Слайд 2Plant Tissue Culture
Plant cells differ from animals cells in that
they are totipotent
A totipotent cell is one that can develop
into specialized cell types & regenerate an entire organism
Tissue culture of plants and the regeneration of complete plants from cells has been done since 1930s
This allows large-scale clonal propagation of plants
Слайд 3http://www.webschoolsolutions.com/biotech/transgen.htm
Plant Cloning
Слайд 4http://catf.bcresearch.com/biotechnology/tissueculture_research.htm
Micropropagation
Callus, undifferentiated mass of plant cells
Seedlings, each from an individual
cell
Слайд 5How Do They Engineer Plants?
Слайд 6Methods of producing transgenic plants
Слайд 7http://www.colostate.edu/programs/lifesciences/TransgenicCrops/how.html
Plant Genetic Engineering
Ti plasmid of Agrobacterium tumefaciens
A. tumefaciens is a
soil microbe that induces crown gall
Crown gall is a ‘cancerous’
mass which forms at the site of infection in plants
Слайд 8T-DNA portion of the Ti plasmid contains genes responsible for
the disease
T-DNA becomes incorporated into the genome of the plant
Part
of the T-DNA may be replaced with a foreign gene and used to incorporate this gene into the plant’s genome
A marker is also added to determine which cells have the recombinant gene
TIBS 1998, 19:500-506.
Слайд 9http://www.webschoolsolutions.com/biotech/transgen.htm
Слайд 10http://faculty.abe.ufl.edu/~chyn/age2062/lect/lect_09/10_19A.GIF
Biolistics (Biological Ballistics)
Useful for engineering corn, rice, wheat, barley, &
other crops
Слайд 11Helios Gene Gun
http://www.bio-rad.com
Uses an adjustable burst low-pressure helium to sweep
DNA- or RNA-coated gold pellets from the inner wall of
a small plastic cartridge directly onto a target
Слайд 12Genetically Engineered Plants
Herbicide tolerance
Insect resistance
Crop improvements
Functional foods
Plants as bioreactors
Biofuels
Timber improvements
Bioremediation
Слайд 13Currently 215 million acres of GM crops grown worldwide
Genetically Modified
(GM) Crops
Слайд 14>60% of the foods we purchase have GM ingredients
95%
of canola is biotech herbicide-tolerant
50% of corn is biotech herbicide-tolerant
35%
of corn is biotech insect-resistant
61% of cotton is biotech herbicide-tolerant
52% of cotton is biotech insect-resistant
93% of soybean is biotech herbicide-tolerant
(2005 Data, Source :GM Crops: The First 10 Years -- Global Socio-economic and Environmental Impacts; PG Economics Limited )
How Much of What We Eat Is GM?
Слайд 15Who Produces GM Food?
BASF Inc.
Aventis Cropscience
Bayer Cropscience
Syngenta Seed Inc.
Pioneer Hi-Breed
International Inc.
Dow Agroscience LLC
Monsanto Company
Слайд 17http://resources.emb.gov.hk/envir-ed/globalissue/images/ModifiedTomato.jpg
The first GM food was the FLAVR SAVR tomato
Introduced in
1994 it had delayed ripening characteristics
Слайд 18Fruit softens because polygalacturonase degrades pectin
Antisense technology was used to
turn off (silence) the polygalacturonase (PG) gene
Gene encoding antisense RNA
was inserted into tomato cells
The antisense RNA finds the normal RNA and hybridizes
The cell then degrades this complex, preventing the normal RNA from being translated
Слайд 19PG gene
transcription
mRNA
translation
PG gene
transcription
mRNA
Antisense mRNA
translation
Antisense Technology
Слайд 20 Polygalacturonase (PG) is an enzyme that breaks down pectin
in ripening fruit walls
Plants with an antisense PG
transgene
produce less PG.
Walls soften more slowly
Many genes manipulated in the
same way to answer basic
questions:
- what is the role of hormones
in ripening?
- what do particular enzymes do in
fruit walls?
Wild-type
fruit
Antisense PG
fruit
PG activity
Days from 1st colour change
0
10
2
4
6
8
Altering Fruit Ripening with Antisense RNA
Слайд 21http://www.wachstumshormon.info/kontrovers/gentechnik/flavrsavr.html?gfx=2
Most GM tomatoes were used only in canned puree
By 1997
FlavrSavr was no longer marketed
Слайд 22Current technologies aid the farmer not the consumer
Herbicide Resistance
Virus Resistance
Insect
Resistance
Слайд 23Herbicide Tolerance
Methods used to promote crop growth also promote weeds
Weeds
often outgrow crops and reduce farm output
Even though there are
about 100 chemical herbicides, weeds still reduce crop productivity by ~12%
Problem is that many herbicides kill both crops & weeds
This has led to the creation of herbicide tolerant crops
Слайд 24Soybean with no herbicides
Soybean after herbicides
Herbicides are used for weed
control
Herbicide Tolerance
Weeds
drastically
reduce
crop
yield
and quality
Слайд 26Non-selective herbicides
(Roundup Ultra and)
Roundup® (chemical name: glyphosate)
Breaks
down quickly in the soil,
eliminating
residual carry-over problems
and
reducing environmental impact.
Roundup Ready®
transgenic varieties
of common crops
completely resistant
to those herbicides
Слайд 28EPSPS Transgene Introduced into Plants
Codon usage modified
for efficient expression
in
plants
promoter
Regulatory sequences recognised by plant (either from plant gene or
plant virus gene). In this case 35S CaMV promoter
Agro. EPSPS
Transit peptide from plant gene added to allow chloroplast import
Слайд 30 Move to greener herbicide
Benefits of Glyphosate Tolerance in
Crops
Can use at any time
- can
wait until there is a problem
Reduced herbicide use
Very effective
- Weeds very sensitive
- GM crop very resistant
GM canola surrounded by weeds
- glyphosate
+ glyphosate
Слайд 31Roundup® Ready Crops
Corn
Alfalfa
Soybeans
Canola
Sorghum
Cotton
Tomato
Potato
Wheat
Слайд 321996 Roundup® Ready Gene Agreement
Terms:
The farmer must pay
a $5 per bag "technology fee“
The farmer must give
Monsanto the right to inspect, monitor and test his/her fields for up to 3 years
The farmer must use only Monsanto's brand of the glyphosate herbicide it calls Roundup®
Слайд 33 The farmer must give up his/her right to save
and replant the patented seed (replanting seed is a practice
as old as agriculture)
The farmer must agree not to sell or otherwise supply the seed to "any other person or entity."
The farmer must also agree, in writing, to pay Monsanto "...100 times the then applicable fee for the Roundup® Ready gene, times the number of units of transferred seed, plus reasonable attorney's fees and expenses..." should he violate any portion of the agreement.
Слайд 34Concerns of Roundup® Ready Crops
Spread of resistance genes to weeds
Problems
with quality of crops
e.g.. Cotton bolls falling off prior to
harvest
Farmers required to purchase seed annually
The herbicide is still toxic at high doses
Слайд 35Benefits of Roundup® Ready Crops
Fields no longer need tilling
Reduction in
weed management costs of up to 37%
Decrease in herbicide use
by >1lb/acre
Overall 74% increase in farmer profits1
1U.S. Corn Crop 2003
Слайд 36Roundup® patent recently expired
Researchers have designed new method of resistance
Sorted
thru 100s of microbes to find a detoxifying enzyme
Found 3
genes in Bacillus licheniformis which encode glyphosate N-acetyltransferase (GAT)
Using directed evolution generated an enzyme 10000x more efficient
~5yrs to market
Слайд 37There are also varieties of various crops resistant to:
Glufosinate
Bromoxyil
Sulfonylurea
Слайд 38Virus Resistance
Yellow Squash resistant to three different viruses were developed
by Asgrow Seed
Resistance was then transferred to zucchini
Virus resistant papaya
were developed in the mid ’90s
This was after a outbreak of papaya ring spot virus destroyed 40% of the Hawaiian crop
The varieties called Rainbow® & SunUp® are provided free to farmers
Слайд 39Transgenic PRV-resistant papaya has been grown commercially in Hawaii since
1996
Increased virus resistance: Papaya ringspot virus (PRV)
Virus has had huge
impact on papaya industry in Hawaii - reduction of fresh fruit production directly related to spread of PRV
No naturally occurring resistance genes - without GM, papaya industry in Hawaii would be destroyed
Слайд 40promoter
Regulatory sequences recognised by plant
(either from plant gene or plant
virus gene).
In this case 35S CaMV promoter and terminator
polyA+
PRV coat
protein gene expressed from 35S CaMV promoter.
Papaya transformed by particle bombardment
PRV coat protein gene
Confers partial resistance to PRV in one variety (‘Rainbow’) and complete resistance in another (‘SunUp’)
Growers have to sign up to careful crop management - minimize virus pressure on transgenics to maintain resistance
Papaya Resistant to PRV
Слайд 41Various Cry genes (CryIA(b), CryIA(c), & Cry9C) have been inserted
crops such as corn, cotton, potatoes, & rice
Pest must ingest
a portion of the plant for the toxin to be effective
Within hours the gut breaks down and the pest dies
Insect Resistance
http://www.agbios.com/docroot/articles/03-314-001.pdf
Wt Corn
Bt Corn
Слайд 42What is BT
doplnit z prednasky roslinna biotechnologie
Слайд 43Molecular basis of the Bt action
Слайд 44Bt Corn & Monarch Butterflies
Cry toxin is expressed in all
of the plant as well as pollen
Corn pollen can blow
onto milkweed growing near corn fields
Monarch caterpillars feed exclusively on milkweed
An early study showed a possible toxic effect of Bt pollen on monarch caterpillars
http://homepages.ihug.co.nz/~mostert/land%20photography/Insects/insects/monarch%20butterfly.jpg
Слайд 45Biodiversity / NTO Studies
Monarch Butterfly, symbol of nature and “wildness”
in North America.
The reports of Bt effects on Monarch butterflies
have fueled much emotional debate on the use of biotech crops.
Слайд 51Bt Corn & Allergies
Bt corn is approved for human consumption
However
Starlink® brand corn is approved only for animal feed
Contains Cry9C
which may be a potential allergen
In 2000 Starlink® was found in Taco Bell-brand taco shells
EPA determined that no one who ate the food was allergic, but they found that it had a moderate potential allergenicity
All the products were recalled and Starlink® corn is not approved for human consumption
Starlink® trademark of Aventis Corp.
Слайд 52Benefits of Bt Corn
Crop yield increases by up to 33%
39%
less insecticide used
Increase in monetary gains by 18%1
1U.S. Corn
Crop 2003
Слайд 53Concerns associated with GM crops
Possible production of allergenic or toxic
proteins
not native to the crop
2. Adverse effects on
non-target organisms,
especially pollinators and biological control organisms
3. Loss of biodiversity
4. Genetic pollution (unwanted transfer of genes to other species)
5. Development of pest resistance
6. Global concentration of economic power and food production
7. Lack of "right-to-know"
(i.e., a desire for labeling transgenic foods)
Слайд 54How to prevent development of Bt resistance in insects?
at
least 20%
of a farm's corn acreage
must be planted
to non-BT corn.
R = resistant European borer;
S = susceptible borer.
few Bt-resistant insects
surviving in the Bt field
would likely mate
with susceptible individuals
that have matured
in the non-Bt refuge.
Thus, the resistance alleles
would be swamped
by the susceptible alleles.
< 80%
> 20%
Strategy will not work if resistance is dominant !!!
Слайд 56Crop Improvements
Current research into crop improvements include:
Increased growth rate
Increased salt tolerance
Increased drought resistance
Modification of seed oil
content
Слайд 57Drought / Salinity Resistance
Trehalose is a protectant against many environmental
stresses; freezing, osmotic pressure (salinity), heat and dessication.
Trehalose (1--D-glucopyranosyl-glucopyranoside)
is synthesised
in a two-step process in yeast.
Zygosaccharomyces rouxii is one of the most highly
osmo-tolerant yeasts – especially to salt
Kwon, S.J., Hwang, E.W. & Kwon, H.B. (2004). Genetic
engineering of drought resistant potato plants by
co-introduction of genes encoding trehalose-6-phosphate
synthase and trehalose-6-phosphate phosphatase of
Zygosaccharomyces rouxii. Korean J. Genet. 26, 199-206.
Transgenic potatoes morphologically identical to parents.
trehalose-6-P synthase
trehalose-6-P phosphotase
2A
RB
LB
CaMV
35S
nptII
NS ter
NS prom
Слайд 58Modification of Seed Oil Content
Слайд 59Plant Seed Oils
Oils either for cooking or industrial uses are
usually extracted from seeds such as,
Corn, safflower, sunflower, canola, coconut,
flax
Seed rely on their stored oil as an energy & carbon sources for germination
Most seed oils are made up of unsaturated fatty acids
Some tropical oils such as palm & coconut have significant levels of saturated fatty acids
Слайд 60http://biology.clc.uc.edu/courses/bio104/lipids.htm
Fatty Acids
Triglyceride
Слайд 61http://food.oregonstate.edu/images/fat/lard1.jpg
http://www.plattsalat.de/Gawang.html
http://www.aces.edu/dept/extcomm/newspaper/feb23b01.html
Canola Oil -10°C Coconut Oil 20-25°C Lard 40.5°C
5% Saturated
85% Saturated 100% Saturated
Слайд 62http://biology.clc.uc.edu/courses/bio104/lipids.htm
Cis-fatty acids, naturally occuring unsaturated acids
Trans-fatty acids, artifically generated to
keep unsaturated fatty acids from going rancid
Trans-fatty acids increase LDL
(bad cholesterol) increasing the risk of heart disease
Слайд 63Soybeans with Modified Oil Content
Soybeans normally have high amounts of
the unsaturated fatty acid linolenic acid
Vistive by Monsanto is Roundup
Ready soybeans bred to have low amounts of linolenic acid
This eliminates the need to hydrogenate the oil
http://www.siberiantigernaturals.com/omega3.htm
Слайд 66Over 60 million tons of seed oil are used for
edible purposes
About 15 million tons is employed in industrial usage
One
of the first plants modified was Rape (Brassica napus oleifera)
A member of the mustard family, Rape has been grown for centuries as animal feed and natural lubricant
In the 1970s selective breeding led to strains of Rape lacking erucic acid
The removal of erucic acid made the oil fit for human consumption, LEAR (low-erucic acid rapeseed)
Слайд 67Rape field full of brillantly yellow flowers
http://www.tiscali.co.uk/reference/encyclopaedia/hutchinson/m0011652.html
Слайд 68The first transgenic crop with modified oil content was a
high lauric oil rapeseed.
Rapeseed oil normally contains about 0.1% lauric
acid
Modified rapeseed contains ~40% lauric acid
Lauric acid from GM rapeseed would be used in place of oils from palm or coconut
The primary use of lauric acid is in detergents
CH2-CH2-CH2-CH2-CH2-CH2-CH2-CH2-CH2-CH2-CH2-CH2-SO4- Na+
Sodium Lauryl Sulfate a.k.a SDS
Слайд 69Other varieties of GM rapeseed could provide:
Steric acid as a
substitute for hydrogenated oils
Jojoba waxes for use in cosmetics and
lubricants
Various acids for use in biodiesel
Phytases for animal feed
Novel peptides for pharmaceuticals
Why is rapeseed so versatile?
One reason is because it is related to…
Слайд 70http://www.teedrogen.info/systematik/7_bilder/ara-th-1.jpg
Arabidopsis thaliana (Cress)
Arabidopsis is a model organism used by scientists
to investigate plant development and genomics
The Arabidopsis genome was recently
completed
Слайд 71http://www.thegutsygourmet.net/post-brassica.jpg
Brassica (Mustard) Family
Слайд 73 Improving Protein Quality
Nutritional value of seed storage
proteins is often limited
- may lack one or more amino
acid essential to human health
e.g. legume seeds lack cysteine and methionine; other seeds can lack lysine
Animals and humans are incapable of making 10 ‘essential’ amino acids
- must obtain in diet
Amino acid balance in seeds has been manipulated in laboratory experiments using a number of strategies:
- introduce seed storage protein from another species
- alter sequence of seed storage protein gene in vitro
- manipulate amino acid biosynthetic pathway to increase abundance of particular amino acids
Similar strategies have been used to improve protein content and composition in non-seed food crops...
Слайд 74‘Increased nutritive value of transgenic potato by expressing a nonallergenic
seed albumin gene from Amaranthus hypochondriacus’
Chakraborty et al., PNAS 97,
3724-3729 (2000)
Potato is the fourth most abundant global crop and used for food, animal feed and production of starch and alcohol
Limited in lysine, tyrosine, methionine and cysteine
Transformed potato with seed albumin from Amaranthus hypochondriacus which has good amino acid balance
p35S CaMV
Nos 3’
AmA1
pGBSS
Nos 3’
AmA1
2 alternative constructs. Promoters constitutive or tuber-specific
Expression in tuber 5-10 fold higher with GBSS promoter than with 35S promoter
pSB8
pSB8G
Слайд 75Changes in protein quality in Amaranthus albumin potatoes
5-8
fold higher essential amino acids in pSB8G transgenics
Total
protein content also increased (35-45%)
Fold
increase
1-
8-
4-
D E S G H R T A P Y V M C I L F K
Amino acid
Слайд 76http://www.princeton.edu/~fecelik/GMFoods/impactshumanconsumptionpros.html
Golden Rice
Inserted genes from other plants & bacteria to produce
–carotene
Vitamin A deficiencies affect >124 million children worldwide
Слайд 77Vitamin A
Vitamin A (retinol) is essential to human growth
Our
bodies cannot make vitamin A,
All carotenoids that contain a
-ring can be converted into retinol, and one of the most important carotenoid pro-vitamins is -carotene
-carotene is a pigment required for photosynthesis
- produced in all plant green tissues
Слайд 78400 million people are at risk of vitamin A deficiency
(VAD), particularly in Asia and Africa
implicated in up to 2.5
million deaths annually in children under 5
0.5 million children go blind each year
because of VAD
Supplementation programmes have reduced child mortality by up to 50% in target areas
supplementation not universal; expensive; misses remote areas
VAD makes children especially vulnerable to infections
Vitamin A deficiency
VAD is most serious in regions where rice is the staple food ; up to 70% children under 5 affected
Слайд 80Vaccine Foods
In the early 1990’s tomatoes, bananas, & potatoes were
proposed as delivery vehicles for vaccines
Touted as a simple method
of delivering vaccines especially to developing countries
Studies have shown plant-produced oral vaccines to increase immunity in mice
Potatoes containing Hepatitis B vaccine have been shown to boost immunity in humans
Слайд 81There are concerns about dosing when these crops are directly
consumed.
Would a dose be? 2 bananas and a tomato
What
if a person eats too many vaccine potatoes?
Also there is concern if the vaccine foods enter the food supply of people who are vaccinated the traditional way
Слайд 82Plants as Bioreactors
Plants (crops or cell culture) can be used
to produce proteins currently produced by microbes or animal cells
The
advantage over microbes:
The proteins are more like human proteins
The advantage over animal cells:
Plants cannot become contaminated with mammalian pathogens
Слайд 83Large Scale Biology Corp. (LSBC) uses tobacco plants for drug
manufacturing
LSBC uses an engineered tobacco mosaic virus (TMV)
Recombinant gene is
inserted into TMV which infects & replicates in the plants
During replication large amounts of the drug are generated
The drug accumulates in the leaves which are harvested
-galactosidase A purified from tobacco is as effective in treating Fabry’s disease as the animal cell derived drug
Слайд 84USDA just approved the use of rice to produce lactoferrin
and lysozyme
Sigma-Aldrich now sells aprotinin and typsin made in tobacco
Duckweed
is being used to produce interferon-
More and More Plants Are Being Used to Produce Proteins
Слайд 86Cellulosic Ethanol
Has higher yield due to the fermentation of sugar
released from cellulose
Requires the addition of cellulase or acid
Agricultural plant
wastes (corn stover, cereal straws)
Plant wastes from industrial processes (sawdust, paper pulp)
Crops grown specifically for fuel production (switchgrass)
Слайд 87BioDiesel
1900 Rudolph Diesel runs his engine on peanut oil
Biodiesel is
defined as “a fuel comprised of mono-alkyl esters of long
chain fatty acids derived from vegetable oils or animal fats”
Transesterification converts triglycerides into methyl esters of fatty acids
http://www.campa-biodiesel.de/caengnof/caenkra2.htm
Слайд 88http://www.biodiesel.org/pdf_files/fuelfactsheets/Production_Graph_Slide.pdf
U.S. consumes 40 billion gallons of diesel/yr
Слайд 89http://www.wired.com/wired/archive/11.04/genetics.html?pg=1&topic=&topic_set=
Timber Biotechnology
Слайд 90Reduction in generation time
Trees can take years to flower
Those overexpressing
the LEAFY (LFY) gene can flower in as little as
7 months.
This is of particular value in fruit bearing trees
Also allows for rapid analysis mature traits
Слайд 91Alteration in tree size or form
Altered expression of a gene
involved in hormone synthesis can give wildly differing results
Overexpression of
GA 20-oxidase gives faster growing trees both in height and diameter and longer wood fibers
Inhibition of GA 20-oxidase gives dwarf trees
Слайд 92From left to right:
antisense-GA 20-oxidase, wild type, & GA 20-oxidase
overexpressing
www.upsc.se/tmoritz.htm
Six Weeks Old Hybrid Aspen
Слайд 93Leaves from GM poplar
http://stacks.msnbc.com/news/947076.asp?0cl=cr&cp1=1
Слайд 94http://www.enn.com/news/enn-stories/1999/08/080999/trees_4724.asp
Trees engineered to produce lower amounts of lignin
These trees grow
faster and have greater cellulose content
Lignin is a glue-like compound
that must be chemically removed from pulp prior to papermaking
Слайд 96Bioremediation using bacteria has limitations
The engineered or specialized bacteria used
are often unable to compete with indigenous soil bacteria
An alternative
is phytoremediation, the use of plants to mop up toxic waste
A standard technique for treating soils contaminated with heavy metals (lead or cadmium), or organic pollutants (pesticides) in a cost-effective way
