carbohydrate digestion & metabolism
DESCRIPTION
CARBOHYDRATE DIGESTION & METABOLISM. Definition. Metabolism (from Greek : μεταβολή " metabolē ", "change" or Greek : μεταβολισμός metabolismos , " outthrow ") is the set of chemical reactions that happen in the cells of living organisms to sustain life. - PowerPoint PPT PresentationTRANSCRIPT
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CARBOHYDRATE DIGESTION & METABOLISM
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Definition• Metabolism (from Greek: μεταβολή "metabolē",
"change" or Greek: μεταβολισμός metabolismos, "outthrow") is the set of chemical reactions that happen in the cells of living organisms to sustain life.
• These processes allow organisms to grow and reproduce, maintain their structures, and respond to their environments. Metabolism is usually divided into two categories.
• Catabolism breaks down organic matter, for example to harvest energy in cellular respiration.
• Anabolism uses energy to construct components of cells such as proteins and nucleic acids.
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Chemical Reaction• The chemical reactions of metabolism are organized into
metabolic pathways, in which one chemical is transformed through a series of steps into another chemical, by a sequence of enzymes.
• Enzymes are crucial to metabolism because they allow organisms to drive desirable reactions that require energy and will not occur by themselves, by coupling them to spontaneous reactions that release energy.
• As enzymes act as catalysts they allow these reactions to proceed quickly and efficiently.
• Enzymes also allow the regulation of metabolic pathways in response to changes in the cell's environment or signals from other cells.
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Selective reaction
• The metabolism of an organism determines which substances it will find nutritious and which it will find poisonous.
• For example, some prokaryotes use hydrogen sulfide as a nutrient, yet this gas is poisonous to animals.
• The speed of metabolism, the metabolic rate, influences how much food an organism will require, and also affects how it is able to obtain that food.
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CARBOHYDRATE DIGESTION
• AMYLUM digestion by amylase enzyme
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Disaccharides digestion
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► Glucose is the most important carbohydrate► Glucose is the major metabolic fuel of
mammals, except ruminants ► Monosaccharide from diet : - Glucose - Fructose - Galactose► Fructose and Galactose glucose at the
liver
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Galactose Metabolism
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Fructose Metabolism
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Blood glucose carbohydrate metabolism exist are :
1. Glycolisis 2. Glycogenesis 3. HMP Shunt 4. Oxidation of Pyruvate 5. Kreb’s Cycle 6. Change to lipids Fasting blood glucose carbohydrate
metabolism : 1. Glycogenolisis 2. Gluconeogenesis
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GLYCOLISIS
Glycolisis oxidation of glucose energy It can function either aerobically or anaerobically
pyruvate lactate Occurs in the cytosol of all cell AEROBICALLY GLYCOLYSIS : Pyruvate Mitochondria oxidized to
Asetil CoA Kreb’s Cycle CO2 + H2O + ATP
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Glycolisis
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Most of the reaction of glycolysis are reversible, except of three reaction :
1. Glucose Glucose-6-phosphate, catalyzed by Hexokinase / Glucokinase
Hexokinase : - Inhibited allosterically by its product
glucose-6-p - Has a high affinity for its substrate glucose - available at all cell, except liver and islet cell
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Glucokinase : - available at liver and islet cell - in the liver to remove glucose from the
blood after meal 2. Fructose-6-P Fructose-1,6-biP - catalyzed by Phosphofructokinase enzyme - Irreversible - Rate limiting enzyme in glycolysis 3. Phosphoenolpyruvate Enol Pyruvate - Catalyzed by Pyruvate kinase enzyme Oxidation of 1 mol glucose 8 mol ATP and 2
mol Pyruvate
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ANAEROBICALLY GLYCOLYSIS : - The reoxidation of NADH through the
respiratory chain to oxygen is prevented - Pyruvate is reduced by the NADH to lactate, by
Lactate dehidrogenase enzyme Lactate dehydrogenase Pyruvate + NADH + H+ Lactate + NAD+
- Oxidation 1 mol glucose via anaerobically glycolysis 2 mol ATP
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ANAEROBICALLY GLYCOLYSIS : Respiratory chain is absence
Reoxidation of NADH NAD+ via Respiratory chain is inhibited
Reoxidation of NADH via lactate formation allows glycolysis to proceed in the absence of oxygen by regenerating sufficient NAD+
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GLYCOLYSIS IN ERYTHROCYTE• Erythrocyte lack mitochondria
respiratory chain and Kreb’s cycle are absence
• Always terminates in lactate• In mammals the reaction catalyzed by
phosphoglycerate kinase may be bypassed by a process that catalyzed Biphosphoglycerate muta-
se• Its does serve to provide 2,3-
biphosphoglycerate bind to hemoglobin decreasing its
affinity for oxygen oxygen readily available to tissues
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GLYCOLYSIS IN ERYTHROCYTE
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OXIDATION OF PYRUVATE• Occur in mitochondria• Oxidation of 1 mol Pyruvate 1 mol
Asetyl-CoA + 3 mol ATP• CH3COCOOH + HSCoA + NAD+ CH3CO-SCoA +
NADH (Pyruvate) (Asetyl-CoA)• Catalyzed by Pyruvate dehydrogenase
enzyme• This enzyme need CoA as coenzyme• In Thiamin deficiency, oxydation of
pyruvate is impaired lactic and pyruvic acid
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OXIDATION OF PYRUVATE
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GLYCOGENESIS• Synthesis of Glycogen from glucose• Occurs mainly in muscle and liver cell• The reaction :• Glucose Glucose-6-P Hexokinase / Glucokinase• Glucose-6-P Glucose-1-P Phosphoglucomutase• Glucose-1-P + UTP UDPG +
Pyrophosphate UDPG Pyrophosphorylase
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GLYCOGENESIS
• Glycogen synthase catalyzes the formation of α-1,4-glucosidic linkage in glycogen
• Branching enzyme catalyzes the formation of α-1,6-glucosidic linkage in glycogen
• Finally the branches grow by further additions of 1 → 4-gucosyl units and further branching (like tree!)
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SYNTHESIS OF GLYCOGEN
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SYNTHESIS OF GLYCOGEN
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GLYCOGENESIS AND GLYCOGENOLYSIS PATHWAY
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Glycogenesis Glycogenolysis
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GLYCOGENOLYSIS
• The breakdown of glycogen• Glycogen phosphorilase catalyzes
cleavage of the 1→4 linkages of glycogen to yield glucose-1-phosphate
• α(1→4)→α(1→4) glucan transferase transfer a trisaccharides unit from one branch to the other
• Debranching enzyme hydrolysis of the 1→6 linkages
• The combined action of these enzyme leads to the complete breakdown of glycogen.
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GLYCOGENOLYSIS Phosphoglucomutase• Glucose-1-P Glucose-6-P Glucose-6-phosphatase• Glucose-6-P Glucose• Glucose-6-phosphatase enzyme a
spesific enzyme in liver and kidney, but not in muscle
• Glycogenolysis in liver yielding glucose export to blood to increase the blood glu-
cose concentration• In muscle glucose-6-P glycolysis
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GLUCONEOGENESIS
Pathways that responsible for converting noncarbohydrate precursors to glucose or glycogen
In mammals occurs in liver and kidney Major substrate : 1. Lactic acid from muscle,
erythrocyte 2. Glycerol from TG hydrolysis 3.Glucogenic amino acid 4. Propionic acid in ruminant
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Gluconeogenesis meets the needs of the body for glucose when carbohydrate is not available from the diet or from glycogenolysis
A supply of glucose is necessary especially for nervous system and erythrocytes.
The enzymes : 1. Pyruvate carboxylase 2. Phosphoenolpyruvate karboxikinase 3. Fructose 1,6-biphosphatase 4. Glucose-6-phosphatase
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GLUCONEOGENESIS
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GLUCONEOGENESIS FROM AMINO ACID
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GLUCONEOGENESIS FROM PROPIONIC ACID
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CORY CYCLE
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HMP SHUNT/HEXOSE MONO PHOSPHATE SHUNT = PENTOSE PHOSPHATE PATHWAY
• An alternative route for the metabolism of glucose
• It does not generate ATP but has two major function :
1. The formation of NADPH synthesis of fatty acid and steroids
2. The synthesis of ribose nucleotide and nucleic acid formation
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HMP SHUNT
• Active in : liver, adipose tissue, adrenal cortex, thyroid, erythrocytes, testis and lactating mammary gland
• Its activity is low in muscle• In erythrocytes : • HMP Shunt provides NADPH for the reduction of
oxidized glutathione by glutathione reductase reduced glutathi-
one removes H2O2 glutathione peroxidase
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HMP SHUNT
Glutathione reductase• G-S-S-G 2-G-SH(oxidized glutathione) (reduced glutathione) Glutathione peroxidase• 2-G-SH + H2O2 G-S-S-G + 2H2O• This reaction is important accumulation of H2O2
may decrease the life span of the erythrocyte damage to the membrane cell hemolysis
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HMP SHUNT
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BLOOD GLUCOSE
• Blood glucose is derived from the : 1. Diet the digestible dietary carbohy- drate yield glucose blood 2. Gluconeogenesis 3. Glycogenolysis in liver• Insulin play a central role in regulating blood glucose
blood glucose• Glucagon blood glucose• Growth hormone inhibit insulin activity• Epinefrine stress blood glucose