Introduction to Molecular Biology PDF

Summary

This document provides an introduction to molecular biology, covering topics like cells, DNA, proteins, and polysaccharides.

Full Transcript

Introduction to Molecular biology
 Bacteria
Animals

Plants

humans
 What are the common thing among:-

Chairs Pencil
Cupboard
 Animals
Bacteria

Cell is the
buliding
unit

Plants humans
 Viruses are not cells but depend on cells for
their replication
 The nucleus is a membrane-enclosed
structure that contains the chromosomes in
eukaryotic cells. The nucleoid, in contrast, is
the aggregated mass of DNA that constitutes
the chromosome of cells of Bacteria and
Archaea
Introduction to molecular biology

Why do we study molecular biology ???

1. Because it is required to get the degree 

2. To understand the basic behavior of cells (growth, division, specialization and
interaction in terms of molecules
3. Medical applications: Identifying of disease-causing genes, sequencing of
human genomes, gene therapy
4. Industrial applications: biotechnology products, production of enzymes and
protein, bioremediation,
Food industry (xanthan), insulin production
5. Agricultural processes: growth hormons, cell and tissue cultures

6. Animal production: dolly, silk worms

7. Forensic applications: crimes, fathership
 Introduction to molecular biology

HISTORY
The term „molecular biology“ was introduced in 1938 by Warren Weaver from the
Rockefeller foundation

DNA was first described in 1869 by F. Miescher

Watson and Crick offered a model for the structure of DNA and ist replication
(DNA is the basis of heredity)

Shortly, thereafter, RNA was discovered as an intermediate in protein synthesis
 Introduction to molecular biology
Plant

animal Cell chromo
Nucleuous
somes
bacteria Or nucleoid

humans

genes

Genes are the functional unit of genetic information
Central dogma of
molecular biology
 Introduction to molecular biology

- Typical cells contain 104-105 different kinds of molecules

half

Small molecules
(inorganic ions and organic compounds) Polymers
moleculaer weight :- < several hundreds 104-1012

Proteins Polysaccharides Nucleic acids
 Water and macromolecules
The bacterial cell is about 70% water, with
over one-half of the dry portion being made
up of protein and one-quarter being made up
of nucleic acids.
 PROTEINS
Proteins are polymers of monomers called
amino acids.
 Hydrogen, an amino functional group
(–NH2), and a carboxylic acid functional
group (–COOH) are a part of each amino acid
 The fourth bond (R bond) can be one of 21
common side groups, which may be ionic,
polar, or nonpolar. It is the heterogeneity of
these side groups that defines the properties
of a peptide or protein.
Introduction to molecular biology

Amino acids

Acidic R Basic R Neutral R

Hydrophilic Hydrophobic
 Through a dehydration synthesis reaction,
amino acids can bond covalently by forming a
peptide bond between the amino and
carboxylic acid groups.
Introduction to molecular biology

α-carboxyl group

α -carbon

α-amino group

R-group
Methyl, sulfydrl, another methyl, a string a methyls,
rings of carbons, and several other organic groups
Noninformational Molecules

Polysaccharides
Introduction to molecular biology
 The relatively simple structure of the
polysaccharides and their derivatives makes
them the most abundant natural polymer on
Earth and allows them to be used for
metabolism, as a component of information
transfer molecules, and for cellular structure.
 Glycosidic bonds combine monomeric units
(monosaccharides) into polymers
(polysaccharides), all with a carbon-water
(carbohydrate) chemical composition
approaching (CH2O)n.
 The two different orientations of the
glycosidic bonds that link sugar residues
impart different properties to the resultant
molecules. Polysaccharides can also contain
other molecules such as proteins or lipids,
forming complex polysaccharides.
Introduction to molecular biology
Molecular biology

Phosphodiester bond
 Introduction to molecular biology
- Polysaccharides are polymers of sugars
(Glucose)
- Complex compounds due to the formation of
covalent bonds
- one sugar unit can be joined by more than two
other sugars forming branched
Macromolecules
-They can be too big and macroscopic
- The cell wall of many bacteria and plant cells are
single gigantic polysaccharide molecules
Informational Molecules

Nucleic Acids
 The nucleic acids deoxyribonucleic acid
(DNA) and ribonucleic acid (RNA) are
macromolecules composed of monomers
called nucleotides. Therefore, DNA and RNA
are polynucleotides. Without a phosphate, a
base bonded to its sugar is referred to as a
nucleoside.
Molecular biology

Polynucleotide consisting of nucleotides

Nucleotide

Cyclic five-C Nitrogenous Phosphate
sugars base group

Ribose deoxyribose H2PO4
 Molecular biology

Nitrogenous bases

Pyrimidines Purines

Cytosine Thymine Uracil Adenine Guanine
C T U A G
Molecular biology
 It is the primary structure, or order, of
pyrimidine and purine bases connected by
the phosphodiester bond that gives nucleic
acids their information-storing capacity.
 Both RNA and DNA are informational
macromolecules. RNA can fold into various
configurations to obtain secondary structure.
Molecular biology

N-glycosylic bond

Nucleotide (mono, di
and poly)
Molecular biology
Molecular biology

Are nucleic acids negatively or positively charged? And why??

Answer:

They are negatively charged due to the presence of the phosphate group

Nitrogenous base + Sugar Nucleoside

Nitrogenous base + Sugar + phosphate Nucleotide

Phosphate
Nucleoside + Nucleotide
 In all cells, DNA exists as two polynucleotide
strands whose base sequences are
complementary. The complementarity of
DNA arises from the specific pairing of the
purine and pyrimidine bases: Adenine always
pairs with thymine, and guanine always pairs
with cytosine.
DNA Structure: The Double Helix
DNA is a double-stranded molecule that
forms a helical configuration and is measured
in terms of numbers of base pairs
Complementary due to the specific pairing
between purines and pyrimidines and form
double helix
The two strands in the double helix are
antiparallel, but inverted repeats allow for
the formation of secondary structure.
 Size of a DNA molecule
Can be expressed by the number of
thousands of nucleotide bases
1000 nucleotide=1 kilobase (1 kbp)
E-coli has about 4640 kb of DNA in its
chromosome

1 Megabase pair (1Mbp)=million of base
pairs
 Size of a DNA molecule
each base pair takes up 0.34 nanometers
(nm) in length
Each turn of the helix contains ca. 10 bp

How many turns and how long is a 1 Kbp
DNA fragment ??
100 turns and 0.34 µm
Inverted repeats, secondary
structure and stem loops
 Widespread in RNA
produced from DANN
This secondary structure is
critical for the
functioning of transfer
RNA and ribosomal
RNA
Inverted repeats in DNA are
binding sites for DNA-binding
proteins
Molecular biology
Why macromolecules have a three-dimensional structure ???

ANSWER:

Because they mainly contain weak (noncovalent) interactions?
Molecular biology

Strong and weak chemical bonds

+ Covalent bonds

O + 2H ------------------------ H2O
Six electrons in
Single electron
the outermost
shell
 Molecular biology
The Random coil
The three dimensional configuration of free rotating chains of polypeptides
And polynucleotides is called random coiling

Intrastrand interaction vs Interstrand interaction

1. Hydrogen bonds
C

C=O…..H-N C-OH……O=C N-H…..N
C
Molecular biology
RNA

Intrastrand hydrogen bonding in RNA result in folding of the RNA
Introduction to molecular biology
DNA

Interstrand hydrogen bonging in DNA result in double stranded molecules
 2. The hydrophobic interactions

The interaction between two molecules (or portions of molecules) that are
somewhat insoluable in water
Example: the nitrogenous bases in nucleic acids are planar organic
rings carrying localized weak charges

Hydrophobic interactions among nitrogenous bases result in BASE STACKING
Molecular biology
3. Ionic bonds

Result from Attraction or repulsion of unlike and like charges, respectively

Example:

Amino acids: aspartic and glutamic acids which are negatively
charged interact with lysine, histidine and arginine which are
positively charged

Ionic bonds are the strongest among the noncovalent interactions

It is destroyed by extremes of pH and high concentrations of salts
 Molecular biology
Van der Waals
Attraction
- Very weak forces exist among all molecules and result from circulation of
electrons

-The attaction forces dependent on 1/r6
where r is the distance between
their nuclei

- Can be easily overcome by thermal motion

- The two molecules can bind to one another by van der Waal forces if
their shape are complementary
- Example is the binding of substrates to enzyme
Molecular biology
 DNA Denaturation
The strands of a double-helical DNA
molecule can be denatured by heat and
allowed to reassociate following cooling