Biological Macromolecules and Lipids PDF

Summary

This document is a lecture presentation about biological macromolecules. It covers the structure and function of large biological molecules, including carbohydrates, lipids, proteins, and nucleic acids. The presentation includes detailed information on monomers, polymers, and the synthesis and breakdown of major macromolecular types.

Full Transcript

Lectures by
Esraa H. Al-Nsour
 Overview: The Molecules of Life
All living things are made up of four classes of large biological
molecules: carbohydrates, lipids, proteins, and nucleic acids
Macromolecules are large molecules composed of thousands of
covalently connected atoms
Molecular structure and function are inseparable
Concept 5.1: Macromolecules are polymers, built
from monomers
A polymer is a long molecule consisting of many similar building
blocks
These small building-block molecules are called monomers
Three of the four classes of life’s organic molecules are polymers
Carbohydrates
Proteins
Nucleic acids
 The Synthesis and Breakdown of Polymers
A dehydration reaction two molecules are covalently bonded to each
other, with the loss of a water molecule, one monomer provides hydroxyl
(OH-), while the other provides (H+): Dehydration synthesis = build by
removing H2O.
Enzymes are organic catalysts = macromolecules that speed up
chemical reactions.
Hydrolysis reaction the bond between monomers is broken by the
addition of water, where (H+) from water attach to one monomer and the
(OH-) to the other one : Hydrolysis = breaking down by adding H2O.
Concept 5.2: Carbohydrates serve as fuel and
building material

Carbohydrates include sugars and the polymers of sugars
The simplest carbohydrates are monosaccharides, or single sugars
Disaccharides are double sugars, consisting of two monosaccharides
joined by a covalent bond.
Carbohydrate macromolecules are polysaccharides, polymers
composed of many sugar building blocks
 Sugars
Monosaccharides have molecular formulas that are usually multiples
of CH2O
Glucose (C6H12O6) is the most common monosaccharide

Monosaccharides are classified by :
1. The location of the carbonyl group (as aldose or ketose)
2. The number of carbons in the carbon skeleton
 Though often drawn as linear skeletons, in aqueous solutions
many sugars form rings, because they are the most stable
form of these sugars under physiological conditions.
Monosaccharides serve as a major fuel for cells and as raw
material for building molecules

(A) Linear and ring forms (B) Abbreviated ring structure
 A disaccharide is formed when a dehydration reaction joins two
monosaccharides by removing H2O to form a covalent bond.
This covalent bond is called a glycosidic linkage.
The dehydration synthesis reaction: C6H12O6 + C6H12O6 =
C12H22O11

Examples of disaccharides:
a. Maltose (glucose + glucose).
b. Sucrose (glucose + fructose).
c. Lactose (glucose + galactose).
Polysaccharides
Polysaccharides are macromolecules, the polymers of sugars, have
storage and structural roles.
The structure and function of a polysaccharide are determined by its
sugar monomers and the positions of glycosidic linkages.
 Storage Polysaccharides
Starch is a plant storage polysaccharide. Starch is made of glucose
monomers.
Plants store surplus starch as granules within chloroplasts and other
plastids.
Glycogen is an animal storage polysaccharide. Glycogen is found in
the liver and muscles.
Storage polysaccharides of plants and animals
Chloroplast Starch Mitochondria Glycogen granules

0.5 µm

1 µm

Amylose
Amylopectin Glycogen

(a) Starch: a plant polysaccharide (b) Glycogen: an animal polysaccharide
Structural Polysaccharides
The polysaccharide cellulose is a major component of the tough wall
of plant cells
Like starch, cellulose is a polymer of glucose, but the glycosidic
linkages differ
The difference is based on two ring forms for glucose: alpha () and
beta ()
(a)  and  glucose
ring structures

4 1 4 1

 Glucose  Glucose

1 4
1 4

(b) Starch: 1–4 linkage of  glucose monomers (c) Cellulose: 1–4 linkage of  glucose monomers
- Polymers with  glucose are helical
- Polymers with  glucose are straight
- In straight structures, H atoms on one strand can bond with OH
groups on other strands
- Parallel cellulose molecules held together this way are grouped
into microfibrils, which form strong building materials for plants
 Enzymes that digest starch by hydrolyzing  linkages can’t
hydrolyze  linkages in cellulose.
Cellulose in human food passes through the digestive tract as
insoluble fiber.
Some microbes use enzymes to digest cellulose.
Many herbivores, from cows to termites, have symbiotic
relationships with these microbes.
 Chitin, another structural polysaccharide, is found in the
exoskeleton of arthropods.
Chitin also provides structural support for the cell walls of fungi.
Unlike starch and glycogen, chitin is a polysaccharide with
nitrogen ( N ) in each sugar monomer.
Concept 5.3: Lipids are a diverse group of
hydrophobic molecules
Lipids are the one class of large biological molecules that do not
form polymers.
The unifying feature of lipids is having little or no affinity for water.
Lipids are hydrophobic because they consist mostly of
hydrocarbons, which form nonpolar covalent bonds.
The most biologically important lipids are fats, phospholipids,
and steroids.
Fats
Fats are constructed from two types of smaller molecules:
glycerol and fatty acids.
Glycerol is a three-carbon alcohol with a hydroxyl group attached
to each carbon.
A fatty acid consists of a carboxyl group attached to a long
hydrocarbon chain.
This fatty acid hydrocarbon can be either saturated or
unsaturated.
 Fats separate from water because water molecules form hydrogen bonds with
each other and exclude the fats
In a fat, three fatty acids are joined to glycerol by an ester linkage,
creating a triacylglycerol, or triglyceride
 Fatty acids vary in length (number of carbons) and in the number and
locations of double bonds
Saturated fatty acids have the maximum number of hydrogen atoms
possible and no double bonds , All C - C bonds are single
Unsaturated fatty acids have one or more double bonds, double
bonds C = C
 Fats made from saturated fatty acids are called saturated fats, and
are solid at room temperature
Most animal fats are saturated
Fats made from unsaturated fatty acids are called unsaturated fats
or oils, and are liquid at room temperature
Plant fats and fish fats are usually unsaturated
 A diet rich in saturated fats may contribute to cardiovascular disease
through plaque deposits.
Hydrogenation is the process of converting unsaturated fats to
saturated fats by adding hydrogen.
Hydrogenating vegetable oils also creates unsaturated fats with trans
double bonds = trans fats.
These trans fats may contribute more than saturated fats to
cardiovascular disease.
 The major function of fats is energy storage
Humans and other mammals store their fat in adipose cells
Adipose tissue also cushions vital organs and insulates the body
Phospholipids
In a phospholipid, two fatty acids and a phosphate group are
attached to glycerol
The two fatty acid tails are hydrophobic, but the phosphate group
and its attachments form a hydrophilic head
A phospholipid is an amphipathic molecule: hydrophilic head and
hydrophobic tails.
 When phospholipids are added to water, they self-assemble into a
bilayer, with the hydrophobic tails pointing toward the interior
The structure of phospholipids results in a bilayer arrangement found
in cell membranes
Phospholipids are the major component of all cell membranes
Steroids
Steroids are lipids characterized by a carbon skeleton consisting of
four fused rings
Cholesterol, an important steroid, is a component in animal cell
membranes
Although cholesterol is essential in animals, high levels in the blood
may contribute to cardiovascular disease
Concept 5.4: Proteins include a diversity of structures,
resulting in a wide range of functions
Proteins account for more than 50% of the dry mass of most cells
Protein functions include structural support, storage, transport,
cellular communications, movement, and defense against foreign
substances
Proteins are polymers called polypeptides.
Amino acids are the monomers used to build proteins.
Examples of proteins functions:
 Enzymes are a type of protein that acts as a catalyst to speed up
chemical reactions
Enzymes can perform their functions repeatedly, functioning as
workhorses that carry out the processes of life
 Polypeptides

Polypeptides are unbranched polymers built from the same set of 20
amino acids
A protein is a biologically functional molecule that consists of one or
more polypeptides
Amino Acid Monomers
Amino acids are organic molecules with carboxyl and amino groups
attached to a central carbon.
Amino acids differ in their properties due to variable side chains,
called R groups
There are 20 different amino acids because there are 20 different
side chains.
 Amino Acid Polymers
Amino acids are linked by covalent bonds called peptide bonds C - N
A polypeptide is a polymer of amino acids.
Polypeptides range in length from a few to more than a thousand
monomers.
Each polypeptide has a unique linear sequence of amino acids, with a
carboxyl end (C-terminus) and an amino end (N-terminus).
Protein Structure and Function
A functional protein consists of one or more polypeptides precisely
twisted, folded, and coiled into a unique shape
A protein folds into a specific Shape / Structure so it
can perform its Function

Groove
Groove

(a) A ribbon model of lysozyme (b) A space-filling model of lysozyme
 The sequence of amino acids determines a protein’s three-dimensional
structure
A protein’s structure determines its function
An antibody binding to a protein from a flu virus
Antibody protein Protein from flu virus
Four Levels of Protein Structure
The primary structure of a protein is its unique sequence of amino
acids
Secondary structure consists of regular coils and folds in the
polypeptide backbone made by hydrogen bonds.
Tertiary structure is determined by interactions among various side
chains (R groups)
Quaternary structure results when a protein consists of multiple
polypeptide chains
4 Levels of protein structure

Primary Secondary Tertiary Quaternary
Structure Structure Structure Structure
 pleated sheet
+H N
3
Amino end
Examples of
amino acid
subunits

 helix
 Primary structure, the sequence of amino acids in a protein, is like
the order of letters in a long word
Primary structure is determined by inherited genetic information
(DNA).
 The coils and folds of secondary structure result from hydrogen
bonds between repeating constituents of the polypeptide backbone
Typical secondary structures are a coil called an  helix and a
folded structure called a  pleated sheet
 Tertiary structure is determined by interactions between R groups,
rather than interactions between backbone constituents
These R group interactions fold the polypeptide into a globular shape
These interactions between R groups include hydrogen bonds, ionic
bonds, hydrophobic interactions, and van der Waals interactions
Strong covalent bonds called disulfide bridges may reinforce the
protein’s structure
Figure 5.20f

Hydrogen
bond
Hydrophobic
interactions and
van der Waals
interactions
Disulfide
bridge
Ionic bond

Polypeptide
backbone
 Quaternary structure results when two or more polypeptide chains
form one macromolecule
Collagen is a fibrous protein consisting of three polypeptides coiled like
a rope
Hemoglobin is a globular protein consisting of four polypeptides: two
alpha and two beta chains each with an iron heme group.
Sickle-Cell Disease: A Change in Primary Structure

A slight change in primary structure can affect a protein’s structure
and ability to function
Sickle-cell disease, an inherited blood disorder, results from a
single amino acid substitution in the protein hemoglobin
What Determines Protein Structure?

In addition to primary structure, physical and chemical conditions
can affect structure
Alterations in pH, salt concentration, temperature, or other
environmental factors can cause a protein to unravel
This loss of a protein’s native structure is called denaturation
A denatured protein is biologically inactive
Protein Folding in the Cell
It is hard to predict a protein’s structure from its primary structure
Most proteins probably go through several stages on their way to a
stable structure
Chaperonins are protein molecules that assist the proper folding of
other proteins
Diseases such as Alzheimer’s, Parkinson’s, and mad cow disease are
associated with misfolded proteins
 Scientists use X-ray crystallography to determine a protein’s
structure
Another method is nuclear magnetic resonance (NMR) spectroscopy,
which does not require protein crystallization
Bioinformatics uses computer programs to predict protein structure
from amino acid sequences
Concept 5.5: Nucleic acids store, transmit, and help
express hereditary information

The amino acid sequence of a polypeptide is programmed by a unit of
inheritance called a gene
Genes are made of DNA, a nucleic acid made of monomers called
nucleotides
The Roles of Nucleic Acids
There are two types of nucleic acids
Deoxyribonucleic acid (DNA)
Ribonucleic acid (RNA)
DNA provides directions for its own replication
DNA directs synthesis of messenger RNA (mRNA) and, through mRNA,
controls protein synthesis
Protein synthesis occurs on ribosomes
Figure 5.25-3
DNA

1 Synthesis of
mRNA
mRNA

NUCLEUS
CYTOPLASM

mRNA
2 Movement of
mRNA into Ribosome
cytoplasm

3 Synthesis
of protein

Amino
Polypeptide acids
The Components of Nucleic Acids
Nucleic acids are polymers called polynucleotides
Each polynucleotide is made of monomers called nucleotides
Each nucleotide consists of a nitrogenous base, a pentose sugar, and
one or more phosphate groups
The portion of a nucleotide without the phosphate group is called a
nucleoside
Figure 5.26

Sugar-phosphate backbone
5 end Nitrogenous bases
Pyrimidines
5C

3C

Nucleoside

Nitrogenous
base Cytosine (C) Thymine (T, in DNA) Uracil (U, in RNA)

5C Purines

1C
Phosphate 3C
group Sugar
5C
(pentose)
Adenine (A) Guanine (G)
3C (b) Nucleotide

Sugars
3 end
(a) Polynucleotide, or nucleic acid

Deoxyribose (in DNA) Ribose (in RNA)

(c) Nucleoside components
 Nucleoside = nitrogenous base + sugar
There are two families of nitrogenous bases
Pyrimidines (cytosine, thymine, and uracil) have a single six-
membered ring
Purines (adenine and guanine) have a six-membered ring fused to a
five-membered ring
In DNA, the sugar is deoxyribose; in RNA, the sugar is ribose
Nucleotide = nucleoside + phosphate group
Nucleotide Polymers
Nucleotide polymers are linked together to build a polynucleotide
Adjacent nucleotides are joined by covalent bonds that form between
the —OH group on the 3 carbon of one nucleotide and the phosphate
on the 5 carbon on the next
These links create a backbone of sugar-phosphate units with
nitrogenous bases as appendages
The sequence of bases along a DNA or mRNA polymer is unique for
each gene
 The Structures of DNA and RNA Molecules
RNA molecules usually exist as single polypeptide chains
DNA molecules have two polynucleotides spiraling around an
imaginary axis, forming a double helix
In the DNA double helix, the two backbones run in opposite 5→ 3
directions from each other, an arrangement referred to as antiparallel
One DNA molecule includes many genes
 The nitrogenous bases in DNA pair up and form hydrogen bonds:
adenine (A) always with thymine (T), and guanine (G) always with
cytosine (C)
Called complementary base pairing
Complementary pairing can also occur between two RNA molecules
or between parts of the same molecule
In RNA, thymine is replaced by uracil (U) so A and U pair