CG920 Genomics
Lesson 11
Genomics – practical applications
Markéta Pernisová
Functional Genomics and Proteomics of Plants,
Mendel Centre for Plant Genomics and Proteomics,
CEITEC - Central European Institute of Technology, Masaryk Univerzity, Brno
marketa.pernisova@ceitec.muni.cz, www.ceitec.muni.cz
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Outline
1. Genomics in medicine
2. Biotechnology
3. Genetically modified organisms
4. GMO – pros and cons
5. Discussion
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GENOMICS IN MEDICINE
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GENOMICS IN MEDICINE
• Biotechnology and gene technology are crucial
technologies in medicine
• Improvement in practice:
• faster identification and analysis of new pathogens
• faster development and production of vaccines and reliable
diagnostic tools
• genetic tests for screening of heritable diseases or severe
genetic defects in the embryo or foetus
• many drugs produced in laboratories:
• bacteria, yeast and mammalian cell cultures produce human
proteins available as drugs
• developing of e.g. edible vaccines produced by transgenic plants
• 1st biotech drug: insulin, 1982
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GENOMICS IN MEDICINE
• Influence of genomics on medicine:
• knowledge of the genome can lead to understanding the origin of
disease - mutant gene – misfunction of the protein
• knowledge of the gene will allow screening for the disease
• understanding gene influence on drug effects and origin of side
effects
• assessing individual genetic predisposition becomes possible
• improving the effectiveness of new approaches to cure diseases
• knowledge of bacterial and viral genomes helps easier
identification of the mechanism of infection and improve
prevention, treatment, as well as accelerate vaccine development
• genome research is helping us better understand the aging
process and improving the quality of life for older people
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GENOMICS IN MEDICINE
• The use of genomics in medicine:
• genetic diagnosis
• individualized medicine
• gene therapy
• regenerative medicine
• xenotransplantation
• molecular in vitro systems to study human diseases
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GENETIC DIAGNOSIS
• test performed to identify specific genetic traits of an
individual
• do not need to know the sequence of the entire genome
• used for:
• clarifying whether a disease appeared as a result of changes in
specific genetic traits
• confirming and refining standard medical diagnosis of an already
apparent disease
• identification of hereditary diseases before they become evident
• pre-implantation screens of embryos fertilized in vitro
• assessment of individual predispositions of a person for
developing certain diseases later in life
• DNA fingerprinting in criminal investigations and paternity
disputes
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PERSONALIZED MEDICINE
The medical approach that emphasizes the systematic use
of information specific to an individual patient to set up an
optimized preventive and therapeutic plan for each patient.
• Presumptions:
• detailed knowledge of the genome of the patient, ideally the
entire genome sequence
• knowledge of the function of individual genes, including
functional differences of individual alleles represented in the
population
• correlation of sequences with the prognosis of the disease, and
with the success rate of therapeutic procedures ...
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PERSONALIZED MEDICINE
• uses knowledge of the genome for:
• prediction of health risks
• diagnosis
• selection of the most appropriate type of treatment
• minimizing the side effects of treatment
• prevention
http://www.personalizedmedicinecoalition.org/ 9
PERSONALIZED MEDICINE
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PERSONALIZED MEDICINE
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PERSONALIZED MEDICINE
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PERSONALIZED MEDICINE
• Problem:
• multigene conditionality of most human diseases
Goh et al., 2007
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PERSONALIZED MEDICINE
• Problem-solving:
• systems biology - uses e.g. gene clustering to identify genes
involved in the observed phenomenon
Topotecan-
resistant
Topotecansensitive
Dietel and Sers, 2006
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PERSONALIZED MEDICINE
• Problem-solving :
• biomarkers
• tests
The Case for Personalized Medicine, 3rd edition 15
PERSONALIZED MEDICINE
• Other problems
• Ethical issues:
• the condition is genetic testing or knowledge of the
genome - easily abused
• risk: insufficient data security
• in some countries, employers or insurance companies do
not have access to such data
• High costs - risks:
• medicine could be divided into first-class and low-class
services
• globalization gap could grow even larger - poor countries
would not be able to afford this
• Privacy:
• crucial and complex issue
• what information about oneself can/should be considered
private? 16
GENE THERAPY
Procedure in which the DNA sequence is inserted into the
patient genome to replace or supplement an original gene
• Options:
• replace the mutated gene
• repair the mutation
• deliver DNA encoding a therapeutic protein
• antisense therapy
• In the future useful for treating e.g. hereditary diseases
• Types:
• somatic gene therapy
• gene therapy of germ cells
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GENE THERAPY
• Methods:
• viral vectors
• retroviruses
• adenoviruses
• herpes simplex virus
• vectors capable of replication
• non-viral methods
• injection of plasmid DNA into muscle
• increased efficiency of DNA delivery:
• electroporation
• sonoporation
• „gene gun"
• magnetofection
• hybrid methods
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The aim is to recover diseased or injured organs or
tissues.
• to overcome the problems of transplantation:
• shortage of donors
• risk of rejection
• severe immunosuppresive course
• therapeutic cloning - cell therapy that uses stem cells to
produce healthy copies of cells/tissues of the patient
• potential medical applications: treatment of degenerative
diseases such as Parkinson's disease, apoplexy, organ
damage, diabetes, burns ...
REGENERATIVE MEDICINE
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REGENERATIVE MEDICINE
• embryonic stem cells from animals have been
successfully programmed to develop into neural, muscle
and other cells - promising results
Ethical issues: egg cell is used to form an embryo that does
not develop into an organism. Instead, after 5-6 days of
development, embryonic stem cells are extracted, which
destroys the embryo. Depending on the definition of the
point from which you must protect human life, it can be
regarded as creating human life to destroy it, and is
therefore prohibited.
• consequence of ethical debate: increased support for
research on adult stem cells
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GENOMICS IN MEDICINE
• The use of genomics in medicine:
• genetic diagnosis
• individualized medicine
• gene therapy
• regenerative medicine
• xenotransplantation
• molecular in vitro systems to study human diseases
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BIOTECHNOLOGY
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BIOTECHNOLOGY
• It uses living organisms, cells or parts of cells
(enzymes) for research, leading to new products and
applications in medicine, agriculture, food,
environmental protection
• Also used in developing better/sustainable production
methods for the chemical industry and other industrial
processes.
• An interdisciplinary approach requiring knowledge of
chemistry, biology, physics, material sciences,
engineering and informatics.
• The origin of biotechnology can be traced back 4,000
years, when the Sumerians (although not knowingly)
used microbes for the production of alcoholic
beverages.
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BIOTECHNOLOGY
• modern biotechnology often changes the genetic
status of cells and organisms to optimize processes,
e.g. by chemical or physical treatment, cell fusion or
genetic engineering.
• genetic engineering modifies isolated nucleic acids
• concepts of modern biotechnology and genetic
engineering are often used as synonyms
• genetic engineering is actually only one branch of the
biotechnology industry
• genetic engineering - GMO
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BIOTECHNOLOGY
• Examples:
• effective utilization of plant biomass for fuel production
• acquisition of starting material (monomers) for the production
of polymers from living organisms instead of from fossil
sources
• phytopharmaceutics – using plants to produce new vaccination
methods such as expression of antibodies, or antigens
suitable for immunization
• European Federation of Biotechnology
http://www.efb-central.org25
PLANT BIOTECHNOLOGY
Agriculture
Fibres
Organic Acids
Polyols
Polyurethanes Polyester Nylon
Polymers
Monomers
Biorefining
Feed
Additives
BioFuels
Green Solvents
(ethyl lactate)
Specialty
Chemicals
High
Performance
Materials
Pharmaceutical
Precursors
Amino
Acids
Lignin
Ethanol
The Biorefinery platform using Agricultural Feed Stocks
Marc Van Montagu, ACPD, Praha 2009 26
PLANT BIOTECHNOLOGY
• Examples:
• production of spider filaments
• production of degradable biopolymers
• production of elastin-like polypeptides (component of animal
tissues)
• production of vaccines and antibodies:
• human (HIV TNF)
• animal (veterinary)
• immunomodulation of plant hormones
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FACTS TO THINK
ABOUT
• Our civilization is built on farming, the surface area needed for
feeding people has decreased by 90% over 10,000 years
• To prevent collapse, it is necessary to reduce this area from
the current 0.45 ha/person to 0.2 ha/person by the year 2050
• Return to original methods of agriculture would be a return to
the original demands on area and therefore would be
unsustainable
• Intensive farming = conversion of water and oil into food
• The goal of plant biotechnology is to use all the available
scientific knowledge to breed varieties with higher yield
with lower inputs (of land, water, fertilizers, sprays ...)
0
0.05
0.1
0.15
0.2
0.25
0.3
0.35
0.4
0.45
1961 1997 2050
hectarespercapita
Source: UN Millennium Ecosystem Assessment
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GENETICALLY MODIFIED ORGANISMS
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BREEDING
• genetic basis of organisms
naturally varies due to mutations
• before the era of genetic
engineering - question of chance
• breeding tools:
• selection and crossing
• selection:
• positive or negative
• results were incidental
• modern breeder learned to
change hereditary information
• chemicals, radiation ...
Success
is not always visible at a glance
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GENETIC ENGINEERING
• Discovery of:
• DNA structure (1953)
• restriction enzymes
• plasmids
• targeted change ("targeted breeding")
• 1973 - bacteria produce frog protein
• recombinant DNA technology = "gene
cut" = genetic engineering
• ability to transfer genes = transgenosis
• according to the law: genetic
modification
• result: GMO
• the first practical application: production
of human insulin in bacteria - 1978 31
BREEDING vs. GENETIC ENGINEERING
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GENETICALLY MODIFIED ORGANISMS
(GMOs)
• Organisms carrying modified genetic
information – either own or foreign (from
another organism), enabling targeted changes
in the organism and its use for specific
purposes
• GMO:
• plants
• bacteria
• animals http://www.gmo-compass.org/
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GMO PLANTS
• Use:
• resistance to pests
• herbicide resistance
• resistance to drought
• resistance to cold
• resistance to salinity
• more efficient nitrogen utilization
• increasing nutritional quality
http://ipbo.vib-ugent.be/
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Bt PLANTS
• resistance to insect pests
• corn, cotton, rice
• genes from Bacillus thuringiensis
(Bt)
• express delta-endotoxins (Cry
proteins)
• increasing yields, reducing the
amount of chemical sprays
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Ht PLANTS
• resistance to systemic herbicides
• glyphosate
• interferes in the synthesis of aromatic amino acids; animals
without the appropriate enzymatic apparatus = harmless
• blocks the enzyme 5-enolpyrovylshikimate-3-phosphate synthase
(EPSPS) in chloroplasts – affects green plants
• ineffective for bacterial EPSPS - evolutionarily divergent
• soya, maize, sugar beet, canola, cotton, alfalfa - added enzyme
for tolerance
• company Monsanto: Roundup
• glufosinate (phosphinothricin)
• prevents processing of ammonium - toxic
• Streptomyces hygroscopicus synthesizes and transforms it:
acetylation by the enzyme phosphinothricin acetyltransferase –
coding gene isolated in 1987 - named bar
• trade names: Basta, Liberty, Finale, Radical ... 36
MULTIRESISTENT PLANTS
• Bt resistance + herbicide
• multiresistant corn - the majority of total production in the
USA
• example of multiresistant corn:
• three Bt genes for resistance to air pests
• three Bt genes for resistance against soil pests
• two genes for herbicide resistance
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DISEASES TOLERANT PLANTS
• viruses - no chemical agents available
• gene encoding non-infectious viral envelope protein increases
resistance to viral infection
• banana; papaya - Hawaii, Southeast Asia
• cassava - a basic food ingredient for more than 500
million people + animal feed
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DROUGHT TOLERANT PLANTS
• chickpeas - more resistant to
drought, but toxic
• corn resistant to drought:
commercially utilizable in 2016
Lathyrus sativus
Chickpea
Cereals
Drought in Ethiopia
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NITROGEN USAGE INCREASE
• use of nitrogen from fertilizers
• gene from barley - 3x higher nitrogen utilization under
oxygen deficiency
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INCREASING NUTRITIONAL QUALITY
• golden rice
• several genes from maize encoding
enzymes for the biosynthesis of βcarotene
(precursor of vitamin A)
• avoid problems with your eyes in a large
part of the population in India and China
• canola and soybean
• improved oil properties: stable, resistant
to high temperatures, long storage
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GMO ANIMALS
• Transgenic cats
• lentiviruses are sensitive to restriction factors
• specific restriction factor: rhesus macaque TRIMCyp + eGFP
• uniform expression, no mosaicity and no silencing in F1
generation
• lymphocytes of transgenic animals resistant to replication of
FIV
Wongsrikeao et al., 2011, Nature Methods
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GMO – PROS AND CONS
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GMO – PROS AND CONS
• GMO plants
• increased yields without insecticides, pesticides, fungicides
• 24% yield gain per acre
• 50% yield improvement for small farmers
Ohio State University, December 2011 44
GMO – PROS AND CONS
• GMO plants
• reduce pesticide use - the negative impact of strong chemicals
currently used in agriculture
• increase nitrogen utilization from mineral fertilizers - the negative
impact of excessive fertilizer use on water quality
• increase the nutritional quality of crops
• reduce cultivation area (increased yield per unit area)
• pollen transfer to other species (hybridization) was detected in
frequencies between 0.05 to 0.53%
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GMO – PROS AND CONS
• GMO plants
• Bt crops: negative impact on other than pest insects ???
• affect some butterflies and beetles
• more insects on Bt cotton
Lu et al., 2012, Nature
berušky
pavouci
zlatoočka
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GMO – PROS AND CONS
• GMO plants
• risk of allergies
• GMO plants always contain only one or
a few transgenes and are very
thoroughly tested
• on the other hand, new varieties created
using strong mutagens, e.g. X-rays are
far less tested. With these methods tens
or hundreds of new mutations occur at
once
• ban on GMO cultivation in Switzerland was
decided by referendum
• 30% of the EU population believes that the
only transgenic plants have genes and
refuse to eat them ...
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GMO – PROS AND CONS
Our task:
• tirelessly to explain the rational use of scientific
knowledge, including genomics, it is necessary both
for advances in medicine and for the preservation of
our civilization
• discussions with the general public about the
importance and benefits of GMOs for human society
• need to defend GMO plants – crops for 21st century
• no technology is without risk, including GMOs, but
there is not cause to demonize GMOs and target them
- financial benefit of some companies ...
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LITERATURE
• see lecture
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GMO – PROS AND CONS
Discussion
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