Genetic Engineering Lecture Notes 2024-2025 PDF

Summary

These lecture notes cover genetic engineering, focusing on RNA isolation techniques. They discuss various methods for extracting and purifying RNA, along with factors affecting RNA isolation. The notes also include information about blotting techniques, and their applications in various fields like cancer diagnosis and genetic diseases.

Full Transcript

College of Applied Science
Department of Biotechnology
Genetic Engineering
4th stage
Dr. Noor Thaer Adnan
Lecture -3
2024-2025

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Isolation of RNA
Isolation of RNA molecules is crucial to many molecular biology applications, such as
cloning, reverse transcription for complementary DNA (cDNA ). Synthesis
There are various approaches to RNA extraction and purification including:
o phenol-chloroform extraction
o spin column purification
o magnetic bead-based methods
Methods are selected based on:
o sample characteristics
o contaminants types
o target RNA length
o abundance
o scale of sample processing
o downstream analysis.

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Isolation of RNA
Requires STRICT precautions to avoid sample degradation.
RNA especially labile.
RNases are naturally occurring enzymes that degrade RNA
Common Laboratory Contaminant (From Bacterial And Human Sources)
Also released from cellular compartments during isolation of RNA from biological
samples and can be difficult to inactivate
RNases are ubiquitous, highly stable, and active in virtually any aqueous environment,
and they can regain their activity after denaturation. RNAis therefore subject to rapid
degradation by RNases, and scrupulous care must be taken in the laboratory setting to
overcome the lability of RNA. RNA isolationrequires steps to inhibit or degrade
cellular RNases and prevents their reintroduction into the isolated RNA

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 RNases act without cofactors and are stable enzymes.. Small amounts of RNase
are sufficient to destroy RNA
If RNA isolation is delayed, samples should be stored at −86° C or less
temporarily in buffer with RNase inhibitors. Addition of Guanidinium thiocyanate
or β-mercaptoethanol to the RNA isolation reagents inhibits or denatures RNase.
Purified RNA is rehydrated in nuclease-free water and stored at −86° C to further
inhibit any remaining RNase activity.
Total RNA : are all types of RNA extracted from a cell which is composed of:
rRNA 80% recognizing and binding to the mRNA molecule
to help translate the information in (mRNA) into
protein
mRNA 1-5% messenger RNA functions as a means to
transfer genetic information encoded by the
DNA in a cell's nucleus to protein-building
machinery
tRNA The remaining mediating the Transfer of the appropriate amino
acid to the ribosome during protein synthesis via
the anticodon 4
Genetic Engineering - Dr.Noor Thaer
RNA Isolation

Unlike genomic DNA, which can be isolated from both active and inactive cells in a
sample, the isolation of RNA allows one to view the genes that are being actively
transcribed. The isolation of RNA is necessary for a variety of experiments such as reverse
transcription complementary DNA (cDNA) synthesis, cloning, RNA sequencing (RNA-
seq), and gene expression analysis. Where DNA analyses identify the presence of a gene,
RNA analysis measure gene expression and can be used to indicate the function or role of a
gene or taxon. The transcriptome of an individual cell is (the full repertoire of RNA
transcripts at a given point in time)
The isolation of RNA, a process that refers to the extraction of RNA molecules from
biological material, is an integral aspect of molecular biology and genetics.
RNA purification, also called RNA cleanup, involves the removal of salts, excess
reagents, enzymes, or other impurities from the isolated RNA samples

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 Mechanical homogenization: The mechanical homogenization step in many of isolation protocols can be
further substituted by tissue disassociating enzymes for increased yield and purity. To obtain sufficient yield
and quality RNA, mechanical homogenization is considered necessary in industrial, medical, and agricultural
applications.

Chemical cell lysis: Many of these methods are designed for high-throughput phenol-free extraction of total
RNA from tissue, cells,

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Trizol -Chloroform Extraction Method

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 Trizol works
by maintaining RNA
integrity during tissue
homogenization, while at
the same time disrupting
and breaking down cells
and cell components

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 Silica Membrane-Based RNA Isolation
The principle of using RNA silica-membrane technology to achieve RNA
separation and purification is mainly to utilize the binding of nucleic acid to silica
matrix material under high salt conditions and detachment under low salt
conditions.

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Isolation of mRNA from total RNA

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Eukaryotic mRNA

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mRNA purification using mRNA purification using oligodT matrix
magnetic oligodT beads

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Gel Electrophoresis
electrophoresis is a basic biotechnology technique that separates macromolecules
according to their charge and size. It is frequently used to analyze and manipulate
samples of DNA, RNA, or proteins. Gel electrophoresis has a rich history, dating
back to the early 20th century. Initially, in the 1930s, scientists like Lothar Cremer
and Alois H. H. F. K. G. Platt began experimenting with electrophoresis to separate
proteins in solution.

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In gel electrophoresis, samples to be separated are applied to a porous gel medium made
of a material such as agarose. Agarose gels are made by pouring a molten solution of
agarose and buffer into a gel mold called a casting tray. Before the agarose solidifies, a
comb is placed in the casting tray to create a row of wells into which samples are loaded
once the comb is removed from the solidified gel. The casting tray and solidified gel are
then placed in an electrophoresis chamber that has wire electrodes at each end. The gel
is covered with a buffer that controls the pH of the system and conducts electricity. The
comb is then carefully removed from the gel and samples are loaded into the resulting
wells using a pipet. Once all the samples have been loaded into the wells, the chamber is
connected to a power supply and an electrical current is applied to the gel. The chamber
is designed with a positive electrode (anode) at one end and a negative electrode
(cathode) at the other end. Molecules with a net negative charge migrate toward the
positive electrode and molecules with a net positive charge migrate toward the negative
electrode because opposite charges attract.

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loading dyes are an important component in gel electrophoresis and are mixed with
samples for use. Loading dyes have three important functions for gel electrophoresis.
First, the main function is that the dye visualizes the sample, thus simplifying the loading
process. Second, loading dyes are used as color indicators of nucleic acid migration in gel
electrophoresis, allowing for the estimation of the distance that nucleic acid fragments
have migrated. Finally, loading dyes containing Ficoll or glycerol add density to the
sample so that it sinks into the gel and does not diffuse into the buffer

Factors Affecting Speed of
Molecules Migration

❑ Net Charge
❑ Size
❑ Shape

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 Genetic Screening
the process of testing a population for a genetic disease in order to identify a subgroup
of people that either have the disease or the potential to pass it on to their offspring

Genetic Screening Methods

Cytogenetic (to examine whole chromosomes)
Biochemical (to measure protein produced by genes)
Molecular (to look for DNA mutations)

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Types of genetic screening
1. Forward genetics (or a forward genetic screen) is an approach used to identify
genes (or set of genes) responsible for a particular phenotype of an organism.
2. Reverse genetics (or a reverse genetic screen), on the other hand, analyzes the
phenotype of an organism following the disruption of a known gene.

forward genetics starts with a phenotype and moves towards identifying the gene(s)
responsible, whereas reverse genetics starts with a known gene and assays the effect of
its disruption by analyzing the resultant phenotypes. Both forward and reverse genetic
screens aims to determine gene function
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 Genetic tests look for :
a) changes in a individual's genes
b) changes in the amount, function,structure of key proteins coded by specific
genes.
Blotting Techniques
Blotting :is a technique by which a macromolecule such as DNA, RNA, or protein is

resolved in a gel matrix, transferred to a solid support, and detected using specific
probe

These powerful techniques allow us to identify and characterize specific molecules
in a complex mixture of related molecules

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Southern blot
is a method used in molecular biology for detection of a specific DNA sequence in DNA
samples.
Southern blotting combines transfer of electrophoresis-separated DNA fragments to a filter
membrane and subsequent fragment detection by probe hybridization.
Southern Blotting could be used to locate a particular gene within an entire genome.
The amount of DNA needed for this technique is dependent on the size and specific activity
of the probe. Short probes tend to be more specific. Under optimal conditions, you can
expect to detect 0.1 pg of the DNA for which you are probing.
One picogram is 10 -12 grams

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Steps involved in southern blotting
1) Extract DNA
2) Digest the DNA with an appropriate restriction enzyme.
3) Run the digest on an agarose gel.
4) Denature the DNA (usually while it is still on the gel).
5) Transfer the denatured DNA to the membrane. Traditionally, a nitrocellulose
membrane is used.
6) Addition labelled prop. This is also known as hybridization. P 32 labelled probe is
used
7) Visualize your radioactively labelled target sequence

Radioactive probes are DNA or RNA sequences that are labelled with radioactive
isotopes.
Hybridization is the process in which two complementary single-stranded DNA and/or
RNA molecules bond together to form a double-stranded molecule.

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Applications

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