradient generated by Na-K ATPase pump in basolateral membrane
GLUT (glucose transporters):
GLUT5--fructose (brush border + basolateral)
GLUT2--fructose, galactose, glucose (basolateral)
Cellular uptake of glucose
liver: GLUT2 (bidirectional glucose transporter), store glucose as glycogen/fatty acid & cholesterol in triacylglycerol TG
muscles: GLUT4 (insulin-sensitive), glucose as major fuel, majorly use fatty acids & ketone bodies, store glucose as glycogen
erythrocytes: GLUT1 depend on glucose
brain: GLUT3, GLUT1 (endothelial cells lining blood-brain barrier), depend on glucose, can use ketone bodies in starvation
adipocytes: GLUT4--increase in insulin → facilitate uptake of glucose → converted to acetyl-CoA for de novo fatty acid biosynthesis → converted to glycerol-3-phosphate (backbone for TG)
galactose: converted to glucose then glycogen in liver
fructose: converted to glucose then glycogen then lactate in liver/fatty acid (low blood fructose concentration)
Cellular fate of glucose
Glucose phosphorylation upon entry, glucose is converted to glucose-6-phosphate (irreversible) to trap glucose in the cell
Glycolysis energy investment phase: glucose -ATP + hexokinase→ glucose 6-P ←→ fructose 6-P -ATP + phosphofructonkinase-1 energy generation phase: fructose-1,6-bis P → 2 NADH + 4 ATP → 2 pyruvate (pyruvic acid) overall: 2 NADH, 2 ATP, 2 pyruvate anaerobic glycolysis:
pyruvate converted by LDH-A to lactate
lactate is exported by MTC (monocarboxylate transporter)
no net generation of NADH Lactate:
in heart muscles, resting skeletal muscles, converted to pyruvate for entering TCA cycle
return to liver to reconvert to glucose by gluconeogenesis via pyruvate (Cori cycle)
Aerobic cellular respiration
oxidation of pyruvate (release CO2) → acetyl-CoA
TCA cycle: CO2, NAD+ → NADH (electron carrier)
oxygen as final electron acceptor in electron transport chain to form water → glucose: CO2: H2O = 1:6:6, 30-32 ATP generated
Pentose phosphate pathway (PPP): provides cellular NADPH (biochemical reductants), ribose-5-phosphate for nucleotide biosynthesis UDP-glucose:
intermediate in formation of glycogen
channelled for addition of sugar to proteins in post-translational modification
Summary & clinical connections
Uptakes
GLUT1: blood cell, blood-brain barrier, baby (fetus cells)
GLUT2: liver, kidney, pancreas, intestine
GLUT3: neurons, placenta
GLUT4: muscle, fat cells
glucose can be synthesized from amino acids in dietary protein, triacylglycerol glucose can be synthesized into galactose, xylulose, and sugars for metabolic processes
Lactose intolerance condition of pain, nausea, flatulence after ingestion of foods containing lactose (dairy products) caused by low levels of lactase/intestinal injury
Malabsorption of fruit juice fructose absorption is less efficient in large amounts → enter colon alongside potential diarrhea inducing ingredients (e.g. sorbitol) → actively fermented by bacteria producing excess gases, excess water drawn in → diarrhea
PET (positron emission tomography) scan
uses glucose analog as radioactive tracer (fluorine-18 fluorodeoxyglucose $^{18}F-FDG$)
OH group on C2 position of glucose substituted by fluorine-18 (radioactive isotope) → taken up by glucose-using cells, phosphorylated by hexokinase (trapped in cell until decay)
allows intense radiolabelling of tissues with high glucose uptake, characteristic to cancers
IAS13
IAS13: Glucose metabolism
common dietary carbohydrates
outline basic digestion and absorptions of common sugars
compare and contrast between anaerobic glycolysis and aerobic cellular respiration
recognize the networks of glucose metabolism
relate metabolic concepts to clinical connections
Dietary carbohydrates
empirical formular: (CH2O)n, n >= 3
α-glucose: starch (amylose, amylopectin), glycogen
β-glucose: cellulose
→ affects angle of bonds formed, 3D molecular structure
starch: major carbohydrate in diet
glycogen: one of the fuel molecules in body stores
glucose: common monomer
lactose (β-1,4 between galactose, glucose)
sucrose (α-1,2 between glucose, fructose)
Glucose metabolism degradation by α-amylases
amylose (linked by α-1,4 glycosidic bonds) → maltotriose + maltose + glucose
amylopectin (branched chain of glucose subunits linked by α-1,6, glycosidic bonds) → α-limit dextrin (α-1,6 + α-1,4)/isomaltose (disaccharide linked by α-1,6) (spatially branching enables more efficient packaging of polymers) glycosidase activities in glycoproteins:
glucoamylase (oligosaccharides): release glucose from α-1,4 linked glucosyl residues
sucrase-isomaltose complex: cleave sucrose, α-1,4, α-1,6 linked glucosyl residues
trehalose: cleave trehalose (α-1,1 glucose-glucose, found in insects, algae, mushrooms)
lactase-glucosylceramidase (β glycosidase complex): cleave β-1,4 between galactose and glucose in lactose → small intestinal disaccharidases
Processing from exogenous supply
→ salivary α-amylase cleave some α-1,4 bonds in amylose chain → hydrolase enzymes absorbed on mucosal cells to convert dietary carbohydrates into free monosaccharides → undigested carbohydrates in ileum (fermented by bacteria) enters colon, egested
Intestinal villi
α-1,4 bonds in amylose cleaved by pancreatic α-amylase to release glucose
glycosidases (small intestinal disaccharidases) attached to membrane in brush border of enterocytes
monosaccharides transporters in intestinal absorptive cells
SGLT (sodium-glucose linked transporters): (brush border) active transport, co-transports glucose or galactose with Na ion down Na concentration gradient generated by Na-K ATPase pump in basolateral membrane
GLUT (glucose transporters):
GLUT5--fructose (brush border + basolateral)
GLUT2--fructose, galactose, glucose (basolateral)
Cellular uptake of glucose
liver: GLUT2 (bidirectional glucose transporter), store glucose as glycogen/fatty acid & cholesterol in triacylglycerol TG
muscles: GLUT4 (insulin-sensitive), glucose as major fuel, majorly use fatty acids & ketone bodies, store glucose as glycogen
erythrocytes: GLUT1 depend on glucose
brain: GLUT3, GLUT1 (endothelial cells lining blood-brain barrier), depend on glucose, can use ketone bodies in starvation
adipocytes: GLUT4--increase in insulin → facilitate uptake of glucose → converted to acetyl-CoA for de novo fatty acid biosynthesis → converted to glycerol-3-phosphate (backbone for TG)
galactose: converted to glucose then glycogen in liver
fructose: converted to glucose then glycogen then lactate in liver/fatty acid (low blood fructose concentration)
Cellular fate of glucose
Glucose phosphorylation upon entry, glucose is converted to glucose-6-phosphate (irreversible) to trap glucose in the cell
Glycolysis energy investment phase: glucose -ATP + hexokinase→ glucose 6-P ←→ fructose 6-P -ATP + phosphofructonkinase-1 energy generation phase: fructose-1,6-bis P → 2 NADH + 4 ATP → 2 pyruvate (pyruvic acid) overall: 2 NADH, 2 ATP, 2 pyruvate anaerobic glycolysis:
pyruvate converted by LDH-A to lactate
lactate is exported by MTC (monocarboxylate transporter)
no net generation of NADH Lactate:
in heart muscles, resting skeletal muscles, converted to pyruvate for entering TCA cycle
return to liver to reconvert to glucose by gluconeogenesis via pyruvate (Cori cycle)
Aerobic cellular respiration
oxidation of pyruvate (release CO2) → acetyl-CoA
TCA cycle: CO2, NAD+ → NADH (electron carrier)
oxygen as final electron acceptor in electron transport chain to form water → glucose: CO2: H2O = 1:6:6, 30-32 ATP generated
Pentose phosphate pathway (PPP): provides cellular NADPH (biochemical reductants), ribose-5-phosphate for nucleotide biosynthesis UDP-glucose:
intermediate in formation of glycogen
channelled for addition of sugar to proteins in post-translational modification
Summary & clinical connections
Uptakes
GLUT1: blood cell, blood-brain barrier, baby (fetus cells)
GLUT2: liver, kidney, pancreas, intestine
GLUT3: neurons, placenta
GLUT4: muscle, fat cells
glucose can be synthesized from amino acids in dietary protein, triacylglycerol glucose can be synthesized into galactose, xylulose, and sugars for metabolic processes
Lactose intolerance condition of pain, nausea, flatulence after ingestion of foods containing lactose (dairy products) caused by low levels of lactase/intestinal injury
Malabsorption of fruit juice fructose absorption is less efficient in large amounts → enter colon alongside potential diarrhea inducing ingredients (e.g. sorbitol) → actively fermented by bacteria producing excess gases, excess water drawn in → diarrhea
PET (positron emission tomography) scan
uses glucose analog as radioactive tracer (fluorine-18 fluorodeoxyglucose $^{18}F-FDG$)
OH group on C2 position of glucose substituted by fluorine-18 (radioactive isotope) → taken up by glucose-using cells, phosphorylated by hexokinase (trapped in cell until decay)
allows intense radiolabelling of tissues with high glucose uptake, characteristic to cancers
NoteStudied by 19 peopleNoteStudied by 66 peopleNoteStudied by 100 peopleNoteStudied by 6 peopleNoteStudied by 18 peopleNoteStudied by 68 people