Biochemistry PDF

Summary

This document provides an overview of biochemistry, covering key concepts such as molecular-level study of life, major chemical components, and buffer systems. It also details mechanisms for maintaining blood pH balance. The content emphasizes the role of biochemistry in understanding diseases and biotechnology.

Full Transcript

1. Biochemistry

Power to Understand What We Are!
 What is Biochemistry?
Generally biochemistry is the study of life at the
molecular level.

Uses basic laws of chemistry, biology and physics to
explain processes of living cells.

 Because life depends on biochemical reactions,
biochemistry has become the basic language of all
life sciences.
 Why study biochemistry?
▪ Lead us to fundamental understanding of life.

▪ Understand important issues in medicine, health,
and nutrition.
Has led to greater molecular understanding of diseases such as
diabetes, sickle cell anemia, and cystic fibrosis.
Next frontier: AIDS, cancer, Alzheimer’s Disease.

▪ Advance biotechnology industries
Biotechnology is the application of biological cells, cell
components, and biological properties to technically and
industrially useful operations.
i. Major objective of biochemistry
▪ Complete understanding at the molecular level of all the
chemical processes associated with living cells.
Isolate-the numerous molecules found in cells,
Determine-their structures,
Analyze-how they function.

ii. Further objective
▪ Attempt to understand how life began.
▪ An appreciation of the biochemistry of less complex form
of life is often direct relevance to human biochemistry.
1.2 The major chemical constituents of cells
Biochemistry = the chemistry of life
Elements - These are single substances which cannot be broken down any
more. there are 110 different elements that are known to man.
 …cont’d
 The living matter is composed of mainly six elements-
Carbon, Hydrogen, Oxygen, Nitrogen, Phosphorus and
Sulphur. (CHONPS)

 These elements together constitute about 90% of the dry
weight of the human body.

 Several other functionally important elements are also found
in the cells.

These include Ca, K, Na, Cl, Mg, Fe, Cu, Co, Zn, F, Mo and
Se.
 Carbon-a unique element of life
 Carbon is the most predominant and versatile element of life.

 It possesses as unique property to form infinite number of
compounds.

 This is attributed to the ability of carbon to form:
stable covalent bonds and C-C chains of unlimited
length.

 It is estimated that about 90% of compounds found in living
system invariably contain carbon.
Carbon can form immensely diverse compounds,
from simple to complex.
Compounds - These are two or more elements combined.
These elements are bonded together.
Complex Molecule
Simple Molecule

Methane with 1
Carbon atom DNA with tens of
Billions of Carbon atoms
 Organization of Life
▪ Life is composed of lifeless chemical molecules.

 elements
 simple organic compounds (monomers)
 macromolecules (polymers)
 supramolecular structures
 organelles
 cells
 tissues
 organisms
 Complex Biomolecules
▪ As regards lipids, it may be noted that they are not
biopolymers in a strict sense, but majority of them contain
fatty acids.
 Composition of the body and major
classes of molecules
 The human body is composed of a few elements that
combine to form a great variety of biomolecules.

 Biomolecules are compounds of carbon with a variety of
functional groups

Element
 The simplest kind of matter which can not be split in to two
or more simpler substances by chemical reactions.
Chemical composition of a normal man
(weight 65 kg)

Constituent Percent (%) Weight (kg)

Water 61.6 40

Protein 17.0 11

Lipid 13.8 9

Carbohydrate 1.5 1

Minerals 6.1 4
Fig. Some common functional groups of biomolecules.
1.3 Acid, Base and Buffer
systems

14
5
coffee

15
 The Body and pH
 Homeostasis of pH is tightly controlled
 Extracellular fluid = 7.4
 Blood = 7.35 – 7.45
✓ If pH is < 6.8 or > 8.0 death occurs
 Acidosis (acidemia) below 7.35
 Alkalosis (alkalemia) above 7.45

16
 …cont’d
 Acids are H+ donors.
 Bases are H+ acceptors.

 Acids and bases can be:
 Strong – dissociate completely in solution
 HCl, NaOH

 Weak – dissociate only partially in solution
 Lactic acid, carbonic acid
 A weak acid has a characteristic dissociation constant, Ka.

 The relationship between the pH of a solution, the Ka of an acid, and the
extent of its dissociation are given by the Henderson-Hasselbalch
17 equation.
 Acid/conjugate base pairs
HA + H2O A - + H 3O +
HA A- + H +
HA = acid ( donates H+)(Bronstad Acid)
A- = Conjugate base (accepts H+)(Bronstad Base)

Ka = [H+][A-] Ka & pKa value describe tendency to
loose H+
[HA]
large Ka = stronger acid
pKa = - log Ka small Ka = weaker acid
 …cont’d
 A buffer is a mixture of an undissociated acid and its
conjugate base (the form of the acid having lost its proton).
 It causes a solution to resist changes in pH when either
H+ or OH- is added.

 A buffer has its greatest buffering capacity in the pH range
near its pKa (the negative log of its Ka).

 Two factors determine the effectiveness of a buffer,:
its pKa relative to the pH of the solution and
its concentration.
 Henderson-Hasselbalch Equation

HA = weak acid
1) Ka = [H+][A-]
[HA] A- = Conjugate base
2) [H+] = Ka [HA]
[A-]
3) -log[H+] = -log Ka -log [HA]
[A-] * H-H equation describes
the relationship between
pH, pKa and buffer
4) -log[H+] = -log Ka +log [A-] concentration
[HA]
5) pH = pKa +log [A-]
[HA]
 …cont’d
 If the pKa for a weak acid is known, this equation can be used
 to calculate the ratio of the unprotonated to the protonated
form at any pH.

 From this equation, you can see that a weak acid is 50%
dissociated at a pH equal to its pKa.

 Most of the metabolic carboxylic acids have pKa ‘s between 2 and
5, depending on the other groups on the molecule.
The pKa reflects the strength of an acid.

 Acids with a pKa of 2 are stronger acids than those with a pKa of
5 because, at any pH, a greater proportion is dissociated.
 The body produces more acids
than bases
Acids take in with foods.
Cellular metabolism produces CO2.
Acids produced by metabolism of lipids and
proteins. CO2

Volatile acid H2CO3 CO2+ H2O CO2 CO2

H2SO4 H3PO4
Fixed acid Uric acid
Lactic acid
Ketone body
22
 Maintenance of blood pH

Three lines of defense to regulate the
body’s acid-base balance
– Blood buffers

– Respiratory mechanism

– Renal mechanism

23
 Buffer systems

Take up H+ or release H+ as conditions
change
Buffer pairs – weak acid and a base
Exchange a strong acid or base for a
weak one
Results in a much smaller pH change

24
 Principal buffers in blood

in Plasma in RBC

H2CO3 / HCO3- 35% 18%

HHb / Hb- 35%

HPro / Pro- 7%

H2PO4- / HPO42- 5%
Total 42% 58% 25
 Bicarbonate buffer
Predominant buffer system in ECF
Sodium Bicarbonate (NaHCO3) and carbonic
acid (H2CO3)
HCO3- : H2CO3: Maintain a 20:1 ratio
[HCO3－]
pH=pKa+lg
H2CO3 H+ + HCO3- [H2CO3]
24
= 6.1+ lg
1.2
20
= 6.1+ lg
1
26
= 6.1+1.3 = 7.4
 Bicarbonate buffer
HCl + NaHCO3 H2CO3 + NaCl

NaOH + H2CO3 NaHCO3 + H2O

27
 Phosphate buffer
Major intracellular buffer

NaH2PO4-Na2HPO4

H+ + HPO42- H2PO4-

OH- + H2PO4- H2O + HPO42-

28
 Protein Buffers

Include plasma proteins and hemoglobin

Carboxyl group gives up H+

Amino Group accepts H+

29
 2. Respiratory mechanisms
CO2 CO2
Exhalation of CO2
Rapid, powerful, but only works with
volatile acids
H+ + HCO3- H2CO3 CO2 + H20

Doesn’t affect fixed acids like lactic acid

Body pH can be adjusted by changing rate
and depth of breathing 30
 3. Kidney excretion
Most effective regulator of pH
The pH of urine is normally acidic (~6.0)
– H+ ions generated in the body are eliminated by
acidified urine.

Can eliminate large amounts of acid (→H+)
Reabsorption of bicarbonate (HCO3-) (←HCO3-)
Excretion of ammonium ions(NH4+) (→NH4+)
If kidneys fail, pH balance fails
31
 Rates of correction
Buffers function: almost instantaneously

Respiratory mechanisms: take several
minutes to hours

Renal mechanisms: may take several
hours to days
32
33
 Acid-Base Imbalances
pH< 7.35: acidosis
pH > 7.45: alkalosis

The body response to acid-base imbalance is
called compensation
– The body gears up its homeostatic mechanism and
makes every attempt to restore the pH to normal level.
– May be complete if brought back within normal limits
– Partial compensation if range is still outside norms.34
 Acid-Base Imbalances
Acidosis- a decline in blood pH ↓
– Metabolic acidosis: due to a decrease in
bicarbonate. ↓
– Respiratory acidosis: due to an increase in
carbonic acid. ↑

Alkalosis- a rise in blood pH ↑
– Metabolic alkalosis: due to an increase in
bicarbonate.↑
– Respiratory alkalosis : due to a decrease in
carbonic acid. ↓ 35
 Compensation
If underlying problem is metabolic,
hyperventilation or hypoventilation can
help: respiratory compensation.

If problem is respiratory, renal
mechanisms can bring about metabolic
compensation.
37
 Metabolic Acidosis
Bicarbonate deficit (↓) - blood concentrations of
bicarb drop below 22mEq/L (milliequivalents /
liter)

Causes:
– Loss of bicarbonate through diarrhea or renal
dysfunction
– Accumulation of acids (lactic acid or ketones)
– Failure of kidneys to excrete H+

Commonly seen in severe uncontrolled DM
(ketoacidosis). 38
 Respiratory Acidosis
Carbonic acid excess caused by blood
levels of CO2 above 45 mm Hg.

Hypercapnia – high levels of CO2 in blood

Causes:
– Depression of respiratory center in brain that
controls breathing rate – drugs or head
trauma
– Paralysis of respiratory or chest muscles
– Emphysema 40
 Metabolic Alkalosis
Bicarbonate excess↑ - concentration in
blood is greater than 26 mEq/L

Causes:
– Excess vomiting = loss of stomach acid
– Excessive use of alkaline drugs
– Certain diuretics
– Endocrine disorders: aldosterone ↑
– Heavy ingestion of antacids
42
 Respiratory Alkalosis
Carbonic acid deficit↓
pCO2 less than 35 mm Hg (hypocapnea)
Most common acid-base imbalance

Primary cause is hyperventilation
– Hysteria, hypoxia, raised intracranial pressure,
excessive artificial ventilation and the action
of certain drugs (salicylate) that stimulate
respiratory centre.
44
 Mixed acid-base disorders
Sometimes, the patient may have two or
more acid-base disturbances occurring
simultaneously.

In such instances, both HCO3- and H2CO3
are altered.

46
Reading Assignment
1. Biological importance of Water
2. Types of chemical bond

47
,
,

2. Carbohydrates
 Learning objectives
At the end of this session the students will be
able to:-

 Explain what is meant by the terms monosaccharide,
disaccharide, oligosaccharide, and polysaccharide.

 Describe the formation of glycosides and the
structures of the important disaccharides and
polysaccharides.

 Explain the roles of carbohydrates.
 Definitions
 Glycobiology is the study of the roles of sugars in health
and disease.

 The glycome is the entire complement of sugars of an
organism, whether free or present in more complex
molecules.

 Glycomics, an analogous term to genomics and
proteomics, is the comprehensive study of glycomes,
including genetic, physiological, pathological, and other
aspects.
 Sources of Carbohydrates

4
 Carbohydrates
▪ are the most abundant organic molecules in nature.

Biomedical Importance(functions)
1.source and storage of energy, glucose and glycogen respectively.
2. Structural components. E.g. skin, bone, cell mm
3. Involved in cell-cell interaction
4. Their derivatives are drugs. E.g. erythromycin

5. Survival of Antarctic fish in icy environment is due to presence of
anti-freeze glycoprotein's in their blood.

6. Ascorbic acid, a derivative of carbohydrate is a water-soluble
vitamin..
Carbohydrates
Metabolic/Nutritional
 principal part of the energy
 Carbohydrate intake can take place in different forms like sugar,
starch, fibers etc.
 Fiber does wonders in keeping your bowel function going
smooth.
 Carbohydrates add on to the taste and appearance of food item,
thus making the dish tempting and mouth-watering
 They are sometimes used as flavours and sweeteners.
 Carbohydrates aid in regulating blood glucose and also do good
to our body by breaking down fatty acids, thus preventing
ketosis.
 Chemical Nature of Carbohydrates
▪ They are polyhydroxy alcohols with a functional aldehyde or keto
group.
Most sugars have formula Cn(H2O)n, “hydrate of carbon.”
Classification of Carbohydrates
based on number of carbon chains present; they are:
1. Monosaccharides - simple sugars with multiple OH groups. Based
on number of carbons (3, 4, 5, 6), a monosaccharide is a triose,
tetrose, pentose or hexose.
2. Disaccharides - 2 monosaccharides covalently linked.
3. Oligosaccharides - a few monosaccharides covalently linked. (3-10
monomer)
4. Polysaccharides - polymers consisting of chains of monosaccharide
or disaccharide units. (>10 monomer)
 Types of Carbohydrates
Simple Carbohydrates
– monosaccharides
– disaccharides

Complex Carbohydrates
– oligosaccharides
– polysaccharides
glycogen
starches Fig. examples of an aldose (A)
Fibers and a ketose(B) sugar.
 1. Monosaccharides: Single
Sugars
Glucose
– carbohydrate form used by the body,
referred to as “blood sugar”
– basic sub-unit of other larger
carbohydrate molecules
– found in fruits, vegetables, honey
The oxidation of glucose by glucose
oxidase (a highly specific test for glucose)
is used by clinical and other laboratories to
measure the amount of glucose in urine
using a dipstick. 9
 Monosaccharides: Single
Sugars
Fructose
– sweetest of the sugars
– occurs naturally in fruits & honey,
“fruit sugar”
– combines with glucose to form
sucrose

Galactose
– combines with glucose to form
lactose, “milk sugar”
10
 , 1. Monosaccharides
They can not be hydrolyzed to small compounds.
Their general formula is Cn(H2O)n.
They are also called as simple sugars.

Nomenclature
 have common (trivial) names and systematic names.
 Systematic name indicates both the number of carbon atoms
present and aldehyde or ketone group.
✓ E.g. glyceraldehyde is a simple sugars containing three carbon
atoms and a aldehyde group.
Simple sugars containing three carbon atoms are referred as
trioses.
In addition, sugars containing aldehyde group or keto group are
called as aldoses or ketoses, respectively.
 ,

Thus, the systematic name for glyceraldehyde is aldotriose.
 Like wise a simple sugar with three carbon atoms and a keto
group is called as ketotriose.

Fig. examples of an
aldose (A) and a
ketose(B) sugar.
 Properties of monosaccharides
1. Optical Isomerism
All the monosaccharides except dihydroxyacetone contain at
least one asymmetric carbon atom and hence they exhibit optical
isomerism.
 D and L-glyceraldehyde are used as parent compounds to designate
all other sugars (compounds) as D or L forms.
CHO CHO

D & L designations are H C OH HO C H

based on the configuration CH2OH CH2OH

about the single D-glyceraldehyde L-glyceraldehyde
asymmetric C in CHO CHO
glyceraldehyde. H C OH HO C H

CH2OH CH2OH
The lower representations
D-glyceraldehyde L-glyceraldehyde
are Fischer Projections.
 O H O H
C C
H – C – OH HO – C – H
For sugars with more than one
‘ HO – C – H H – C – OH
chiral center, D or L refers to H – C – OH HO – C – H
the asymmetric C farthest H – C – OH HO – C – H
from the aldehyde or keto CH2OH CH2OH
group. D-glucose L-glucose

If the hydroxyl group of the highest numbered chiral carbon is pointing to the
right, the sugar is designated as D (Dextro: Latin for on the right side).

If the hydroxyl group is pointing to the left, the sugar is designated as L (Levo:
Latin for on the left side).

Most naturally occurring carbohydrates are of the D-configuration
 2.Optical Activity
Monosaccharides except dihydroxy acetone exhibit optical
activity because of the presence of at least 1 asymmetric
carbon atom.
If a sugar rotates plane polarized light to right then it is called
as dextrorotatory and if a sugar rotates the plane polarized light to the
left then it is called as levorotatory.
Usually ‘+’ sign indicates dextrorotation and ‘–’ sign indicates
levorotation of a sugar.
CHO CHO
H OH HO H
CH2OH CH2OH
D-glyceraldehyde L-glyceraldehyde
R-(+)-glyceraldhyde S-(-)-glyceraldhyde
(+)-rotation = dextrorotatory (-)-rotation = levorotatory
 The Aldotetroses
Glyceraldehyde is the simplest carbohydrate (C3, aldotriose, 2,3-
dihydroxypropanal).
The next carbohydrate are aldotetroses (C4, 2,3,4-trihydroxybutanal).
aldotriose

2n H
CHO
OH
CH2OH
HO
CHO
H
CH2OH

D-glyceraldehyde L-glyceraldehyde

aldotetroses
1 CHO 1 CHO
H
2
OH HO 2 H
highest numbered highest numbered
"chiral" carbon H
3
OH HO 3 H "chiral" carbon
4 CH2OH 4 CH2OH

D-erythrose L-erythrose

CHO CHO
HO H H OH
highest numbered highest numbered
H OH HO H
"chiral" carbon "chiral" carbon
CH2OH CH2OH

D-threose L-threose
16
 Aldopentoses and Aldohexoses
Aldopentoses: C5, three chiral carbons, eight stereoisomers
CHO CHO CHO CHO
H OH HO H H OH HO H
H OH H OH HO H HO H
H OH H OH H OH H OH
CH2OH CH2OH CH2OH CH2OH

D-ribose D-arabinose D-xylose D-lyxose

Aldohexoses: C6, four chiral carbons, sixteen stereoisomers
CHO CHO CHO CHO CHO CHO CHO CHO
H OH HO H H OH HO H H OH HO H H OH HO H
H OH H OH HO H HO H H OH H OH HO H HO H
H OH H OH H OH H OH HO H HO H HO H HO H
H OH H OH H OH H OH H OH H OH H OH H OH
CH2OH CH2OH CH2OH CH2OH CH2OH CH2OH CH2OH CH2OH

D-allose D-altrose D- glucose D-mannose D-gulose D-idose D-galactose D-talose

17
3.Isomers and epimers
✓ Compounds that have the same chemical formula but have different
structures are called isomers.
✓ E.g. fructose, glucose, mannose, and galactose are all isomers of
each other, having the same chemical formula, C6H12O6.
✓ Carbohydrate isomers that differ in configuration around only one
specific carbon atom (with the exception of the carbonyl carbon) are
defined as epimers of each other.

4. Functional Isomers
 same molecular formulae but different functional groups.
 For example, glucose and fructose have same molecular formulae
C6H12O6, but glucose contains aldehyde as functional group and
fructose contains keto group.
 H O
C CH2OH

H C OH C O

HO C H HO C H

H C OH H C OH

H C OH H C OH

CH2OH CH2OH

D-glucose D-fructose

Aldoses (e.g., Ketoses (e.g.,
glucose) have an fructose) have
aldehyde group a keto group,
at one end. usually at C2.
 Cyclic Structure for Glucose
Glucose cyclic hemiacetal formed by reaction of -CHO with -
OH on C5.

=>
20 D-glucopyranose
 Cyclic Structure for Fructose
Cyclic hemiketal formed by reaction of C=O at C2 with -OH
at C5.

D-fructofuranose

=>
21
 5. Anomers
Cyclization of glucose produces a new asymmetric center at C1.
The 2 stereoisomers are called anomers, α & β.
Haworth projections represent the cyclic sugars as having
essentially planar rings, with the OH at the anomeric C1:
 α (OH below the ring)
 β (OH above the ring).

6 CH2OH 6 CH2OH
5 O 5 O
H H H OH
H H
4 H 1 4 H 1
OH OH
OH OH OH H
3 2 3 2
H OH H OH
-D-glucose -D-glucose
6. Enantiomers
 A special type of isomerism is found in the pairs of structures
that are mirror images of each other.
 These mirror images are called enantiomers.

Enantiomers
(mirror images)
of glucose.
Joining of monosaccharides
 Monosaccharides can be joined to form disaccharides,
oligosaccharides, and polysaccharides.
 The bonds that link sugars are called glycosidic bonds. These are
formed by enzymes known as glycosyltransferases.
Joining and Cleaving Sugar
Molecules

25
 2. Disaccharides
 They provide energy to human body.
 They consist of two monosaccharide units held together by
glycosidic bond. So, they are glycosides.
 Most commons are maltose, lactose and sucrose
a) Maltose (two glucose units )
 The glycosidic linkage of maltose is symbolized as α (1→4).
i.e. The anomeric carbon is bonded to oxygen on C4 of second
sugar. And α-indicates the configuration of anomeric carbon atoms
of both glucose units.
 Systematic name for maltose is O-α-D glucopyranosyl-(1→4)-
α-D glucopyranose.
 Maltose is a reducing sugar because anomeric carbon of second
glucose is free.
 6 CH2OH 6 CH2OH

Disaccharides: H
5 O H H
5 O H
H H
Maltose, a cleavage 4 OH H 1 4
OH H 1

product of starch (e.g., OH 3 2
O
3 2
OH

amylose), is a H OH
maltose H OH
disaccharide with an
α(1→ 4) glycosidic 6 CH2OH 6 CH
2OH
5
link between C1 - C4 H
H
O H
5 O OH
H
OH of 2 glucoses. 4
OH H 1 O 4
OH H 1

H H
It is the α anomer (C1 OH 3 2 3 2

O points down). H OH
cellobiose
H OH

Cellobiose, a product of cellulose breakdown, is the otherwise
equivalent β anomer (O on C1 points up).
The β(1 → 4) glycosidic linkage is represented as a zig-zag, but
one glucose is actually flipped over relative to the other.
Source for maltose

 Maltose is present in germinating cereals and in barley.

 Commercial malt sugar contains maltose

 may be formed during the hydrolysis of starch.
 b)Lactose
Structure
 It contains one glucose and one galactose.
 It is symbolized as β (1→4).
 O-β-D galactopyranosyl-(1→4)-β-D-glucopyranose.
 It is a reducing sugar because anomeric carbon of glucose is free.

Source for lactose
 Lactose is synthesized in mammary gland and hence it occurs in
milk.
 Lactose
 Galactose + glucose linked 1-4’.
 “Milk sugar.”

CH2OH CH2OH
O O
H OH..... H
OH
H
1 O 4 H
H OH H
OH H H..... OH
H

H OH H OH
-Galactose Glucose
− and −Lactose
30
 c) Sucrose
 It contains glucose and fructose.
 common table sugar.
 glucose is in α-form whereas fructose is in β-form in sucrose.
 α, β(1→2).
 O-α-D-glucopyranosyl-(1→2)-β-D-fructofuranose.
 Nonreducing sugar b/c both the functional groups of glucose
and fructose are involved in glycosidic linkage.

Source of sucrose
 Ripe fruit juices like pineapple, sugar cane, juice and honey are
rich sources for sucrose.
 It also occurs in juices of sugar beets, carrot roots and sorghum.
 CH2OH
O
H H
-Glucose H
1
OH H
OH

H OH

CH2OH O
O
-Fructose OH 2
H
H CH2OH

OH H
Sucrose
 Oligosaccharides
 Beans and peas contain some oligosaccharides.

 These oligosaccharides contain 4 to 5 monosaccharide units.

 Stachyose and verbascose are a few such oligosaccharides.

 Usually these oligosaccharides are not utilized in human body.

 Also found in glycoproteins where they have important
functions. Oligosaccharides are also important constituents of
glycolipids present in cell membrane
 Complex Carbohydrates
Oligosaccharides
– short carbohydrate chains of 3 - 10
monosaccharides
– found in legumes and human milk
– Examples: cannot be broken down by human
enzymes, though can be digested
raffinose
by colonic bacteria
stachyose

34
 Polysaccharides
 They are polymers of monosaccharides.

 They contain more than ten monosaccharide units.

 The monosaccharides are joined together by glycosidic
linkage.
– alpha () bonds (starch)
– beta () bonds (found in fiber)
 Classification of Polysaccharides
 Two types on the basis of the type of monosaccharide present.

a) Homopolysaccharides
 They are entirely made up of one type of monosaccharides.
 On hydrolysis, they yield only one kind of monosaccharide.

b) Heteropolysaccharides
 They are made up of more than one type of monosaccharides.
 On hydrolysis they yield more than one type of monosaccharides.
 Homopolysaccharides
 Important homopoly-saccharides are starch, glycogen, cellulose.
 All these contain glucose as repeating unit.
 Other name for homopolysaccharides are homoglycans.

Starch
Structure
 It consist of two parts.
A minor amylose component and a major amylopectin
component.
 CH2OH 6CH OH CH2OH CH2OH CH2OH
2
O 5 O H O H O H H O H
H H H H H
H H H H H
OH H 1 4 OH H 1 OH H OH H OH H
O O O O OH
OH 2
3
H OH H OH H OH H OH H OH
amylose

Polysaccharides:
Plants store glucose as amylose or amylopectin, glucose
polymers collectively called starch.
Glucose storage in polymeric form minimizes osmotic
effects.
Amylose is a glucose polymer with (1→4) linkages.
The end of the polysaccharide with an anomeric C1 not involved in
a glycosidic bond is called the reducing end.
 CH2OH CH2OH
H O H H O H amylopectin
H H
OH H OH H 1
O
OH
O
H OH H OH

CH2OH CH2OH 6 CH2 CH2OH CH2OH
H O H H O H H 5 O H H O H H O H
H H H H H
OH H OH H OH H 1 4 OH H OH H
4 O O
O O OH
OH 2
3
H OH H OH H OH H OH H OH

Amylopectin is a glucose polymer with mainly (1→4) linkages,
but it also has branches formed by (1→6) linkages. Branches
are generally longer than shown above.
The branches produce a compact structure & provide multiple
chain ends at which enzymatic cleavage can occur.
 Function
1. It is the major polysaccharide present in our food.

2. It is also called as storage polysaccharide because it serve as
reserve food material in plants.

3. It is present in food grains, tubers and roots like rice, wheat,
potato and vegetables.
 Complex Carbohydrates
Glycogen
– highly branched chains of
glucose units
– animal storage form of
carbohydrate
found in LIVER and MUSCLE
Humans store ~ 100g in liver;
~ 400g in muscle
– negligible source of
carbohydrate in the diet
(meat)
41
 Glycogen
 similar to that of amylopectin of starch. But the number of
branches in glycogen molecule is much more than amylopectin.
 There is one branch point for 6-7 glucose residues.

Function
1. It is the major storage polysaccharide (carbohydrate) in human
body.

2. It is mainly present in liver and muscle.

3. It is also called as animal starch.
 CH2OH CH2OH
H O O
glycogen
H H H
H H
OH H OH H 1
O
OH
O
H OH H OH

CH2OH CH2OH 6 CH2 CH2OH CH2OH
H O H H O H H 5 O H H O H H O H
H H H H H
OH H OH H OH H 1 4 OH H OH H
4 O O
O O OH
OH
3 2
H OH H OH H OH H OH H OH

Glycogen, the glucose storage polymer in animals, is similar in
structure to amylopectin.
But glycogen has more (1→6) branches.
The highly branched structure permits rapid glucose release from
glycogen stores, e.g., in muscle during exercise.
The ability to rapidly mobilize glucose is more essential
to animals than to plants.
 Cellulose
 It has linear chain of glucose residues, which are linked by
β(1→4) glycosidic linkage.
 It occurs as bundle of fibres in nature.
 The linear chains are arranged side by side and hydrogen
bonding between adjacent stands stabilizes the structure.
 The role of cellulose is to impart strength and rigidity to plant
cell walls, which can withstand high hydrostatic pressure
gradients. Osmotic swelling is prevented.

CH2OH 6CH OH CH2OH CH2OH CH2OH
2
O 5 O O H O H O OH
H H H
H H H H H
OH H 1 O 4 OH H 1 O OH H O OH H O OH H
OH H H H
H 2 H
3
H OH H OH H OH H OH H OH
cellulose
 Starch Glycogen Cellulose
1.Nature: Stored form of Structural form of carbohydrate
Stored form of carbohydrate in plants. carbohydrates in animals. in plant cells but prevents
constipation in human.

1.Source: Muscles and liver Linen and cotton are nearly pure
Cereals, e.g., wheat, rice, and tubers, e.g., cellulose.
potatoes.

1.Solubility: Water soluble forming Water insoluble.
Amylose is water soluble and amylopectin is colloidal solution.
insoluble.

1.Nature of the chains: Branched chain similar to Straight chain (large number of
Amylose is helical straight chain (-glucose amylopectin but its -glucose units linked by -
units linked by -1,4-glucosidic bonds). trees are shorter and 1,4- glucosidic bonds).
Amylopectin is branched chain (-glucose have more branches
units linked by -1,4- and -1,6-glucosidic than amylopectin tree.
bonds).

1.Reaction with iodine: Gives red color. No color.
Amylose gives blue color and amylopectin gives
red color.

1.Digestibility: Digestible by amylase into Non-digestiblebut HCl hydrolysis
Is hydrolyzed by HCl or amylase into dextrins dextrins and maltose. gives cellobiose.
and maltose.
HETEROPOLYSACCHARIDES
 also called mucopolysaccharides & glycosaminoglycans.
 Mucopolysaccharides consist of repeating disaccharide units(of
two types monosaccharides.)
 mucopolysaccharides are component of connective tissue, hence
often called structural polysaccharides.

 Mucopolysaccharides are also components of extracellular
matrix of bone, cartilage and tendons.

 The complex of mucopolysaccharide and protein is called as
proteoglycan.
 Mucopolysaccharides also function as lubricants and shock absorbers
Heparin
 The repeating disaccharide unit of heparin consist of
glucosamine and either iduronic acid or glucuronic acid.

 Majority of uronic acids are iduronic acids. Further amino
groups of glucosamine is sulfated.

iduronate-2-sulfate N-sulfo-glucosamine-6-sulfate
H CH2OSO3−

H O H O H
COO− H
OH H O OH H
H O

H OSO3− H NHSO3−
heparin or heparan sulfate - examples of residues
 Functions
1. Heparin is a normal anti-coagulant present blood.

2. It is produced by mast cells present in the arteries, liver,
lung and skin.

3. Unlike other glycosaminoglycans, heparin is an
intracellular component.

4. It can be used during the treatment of myocardial
infarction as well as for the prevention of deep venous
thrombosis during hospitalizations.
 Complex Carbohydrates
Fiber
Dietary Fiber
– non-digestible carbohydrates (chains of
monosaccharides) and lignin that are intact and
intrinsic in plants (includes oligosaccharides)
Functional Fiber
– isolated, non-digestible carbohydrates that have
beneficial physiological effects in humans

49
 Complex Carbohydrates
Fiber cont.
dietary fiber found in all types of plant
foods
refining removes fiber from whole
grains and other foods

50
 Complex Carbohydrates
Fiber cont.
types of non-starch
polysaccharides include:

cellulose
hemicelluloses
pectins
gums & mucilages
-glucans
chitin & chitosan
lignans
51
 Summery
Functions of Carbohydrates
1) Energy
glucose fuels the work of most of the body’s
cells
– preferred fuel of NERVOUS TISSUE (the brain,
nerves) and RED BLOOD CELLS (RBC)
excess glucose is stored as GLYCOGEN in
liver and muscle tissue

52
 Functions of Carbohydrates
2) Sparing Body Protein
if diet does not provide enough glucose, then
other sources of glucose must be found
if carbohydrate intake < 50 - 100 g, body
protein will be used to make glucose
an adequate supply of carbohydrate spares
body proteins from being broken down to
synthesize glucose

53
 Functions of Carbohydrates
3) Preventing Ketosis (Anti-ketogenic)
carbohydrates required for the complete
metabolism of fat
incomplete fat metabolism produces
KETONES
an adequate supply of carbohydrate (>
50 – 100 g per day) prevents KETOSIS

54
 Fiber
beneficial for weight control by contributing to
satiety & delay gastric emptying
soluble fibers lower blood cholesterol to help
reduce risk of cardiovascular disease

minimizes risk of and helps control Type II
Diabetes
insoluble fibers help promote intestinal health
by enlarging stool size and easing passage of
stool

55
 Soluble Fiber
examples include gums, pectins,
mucilages, some hemicelluloses

functions:
– delay gastric emptying
– slow transit through the digestive system
– delay glucose absorption
– bind to bile, help decrease cholesterol

food sources: fruits
56
 Insoluble Fiber
examples include cellulose, hemicellulose

functions:
– speed transit through the digestive tract
– delay glucose absorption
– increase fecal weight and soften stool to ease
passage
– reduces risk of hemorrhoids, diverticulitis and
appendicitis

food sources: cereal grains, legumes,
vegetables, nuts
57
 Fiber: Too much of a good
thing?

Excessive amounts of fiber may lead to:
– displacement of other foods in the diet
– intestinal discomfort
– interference with the absorption of other
nutrients

58
 Summary
Carbohydrates are major constituents of human food and human
tissues. They are characterized by the type and number of
monosaccharide residues in their molecules.
Glucose is the major metabolic fuel of humans and a universal fuel of
the fetus.

The physiologically important monosaccharides include glucose, the
"blood sugar," and ribose, an important constituent of nucleotides and
nucleic acids.

The important disaccharides include maltose (glucosyl-glucose),
sucrose(glucosyl-fructose), and lactose (galactosyl-glucose),.
Starch and glycogen are storage polymers of glucose in plants and
animals, respectively. Starch is the major metabolic fuel in the diet. 59
 References
 DM Vasudevan, Sreekumari S. Text Book of Biochemistry for
Medical Students, 5th Edition. 2007.

 Murray R.K et al. Harper's illustrated Biochemistry 30th
edition.
 Pamela C.C, and Richard A.H., Lippincott's Illustrated
Reviews: Biochemistry 5th edition, J.B.

 Thomas M. Devlin. Text Book of Biochemistry with Clinical
Correlations. 6th Edition, 2006, Wiley-Liss Publication, USA

 Marks' Essential Medical Biochemistry, 2nd Edition Copyright
2007 Lippincott Williams & Wilkins.
,
Lipids
 Introduction
▪ Lipids are a heterogeneous group of organic compounds defined by
their solubility in nonpolar solvents such as chloroform, ether, and
benzene and by their poor solubility in water.
 Unlike the polysaccharides ,proteins and nucleic acids, lipids are not
polymers. Further, lipids are mostly small molecules.
▪ Lipids may be polar or nonpolar (amphipathic).
Major polar lipids include fatty acids, cholesterol, glycerophosphatides,
and glycosphingolipids.
✓ Very short chain fatty acids and ketone bodies are readily soluble in water.

Nonpolar lipids serve principally as storage and transport forms
of lipid. E.g triacylglycerols (also called triglycerides) and cholesteryl
esters.
Occurrence
Lipids present in humans, animals, plants and micro-
organisms to some extent.

✓ Animal fat, egg yolk, butter and cheese are lipids of
animal origin.

✓ vegetable or cooking oils are lipids are plant origin.
Functions of lipids
1. Under skin it serve as thermal insulator against cold.

2. Fat around kidney serve as padding against injury.

3. Serve as a source of energy for cell like carbohydrates.

4. It is an ideal form of storing energy in the human body
compared to carbohydrates and proteins because:
(a) Energy content of fat is higher.
(b) Only fat can be stored in a water free form which is not
possible with carbohydrates and proteins
 ,

5. Lipids are structural components of cell membrane and
nervous tissue.
6. Some lipids serve as precursors for the synthesis of
complex molecules. For example, acetyl-CoA is used for the
synthesis of cholesterol.

7. Lipoproteins, which are complexes of lipids and proteins are
involved in the transport of lipids in the blood and components
of cell membrane.
8. Some lipids serve as hormones and fat soluble vitamins are
lipids.
9. Fats are essential for the absorption of fat soluble vitamins.

10. Fats serve as surfactants by reducing surface tension.
 ,

11. Eicosanoids which have profound biological actions are derived from
the essential fatty acids.

12. Lipids present in myelinated nerves act as insulators for propagation
of depolarization wave.

13. Some saturated fatty acids are anti-microbial and anti-fungal agents.

14.Lipids are an important group of antigens of parasites that cause
filariasis, cysticercosis, leishmaniasis and schistosomiasis in third world
countries.
Anti-lipid antibodies are found in the blood of individuals affected with these
diseases.

15. Saturated free fatty acids (SFFAs) are pheromones of animals like
tiger etc...
Classification of Lipids
 Lipids

Simple Complex
/Compou Derived
nd

Fat or
oil Waxes Fatty Fat Sol
Carotenoid
Acids/Ster Vitamin
s
oids s

Glycolipid
s Phospholipids Lipoproteins
Sulfolipids
 Classification of Lipids
 Lipids are broadly classified into simple, complex, derived and
miscellaneous lipids, which are further subdivided into different
groups.

1. Simple lipids:- esters of fatty acids with different alcohols.

a. Fats and oils ( TAGs) :- These are esters of fatty acids with
glycerol.
The difference between fat and oil is only physical. Thus, oil is a
liquid while fat is a solid at room temperature.

b. Waxes:- Esters of fatty acids(usually long chain) with alcohols
other than glycerol like mericyle and cetyle.
 2. Complex (Compound) lipids
 These are esters of fatty acids with alcohols containing additional
groups such as phosphate, nitrogenous base, carbohydrate,
protein …etc.

A. Phospholipids:- Esters of the above type containing
phosphoric acid and frequently a nitrogenous base.
i) Glycerophospholipids
These phospholipids contain glycerol as the alcohol
E.g. lecithin, cephalin.
ii) Sphingophospholipids
The alcohol is sphingosine.
E.g. sphingomyelin
B. Glycolipids
 These lipids contain a fatty acid, carbohydrate and nitrogenous
base.
The alcohol is sphingosine, hence they are also called as
glycosphingolipids.
Glycerol and phosphate are absent.
E.g. Cerebrosides, gangliosides.

C. Lipoproteins:
Macromolecular complexes of lipids with proteins.

D. Other complex lipids:
Sulfolipids, amino lipids and lipopolysaccharides are among the other
complex lipids.
3. Derived lipids
 These are the derivatives obtained on the hydrolysis of simple and
complex lipids which possess the characteristics of lipids.
These include fatty acids, mono- and diacylglycerols, lipid(fat)
soluble vitamins, steroid hormones, cholesterol and ketone
bodies.

4. Miscellaneous lipids: These include a large number of
compounds possessing the characteristics of lipids.
E.g., carotenoids, squalene,hydrocarbons such as pentacosane(in
bees wax), terpenes etc.
Neutral Lipids:
These are lipids which are uncharged.
These are mono-, di-, and triacylglycerols, cholesterol and
cholesteryl esters.
 Fatty acids
▪ Are carboxylic acids with hydrocarbon side chain.
▪ They are the simplest form of lipids.

The anionic group has an affinity for water, giving the fatty acid
its amphipathic nature (having both a hydrophilic and a
hydrophobic region).
 …cont’d
▪ Fatty acids with less than 12 and more than 24 carbon atoms
are uncommon in biological systems.
 Palmitic acid (l6C) and stearic acid(18) are the most
common.

 Most of the fatty acids have even number of carbon atoms.
This is due to biosynthesis of fatty acids mainly occurs with
the sequential addition of 2 carbon units.

▪ They rarely occur in free form and are usually found in
esterified form as the major components of various lipids.
 ,,

 Long-chain fatty acids (LCFAs), the hydrophobic portion
is predominant.
 highly water-insoluble, and must be transported in the
circulation in association with protein.

 More than 90% of the fatty acids found in plasma are in the
form of fatty acid esters (primarily triacylglycerol,
cholesteryl esters, and phospholipids) contained in circulating
lipoprotein particles..

▪ Unesterified (free) fatty acids are transported in the
circulation in association with albumin.
▪ Based on the nature of …cont’d
hydrocarbon side chain, they
are divided into:
A. Saturated fatty acids:
✓ contain no double bonds—that
is, be saturated
✓ they can not undergo
further hydrogenation.

B. Unsaturated fatty acids:
contain one or more double
Fig. A saturated (A) and
bonds—that is, be mono- or
polyunsaturated fatty acids. an unsaturated (B) fatty acid.
which may further be NB: Cis double bonds cause a fatty
hydrogenated. acid to “kink.”.

A. Saturated fatty acids
All C bonded to H
 No double bonds
 long, straight chain
 most animal fats
 solid at room temp.
contributes to
cardiovascular disease
(atherosclerosis)
= plaque deposits
 B. Unsaturated fatty acids
 Have a double bonds in
the fatty acids
 plant & fish fats
 vegetable oils
 liquid at room temperature
 the kinks made by double
bonded C prevent the
molecules from packing
tightly together
 In which hydrocarbon side chain is unsaturated (one or more
,

double bonds are present).

 All the naturally occurring unsaturated fatty acids are cis-
isomers.

 Cis and trans isomers are not interchangeable in cells.

 Only cis isomers can fit into cell membrane because of bend at
double bond.
 Trans Fats – The Double Whammy
 Trans fats come from adding hydrogen to
vegetable oil (unsaturated fats) through a
process called hydrogenation.
 “Partially hydrogenated” oils may contain
higher levels of trans fats.

 Trans fats are more solid than oils.

 Trans fats increase the shelf life of foods.

 Unlike other fats, trans fats both raise your
"bad" (LDL) cholesterol and lower your
20
"good" (HDL) cholesterol.
 Fatty Acid Structure
 Why would the type of fatty acid
determine its state at room
temperature?
 Double bonds create the kinks in the
structure→ can’t be packed as closely
together → lessVan der waals forces
intraction.
 This makes them more fluid at room
temperature → lower melting temperature
The peanut butter puzzle…
 Fats are usually found in animals
 Oils are usually found in plants
 So why is peanut butter solid?
 hydrogenation
Saturated vs. unsaturated
saturated unsaturated
 Nomenclature of fatty acids
 The naming of a fatty acid (systematic name) is based on the
hydrocarbon from which it is derived.

 The saturated fatty acids end with a suffix -anoic
(e.g. octadecanoic acid) while the unsaturated fatty acids
end with a suffix –enoic (e.g. octadecenoic acid).

 In addition to systematic names/ fatty acids have common
names which are more widely used.
 Numbering of carbon atoms
 It starts from the carboxyl carbon which is taken as number 1.
 The carbons adjacent to this (carboxyl C) are 2, 3, 4 and so on or
alternately α , β, γ and so on.

 The terminal carbon containing methyl group is known omega
(ω) carbon.
Starting from the methyl end, the carbon atoms in a fatty acid
are numbered as omega 1, 2, 3 etc.
 Shorthand representation of fatty
acids
 The total number of carbon atoms are written first,
 followed by the number of double bonds and
 finally the (first carbon) position of double bonds, starting from
the carboxyl end.
 Thus, saturated fatty acid, palmitic acid is written as l6:0
 oleic acid as 18:1;9,
 Arachidonic acid as 20 : 4; 5, 8, 11, 14.
 Δ9 indicates that the double bond is between 9 and 10 of the
fatty acid.
 ω9 represents the double bond position (9 and 10) from the
ω end.
 Essential fatty acids
 They are not synthesized in the body.

 Two fatty acids are dietary essentials in humans :
▪ linoleic acid- which is the precursor of arachidonic acid, the
substrate for prostaglandin synthesis.
▪ α-linolenic acid- important for growth and development.

▪ Arachidonic acid becomes essential if linoleic acid is deficient
in the diet.

❖ Essential fatty acid deficiency can result in a scaly dermatitis, as
well as visual and neurologic abnormalities. Essential fatty acid
deficiency, however, is rare.
 Alpha-linolenic acid
– omega-3 fatty acid

Linoleic acid
- omega-6 fatty acid

Table. Common names and
structures of some fatty acids
of physiologic importance.
28
 Shorthand representation of fatty acids
Linoleic acid

CH3(CH2)4CH=CHCH2CH=CH(CH2)7COOH

18:2 n-6

Alpha-linolenic acid

CH3CH2CH=CHCH2CH=CHCH2CH=CH(CH2)7COOH

18:3 n-3

Eicosapentaenoic acid(EPA, fish oil)

CH3CH2CH=CHCH2CH=CHCH2CH=CHCH2CH=CHCH2CH=CH(CH2)3COOH

20:5 n-3
  NB: Humans have carbon 9, 6, 5 and 4 desaturases, but lack the
enzymes to insert double bonds at carbon atoms beyond C-9 in
,
the fatty acid chain.

 This is the basis for the nutritional essentiality of the
polyunsaturated linoleic (cis double bonds) ,and α-linolenic
acids(has all cis double bonds).

 Essential fatty acids are required for:
 membrane structure and function,
 transport of cholesterol,
 formation of lipoproteins, prevention of fatty liver etc.
 also needed for the synthesis of another important group of
compounds, namely eicosanoid.
Good sources of ‘omega-3 fatty acids’

Oily fish
(salmon, mackerel, sardines, tuna)
Pumpkin seeds, sesame seeds
soybean oil
 Good sources of ‘omega-6 fatty acids’
Most vegetable oil, Sunflower oil, Corn oil, Soybean oil
Cotton seeds oil
Pumpkin seeds
Nuts and cereals
Poultry, eggs
Avocado
1. Storage lipids
▪ The fats and oils used almost universally as stored forms of
energy in living organisms are derivatives of fatty acids.
▪ Two types of fatty acid–containing compounds,
triacylglycerols and
waxes.

▪ They are esters of fatty acids with alcohols.
▪ An ester is formed when acid reacts with alcohol.
Eg. Fats and waxes
Formation of an ester:
O O
R'OH + HO-C-R" R'-O-C-R'' + H2O
Fats
,

▪ Esters of fatty acids with glycerol.

▪ Also called as triglycerides or triacylglycerols.
because all the three hydroxyl groups of glycerol are
esterified.

 Fats are also called as neutral fats.
,
Triacylglycerol

Formation of an ester:
O O
R'OH + HO-C-R" R'-O-C-R'' + H2O
 Structure of Triacylglycerol/ fats
✓ 3 fatty acids linked to glycerol.
i.e. three molecules of fatty acids esterified with one molecule of
glycerol.
All the three fatty acids can be same or different.

Functions of Triglycerides
1.They function as storage lipids in animals and in plants.

2. In man adipose tissue or fat tissue found under the skin, in the
abdominal cavity and in the mammary gland contain
triacylglycerols.
 …Cont’d.

3. In other animals and plant cells also triacylglycerols are found as
tiny droplets in cytosol.

4. The fat stored under the skin serve as energy store and as
insulator against cold.

5. Women have more fat than men.
6. In obese (fat) people, many kilograms of triacylglycerol is
stored under the skin.

7. The antarctic and arctic animals like seals and penguins appear
bloated because of high concentration of triglycerides in their
bodies.
Physical Properties of TAGs
1. Pure fats have no colour, taste and odour.

2. At room temperature,
✓ fat of plant origin remains oil because it contains more
unsaturated fatty acids where as
✓animal fat remain as solid, because it contains mostly
saturated fatty acids.

3. Triglycerides containing asymmetric carbon atom are
optically active.
 Steroids
▪ Steroids are complex molecules containing four fused rings.
 The four fused rings makeup
‘cyclopentanoperhydrophenanthrene’(CPPP) or ‘sterane’ ring.
 Sterane ring is also called as steroid nucleus. The most abundant
steroids are sterols which are steroid alcohols.

Fig. structure of steroid nucleus
Fig. structure of steroid Cholesterol.
 COMPOUND LIPIDS
When a lipid contains an element or moiety in
addition to fatty acids and alcohol present in simple
fats, it is known as a compound or conjugated lipid.
 Saturated C16 or C18 FA

Phosphodiester Unsaturated C16 – C20 FA
linkage Derived from polar alcohol
smallest = H (from H-OH)
least common in membranes
phosphatidic acid
 Cardiolipin
▪Cardiolipin is an important
component of the inner
mitochondrial membrane

▪ This the only human
glycerophospholipid that is
antigenic.

▪ For example,cardiolipin is
recognized by antibodies raised
against Treponema pallidum,
the bacterium that causes
syphylis.
▪ Cardiolipins are used in
serological diagnosis of syphilis
and autoimmune diseases.
Plasmalogens
Platelet-activating factor (PAF)

PAF is synthesized /released by a
variety of cell types.

binds to surface receptors,
triggering potent thrombotic and
acute inflammatory events.
PAF activates inflammatory cells
and mediates hypersensitivity,
acute inflammatory, and
anaphylactic reactions.
neutrophils causes platelets to
aggregate and degranulate, and
alveolar macrophages to generate
superoxide radicals
 Sphingophospholipids

S Sphingomyelin is an
important constituent of the
myelin of nerve fibers.
T
T The myelin sheath is a
layered, membranous
structure that insulates and
protects neuronal fibers of
the central nervous system.
Sphingophospholipids
 Ceramide

OH O
CH3 (H2C)12 CH CH CH CH NH C R1
Sphingosine Fatty acid
CH2
O CH3
Phosphate O P O CH2 CH2 N+ CH3 Choline
OH CH3
Sphingomyelin
Sphingomyelins are found in large amounts in brain and nerves and
in smaller amounts in lung, spleen, kidney, liver and blood.

Sphingomyelins differ from lecithins and cephalins in that they
contain sphingosine as the alcohol instead of glycerol, they contain
two nitrogenous bases: sphingosine itself and choline.
 Glycolipids
Glycolipids are lipids that contain carbohydrate residues in
addition to the alcohol (sphingosine) and a very long-chain fatty
acid (24-carbon series).
They are present in cerebral tissues and, therefore, are called
cerebrosides.
They are also referred to as sphingogalactolipids or galactosides as
galactose is an important constituent of their structure.
Classification of glycolipids: According to the number and nature
of the carbohydrate residue(s) present in the glycolipids the
following types exist:
Cerebrosides: They have one galactose molecule (galactosides).
Sulfatides: They are cerebrosides with sulfate substitution on the
sugar (sulfated cerebrosides).
Gangliosides: They have several sugar and sugaramine residues
and at least one residue of N-acetyl neuraminic acid (NANA).
Glycolipids help form insulation for
nervous system electrical activity
Negatively charged gangliosides in glia membrane
Repel negative ions & attract positive ions
Myelin insulation greatly increases the speed of
action potentials
 Glycolipids

Pattern of sugar residues is variable
Always in outer leaflet of cell membrane, & inner
leaflet of organelles

Hydrophilic
(soluble)

Hydrophobic
(not soluble
= lipophilic)
 Cerebrosides
▪ The cerebrosides, as the name suggest (cerebral = related to
brain), occur in myelin sheath of nerves and white matter of the
brain tissues and cellular membranes.
▪ They are important for nerve conductance. They contain sugar,
usually -galactose (sometimes glucose or lactose), sphingosine
and fatty acid, but no phosphoric acid.
Cerebron (Phrenosin) contains
Ceramide
cerebronic acid (2-
hydroxylignoceric acid) and
OH O galactose.
CH3 (H2C)12 CH CH CH CH NH C R1 Nervon contains nervonic acid
Sphingosine Fatty acid (lignoceric acid unsaturated at
CH2 C15) and galactose.
CH2OH Oxynervon contains oxynervonic
O
OH H O acid (2-hydroxynervonic acid) and
Galactose galactose.
OH H H
H Other Cerebrosides: Some
H OH cerebrosides contain
carbohydrates other than
Psychosin
galactose
Cerebroside
 Gangliosides
They are compound lipids present in gray matter of the brain,
ganglionic cells, and RBCs.
They are composed of a glycosphingolipid (ceramide and
oligosaccharide) with one or more sialic acids (i.e., N-
acetylneuraminic acid; NANA) linked as a branch to the sugar
chain.
Gangliosides are classified according to the oligosaccharide
attached to ceramide.
The basic oligosaccharide unit attached to ganglioside GM1
consists of five monosaccharides, i.e., Ceramide-Glucose 
Galactose (NANA)  N-Acetylgalactosamine  Galactose (with
NANA attached to the first galactose).
GM1ganglioside is the site of attachment of the Vibrio cholerae
exotoxin that causes the acute diarrhea of cholera. GM2 and GM3
gangliosides are derived from GM1 by removal of terminal
galactose and N-acetylgalactosamine, respectively.
 Although a minor membrane component
(~2%), glycolipids have some special
functions

▪ Gangliosides in neurons
Oligosaccharides with negatively charged sialic
acid residues
Attract positive ions, e.g. Ca++
Affects electrical properties & signaling
 Gangliosides act as
Receptors Gangliosidoses
As components of the
cell plasma membrane,
gangliosides modulate
cell signal transduction
events. They have
recently been found to
be highly important in
immunology. They
transfer biogenic amines
across the cell
membrane and act as
cell membrane
receptors. They work as
the receptors for cholera
toxin on the human
intestine mucosal cells
and as receptors for
certain viruses. Natural
and semi-synthetic
gangliosides are
considered the potential
therapeutic agents for
neurodegenerative
disorders.
 Sphingolipids at Cell Surfaces are Sites of Biological
Recognition
▪ In humans, at least 60 different
sphingolipids have been identified in
cellular membranes
 Many of these are prominent in the
plasma membranes of neurons
Glycosphingolipids as determinants
of blood groups: 
 The carbohydrate moieties of certain
sphingolipids;
 define the human blood groups
 therefore determine the type of blood

 that individuals can safely receive in
blood transfusions

Fuc sugar fucose
58
Lipid rafts have higher concentrations of -

Sphingolipid
Cholesterol
Glycolipids
Lipoproteins
▪ Lipoproteins are lipids combined with proteins in the
tissues. The lipid component could be a phospholipids,
cholesterol or triglycerides. The lipoproteins could be
described as of two types.
▪ Structural lipoproteins: These are widely distributed in
tissues, being present in cellular and subcellular
membranes. In lung tissues, they act as surfactants in a
complex of a protein and lecithin. In the eye, rhodopsin of
rods is a lipoprotein complex.
▪ Transport lipoproteins: These are the forms present in blood
plasma. They are composed of a protein called
apolipoprotein and different types of lipids. (Cholesterol,
cholesterol esters, phospholipids and triglycerides). As the
lipid content increases, the density of plasma lipoproteins
decreases and the diameter increases and vice versa.
 Classification of Lipoproteins

Lipoproteins are classified by their density which, in turn, reflects
size. The greater the lipid/protein ratio in the complex, the larger it is
and the lower its density.
There are five main classes of lipoproteins.
Triglyceride-rich particles include :
Chylomicrons, which transport exogenous lipid from the intestine
to all the cells.
VLDL (very low density lipoproteins), which transport
endogenous lipid from the liver to cells;.
IDL (intermediate density lipoproteins), which are usually
undetectable in normal plasma. It is normally a transient
intermediate lipoprotein formed during the conversion of VLDL to
LDL.
It contains both cholesterol and endogenous triglycerides.
Classification of Lipoproteins

LDL (low density lipoproteins):
formed from VLDL, transport cholesterol to cells.
HDL (high density lipoproteins):
These are involved in the transport of cholesterol from
the cells to the liver.
LDL and HDL are two smaller lipoproteins contain mostly
cholesterol.
The classes of lipoproteins are chylomicrons, VLDLs, IDLs,
LDLs, and HDLs.
Classification of Lipoproteins

Chylomicrons:
synthesized in small intestine and secreted into the lymph.
Apolipoprotein present:-
Apo-B, Apo AI, ApoAII, ApoAIV, ApoCII, ApoCIII, ApoE.
composition:
1 % protein.
87 % triglyceride.
8 % phospholipid.
3 % cholesteryl ester.
1 % free cholesterol.
 Lipoprotein Classification
Very low density lipoproteins (VLDL)
synthesized in the liver, rich in triglyceride
apo-lipoproteins:
Apo-B100, ApoC-III, Apo-E, ApoA-I, ApoA-II
composition:
7 - 10 % protein.
50 - 55 % triglyceride.
18 - 20 % phospholipid.
12 - 15 % cholesteryl ester.
8 - 10 % free cholesterol.
 Low density lipoproteins (LDL)

LDL and IDL, are the catabolic products of VLDL
apo-lipoproteins present: Apo-B
Composition:
20 - 22 % protein
12 - 15 % triglyceride
20 - 28 % phospholipid
37 - 48 % cholesteryl ester
8 - 10 % free cholesterol
 High density lipoproteins (HDL)

formed around ApoAI secreted from liver and
intestine.
apo –lipoproteins present:
Apo A-I, Apo A-II, ApoAIV, ApoCIII, ApoE
Composition:
33 - 57 % protein
3 - 15 % triglyceride
26 - 43 % phospholipid
15 - 30 % cholesteryl ester
2 - 10 % free cholesterol
HDLs are used for the transport of lipid through the circulatory system to the
liver, and high levels of HDLs forecast a low risk of heart attack. In contrast,
high levels of LDLs (which transport cholesterol to the non-hepatic tissues) are
considered cautionary.

D stands for “density” in these acronyms because fat has a density of about 0.88
g/ml, whereas protein has a density of about 1.0 g/ml. In consequence, the
higher the fat content, the lower the density of the particle.
  Since cholesterol is hydrophobic
(water fearing) and blood is
hydrophilic (water loving), the two
do not mix.
 Cholesterol is carried through the
bloodstream in protein packages
called lipoproteins, made up of
lipid on the inside and protein on
the outside.
 Two kinds of lipoproteins carry
cholesterol throughout your body.

- High density lipoproteins (HDL) - Low density lipoproteins (LDL)
70
 LDL and HDL …cont’d
 LDL cholesterol is sometimes called bad cholesterol.
 High LDL cholesterol leads to a buildup of cholesterol
in arteries.
 The higher the LDL level in your blood, the greater
chance you have of getting heart disease.

 HDL cholesterol is sometimes called good cholesterol.
 HDL carries cholesterol from other parts of your body
back to your liver. The liver removes the cholesterol
from your body.
 The higher your HDL cholesterol level, the lower your
chance of getting heart disease.
71
Chemistry of Amino
Acids and Proteins - I

1
 Outline of the topic
 General structure of Amino Acids
 Classification of Amino acids
 Function of Amino Acids
 Acid-Base property of amino acids
 Peptide bond structure and functional peptides
 Protein structure
 Biological functions of proteins
 Protein classification
2
 Objectives of the topic
At the end of this session, you will be able to
Describe general structure of amino acids
List the biochemical functions of amino acids
Categorize amino acids by different basis of classification
Explain acid-base property of amino acids
Explain peptide bond and its character
Mention functional peptides
Give details of protein structure
Elucidate biological functions of proteins
Classify proteins 3
What are Proteins?
Unbranched Polymers of amino acids linked head to tail

Major constituent of most cells

Usually form multi-molecular complexes

They are folded into specific conformations

Their conformation and functional-group chemistry controls
function

Responsible for most of our phenotype (define what an
organism is, what it looks like, how it behaves, etc.)

Made from almost 20 different types of standard amino-
acids
Special condition: Selenocysteine incorporated during co-
translation in human 4
 Amino acids
 Structure:
 central carbon H O
 amino group
H | ||
 Carboxyl group
—N—
—C— C—OH
H |
Side chain (R group)
 variable group
R
 confers unique
chemical functionality

 Chiral/ Optically active
 Acid–base properties
 Capacity to polymerize
5
 Classification of Amino Acids

Amino acids can be classified based on

 Side chain character

 Nutritional value

 Metabolic fate

 Presence/ absence in proteins
6
Amino Acid Classification by Side Chain Character

 Hydrophobic side chain: stabilize protein structure by hydrophobic
interactions.

 Tyrosine can form hydrogen bonding. 7
Classification...

 Reversible formation of a
disulfide bond by the
oxidation of two molecules
of cysteine
8
 Classification…

Acidic side chain:
H+ (proton) donor

9
 Classification …

Basic side chains:
H+ acceptors

 Histidine side chain
pKa= 6.0

 10% protonated at pH= 7

 Serving as a proton
donor/ acceptor in many
enzymatic reactions

 Identification of carbon atoms
in amino acids
10
 Names and Codes of Amino Acids
Name One Three R-Group Properties
letter Letter
Glycine G Gly Hydrophobic
Alanine A Ala Hydrophobic
Valine V Val Hydrophobic
Leucine L Leu Hydrophobic
Isoleucine I Ile Hydrophobic, two chiral carbons
Proline P Pro Cyclic, not terribly hydrophobic
Phenylalanine F Phe Hydrophobic, bulky
Tyrosine Y Tyr Less hydrophobic (than Phe), bulky
Tryptophan W Trp Hydrophobic, bulky (indole ring)
Cysteine C Cys Hydrophobic, highly reactive (S-S link)
Methionine M Met Hydrophobic (start a.a.)
Serine S Ser Hydrophilic, reactive
Threonine T Thr Hydrophilic, reactive, two chiral carbons
Lysine K Lys Highly hydrophilic, positively charged
Arginine R Arg Highly hydrophilic, positively charged
Histidine H His Highly hydrophilic, positive or neutral
Aspartate D Asp Highly hydrophilic, negatively charged
Glutamate E Glu Highly hydrophilic, negatively charged
Asparagine N Asn Polar, Uncharged
Glutamine Q Gln Polar, Uncharged 11
Amino Acid Classification Based on Nutritional Value
 Basedupon whether the AAs can be synthesized in
human body or not
 Indispensable or essential amino acids: 9 amino
acids
 Not synthesizable in the body in adequate amounts

 Val, Ile, Thr, Trp, Leu, Lys, Met, Phe and His.

 Dispensable or non-essential AAs
o Can be synthesizable in the body from the essential
ones
 Conditionally essential amino acids: During illness or stress

 Tyrosine, cysteine, arginine, glutamine, glycine, proline, and serine.

12
 CLASSIFICATION BASED ON METABOLIC FATE
 Based upon the catabolic fate of
Carbon skeleton of amino acids Ketogenic
Mixed
Glucogenic
Type
 Ketogenic

Catabolically give intermediates Leu IIe
convertible into Acetyl-CoA or
Acetoacetyl-CoA
Lys Tyr Ala, Arg Asp,
 Glucogenic
Asn Glu, Gln
14 of them give rise to intermediates of Ser, Met Pro,
Trp
glycolysis or Kreb’s cycle Gly His, Thr
Val, Cys
 Mixed type
Carbon-skeleton of which is catabolized to Phe
produce glycolytic intermediates or acetyl
CoA derivatives
13
Some Common Biological Functions of Amino Acids
 Formation of peptides and proteins

 Stabilize 3D structure of proteins by forming multiple bonds

 Specific AAs at the active site are vital for enzyme catalysis

 Some AAs as source of glucose

 Cys and Met are sources of S in the body (e.g. for Fe-S center
formation)

 Carbon skeleton and Nitrogen of AAs used for nucleic acid
synthesis

 Gly and Met help in the detoxification mechanisms

 Met can act as a methyl group donor in methylation reactions 14
Amino Acids as Precursors of Biologically Important Derivatives

 Gycine is a precursor for
 Heme

 Creatine

 Tyrosine is the precursor for number of hormones:
 Thyroxine & Triiodothyronine

 Epinephrine & nor-epinephrine

 Skin pigment melanin

 Tryptophan can give rise to
Niacin
Serotonin
 Histidine can be converted to Histamine
15
Uncommon Amino Acids – Found in proteins
Hydroxylysine and hydroxyproline
- Mainly in collagen
- Found in connective tissues

Tyroxine and Triiodotyronine
- Produced from degradation of thyroglobulin

- Act as hormones for growth &
development

N-methylarginine and N-acetyllysine
- found in histone proteins

16
Uncommon Amino Acids – Found in proteins

Methylhistidine, -N-methyllysine, &
N,N, N-trimethyllysine
- Methylated amino acids in myosin

-Carboxyglutamic acid
- In blood clotting proteins & Ca2+
containing proteins
e.g. Prothrombin

17
Uncommon Amino Acids – Found in proteins

Desmosine
- Derivative of four Lys residues
- Found in fibrous protein elastin

Selenocysteine
- Derived from serine
- Introduced during protein synthesis
- Role in antioxidant activity
e.g. Gluthione peroxidase active site
18
 Amino Acids not found in proteins

GABA (decarboxylation of
glutamic acid)
- a potent neurotransmitter.

Histamine (decarboxylation of
histidine) & Serotonin (from
tryptophan)
- function in smooth muscle
contraction, as nurotransmitter, vascular
permeability, etc

-Alanine
- for synthesis of carnosine (for muscle
endurance)
19
 Amino Acids not found in proteins
Epinephrine

Ornithine & Citrulline
- in urea cycle, Arg synthesis.

Dopa (3,4-dihydroxyphenylalanine): Precursor of melanin

S-adenosyl methionine (SAM): a methyl donor in transmethylation rxn
20
Acid-Base Properties of Amino Acids

 Ammonium form acts as an acid, the carboxylate as a base.
21
 pI of Neutral Amino Acids

 The PI can be
calculated as the
average of pKa1
and pKa2

22
pI of Amino Acids - Alanine

23
Amino Acids with Ionizable Side Chains

Lysine

24
pI of Amino Acids – With Acidic, Neutral and Basic Side Chains

25
pKa and PI Values of Common Amino Acids

26
 Peptide Bond
&
Functional Peptides

27
 Peptide Bonds (Amide bond)
Condensation rxn
Formation of dipeptide, tripeptides, etc....
 Forms N-terminal and C-terminal
Acid-base behavior of a peptide can be
predicted from its free -amino and -carboxyl
groups as well as the nature and number R
groups.

 Have characteristic characteristic pI

 pKa value for an ionizable R group can
Serylglycyltyrosylalanylleucine
change somewhat when an amino acid or
becomes a residue in a peptide. Ser–Gly–Tyr–Ala–Leu
28
 Planar peptide groups in a polypeptide chain
Amide nitrogen are non-basic because their unshared electron pair is
delocalized by interaction with the carbonyl group.
Rotation around C-N bond is restricted due to the double bond nature
Peptide groups are therefore planar

Planar Structure of peptide
29
 Biologically Active Peptides
 Glutathione
– Formed from -glutamic acid, Cysteine & Glycine

– It protects the cell membrane from damage,

 e.g., prevents hemolysis of erythrocytes

Slightly larger peptides/ Oligopeptides
 Insulin

– contains two polypeptide chains

one having 30 and the other has 21amino acid residues

 Corticotropin

– is a 39-residue hormone of the anterior pituitary gland

– stimulates the adrenal cortex
30
 Commercial peptide: Example

O O O

H2N CH C NH C CH C OCH3
 Aspartame/ L-Aspartyl-
CH2 CH2
L-phenylalanine methyl Methyl ester
ester/ Neurasweet C OH
 Artificial sweetener O

Aspartic Acid
Phenylalanine

31
 Structure
and
Classification of Proteins

32
 Protein structure
 The 3-D structure mainly depends on types,
number and sequence of amino acids
 twisted, folded, coiled into unique shape
Pepsin
 Structure determines the function of a protein

 Native, folded structure of the protein depends on
several factors Collagen
(1) interactions with solvent molecules
(2) the pH and ionic composition of the solvent
(3) the sequence of amino acid in a protein.
Hemoglobin 33
Primary structure of proteins
 Describes sequence and number of amino acids
in chain
◦ Determined by gene (DNA sequence)
◦ Contain all information necessary for folding into its
“native” structure

 Amino acid sequence of Lysozyme
34
 Primary structure...
Does Amino Acid Sequence determine protein function?

Oxytocin Ile Gln
Tyr Asn
- Initiates contractions of the uterus during childbirth
Cys Cys
Pro-Leu-GlyNH 2
- Plays a role in the release of milk during lactation S S

Vasopressin (ADH) Phe Gln
Tyr Asn
- Regulate the amount of water
Cys Cys
present in the body Pro-Arg-GlyNH2
S S

35
 Primary structure...
Change in amino acid sequence may cause problem!
Hemoglobin – 574 amino acids

36
Secondary structure of proteins: Local folding

 Formed by H-bonding
 Describes about folding
pattern along short
sections of polypeptide

 The Development of
regular patterns of
hydrogen bonding result
in distinct folding patterns

37
Secondary structure:
Examples
 -helix
 Peptide carbonyl H-bonded to peptide N-
H group four residues farther
 One turn of the helix represents 3.6
amino acid residues (13 atoms from
the O to the H of the H-bond - 3.613
helix)
 All of the H-bonds lie parallel to the
helix axis
 All of the carbonyl groups are
pointing in one direction along the
helix axis

38
Secondary (2°) structure: Examples

e.g. Myoglobin – 153 AAs
- Eight stretches of  -helix forming a
box to contain the heme prosthetic grp.

Other forms of Helix

310 helix
- 3.0 residues per turn (with 10 atoms in the ring
formed by making the hydrogen bond three residues up the
chain)
27 ribbon

39
Secondary (2°) structure: Examples
 -Pleated Sheet
 Each strip of paper as a
single peptide strand
 Peptide backbone makes a
zigzag pattern along the
strip
 –carbons lying at the
folds of the pleats.
 Formation of interstrand H-
bonds
 Side chains oriented
perpendicular to the plane
of the sheet,
 Side chains extending out
from the plane on
alternating sides
40
 Secondary (2°) structure: Examples

Two types
Parallel pleated sheet

- Typically large structures

Usually > five strands

Antiparallel pleated sheet

- Usually having hydrophobic side chain
on one side, so it requires alternating
hydrophobic & hydrophilic residues
arrangement in primary structure

41
 Secondary (2°) structure: Examples
-Turn/ tight turn/ -bend

- A tight loop formed by the carbonyl O
of the 1st is H-bonded with amide N of
the 4th residue down the chain

- Proline & glycine, occur
frequently in -turn sequences

- Abundant in globular structures

42
 Secondary (2°) structure: Examples

-Bulge

 A small piece of non-repetitive structure
that can occur by itself
 Most often occurs as an irregularity in
antiparallel -structures
 Occurs between two normal –
structure H-bonds and comprises 2
residues on one strand and one residue on
the opposite strand
 Bulges thus cause changes in the
direction of the polypeptide chain, but to a
lesser degree than -turns.

43
Super Secondary
Common motifs:
Examples

44
Super-secondary structures
commonly found in some DNA-
binding proteins

45
Tertiary (3°) structure: All things hold together
 Shows the whole molecule folding pattern
◦ Describes about overall 3-D structure of a polypeptide
◦ Determined by interactions between R groups
◦ Bonds that determine 3D-structure are:
 Hydrogen bond
 Hydrophobic
interactions
 Disulfide bridges
 Ionic bonds
 Van der Waals Force
46
Bonds determining 3°
structure of proteins

47
Examples of some domains

-Barrel Bundle Saddle

48
 Quaternary (4°) structure
 Formed from more than one polypeptide chain
 Organized by the same types of bonds as tertiary
structure
 Most intracellular enzymes are oligomers

C) Immunoglobulin49
 Advantages of Quaternary Association

Stability
- Favorable reduction of the protein’s surface-to-volume ratio

- Interactions stabilizes the protein energetically

- Shield hydrophobic residues from solvent water

Genetic Economy and Efficiency

- Less DNA is required to code for a monomer

50
 Advantages of …
Bringing Catalytic Sites Together
 Monomer may not constitute a complete enzyme active site

 May also carry out different but related reactions on different subunits

e.g. Tryptophan synthase (22)
-subunit:
- subunit :

Cooperativity
- Regulate catalytic activity by subunit interactions

- Some proteins are inactive when oligomers
e.g. Insulin hexamer formation in solution

- Ligand binding at one site changes affinity of Hb the other site for O2
51
Examples of Proteins with Quaternary Structure

52
 Summary of Levels of Protein Structure

aa sequence
peptide bonds
determined by DNA

H bonds of carbonyl O
and Amide H of peptide R groups
Hydrophobic, Ionic,
Disulfide bridges, H-bond

Multiple polypeptides
All bond types like tertiary53
Classification of Proteins – Based on Function
 a. Enzymes:
 e.g. Glucokinase
 b. Regulatory Proteins
 Regulating other proteins
 Eg. Insulin

 Regulation of gene expression
e.g. Transcription activators

c. Transport Proteins
e.g. Hb:
Serum albumin: Fatty acid transport
Membrane transporters (channels): e.g. AA & Glucose
transporters 54
 Functional classes …
d. Storage Proteins:
e.g. Casein: Major source of
Calcium phosphate in mammalian
infants
E.g. Ferritin: for Hb synthesis
e. Contractile and Motile Proteins፡ For
cell motility, muscle contraction , cell
division
e.g. Actin & Myosin: muscle
contraction

Dynein and Kinesin (Motor
proteins): drive the movement of
vesicles, granules, and organelles
along microtubules 55
 Functional classes …
f. Structural Proteins

- Provide strength & protection to cells & tissues

e.g. -keratin: hair, horns, and fingernails

Collagen: bone, connective tissue, tendons, cartilage,

Elastin: an impor