Carbohydrates Metabolism PDF

Summary

This document provides an outline of carbohydrate metabolism, including the various processes, reactions, and pathways involved. It details stages of metabolism including catabolism and anabolism, then dives into the importance of ATP, glycolysis, and the Kreb's Cycle. It also explains gluconeogenesis, the Cori Cycle and glycogenolysis.

Full Transcript

CARBOHYDRATES
PART 2: METABOLISMS
Metabolism
 Sum of all enzymatic reactions
occurring in biological systems.
 Involves energy transformation; it tells
how energy is acquired, transformed,
used and stored in a cell.
Phases of Metabolism
1. Catabolism
- degradative phase or breaking down process.
- metabolic pathway that leads to the decomposition
of large complex molecules into small molecules.
- often accompanied by release of energy; energy
producing process.
Ex. (CH2O)n, proteins, fats CO2, H2O,
NH3, Urea.
Phases of Metabolism
2. Anabolism
- biosynthetic phase or building process.
- metabolic pathway where in large complex
organic molecules are constructed from small
molecules.
- often requires the input of energy; energy
consuming process.
Ex. Pyruvate, glucose, CO2
(CH2O)n, proteins, fats
Sources of Caloric Energy
1. Carbohydrates 1 g = 4 kcal
2. Fats 1g = 9 kcal
3. Protein 1g = 4 kcal
Average Filipino Diet
55 – 65% Carbohydrates
15 – 20% Fats
5 – 15% Protein
 Digestion of carbohydrates –
Top – Early digestion depicting the intake of dietary
carbohydrates and the role of salivary amylase
 Digestion of carbohydrates
Middle – Luminal digestion showing the combined
roles of the stomach, pancreas and intestine.
 -amylase

-amylase
etc.
1→6
etc.
1→4

Maltotriose

-Amylase, of salivary or pancreatic origin,
cleaves amylopectin to produce all of the
products shown
 -amylase

-amylase
etc.
1→6

1→4

-limit dextrin
(branched oligosaccharide;
unbranched also produced)

-Amylase, of salivary or pancreatic origin, cleaves
amylopectin to produce all of the products shown
 etc.
-amylase -amylase
1→6

1→4

Maltose Glucose

-Amylase, of salivary or pancreatic origin, cleaves
amylopectin to produce all of the products shown
 Digestion of carbohydrates
Bottom – Summary of the brush border glycoprotein complexes containing
disaccharidases and oligosachharidases.
Carbohydrates Metabolism
 Is centered on the provision and fate of
glucose
 Glucose is known as blood sugar;
dextrose.
 One major pathway for the utilization
of glucose is GLYCOLYSIS.
GLYCOLYSIS
 Is localized in the cytosol (soluble portion of the
cytoplasm) of all cells.
 It is a unique pathway, since it can utilize O2 if
available (Aerobic) or it can function in the total
absence of O2 (Anaerobic).
 In aerobic condition the end product is Pyruvate.
 In anaerobic condition, the end product is
Lactate.
ARSENATE/Pi=1-ARSENO-
3-PHOSPHOGLYCERATE

Mn2+
ATP
 Stands for
Adenosine
Triphosphate
 It is composed of
Adenine
(Nitrogenous base),
Ribose (5 C sugar)
and Phosphate
group.
Role of ATP
 Food and oxygen react chemically to produce
energy. (food is oxidized to release energy)
 Oxidation of food in the cells is also known as
CELLULAR RESPIRATION.
 The energy produced during Cellular Respiration
is trapped in molecules of ATP.
 ATP supplies the energy needed for all activities
of the cells.
How is ATP produced in
biological system?
Two types of ATP Production
1. Oxidative Phosphorylation
- production of ATP through redox reactions
in the mitochodria by the way of Electron
Transport Chain (E.T.C)

1 mol NADH → E.T.C.→ 3 ATPs
1 mol FADH2→E.T.C.→ 2ATPs
How is ATP produced in
biological system?
2. Substrate Level Phosphorylation
- production of ATP at the substrate level.
Kreb’s Cycle
sequence of reactions in mitochondria

oxidizes the acetyl moiety of acetyl-CoA

reduces coenzymes that are reoxidized
through the electron transport chain
final common pathway for the oxidation of
carbohydrate, lipid, and protein
Kreb’s Cycle
 Acetyl CoA comes from pyruvate produce in
aerobic glycolysis.
 Rxn for pyruvate conversion to Acetyl CoA:
CH3COCOO + NAD+ + CoASH
(Pyruvate) (CoenzymeA)
CH3COSCoA + CO2 + NADH
(Acetyl CoA)
 REGULATORY STEP
-NADH,SUCCINYL COA

REGULATORY
STEP:
+ADP,Ca
REGULATORY STEP:
-NADH,ATP
-NADH,SUCCINYL
COA
Gluconeogenesis
 Synthesis of glucose from non
carbohydrate sources.
 Major substrates are:
1. Glucogenic amino acids
2. Lactate
3. Glycerol
4. Propionate
Major tissues involved: liver and
kidney.
Biomedical Importance of
Gluconeogenesis
Response the needs of the body for glucose
when carbohydrate is not available in sufficient
amounts from the diet.
A continual supply of glucose is necessary as a
source of energy, especially for the nervous
system and the erythrocytes (red blood cells).
Biomedical Importance of
Gluconeogenesis
 Brain is highly dependent on glucose as the
primary fuel.
Below a critical blood glucose
concentration, brain will
malfunctioned, which can lead to
coma and death.
Biomedical Importance of
Gluconeogenesis
 Glucose is also required in adipose tissue
(fat tissue) as a source of glyceride, and
plays a role in maintaining the level
intermediates of the Kreb’s cycle in many
tissue.
Biomedical Importance of
Gluconeogenesis
 Glucose is the only fuel that will supply
energy to skeletal muscles under anaerobic
conditions.
 Glucose is the precursor of milk sugar
(lactose) in the mammary gland, and is
taken up actively by the fetus.
Gluconeogenesis
 Gluconeogenesis involves glycolysis, citric acid
cycle plus some special reactions.
 Carbon atoms for gluconeogenesis from lactate,
some amino acids, and glycerol are converted to
pyruvate or other intermediates.
 Seven reactions are the reverse of glycolysis and
use the same enzymes.
Gluconeogenesis
 Special reactions:
1. Pyruvate to Oxaloacetate
2. Oxaloacetate to Phosphoenolpyruvate
3. Fructose 1,6 – bisphosphate to
Fructose 6- phosphate
4. Glucose 6 - phosphate to Glucose
Gluconeogenesis: Glucose
Synthesis
 Cori Cycle
 When anaerobic conditions occur in active muscle,
glycolysis produces lactate.
 The lactate moves through the blood stream to the
liver, where it is oxidized back to pyruvate.
 Gluconeogenesis converts pyruvate to glucose, which
is carried back to the muscles.
 The Cori cycle is the flow of lactate and glucose
between the muscles and the liver.
Cori Cycle
Glycogen Metabolism
Glycogen is the human storage
glucan polysaccharide.
 In a 70kg adult:

80g in liver
260g in skeletal muscles.
Glycogen Metabolism
 Hepatic glycogen serves to
maintain the blood glucose
concentration particularly between
meals.
 Muscle glycogen serves only as an
energy reserve for muscle activity.
Glycogen molecules are branched chains of
α14-linked glucose residues held together
via α16 linkages.

α14 linkages

α16 linkage (branch point)

α14 linkages
Glycogen Metabolism
1. Glycogenesis
2. Glycogenolysis
Glycogenesis
 Synthesis of glycogen from glucose
 It is carried out by the enzyme glycogen
synthase
 Occurs when there is excess of glucose in
the body thus helps in the control of
glucose in the blood
 Is stored in the liver
 Occurs in all the tissues of the body but the
major sites are liver and muscles
Glycogenesis
Glycogenesis
 Glycogen Metabolism

Glycogenolysis
is the break down of
glycogen to glucose.
Gycogenolysis
Glycogenolysis
Regulation of Glycogen
Metabolism
 Glucagon and insulin are major
regulators of glycogen metabolism.
 Adrenaline also has an important role
in regulating breakdown of glycogen.
 Hormonal regulation of carbohydrate
metabolism proceeds via complex
intracellular signalling cascades
involving phosphorylation and
dephosphorylation of proteins.
Regulation of Glycogen
Metabolism
 Glucagon stimulates breakdown
of glycogen resulting in release
of glucose into the blood.
 Glucagon has a short half-life in
the blood (c. 5min). This enables
rapid changes in glycogen
metabolism to suit to the body’s
needs.
Regulation of Glycogen
Metabolism
 Glucagon causes:

inhibition of glycogen
synthesis
stimulation of glycogen
breakdown
 These processes result in
release glucose from the liver.
Regulation of Glycogen
Metabolism
 INSULIN REVERSES THE EFFECTS
OF GLUCAGON ON GLYCOGEN
METABOLISM
 Insulin receptors are present on liver,
muscle and fat cells (adipocytes).
stimulates glycogen synthesis

stimulates glycolysis

inhibits gluconeogenesis.
Regulation of Glycogen
Metabolism
 ADRENALINE (EPINEPHRINE)
STIMULATES BREAKDOWN OF
GLYCOGEN TO GLUCOSE IN THE LIVER
AND MUSCLES
 Adrenaline stimulates glycogen
breakdown via protein phosphorylation
 Adrenaline-mediated protein
phosphorylation results in glycogen
breakdown to glucose and release of
glucose from the liver into the
bloodstream.
D:\carbohydrate\carbohydrate\53.jpg
Flight or Fight Response
 This is the body's response to perceived threat or
danger. During this reaction, certain hormones
like adrenalin and cortisol are released, speeding
the heart rate, slowing digestion, shunting blood
flow to major muscle groups, and changing
various other autonomic nervous functions,
giving the body a burst of energy and strength.
Pathways for Glucose
“The End”