Metabolism 1 PDF

Summary

This document provides an introduction to metabolism, the sum of chemical reactions in living cells. It covers catabolism, anabolism, and amphibolism, along with the cellular pathways and energy involved. It also explains the steps of carbohydrate digestion.

Full Transcript

Introduction to Metabolism

Thousands of chemical reactions are taking place inside a cell in an organized,
well coordinated, and purposeful manner; all these reactions are collectively
called metabolism.

Metabolism is the sum total of all chemical reactions in living cells; It is the
overall process through which living systems acquire and utilize free energy
to carry out their functions

Metabolism (syn = intermediary metabolism)
Is the totality of the chemical reactions in the cell catalyzed by enzymes

The intermediates, substrates or products of these enzyme-catalyzed reactions
are called metabolites

Sequence of enzymatic reactions that produce specific products are called
metabolic pathways
There are 3 types of metabolic pathways:
i. Catabolism or catabolic pathway: “down”
ii. Anabolism or anabolic pathway: “up”
iii. Amphibolism or amphibolic pathway: “cross road”

Metabolic pathways
Catabolism: is the breakdown of large molecules to small
molecules. It yields energy

Anabolism: is the formation of big molecules from small
molecules. It consumes energy

Amphibolism: is the pathway that involves in both breakdown
and build up of molecules. It is described as “cross road”
between anabolic and catabolic pathways e.g CAC
- Chemical energy is obtained from the degradation of energy rich
nutrients.

- When energy rich complex macromolecules are degraded into
smaller molecules, energy release during this process is trapped
as chemical energy, usually as ATP i.e. catabolism.

- The cells need this energy to synthesize complex molecules from
simple precursors i.e. anabolism.

- The degradation of foodstuffs occurs in 3 stages:
1. Digestion in the GIT to convert the macromolecules into small
units e.g. proteins are digested to amino acids. This is called
primary metabolism.

2. Absorption of these products, followed by degradation/
catabolism to smaller units, and ultimately oxidized to CO 2.
During this stage, reducing equivalents are generated in the
mitochondria by the common oxidative pathway (i.e.
amphibolic) known as citric acid cycle (CAC). In this process,
NADH or FADH2 are generated. This called secondary or
intermediary metabolism.
3. Finally, these reduced equivalents enter into electro transport
chain, ETC (Respiratory chain) where energy is released. This is
tertiary metabolism or internal respiration (or cellular
respiration).

Digestion of Carbohydrates
In the diets, carbohydrates are present as complex
polysaccharides (starch, glycogen), and in some cases as
disaccharides (sucrose and lactose).

They are hydrolysed to monosaccharide units (glucose, galactose
and fructose) in GIT.

a. Digestion in mouth:
- Digestion of carbohydrates starts in the mouth, where they
come in contact with saliva during mastication.
- Saliva contains a carbohydrate splitting enzyme called
salivary amylase (ptyalin).
- The enzyme hydrolyzes α-1 → 4 glycosidic linkage inside
polysaccharide molecule like starch, glycogen and dextrins,
producing smaller molecules maltose, glucose and
trisaccharide maltotriose.
b. Digestion in stomach
- Practically no action. No carbohydrate splitting enzymes
available in gastric juice.

c. Digestion in duodenum
- Food bolus reaches the duodenum from stomach where it
mixes with the pancreatic juice.
- Pancreatic juice contains a carbohydrate-splitting enzyme
pancreatic amylase (also called amylopsin) similar to
salivary amylase.
- The enzyme hydrolyses α-1→4 glycosidic linkage in
polysaccharide molecule.

d. Digestion in Small Intestine
- Intestinal juice (succus entericus) contains amylase, lactase,
maltase, isomaltase and sucrase.
- Intestinal amylase hydrolyses terminal α-1→4, glycosidic
linkage in polysaccharides and oligosaccharide molecules
liberating free glucose molecule.
- Lactase hydrolyses lactate to equimolar amounts of glucose
and galactose.
 Specific Transporters For Glucose.
GluT 1 is present in RBC, brain, kidney, colon, retina and
placenta. It is responsible for glucose uptake in most cells.

GluT 2 is found in the serosal surface of intestinal cells, liver,
beta cells of pancreas. It is responsible for glucose uptake in liver
and it is the glucose sensor in beta cells. It has low affinity for
glucose.

GluT 3 is found in neurons and brain. It has high affinity for
glucose. It is responsible for glucose uptake into the brain cells.

GluT 4 is found in skeletal muscle, heart muscle and adipose
tissue. It is responsible for insulin mediated glucose uptake.

GluT 5 is found in small intestine, testis, sperms and kidney. It
has poor ability to transport glucose but it serves as fructose
transporter.

GluT 7 is found in liver ER. It involves in transport of glucose
Absorption of Carbohydrates
- Only monosaccharides are absorbed by the intestine.
- Absorption rate is maximum for galactose, moderate for glucose
and minimum for fructose.

Mechanisms of Absorption
Simple/passive diffusion
- This is dependent on sugar concentration gradients between the
intestinal lumen, mucosal cells and blood plasma.
- All the monosaccharides are probably absorbed to some extent
by simple ‘passive’ diffusion.

Facilitated diffusion /“Active” Transport Mechanisms
- Glucose and galactose are absorbed very rapidly and hence it
has been suggested that they are absorbed actively and it
requires energy.
- Glucose, galactose and fructose are absorbed by facilitated
diffusion which is mediated by specific carrier molecule
(membrane proteins) present in the enterocyte membrane.
Mechanism of glucose absorption

I. Co-transport from lumen to intestinal cell
- Process is mediated by sodium-dependent glucose transporter-1
(S GluT-1).
- Glucose is co-transported with sodium. The sodium is later
expelled by sodium pump.
- This is involved in the treatment of diarrhea.
- The oral rehydration fluid contains sodium and glucose.
- Presence of glucose allows uptake of sodium to replenish sodium
chloride lost due to dehydration.

II. Uniport system
- Intestinal cells release glucose into blood stream by carrier
molecule called Glucose transporter 2 (GLUT 2).
- This transporter is not dependent on sodium. It is a uniport,
facilitated diffusion.
III. Glucose Transporter 4
- GluT4 is the major glucose transporter in skeletal muscle and
adipose tisuue.
- It is under the control of insulin while other GluTs are not under
insulin control.
- Insulin induces GluT4 on the cell surface and thus increases
glucose uptake.
- In type 2 DM, membrane GluT4 is reduced leading to insulin
resistance in muscle and fat cells.

Pathways of carbohydrates metabolism
Glycolysis
Glycogenesis
Glycogenolysis
Citric acid cycle (Tricarbocylic acid cycle or Kreb’s cycle)
Gluconeogenesis (Neoglucogenesis)
Pentose phosphate pathway (Hexose monophosphate shunt)
Glycolysis: Emden-Meyerhof Pathway
- The sequence of enzyme-catalyzed reactions involved in the
breakdown of one glucose molecule to two molecules of
pyruvate or lactate

Types of Glycolytic pathway
1. Aerobic glycolysis
2. Anaerobic glycolysis

- Glucose is the body’s most readily available source of energy.

- After digestive processes break polysaccharides into
monosaccharides, including glucose, the monosaccharides are
transported across the wall of the small intestine and into
circulatory system, which transports them to the liver.

- In the liver, hepatocytes either pass the glucose on through the
circulatory system or store excess glucose as glycogen.

- Cells in the body take up the circulating glucose in response to
- Glycolysis can be divided into two phases:
i. energy consuming (also called chemical priming) and
ii. energy yielding.

- During the energy consuming phase, two ATP molecules are
required to start the reaction for each molecule of glucose.

- However, the end of the reaction produces four ATPs, resulting in
a net gain of two ATP energy molecules.

- Glycolysis can be expressed as the following equation:

Glucose + 2ATP + 2NAD+ + 4ADP + 2Pi → 2 Pyruvate + 4ATP +
2NADH + 2H

- This equation states that glucose, in combination with A TP (the
energy source), NAD (electron acceptor), and inorganic
phosphate, breaks down into two pyruvate molecules,
generating four A TP molecules— for a net yield of two ATP—and
two energy containing NADH coenzymes
GLYCOLYSIS Glucose
ATP
hexokinase ADP
Glucose 6-phosphate
phosphogluco-
isomerase
Fructose 6-phosphate
ATP
phosphofructokinase ADP
Fructose 1,6-bisphosphate
aldolase

triose phosphate isomerase
Dihydroxyacetone Glyceraldehyde
phosphate 3-phosphate
 Glyceraldehyde 3-phosphate
glyceraldehyde NAD+ + Pi
3-phosphate
dehydrogenase NADH + H+
1,3-Bisphosphoglycerate

ADP
phosphoglycerate kinase ATP
3-Phosphoglycerate

phosphoglyceromutase
2-Phosphoglycerate
enolase H2O
Phosphoenolpyruvate
ADP