ABT11 Lecture 2 - Principles of Modern Biotechnology PDF

Summary

This document is a lecture on the principles of modern biotechnology with a focus on genetic engineering. It explains the basis of genetic engineering, including the structure of DNA, gene function and the flow of genetic information. It discusses recombinant DNA technology and its applications.

Full Transcript

Copyright EM Tecson-Mendoza 2010-2018

Principles of
Modern Biotechnology

Carlo Miguel C. Sandoval, PhD Roberta N. Garcia, PhD
Eureka Teresa M. Ocampo, PhD Evelyn Mae Tecson-Mendoza, PhD
Learning objectives

To discuss the basis and principles of genetic engineering

To understand the steps involved in genetic engineering

To learn about current and future products of modern biotechnology
 Genetic engineering of animals Genetic engineering of plants
Modern
Recombinant medicines
“DNA simple2” by Forluvoft.
Creative Commons CC0 license

Recombinant microorganisms
Recombinant vaccines
Recombinant diagnostics,
DNA markers GMO(2) by Prince TC. Creative Commmons
Protein markers Attribution-Share Alike 4.0 International License

Cell culture
Immunodiagnostics Plant tissue culture
Classical

“Plant tissue cultures, National Center for Genetic Resources
Preservation, USDA” by Lance Cheung. Creative Commons CC0 License

Vaccines
Antibiotics
Biofertilizers, biological
nitrogen fixation,
fermentation
“Wine and Cheese 6995 (2008)” by Narek75. Creative
Commmons Attribution-Share Alike 4.0 International License

©EMTMendoza 2019
Ancient Classical Modern
I. Basis of Genetic Engineering

What is a gene?

What are the information encoded in genes converted into traits?

What is recombinant DNA technology or genetic engineering genome editing?
In 1866, Gregor Mendel discovered important
concepts of genetics

Traits are inherited from one generation to another

Elementen (genes) control the traits of an organism
“Gregor Mendel” by Wilfredor. Creative Commons CC0 License

There is recombination of
parental traits in the offspring

Some genes are dominant,
some are recessive

“Mendel seven characters” by Mariana Ruiz. Creative Commons CC0 License
Structure of DNA

Important information that contributed to the discovery of the DNA structure:

1. X-ray diffraction patterns of Rosalind Franklin and Maurice Wilkins

2. Chargaff’s ratio

3. Physical and chemical of constituents: bases, sugar, phosphate

Used by James Watson and Francis Crick
1. X-ray diffraction patterns indicated helical structure of the DNA

The distinctive “X” tells this is a helix

X-ray pattern is regular, so
diameter of helix stays the same

Vertical distance between bars
gives height of one turn

Sugar-phosphate backbone
deduced to be outside
“Experimental setup of Photo 51” by MagentaGreen CC BY-SA 2.0
2. Chargaff’s ratio

Chargaff observed that the: number of guanine (G) equals cytosine (C)
number of adenine (A) equals thymine (T)

DNA base ratio is 1:1 (purines to pyrimidines)

Universal (observed in all life forms)

Ratio will differ in different species
3. Physico-chemical properties of DNA constituents

Molecular structure of the bases, sugar, phosphate

Physical (size, shape charge) and chemical properties

“GC DNA base pair” and “AT DNA base pair” by Isilanes. Creative Commons CC0 license
DNA Double Helix

Major Groove
Minor Groove

“229 Nucleotides-01” by OpenStax College. Creative Commons Attribution 3.0 Unported License
A will always pair with T; and G with C; they are complementary to each other.
 “0321 DNA Macrostructure” by OpenStax. Creative Commons Attribution 4.0 International License

What is a gene? DNA?
Gene
a DNA
codes for a trait
 Gene 1

Gene 2

“DNA simple2” by Forluvoft,
“Simple chromosome illustration” Creative Commons CC0 license
by Prateek Pattanaik. Creative
Commons Attribution-Share Alike
4.0 International License

"NHGRI human male karyotype" by National Human Genome Research Institute. Creative Commons CC0 License

genome
TOTALITY of our traits
Why was the discovery of Watson and
Crick very important?
Based on the physical and chemical properties of
DNA, Crick and Watson hypothesized a double-
helix structure for DNA, much like a twisted ladder.

This structure explains:
ü How the DNA molecule could replicate or produce
identical copies of itself (replication)
ü How the information in the gene is expressed
(transcription and translation) Copyright CMCSandoval, 2018

Original model of the DNA double helix proposed by Watson and Crick
Cavendish Laboratory, University of Cambridge
You might ask, why was Rosalind Franklin not
included as co-winner of the Nobel prize? This was
primarily because Nobel org does not give post-
humous awards (Dr. Franklin died before 1962).
There are many articles written on this. You can
also read the original articles of Dr. Franklin to see
for yourself if she should be a co-winner of the
Nobel prize. Nonetheless, her contributions to
science have been recognized by many.

http://www.nobelprize.org/nobel_prizes/medicine/laureates/1962/
Flow of genetic information
The information in the gene is transcribed
to a complementary single strand called
messenger or mRNA; for mRNA, U
(uracil) used instead of T (thymine)

The mRNA travels from nucleus to
cytoplasm and is translated to protein

“0328 Transcription-translation Summary” by OpenStax College. Creative Commons Attribution 4.0 International License
The information for traits is encoded in the genes

Some traits are simple; one gene for one trait
◦ color, selected pest resistance traits

Some traits are complex; many genes contribute to the
formation of the trait
◦ yield, intelligence
 DNA
Since the nucleotide sequence of a strand is
Parent Strand
complementary to that of its partner strand,
both strands will bear the same genetic DNA
information.

This process of DNA replication ensures
that the resulting daughter DNA molecules Complementary
Complementary Strand Forming
are identical to the parental DNA helix. Strand Forming
SEMI-CONSERVATIVE

“DNA replication split” by Madprime. Creative Commons CC0 1.0 Universal Public Domain Dedication
Flow of genetic information

“Genetic code” by Madprime. Creative Commons CC0 1.0 Universal Public Domain Dedication “The genetic code wheel” by Genomics Education Programme. Creative
Commons Attribution 2.0 Generic License
In summary

Modified "Central Dogma of Molecular Biochemistry with Enzymes" by Daniel Horspool. Creative Commons Attribution-Share Alike 3.0 Unported License
 Part II.
Principles of Modern Biotechnology
“Modern biotechnology means the application of
(a) in vitro nucleic acid techniques, including recombinant
DNA technology or direct injection of nucleic acid into cells or
organelles
(b) Fusion of cells beyond the taxonomic family, that
overcome natural physiological reproductive or recombination
barriers and that are not techniques used in traditional
breeding and selection.”
Cartagena Protocol on Biosafety 2000
Conventional breeding
A B (elite line)
In conventional breeding,
genes of parents are x
mixed; desired gene
comes with many others
which may not have
useful or desired traits
 Gene of interest
(1 page)

Genetic
engineering
Conventional
breeding Genome editing-
(CRISPR-Cas)

Represents
one book The genome is like
containing a library of books
1000 pages
Recombinant DNA technology
is a method that allows the combination of genes in a test tube
to form a hybrid DNA.

Design gene for specific trait

Genetic engineering, a type of modern biotechnology, allows
the transfer of a specific gene for a desirable trait
Basis of Genetic Engineering or
Recombinant DNA Technology
Why is it possible for a gene from an organism to be introduced
and integrated in the genetic material of another organism, and
also be expressed?
For example, the genes for synthesizing beta-carotene from
microorganism and flower can be introduced into the rice plant
and be expressed in the rice grain!
What is the basis for Genetic Engineering?
Cells of different organisms are similar. Thus, a gene transferred to
Their cellular constituents are also similar. a new host organism can
work and be expressed!
They contain the same large and small molecules.
They follow the same chemical, physical, and genetic laws.

"Simple diagram of plant cell" by domdomegg. Creative "Average prokaryote cell" by Mariana Ruiz Villareal. "Simple diagram of animal cell" by domdomegg. Creative
Commons Attribution 4.0 International License Creative Commons Attribution-ShareAlike License Commons Attribution 4.0 International License
Tools are available
Cutting (splicing) genes at specific sites by using restriction enzymes

Ligating DNA fragments using DNA ligase

Synthesizing DNA or RNA using DNA or RNA polymerase
Multiplying copies of DNA using polymerase chain reaction
Cohen (plasmids) of Stanford University and Boyer (restriction
enzyme) of UCSF invented recombinant DNA technology, 1972
Let us define some terms...
Restriction enzyme – bacterial enzymes that cut DNA at specific sites

DNA ligase – enzymes that can form a phosphodiester bond at a single-strand
break in DNA

Plasmid – double-stranded, circular, autonomously replicating, extra-chromosomal
DNA molecules of bacteria

Vector – autonomously replicating DNA molecules used to transfer foreign DNA
segments between host cells
Steps in recombinant DNA technology or genetic
engineering
1.) Isolation of gene from source
2.) Modification of gene (if necessary) and prepare gene
construct for delivery into target organism
2. Modification of gene and preparation gene construct

The gene and its parts
promoter structural gene terminator Insert modified gene in
appropriate plasmid or
vector

Bt gene (cry1Ac)
Steps in recombinant DNA technology or
genetic engineering
1.) Isolation of gene from source
2.) Modification of gene (if necessary) and prepare gene
construct for delivery into target organism
3.) Introduce construct to organism (transformation)
4.) Selection of transformants
When do we use genetic engineering?
the trait to be introduced is not present in the germplasm of
the crop
the trait is very difficult to improve by conventional breeding
methods
it will take a very long time to introduce and/or improve such
trait in the crop by conventional methods
Genetic Engineering of
Microorganisms
Genetic Engineering of Plants
Engineering
cinnamon-
flavored a b c d e
apple

f g h i j
Genetic Engineering of Animals
Current and future applications
of modern biotechnology
Generations or waves of biotech processes or products
Modern Biotechnology Generations

Fourth wave
Biofuels from
Renewable cellulosic
resources materials
Third wave
Factories
Industrials,
pharmaceuticals
Second wave
Quality traits
Improved nutrition,
First wave quality traits
Production of health
Agronomic traits products in
Biotic or abiotic stresses microorganisms and
mammalian cells

Most of the current products belong to the first wave.
"Golden Rice" by International Rice Research Institute (IRRI). Creative Commons CC0 License

"Holstein dairy cows" by Scott Bauer. Creative Commons CC0 License
The Global Biotechnology Market
Global biotech market valued at USD 270.50
billion in 2013;

Expected to grow at 12.3% growth rate from
2014 to 2020

Non-food fermentation products

} USD 4.9 Billion in 2004
} USD 71.8 Billion in 2021
Adoption of GM Crops
2.5 billion hectares are planted with biotech crops globally

A total of 72 countries have adopted biotech crops

29 countries (24 developing countries and 5 industrial countries)
planted biotech crops

43 additional countries imported

Based on ISAAA report, 2019
GM crop events approved in the Philippines
Crop No. of events For propagation
Alfalfa 4 Single transformation events
Canola 6 Corn MON810 Corn Bt11
Corn TC1507 Corn NK603
Cotton 16
Corn MIR162 Corn MON89034
Eggplant 1 Corn GA21 GR2E Rice
Corn 64 Stacked traits/events
Potato 11 Corn MON89034 x Corn NK603
Corn TC1507 x Corn MON810 x Corn NK603 and all its intermediates
Rice 2
Corn Bt11 x MIR162 x MON89034 x GA21 and all its intermediates
Soybean 24 Corn MON89034 x TC1507 x NK603 and all its intermediates
Sugarbeet 1 Corn Bt11 x TC1507 x GA21 and all its intermediates
Source: ISAAA, 2022 Corn MON810 x NK603
Source: DA-BPI, 2022
GM crop events approved in the Philippines

For direct use as food, feed and processing

Single transformation events Stacked events
Corn (20) Rice (1) Corn (21)
Cotton (11) Alfalfa (3) Cotton (4)
Canola (2) Potato (3) Soybean (8)
Soybean (14) Eggplant (1) Alfalfa (3)
Rapeseed (3) Sugarbeet (1)

Source: DA-BPI, 2022
Biotech corn — the ffiirst biotech crop
in the Philippines
By Zabrina J. Bugnosen

isaaa photo

A filipino farmer tends to drying harvested corn in general Santos city. Biotech corn has been grown in the country since 2003.

In December 2002, the Philippines planting season. MON810 changed insect pests like MON810, while
was the first country in Asia to all that. After planting MON810, others are tolerant to herbicides
approve the commercial planting of farmers realized the benefits of Bt to help farmers manage weeds
genetically modified (GM) corn. In corn. They harvested more corn in their farms better. Some
its first year of planting, Bt corn was and did not have to buy chemical have additional traits known as
Bt corn is first GM crop commercialized in the Philippines

The Philippines is the first Asian country to commercialize a genetically modified
food crop.

In 2002, Bt corn was planted to 10,000 ha.

In 2003-2004 to 2007-2008, Bt corn showed consistently higher %ROI, inspite of
higher cost of seed.

As of 2019, approximately 800,000 ha planted to Bt corn (single trait Bt (insect
protected) and HT, (herbicide tolerant) and stacked Bt and HT)
The Bt technology
Bt used as microbial pesticide for the past 40 years with a history of safe use
Bt gene transferred to plant genome; plant produces toxic protein which is pesticidal

In the gut of larvae
specific toxic protein binds with receptors on gut
of target larvae
death
"Corn borer" by Keith Weller. Creative Commons CC0 License

alkaline pH receptor
Toxin-
Bt protoxin toxin “ulcer-like”
receptor
The Bt protein in Bt corn is toxic specifically to Lepidoptera

dead larva live larva on
on Bt corn sweet corn

spider lady bug
Bt eggplant July 23, 2021 - The Philippine government has approved
Bt eggplant for direct use as food, feed or for processing
(FFP) [Biosafety Permit No. 21-078FFP]
Bt eggplant project led by Dr. Hautea
Crossed Bt eggplant developed by
Mahyco with Philippine elite lines
Field test completed

Bt protein affects EFSB worm ONLY
Safe for human, farm animals and non-target insects
with ABSPII, USAID,
UPLB, DA Biotech funds
Photos from Dr. DM Hautea,
Photos from Dr. DM Hautea and SEARCA BIC
SEARCA BIC
[email protected]
September 2022
https://www.pna.gov.ph/articles/1148086

[email protected]
September 2022
Golden Rice
produces high levels of beta-carotene in the endosperm
phytoene synthase from E. uredovora and phytoene desaturase from
daffodil (GR1) and corn (GR2)
initiated by Dr. Ingo Potrykus and Dr. Peter Beyer

http://www.goldenrice.org/Content2-How/how1_sci.html
Golden Rice
July 21, 2021 - The Philippine government has approved the
COMMERCIAL PROPAGATION of “Golden Rice”.
Permit issued by the DA-Bureau of Plant Industry (BPI) based on the rigorous biosafety
assessments and recommendation by the Joint Departments – DOST, DA, DENR, DOH
and DILG
(Joint Department Circular No.1, Series of 2016)

https://www.pna.gov.ph/articles/1148037

Courtesy of Dr. Antonio Alfonso, PhilRice

[email protected]
September 2022
Ringspot virus-resistant papaya
Introduction of viral coat protein gene results in overproduction of coat protein RNA
and suppression of its synthesis

Hawaii
Photo courtesy of
Dr. Dennis Gonsalves
Long shelf-life papaya with PRSV
resistance

developed at the Institute of Plant
Breeding, CAFS, UPLB

expression of ACC synthase gene was
silence using anti-sense technology

Future biotech product
Carnation
Moondust Carnation (1996) by Florigene
delphinidin genes from petunia
Available in Au, Canada, USA, UK, Japan, Germany,
Holland, Puerto Rico

Blue Rose
Developed by Suntory & Florigene
Used technology for blue carnation-transferred
delphinidin genes from pansies

https://www.suntory.com/sic/research/s_bluerose/story/ http://www.florigene.com
https://www.suntory.com/sic/research/s_bluerose/story/
Transgenic Glofish®
gene from jellyfish and anemone
injected to eggs of zebra fish

developed by Zhiyun Gong of
National University of Singapore

www.glofish.com
AquAdvantage® Salmon

developed by Aqua Bounty Farms

capability of growing from egg to market size in half
the time compared with non-transgenic

approved for commercial release in November 2015
http://www.aquabounty.com/

Dr. Arnold Sutterlin with
transgenic trout
AquAdvantage® Salmon

gene construct:
growth hormone gene from Chinook
salmon under the control of a promoter
from another type of fish called an
ocean pout.

(AP photo/Aqua Bounty)
First biopharm drug approved
Atryn, an anticlotting drug from
GTC Biotherapeutics was
approved for release by the
European Medicines Agency
(June 2006) and US FDA 2009

First biotech product produced in
milk of goats
(c) GTC Biotherapeutics, now rEVO Biologics
Second biopharm drug approved
In December 2015, Kanuma was approved by the US
FDA; also approved in Europe and Japan
Treatment for a rare disease, lysosomal acid lipase (LAL)
deficiency, which causes build-up of lipids in cells of
various tissues which can lead to liver and cardiovascular
diseases.
Recombinant lysosomal acid lipase is produced in the egg
whites of transgenic chickens.
Biopharming: Future products

production of pharmaceuticals in crops
antibodies, antigens, growth factors, hormones, enzymes, blood
proteins and collagen
treatment of cancer, HIV, heart disease, diabetes, Alzheimer's disease,
kidney disease, Crohn's disease, cystic fibrosis, multiple sclerosis,
spinal cord injuries, hepatitis C, chronic obstructive pulmonary disease,
obesity and arthritis.
List of selected GM products and technologies which are potentially beneficial to the Philippines.

Agriculture/Crops Status
Other Bt Corn events such as those with resistance to lower ground and upper
1
ground insect pests
2 Rainbow papaya (PRSV-resistant) Available since the 1990s in Hawaii
3 Corn with abiotic stress (drought) tolerance
4 Sugarcane with 30% higher sugar content Indonesia 2020
5 Sugarcane with drought resistance Indonesia 2013
6 Sugarcane with insect protection Brazil (June 2017)
Agriculture/Animals
7 AquAdvantage Salmon Approved since 2018; available as food
Health
8 Vaccine (traditional and modern) development and production
9 Control of dengue using GM mosquito technology Available since 2002
Industry
10 Cellulosic ethanol Available since mid 2000s
11 Bioethanol Using recombinant yeast
Ordonio RL (2022). More modern biotechnologies for applciation in the Philippines and their potential challenges. In: DOST-NCBP. The National Committee on
Biosafety of the Philippines (NCBP): Thirty Years of Biosafety Regulations in the Philippines. Department of Science and Technology. National Committee on
Biosafety of the Philippines. Manila, Philippines, pp 291-299.
Watch the following videos

Biotech for Every Juan and Baby Biotech Trip

https://www.youtube.com/watch?v=Eoaf1ia2ySU https://www.youtube.com/watch?v=JIj9WbYDNWs
Assignment No. 2

Identify two (2) genetically modified organisms in agriculture.
1.) What trait was modified (or traits, if there are multiple)?

2.) Who developed the GMO?

3.) What gene was inserted, deleted or modified (or genes, if there are multiple)?

4.) Is it currently available in the market? If not, at what stage of development or
biosafety approval is it currently in?