Carbohydrates Metabolism Lecture PDF

Summary

These lecture notes on carbohydrate metabolism cover various processes such as digestion, glycolysis, gluconeogenesis, glycogenolysis, and the Cori cycle. The document provides a comprehensive overview of glucose metabolism and its regulation.

Full Transcript

CHAPTER 13: Carbohydrates
Metabolism
(LECTURE)
 Lesson Outline
Digestion of Carbohydrates
Glycolysis
Regulation of Glycolysis
Fates of Pyruvate
Gluconeogenesis
Glycogenesis and Glycogenolysis
Cori Cycle
Blood Sugar
Hormonal Control of Carbohydrate Metabolism
 Digestion of Carbohydrates
Dietary carbohydrates serve as energy resources
Account for 45–55% of daily energy needs in a typical American diet
During carbohydrate digestion, di- and polysaccharides are hydrolyzed
to monosaccharides

polysaccharides + H 2 O ⎯⎯⎯⎯
→ glucose digestion

sucrose + H 2 O ⎯⎯⎯⎯
→ glucose + fructose
digestion

lactose + H 2 O ⎯⎯⎯⎯
→ glucose + galactose
digestion

maltose + H 2 O ⎯⎯⎯⎯
→ glucose digestion
 Digestion of Carbohydrates
After digestion is completed, glucose, fructose, and galactose are
absorbed into the bloodstream through the lining of the small intestine
and transported to the liver
In the liver, fructose and galactose are converted to glucose or to compounds
that are metabolized by the same pathway as glucose

polysaccharides + H 2 O ⎯⎯⎯⎯
→ glucose digestion

sucrose + H 2 O ⎯⎯⎯⎯
→ glucose + fructose
digestion

lactose + H 2 O ⎯⎯⎯⎯
→ glucose + galactose
digestion

maltose + H 2 O ⎯⎯⎯⎯
→ glucosedigestion
 Glycolysis
Glucose (C6) is catabolically oxidized through a series of steps to
pyruvate (C3)
Occurs in the cellular cytoplasm
Net reaction
glucose + 2Pi + 2ADP + 2NAD + → 2Pyruvate + 2ATP + 2NADH + 4H + + 2H 2O
In addition to two molecules of pyruvate, two molecules of ATP, two
molecules of NADH, four molecules of H+, and two molecules of H2O
are produced
Glycolysis
 Glycolysis
Stage 1
A phosphate group is added to glucose in
the cell cytoplasm, by the action of
enzyme hexokinase.
In this, a phosphate group is transferred
from ATP to glucose forming glucose,6-
phosphate.
Stage 2
Glucose-6-phosphate is isomerized into
fructose,6-phosphate by the enzyme
phosphoglucomutase.
 Glycolysis
Stage 3
The other ATP molecule transfers a
phosphate group to fructose 6-
phosphate and converts it into fructose
1,6-bisphosphate by the action of the
enzyme phosphofructokinase.
Stage 4
The enzyme aldolase converts fructose
1,6-bisphosphate into glyceraldehyde 3-
phosphate and dihydroxyacetone
phosphate, which are isomers of each
other.
 Glycolysis
Stage 5
Triose-phosphate isomerase converts
dihydroxyacetone phosphate into glyceraldehyde 3-
phosphate which is the substrate in the successive
step of glycolysis.
Stage 6
The enzyme glyceraldehyde 3-phosphate
dehydrogenase transfers 1 hydrogen molecule from
glyceraldehyde phosphate to nicotinamide adenine
dinucleotide to form NADH + H+.
Glyceraldehyde 3-phosphate dehydrogenase adds a
phosphate to the oxidized glyceraldehyde phosphate
to form 1,3-bisphosphoglycerate.
 Glycolysis
Stage 7
Phosphate is transferred from 1,3-
bisphosphoglycerate to ADP to form ATP
with the help of phosphoglycerokinase.
Thus two molecules of
phosphoglycerate and ATP are obtained
at the end of this reaction.
Stage 8
The phosphate of both the
phosphoglycerate molecules is
relocated from the third to the second
carbon to yield two molecules of 2-
phosphoglycerate by the enzyme
phosphoglucomutase.
 Glycolysis
Stage 9
The enzyme enolase removes a water
molecule from 2-phosphoglycerate to
form phosphoenolpyruvate.
Stage 10
A phosphate from phosphoenolpyruvate
is transferred to ADP to form pyruvate
and ATP by the action of pyruvate
kinase. Two molecules of pyruvate and
ATP are obtained as the end products.
 Glycolysis
Fructose enters glycolysis as dihydroxyacetone phosphate and
glyceraldehyde-3-phosphate

Galactose enters glycolysis as glucose-6-phosphate
 Glycolysis
Regulation of Glycolysis
Glycolysis pathway is regulated by hexokinase, phosphofructokinase,
and pyruvate kinase
Glucose-6-phosphate noncompetitively inhibits hexokinase (feedback
inhibition)
Phosphofructokinase is inhibited by high concentrations of ATP and citrate
Activated by high concentrations of ADP and AMP
Pyruvate kinase is inhibited by high concentrations of ATP
As glycolysis occurs, the citric acid cycle and electron transport chain
produce large quantities of ATP
If the ATP level is low, then AMP and ADP levels are high
 Glycolysis
Regulation of Glycolysis
 Fates of Pyruvate
After glycolysis, pyruvate can be:
Oxidized to acetyl CoA (under aerobic conditions)
Reduced to lactate (under anaerobic conditions)
Reduced to ethanol (under anaerobic conditions for some prokaryotic
organisms)
All processes must regenerate NAD+ from NADH so that glycolysis can
continue
 Fates of Pyruvate
Pyruvate Oxidation to Acetyl CoA
Occurs in the mitochondria under aerobic conditions
Aerobic – in the presence of oxygen
Most of the acetyl CoA will be completely oxidized to CO2 in the citric
acid cycle
NAD+ is regenerated when NADH transfers its electrons to O2 in the
electron transport chain
Some acetyl CoA will serve as starting material for fatty acid
biosynthesis
 Fates of Pyruvate
Pyruvate Reduction to Lactate
Occurs in cells after strenuous or long-term muscle activity because
the cellular supply of oxygen is not adequate for the reoxidation of
NADH to NAD+
Under anaerobic conditions, animals and some microorganisms can
obtain limited energy through lactate fermentation
Anaerobic - in the absence of oxygen
Lactate fermentation – production of lactate from glucose
 Fates of Pyruvate
Pyruvate Reduction to Ethanol
Under anaerobic conditions, some microorganisms can obtain limited
energy through glycolysis
Alcoholic fermentation – conversion of glucose to ethanol
Overall equation:

Step-wise equations:
Fates of Pyruvate
 Gluconeogenesis
Synthesis of glucose from noncarbohydrate molecules

( lactate, certain amino acids, glycerol ) → pyruvate → glucose
Primarily occurs in the liver (90%)
Helps maintain blood glucose level
Occurs in the kidneys, brain, skeletal muscle, or heart in small
amounts
 Gluconeogenesis
Gluconeogenesis originates in the liver or kidney’s cytoplasm or
mitochondria. To make oxaloacetate, two pyruvate molecules are
required to carboxylate first. This requires one ATP (energy) molecule.
NADH converts oxaloacetate to malate, which can then be transported
out of the mitochondria.
Once malate leaves the mitochondria, it is oxidized back to
oxaloacetate.
The enzyme Phosphoenolpyruvate carboxykinase (PEPCK) converts
oxaloacetate to phosphoenolpyruvate.
 Gluconeogenesis
By reversing glycolytic processes, phosphoenolpyruvate is converted
into fructose 1,6-bisphosphate.
Fructose-1, 6-bisphosphate is converted to fructose-6-phosphate in the
reaction releasing inorganic phosphate and is catalyzed by fructose-
1,6-bisphosphatase.
The enzyme phosphoglucoisomerase converts fructose-6-phosphate to
glucose-6-phosphate.
Glucose-6-phosphate generates inorganic phosphate that yields free
glucose, which enters the blood. Glucose 6-phosphatase is the enzyme
involved.
Gluconeogenesis
 Glycogenesis
Synthesis of glycogen from glucose
Glucose units bond to a growing glycogen chain
Hydrolysis of UTP (uridine triphosphate) provides energy
Occurs in all cells but is an especially important function of liver and
muscle cells
Glycogen is mainly stored in liver and muscle tissue
Liver can store 110 g glycogen
Muscles can store 245 g glycogen
 Glycogenesis
Enzyme glycogen synthase forms the new α(1→4) linkages between
each glucose unit and lengthens the chain
α(1→6) branch points on the chain are inserted by amylose (1,4-1,6)-
trans-glycosylase
Glycogenesis
 Glycogenolysis
Breakdown of glycogen to glucose
Occurs in the liver, kidney, and intestinal cells but not in the muscle
tissue
Step 1 - Cleavage of α(1→4) linkages is catalyzed by glycogen
phosphorylase

(glucose) n + Pi → (glucose) n−1 + glucose -1- phosphate
glycogen glycogen with one
fewer glucose unit
 Glycogenolysis
Step 2 - Cleavage of α(1→6) linkages by hydrolysis
Hydrolysis is carried out by a debranching enzyme
glucose 1-phosphate → glucose 6-phosphate
Step 3 - Hydrolysis of glucose 6-phosphate
glucose - 6 - phosphate + H 2O → glucose + Pi
Glycogenolysis
 Glycogenolysis
Muscle cells cannot form free glucose from glycogen
Can carry out the first two steps of glycogenolysis to produce glucose-6-
phosphate for energy production
Liver
Maintains a relatively constant level of blood glucose
Has the capacity to degrade glycogen to glucose, which is released into the
blood during muscular activity and between meals
Metabolic Pathway of Glucose
 Cori Cycle
Process in which glucose is converted to lactate in muscle tissue,
lactate is reconverted to glucose in liver, and glucose is returned to the
muscle
During active exercise:
Lactate levels increase in muscle tissue and the compound diffuses out of the
tissue into the blood
Lactate is taken to liver and converted back to pyruvate
Pyruvate is converted to glucose by gluconeogenesis pathway and glucose
enters the blood and returns to the muscles
Cori Cycle
Cori Cycle
 Blood Sugar
Blood sugar level: Amount of glucose present in
blood, normally expressed as mg glucose per 100
mL of blood
Highest about one hour after a carbohydrate-
containing meal
Returns to normal after two to two and a half hours
Hypoglycemia – lower-than-normal blood sugar
level
Hyperglycemia – higher-than-normal blood sugar
level
 Blood Sugar
Renal threshold – blood sugar level at which sugar is not completely
reabsorbed by the kidneys
Glucosuria – condition in which elevated blood sugar levels result in the
excretion of glucose in the urine
Prolonged hyperglycemia at glucosuric levels is considered serious
Liver regulates the blood glucose level
Responds to increase in blood glucose after a meal by removing glucose from
bloodstream
Converts the removed glucose to glycogen or triglycerides
Converts glycogen to glucose and synthesizes new glucose from
noncarbohydrate substances when blood glucose levels are low
 Hormonal Control of Carbohydrate
Metabolism
Insulin
Source - β-cells of pancreas
Enhances the absorption of glucose from the blood into cells of active tissue
Increases the rate of synthesis of glycogen, fatty acids, and proteins and
stimulates glycolysis
Glucagon
Source - α-cells of pancreas
Increases blood glucose levels
Activates the breakdown of glycogen in the liver
 Hormonal Control of Carbohydrate
Metabolism
Epinephrine
Source - Adrenal medulla
Increases blood glucose levels
Stimulates glycogen breakdown in
muscles, and to a smaller extent in the
liver
Blood sugar level depends on the
biochemical balance between
insulin and glucagon
Influenced to some degree by growth
hormones and adrenal cortex steroids