Module 2: Genetic Engineering in Food Agriculture PDF

Summary

This document provides background information on genetic engineering in food agriculture. It discusses the historical use of selective breeding, modern techniques like genetic engineering, and key events in biotechnology. The document also covers methods for gene transfer and application of genetic engineering tools to plants.

Full Transcript

MODULE 2: GENETIC ENGINEERING IN FOOD AGRICULTURE

BACKGROUND INFORMATION
PART 1
Genetic Engineering
For most of history, farmers had to wait several plant
generations before crops had the traits they most desired.
The farmers used selective breeding, the process of choosing
parent plants with the best traits over many generations.
Selective breeding resulted in dramatic genetic changes to
the species. While earlier farmers had no concept of the
science of genetics, selective breeding based on observable
traits allowed them to use plants’ DNA to solve agricultural
challenges and to improve the food supply. This approach to
selecting specific traits is exemplified by the apple activity in
Module 1.
Although selective breeding is still widely used, there are
more modern processes available to alter the genetics
of microorganisms, plants, and animals. More modern
techniques to alter an organism’s genetics includes mutation
breeding, molecular marker-assisted breeding, genetic
engineering, and genome editing.
Genetic engineering (GE) refers to deliberately modifying
the characteristics of an organism by altering its genetic
material. GE techniques include particle bombardment,
Agrobacterium-mediated transformation, and targeted
genome editing (the most recent additions to the genetic
engineer’s toolbox). Using GE technology, scientists can
bring us improved agricultural products and practices faster
than in the past.
Why genetically engineer plants?
Plants are genetically engineered for many of the same
reasons that selective breeding is used: Better nutrition,
higher crop yield (output), greater resistance to insect
damage, and immunity to plant diseases.

Key biotechnology events related to food
agriculture
1901 Japanese biologist Shigetane Ishiwatari discovered
Bacillus thuringiensis (Bt), which makes a natural
pesticide, found in soil worldwide and used by farmers
since the 1920s.
1919 Karoly Ereky introduced the new term biotechnology
(i.e., using biological systems to create products).
1971 Paul Berg completed a landmark gene splicing
experiment.
1973 Stanley Cohen and Herbert Boyer created the first
modified organism using recombinant DNA (rDNA)
technology.
1974 Rudolf Jaenisch and Beatrice Mintz created the first
transgenic animal (a mouse).
1978 Herbert Boyer starts a new company, Genentec and
produces recombinant insulin.
1983 Mary-Dell Chilton inserted an antibiotic-resistant gene
into a tobacco plant creating the first GE plant.
1987 Calgene creates the FlavrSavr® tomato.
1989 Chymosin from GE microorganisms authorized as a
food processing aid by FDA.
1994 FDA concludes the FlavrSavr® tomato is as safe as
comparable non-GE tomatoes.
1995 EPA approves the use of a Bt toxin as a plantincorporated pesticide in a GE crop.
1998 GE virus-resistant papaya was grown commercially in
Hawaii.
2012 CRISPR-Cas9 is used as a programmable
RNA-guided DNA cutting tool.

Selective breeding techniques involve repeatedly crossbreeding plants until the breeder identifies offspring
that have inherited the genes responsible for the desired
combination of traits. However, this method may also
result in the inheritance of unwanted genes responsible for
unwanted traits (called linkage drag), and it can result in
the loss of desired traits.

2015 Genetically modified salmon is the first GE animal
approved for food use in the United States.

GE techniques can be used to isolate a gene or genes for
the desired trait, add a gene from another organism or edit
chromosomal DNA in a single plant cell, and generate a

new plant with the trait from that cell. By adding one desired
gene from the donor organism or by editing the gene in the
chromosomal DNA of the single cell, the unwanted traits

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2017 GE apples are available for sale in the United States.
2019 FDA completes consultation of high oleic soybean oil,
first food from a genome edited plant.

MODULE 2: GENETIC ENGINEERING IN FOOD AGRICULTURE

BACKGROUND INFORMATION
from the donor’s other genes can be excluded. GE is used
in conjunction with selective breeding to produce GE plant
varieties that are on the market today.

Advanced Content
GE techniques can be used to add new DNA to code for
the expression of a new protein or to suppress expression
of a native plant protein. Protein suppression can be
achieved though transcriptional or post-transcriptional
gene silencing (PTGS). RNA interference (RNAi) is a
form of PTGS that targets mRNA transcripts for cleavage,
preventing their translation into protein. The two different
ways to achieve a desired trait are important, because
both have been used to create GE plants that are used in
food today.
Development of GE Tools in Bacteria
Throughout the past 100 years, several developments have
led to current GE methods. After early geneticists were
able to identify the gene locus for specific plant traits,
various methods were used to try to transfer the specific
DNA sequence from one plant to another. One method
was injecting the DNA from the donor plant directly into
the recipient plant cell to see if it would integrate into
the recipient cell’s genome. Unfortunately, the DNA was
degraded, and the method was unsuccessful. It was like
trying to send an envelope through the mail with only a zip
code; the postal service wouldn’t know where to deliver it.
Scientists eventually used bacteria to transfer new DNA to
the recipient plant cell.
Transformation is the changing of the cell’s genetic makeup
through the addition of new DNA. The DNA can come
from the environment surrounding the cell via “horizontal
gene transfer” or be added in a laboratory through GE
methods. The laboratory method developed to combine
genetic sequences that would not otherwise be found in the
genome is called recombinant DNA (rDNA) technology.
In 1973, Herbert Boyer and Stanley Cohen produced the
first successful GE organism. Boyer had expertise using
restriction endonucleases (enzymes that cut DNA at
specific nucleotide sequences), and Cohen studied plasmids
(small rings of DNA) in bacteria. They were able to use a
restriction enzyme to cut open a plasmid loop from one
bacterial species, insert a gene from a different bacterial
species, and close the plasmid, which combined the genes
from different bacteria into one rDNA molecule. An enzyme
called ligase was used to help join the cut DNA strand. Then
they transformed this rDNA plasmid into the bacterium
Escherichia coli (E. coli) and showed that the bacteria could
utilize the rDNA. In Boyer and Cohen’s experiment, one gene
coded for tetracycline resistance and the other for kanamycin

resistance. Tetracycline and kanamycin are antibiotics that kill
bacteria that do not have resistance genes. It was possible to
see which of the E. coli in their experiment had successfully
acquired the new genes by culturing them in the presence
of the antibiotics, where only the successfully transformed
bacteria could grow. These experiments showed that
bacterial transformation could be used to deliver the desired
DNA to a useful site, just as the postal service delivers mail to
the correct address.
Restriction enzymes are like scissors that cut DNA at
specific sequences. Some restriction enzymes leave blunt
DNA ends while others leave short, single-stranded
overhangs called sticky ends.
Restriction Enzyme
DNA

G AA T T C
C T T AA G

GAA T T C
C T T A AG

Enzyme Cuts DNA

DNA Fragments
have Sticky Ends

Ligase enzymes are like the glue or tape for connecting
DNA sequences in GE, or molecular biology, procedures.
Bacterial transformation still serves as the basis for a number
of DNA technologies. Bacteria are used extensively in the
laboratory for rDNA research. There are even some species
of bacteria that go through the transformation process
naturally, but most bacteria needs manipulation to become
competent (able to take up the plasmid). Using the
techniques from bacterial transformation, scientists have
learned how to change the genome of plants, including
plants that we use for food.
Scientists worldwide continue to use the Boyer and Cohen
techniques to improve GE tools that develop, modify, and
improve consumer products, including many of the food
products we eat.

Nature’s Own Genetic Engineer
A widely used method of transferring a transgene to
a plant is to use the soil bacterium Agrobacterium
tumefaciens (A. tumefaciens). This bacterium has a
natural ability to enter a plant cell and insert its own DNA
into a plant’s genome. A plasmid is constructed to include
A. tumefaciens genes needed for transferring DNA into
the recipient plant cell, the transgene of interest, and a
selectible marker, such as a gene conferring antibioticresistance or herbicide tolerance. Scientists now use the
bacterium’s natural behavior to insert the transgene into
a plant’s genome.
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MODULE 2: GENETIC ENGINEERING IN FOOD AGRICULTURE

BACKGROUND INFORMATION
Simplified Steps of Plasmid Development
1. Plasmid Cut with a
Restriction Enzyme

Selection
Marker
Gene
Restriction
Enzyme

Sticky
End

2. Plasmid and Desired Gene
Joined Using DNA Ligase

Ligase
Enzyme

Application of GE Tools in Plants
Plants can be genetically engineered to be resistant to pests
and herbicides, to increase crop yield, or to tolerate adverse
weather conditions using a process similar to bacterial
transformation. Plants can also be engineered to produce
fruits and vegetables that have longer and more stable
shelf-lives in the grocery store. These GE uses have potential
trickle-down benefits from the farmer to consumers,
animals, and the environment. Because plants are eukaryotic
and contain a nucleus, a slightly different method than the
one used for bacterial transformation is used to insert the
gene of interest.
For example, if scientists find a gene for enhanced drought
resistance in a plant, and they want to use the gene to
make another plant more drought resistant, an advantage
of GE over selective breeding is that less time is required and
linkage drag is avoided. The desired gene to be transferred
and added to the genome of the recipient plant is often
referred to as a transgene.

3. Plasmid with Desired
Gene Inserted

Desired Gene That
was Cut with Same
Restriction Enzyme
as the Plasmid
The technologies used to clone or synthesize genes are
changing and evolving. The three major methods currently
used are:
• Traditional cloning – isolating DNA directly from the
genome of the donor organism and inserting it into a
plasmid for later use
• Subcloning the gene of interest – copying the gene from
an existing collection of DNA clones (“DNA library”)
• De novo gene synthesis – building a gene from scratch,
using single nucleotides or short oligonucleotide strands
without the need for a physical template
The techniques used by scientists to assemble and insert
DNA pieces into the plasmid are also evolving along with
the complexity of multi-gene DNA constructs. While simple
restriction enzyme protocols can be used to create a single
gene insert, multi-gene constructs such as those required
for complex plant traits require more complex assembly
strategies.

Genetic Engineering

What is a DNA Library?

• Allows the direct transfer of one or just a few genes
between either closely or distantly related organisms
• Achieves crop improvement in a shorter time compared
to conventional breeding
• Allows plants to be modified by adding, removing, or
switching off particular genes

A DNA library is a collection of cloned DNA fragments
that are stored in plasmids, which in turn are maintained
and propagated in bacterial or yeast cells. The type
of library is classified by the source of the DNA and
the plasmid – referred to as a cloning vector – used to
construct the library. Sources of DNA may be a single
cell, a tissue, an organism, or an environmental sample
containing multiple organisms. The DNA may be obtained
from genomic sequences or from isolated mRNA and
converted to complementary DNA (cDNA). Scientists use
DNA libraries to find and study DNA encoding proteins or
other functions of interest.

Adapted from: Agricultural Biotechnology (A Lot More than
Just GM Crops).
www.isaaa.org/resources/publications/agricultural_
biotechnology/download/Agricultural_Biotechnology.pdf

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MODULE 2: GENETIC ENGINEERING IN FOOD AGRICULTURE

BACKGROUND INFORMATION
General Plasmid Preparation
Bacterial plasmids are used to store a ready supply of the
gene of interest. In the case of Agrobacterium-mediated
plant transformation, the plasmids are used to transfer
the gene of interest to the genome of the recipient plant.
To receive the gene of interest, the bacterial plasmids are
treated with a restriction enzyme that is compatible with the
gene. This way, the plasmid DNA will have the same sticky
ends as the gene, so they will combine more easily. The gene
and plasmid DNA preparations are mixed with DNA ligase to
seal the sticky ends of the DNA molecules together.
Scientists may also modify the bacterial plasmid using a
similar process to insert one or more selectable marker
genes. The selectable marker genes will be important later
in the GE process when bacteria or plant cells with the gene
of interest are being isolated. There are many selectable
markers used to screen for bacterial, as well as plant
transformants.
Selectable markers include:
• Auxotrophy (selects for the ability to grow on certain
carbon sources)
• Antibiotic resistance (selects for ability to grow in the
presence of a specific antibiotic)
• Herbicide tolerance (selects for ability to grow in the
presence of a specific herbicide)
This new bacterial plasmid is called a transformation
plasmid and has the gene of interest as well as the
selectable marker gene. The transformation plasmid is
added to bacteria using a bacterial transformation method.
Finally, the bacteria are plated onto a medium containing the
selection factor that will inhibit the growth of bacteria that
did not take up the plasmid. The Petri plates are incubated to
encourage bacterial growth, and only the bacteria that have
taken up the transformation plasmid with the selectable
marker gene will grow. Bacteria without it will not grow,
resulting in millions of bacteria with the gene of interest in
their DNA.
The next step is to transfer the gene to the plant
cells. Currently, the most frequently used technique is
Agrobacterium-mediated transformation. Bombardment
with a gene gun is less common and typically used in
cases where Agrobacterium-mediated methods don’t
work. Agrobacterium is a plant pathogen that has the
natural ability to transfer DNA to plant cells. GE methods
use a version of the Agrobacterium plasmid that has been
“disarmed”: the modified plasmid still has the ability to

transfer DNA into the plant’s genome, but it’s diseasecausing genes have been removed. Agrobacterium that
have been transformed with the plasmid carrying the gene
of interest and selectable marker are mixed with the plant
cells. The Agrobacterium enters the plant cells and inserts
a segment of the plasmid DNA (containing the gene and
selectable marker gene) into the plant’s genome. Once the
Agrobacterium has had time to transform the plant cells,
the cells are placed on medium containing: (1) An antibiotic
that kills the Agrobacterium, (2) the selection factor that
will inhibit growth of plant cells that did not take up the
plasmid DNA, and (3) plant hormones that encourage the
transformed cells to grow into new plants.
After a gene has been successfully inserted into the plant’s
genome, the modified plant must be able to grow and
reproduce with its newly modified genome. First, the
genotype of the plant must be studied so that the scientists
only grow plants in which the genome has been modified
correctly. When this is done, the GE plants will be grown
under controlled conditions in a greenhouse and then in field
trials to make sure that the new plants possess the desired
new trait and show no new undesired characteristics.
Food from GE Plants
The first GE plant evaluated by the FDA for human
consumption was the FlavrSavr® tomato. FDA concluded that
the FlavrSavr® tomato was as safe as comparable non-GE
tomatoes. It was brought to market in 1994, but it was not
sufficiently profitable to continue production. Although there
are currently no GE tomatoes on the market, other GE food
crops are commercially available. Most of these GE plants
were engineered to increase resistance to disease or pests, or
tolerance to specific herbicides.
As of 2019, there were 10 GE food crops available in the
U.S. Of these, only a few GE crops in the grocery store are
available as whole produce. Whole produce could include
certain cultivars of apple, potato, papaya, sweet corn, and
squash. Ingredients derived from GE corn, soybeans, sugar
beets, and canola (such as flour, oil, starch, and sugar) are
used in a wide variety of foods including cereal, corn chips,
veggie burgers, and more.
The 10 GE crops today are: Alfalfa, apples, canola, corn
(field and sweet), cotton, papaya, potatoes, soybeans,
squash, and sugar beets.
Animal food: In the United States, more than 95 percent
of food-producing animals consume food containing
ingredients from GE crops. GE plants can also be found in
food for non-food producing animals, such as cats and dogs.

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