BT1010 Introduction to Life Sciences Lecture 3 PDF

Summary

This document covers a lecture on biomolecules, nucleic acids, DNA-based information technologies, and cloning. The lecture, part of BT1010 Introduction to Life Sciences, was given on October 28, 2024, at IIT Hyderabad, India.

Full Transcript

BT1010 Introduction to Life Sciences
Lecture 3: Biomolecules_Nucleic Acids, DNA-Based Information
Technologies, Cloning
28/10/2024

Course Instructor:
Dr. Gunjan Mehta, Ph.D.
Assistant Professor
Department of Biotechnology
IIT Hyderabad
(M.) +91 70168 96886 Email: [email protected]
 Nucleic Acids

See how DNA and proteins work together:
https://www.youtube.com/watch?v=7Hk9jct2ozY&t=
67s

Genetic material
 Why do we look similar to our parents or siblings?

From mother
From father
Genetic Inheritance Human Chromosomes
What is the difference between a DNA, Gene, Chromosome and Genome?
 Introduction to Nucleic Acids

DNA: Deoxyribonucleic Acid
RNA: Ribonucleic Acid

Nucleotides are the building blocks of nucleic acids.

The amino acid sequences of proteins are specified by a nucleotide
sequence in the cell’s DNA.
Central Dogma of Molecular Biology
 Building blocks of the nucleic acids (DNA and RNA)

Nucleotides have three characteristic components: 1) a nitrogenous base,
2) a pentose, 3) one or more phosphates.
Structure of nucleotides

The nitrogenous bases are derivatives
of two parent compounds, pyrimidine
and purine.
Major purine and pyrimidine bases of nucleic acids
 A nucleotide without a phosphate group is called a nucleoside.
 Types of pentose sugars

Nucleic acids have two kinds of pentoses.
DNA contains 2’-deoxy-D-ribose
RNA contains D-ribose
Deoxyribonucleotides and ribonucleotides of nucleic acids
 Phosphodiester bonds link successive nucleotides in nucleic acids

The successive nucleotides of both
DNA and RNA are covalently linked
through phosphate-group “bridges”, in
which the 5’-phosphate group of one
nucleotide is joined to the 3’-hydroxyl
group of the next nucleotide, creating a
phosphodiester linkage.
Hydrogen-bonding patterns in the base pairs
 History and Discovery of DNA

DNA was first isolated and characterized by Friedrich Miescher in 1868. He
called the phosphorous-containing substance “nuclein”.
In 1940, Avery, MacLeod and McCarty found that the DNA extracted from a
virulent (disease-causing) strain of the bacterium Streptococcus pneumoniae and
injected into a nonvirulent strain transformed the nonvirulent strain into a
virulent strain.
In 1952, Hershey and Chase studied the infection of bacterial cells by a virus
(bacteriophage) with radioactively labeled DNA or protein confirmed that DNA,
not protein, is the genetic material.
In 1940, Erwin Chargaff provided following conclusions: (Chargaff’s Rules)
1) The base composition of DNA generally varies from one species to another.
2) DNA specimens isolated from different tissues of the same species have the
same base composition.
3) The base composition of DNA in a given species does not change with an
organisms’s age, nutritional status, or changing environment.
4) In all cellular DNA, A=T and G=C. (A+G = T+C)
 History and Discovery of DNA

In 1950s, Rosalin Franklin and Maurice X-Ray diffraction pattern of DNA fibers
Wilkins used X-Ray diffraction to analyze
DNA fiber.
In 1953, James Watson and Francis Crick relied
on this accumulated information about DNA
and postulated a 3D structure of DNA.
In 1962, Watson, Crick and Wilkins were
awarded the Nobel Prize in Physiology or
Medicine.
At Cold Spring Harbor Laboratory, New York, 2013

James Watson
 Structure of DNA

It consists of two helical DNA chains wound around
the same axis to form a right-handed double helix.
The hydrophilic backbones of alternating deoxyribose
and phosphate groups are on the outside of the double
helix, facing the surrounding water.
The offset pairing of the two strands creates a major
groove and minor groove on the surface of the duplex.
Three hydrogen bonds form between G and C,
whereas only two hydrogen bonds form between A and
T.
Both strands of DNA are in antiparallel orientation.
Vertically stacked bases are 3.4 A apart.
 RNA (Ribonucleic Acid)

RNA is the second major form of nucleic acid
in cells.

RNA carries genetic information from DNA to
the protein biosynthetic machinery of the
ribosome.

By the process of transcription, RNA is
synthesized from the DNA template.

Three types of RNAs involved in protein
synthesis:
1) mRNA: Messenger RNA
2) tRNA: Transfer RNA
3) rRNA: Ribosomal RNA
Secondary and Tertiary Structures of RNA
How the polypeptide/protein chain is synthesized based on the DNA and RNA sequences?

Amino acid codon table

Transcription

Translation
 DNA-based information technologies_Cloning

Cloning is a technique scientists use to make exact genetic copies of living organisms.

Genes, cells, tissues and even whole animal can be cloned.

Dolly the sheep: was the first mammal to have been successfully cloned from an adult somatic cell.
 Ethical Issues of Cloning Animals

There are a variety of ethical concerns regarding the possibilities of cloning, especially human cloning.

While many views are religious in origin, there are also secular perspectives.

Advocates support development of therapeutic cloning to generate tissues and whole organs to treat
patients.

Advocates for reproductive cloning believe that patients who cannot reproduce should have access to
the technology.

Opponents of cloning have concerns that the technology can be prone to abuse and how cloned
individuals could integrate with families and with society at large.

Religious groups believes that the technology can be misused as usurping “God’s place”. Also this
technology uses embryos, so it destroys human life. Other religious groups support therapeutic
cloning’s potential life-saving benefits.

Cloning of animals is opposed by animal-groups due to the number of cloned animals that suffer from
malformations before they die.
 DNA Cloning / Molecular Cloning / Recombinant DNA Technology / Genetic Engineering
DNA cloning is a molecular biology technique that makes many identical copies
of a piece of DNA, such as a gene.

In a typical DNA cloning procedure, the gene (perhaps a gene for a medically
important human protein) is first inserted into a circular piece of DNA called a
plasmid. The insertion is done using enzymes that “cut and paste” DNA, and it
produces a molecule of recombinant DNA.

Cloning of DNA entails five general procedures:
1) Cutting target DNA at precise locations. (Sequence-specific endonucleases)
provide the necessary molecular scissors.
2) Selecting a small carrier DNA capable of self-replication. These DNAs are
called cloning vectors or plasmids.
3) Joining two DNA fragments covalently. DNA ligase is an enzyme that links the
cloning vector and the DNA to be cloned. The resultant DNA molecule is
known as recombinant DNA.
4) Moving recombinant DNA from the test tube to a host cell that will provide the
enzymatic machinery for DNA replication.
5) Selecting host cells that contain recombinant DNA.

The methods used to accomplish these and related tasks are collectively referred
to as recombinant DNA technology or Genetic engineering.
 Cloning vectors (plasmids) allow amplification of inserted DNA segments
Plasmids: A plasmid is a circular DNA molecule that replicates separately from the host chromosome.

Their size ranges from 5000 to 400000 bp.

To survive in the host cell, plasmids incorporate several specialized sequences that enable them to make
use of the cell’s resources for their own replication and gene expression.

pBR322, constructed in 1977, is a good example of a plasmid with features
useful in almost all cloning vectors.
1) Origin of replication (ori), a sequence where replication is initiated by
cellular enzymes. An associated regulatory system is present that limits
replication to maintain pBR322 at a level of 10 to 20 copies per cell.
(Two different plasmids cannot function in the same cell if they use the same ori.)
1) Antibiotic resistance genes TetR (Tetracycline Resistance) and AmpR
(Ampicillin Resistance) allow selection of cells that contain the intact
plasmid or a recombinant version of the plasmid.
1) RE sites to be cut and insert foreign DNA.
2) Small size of the plasmid (4361 bp) facilitates its entry into cells and
the biochemical manipulation of the DNA.
 DNA ligase joins the DNA molecule
DNA ligase is used to join two DNA molecules. It forms phosphodiester bonds between the DNA
molecules.

A vector (plasmid) digested by EcoRI can be ligated to an insert digested by the same RE. It can not be
ligated to an insert digested by BamHI.

Blunt ends can also be ligated, albeit less efficiently.
In general, a 6 bp sequence recognized by a RE (such as BamHI) would occur on average
once every 46 (4096) bp.

An enzyme that recognize a 4 bp sequence would occur on an average once every 44
(256) bp.
 How to introduce plasmids into bacterial cells?
There are two ways:
1) Transformation:
The bacterial cells (often E. coli) and plasmid DNA are incubated together at 0 oC in
a calcium chloride solution, then subjected to heat shock by rapid shifting the
temperature to between 37 oC and 43 oC.

1) Electroporation:
The bacterial cells (often E. coli) are incubated with plasmid DNA are subjected to
high-voltage electric pulse. This approach transiently renders the bacterial membrane
permeable to large molecules.

Regardless of the approach, relatively few cells take up the plasmid DNA, so a method is
needed to identify those cells which contain the plasmid.

Plasmids usually contains one or two selectable markers (such as TetR, AmpR).
 Use of pBR322 to clone foreign DNA in E. coli and identify cells containing it.
A cloning strategy
with pBR322
 Cloned genes can be expressed to amplify protein production
Frequently, the product of the cloned gene, rather than the gene itself, is of primary interest-particularly
when the protein has commercial, therapeutic or research value.

Cloning vectors with the transcription and translation signals needed for the regulated expression of a cloned
gene are called expression vectors.

Site-directed mutagenesis can be used to produce a mutant version of the protein.
 Further reading

Book: Lehninger: Principles of Biochemistry, 6th edition. ISBN: 1464109621.

Chapter 8: Nucleotides and Nucleic Acids, Page 281-312.
Chapter 9: DNA-Based Information Technologies, Page 313-355.

Next class on 04/11/2024 (Monday)
 Restriction Endonucleases
Restriction endonucleases (RE), also called restriction enzymes, recognize and cleave DNA at specific sequences
(recognition sequences or restriction sites) to generate a set of smaller fragments.

REs are found in a wide range of bacterial species. However, in its host cells, REs can’t digest its DNA because of
methylation of the DNA bases. This mechanism is known as Restriction Modification System.

Three types of REs: Type I, Type II and Type III

Type I and III are generally large, multisubunit complexes containing both the endonuclease and methylase
activities. They require ATP for energy.

Type I REs cleave DNA at random sites that can be more than 1000 bp from the recognition sequences.

Type III REs cleave the DNA about 25 bp from the recognition sequences.

Type II REs cleave the DNA within the recognition sequence itself. They don’t need ATP. The recognition
sequences are usually 4 to 6 bp long and they are palindromic.

Some of the Type II REs make staggered cuts on the two DNA strands, leaving two to four nucleotides of one strand
unpaired at each resulting end. These unpaired strands are referred to as sticky ends.
DNA can occur in different three-dimentional forms

The Watson and Crick’s structure is also referred to as the B form
and it is the most stable structure under physiological conditions.

A form is preferred in many solutions which are devoid of water.