Presentation is loading. Please wait.

Presentation is loading. Please wait.

Synthetic Biology, ‘New Breeding Techniques’ GM & Genome Editing Ricarda A. Steinbrecher, PhD Econexus Oxford, 6 January 2016.

Published byIrma Parsons Modified over 8 years ago

Similar presentations

Presentation on theme: "Synthetic Biology, ‘New Breeding Techniques’ GM & Genome Editing Ricarda A. Steinbrecher, PhD Econexus Oxford, 6 January 2016."— Presentation transcript:

1 r.steinbrecher@econexus.info Synthetic Biology, ‘New Breeding Techniques’ GM & Genome Editing Ricarda A. Steinbrecher, PhD Econexus Oxford, 6 January 2016

2 –BioCAD software, –Robotic cloning, –Metabolic modelling, –Protein engineering, –DNA databases and registries, –Part and device libraries, –Regulatory circuits, –DNA synthesis, –Gene and genome assembly, –Genome editing: MAGE, CRISPR, TALENs, zinc fingers ** –Epigenetic engineering ** Microscopy, Molecular profiling Tools & technologies of Synthetic Biology

3 Predictability Microorganisms Plants Animals Human Precision Approach - designing and controlling biological processes - making organisms perform according to design of the outcome of our doing & intervention on all levels the dream of the realisation of precision ? invites a mechanistic approach and mindset (as we have insufficient knowledge)

4 Princeton School of Engineering and Applied Science www.princeton.edu/cbe/people/data/j/javalos/profile/

5 New Breeding Techniques under scrutiny by EC (are they GMOs??): 1) * Zinc Finger Nuclease Technology (ZFN-1/2/3) 2) * Oligonucleotide Directed Mutagenesis (ODM) 3) * Cisgenesis/Intragenesis 4) RNA-dependent DNA methylation (RdDM); 5) Grafting (onto a GMO rootstock); 6) Reverse Breeding (RB); 7) Agro-infiltration (both Agro-infiltration ‘sensu stricto’ & Agro-inoculation) (8 Synthetic genomics ) plus other NBTs mentioned by industry and interest groups: eg: MAS (marker assisted selection) - not GM !

6 distributed by EuropaBio

7 Metabolic pathways Metabolism is the set of chemical reactions that occur in a cell, which enable it to keep living, growing and dividing. Metabolic processes are usually classified as: catabolism - obtaining energy and reducing power from nutrients. anabolism - production of new cell components, usually through processes that require energy and reducing power obtained from nutrient catabolism.

8 ct: glycolysis - glucose oxidation in order to obtain ATP cb: citiric acid cycle (Kreb’s cycle): acetyl-CoA oxidation in order to obtain GTP and valuable intermediates. bl: AA degradation

9 metabolic map Organism = chemical factory  making different compounds according to design  utilise “precursors”  Change plumbing (genes)  “Petrol” in …. product out

10 cells nucleus chromosome DNA gene T A AA C C C G GG T TT A Basepairs: A-T & C-G (nucleotides)

11 Genes and Genetics: The Fundamentals “The New Genetics” 3. In many cases, more than one RNA/protein is produced from a given gene. DNA transcription RNA processing (alterations, splicing) mRNA translation protein 3D Protein

12 Gene & gene construct promoter Gene for trait (Bt toxin) end Regulatory sequence: on/off switch - often CaMV (virus) Coding sequence of a gene - e.g. pat or bar gene for herbicide resistance from soil bacteria Regulatory sequence: Termination signal - e.g. from pea Plasmid backbone DNA, superfluous genetic material

13 Transformation No control of where the gene will insert itself: Random integration Imprecision (incl. superfluous DNA) 100 -1000s of Mutations (Sala et al. 2000, Wang et al. 1996, Labra et al 2001) ? Agrobacterium used as “shuttle” Particle bombardment

14 Targeted ‘break’ of both strands of DNA in a chromsome Special enzyme

15 The special enzymes are called: 1.CRISPR/Cas 2.ZFN (zinc finger nucleases) 3.Tales/Talens (transcription activator–like effector nucleases) 4.Meganucleases 9/35

16 Synthesis “Computer, give me 1000 variants” – put into 1000 organisms A A T T C C G G ACGTTTTAACGTTTACGGGT … … A A A A A A A A C C C C C C G G G G G G G G T T G G T T T T T T T T T T T T A A C C

17 Two separate breaks result in large deletion of material Material ‘deleted’ 6/35

18 the double-stranded break results in degradation of both strands by endogenous enzymes, enlarging the area of damage the damage can be repaired by rejoining (leaving a deletion or other change), by a template-directed repair (that may change function) or a template-directed insertion

19 Unpredictabilities and risks - Off-target effects (due to non-specific binding to non- target DNA): off-target mutations in the genome. These mutations can a) if in the coding sequence, result in changes of function of proteins, or b) if in regulatory sequences, result in changes in the expression of genes, such as increased presence of plant toxins, or absence of proteins important for nutrition, plant defence or disease resistance, increased presence of allergens. - Integration of added DNA or oligonucelotides into the genome - Impacts of the genetic engineering processes (mutations) Steinbrecher, R (2015). Genetic Engineering in Plants and the “New Breeding Techniques” (NBTs) - Inherent risks and the need to regulate.

20 The idea of precision is based on that one knows what one is doing – here this is not the case. Knowledge & precision at the level of nucleotides is only the bottom layer. What is missing is the contextualisation into the genome the epigenetic landscape the organism the ecosystems the socio-economic conditions that differ around the world Precision around nucleotides gives a false sense of predictability and safety – there is no data to support such extrapolations. The idea of Precision

21 thank you

22 Push Pull Technology – East Africa Problem for maize yield: Stem borer (eg chilo partellus moth) effect a third of the region’s maize crop. Scientists of the Mbita Point Research Station, Lake Victoria, Kenya came up with a simple solution: Pull: Napier grass (up to 70% yield increase). Push: Desmodium, a common legume “weed” species, repels the stem borer Secondary benefits: Desmodium enriches soil with nitrates, prevents soil erosion during rains and suppresses the growth of Striga weed, a parasitic plant causing US$ 10 billion yield loss/year (effecting 100 million Africans). Napier grass can be used and sold as fodder.

23 GE vs. Alternatives in Developing Countries

24 Locally researched Solutions already Exist

25 GE vs. Alternatives in Developing Countries

26 “Biomass doesn’t cut it.. Carbohydrates are not a substitute for oil. I was wrong in that and I admit it. That will never replace oil because the economics don’t work. You can’t take carbohydrates and convert them into hydrocarbons economically” Alan Shaw (formerly Codexis)

27

Download ppt "Synthetic Biology, ‘New Breeding Techniques’ GM & Genome Editing Ricarda A. Steinbrecher, PhD Econexus Oxford, 6 January 2016."

Similar presentations

Frontiers of Genetics Chapter 13.

Frontiers of Genetics Chapter 13.
Recombinant DNA technology

Recombinant DNA technology
Medical Genetics & Genomics

Medical Genetics & Genomics
Key Area : Genetic Control of Metabolism in Micro-organisms Unit 2: Metabolism and Survival.

Key Area : Genetic Control of Metabolism in Micro-organisms Unit 2: Metabolism and Survival.
Central Dogma of Molecular Biology. Gene Expression How does a cell control the timing and choice of synthesizing a particular protein? A gene is expressed.

Central Dogma of Molecular Biology. Gene Expression How does a cell control the timing and choice of synthesizing a particular protein? A gene is expressed.
CHAPTER 31 Genetic Engineering and Biotechnology.

CHAPTER 31 Genetic Engineering and Biotechnology.
Biotechnology and Recombinant DNA

Biotechnology and Recombinant DNA
Chapter 9: Biotechnology

Chapter 9: Biotechnology
Genetic Change DOT Point Distinguish between mutations of chromosomes distinguisg.

Genetic Change DOT Point Distinguish between mutations of chromosomes distinguisg.
Biotechnology Review.

Biotechnology Review.
Synthetic biology Genome engineering Chris Yellman, U. Texas CSSB.

Synthetic biology Genome engineering Chris Yellman, U. Texas CSSB.
Genetic Engineering: Transcription, Translation, and Genetically Modified Organisms.

Genetic Engineering: Transcription, Translation, and Genetically Modified Organisms.
+ Bacterial Genetics March 2015. + Terminology Genetics: The study of what genes are, how they carry information, how information is expressed, and how.

+ Bacterial Genetics March Terminology Genetics: The study of what genes are, how they carry information, how information is expressed, and how.
Molecular Biology DNA Fingerprint – a sequence of bands that shows a persons DNA sequence How to make a DNA Fingerprint 1.DNA Extraction Cell is opened.

Molecular Biology DNA Fingerprint – a sequence of bands that shows a persons DNA sequence How to make a DNA Fingerprint 1.DNA Extraction Cell is opened.
Genetically Modified Organisms (GMOs)

Genetically Modified Organisms (GMOs)
Control & Manipulation of Genes  Before Transcription  Access Acetylation loosens grip of histone, allowing access of polymerase to DNA Methylation.

Control & Manipulation of Genes  Before Transcription  Access Acetylation loosens grip of histone, allowing access of polymerase to DNA Methylation.
AP Biology: Chapter 14 DNA Technologies

AP Biology: Chapter 14 DNA Technologies
AP Biology 2007-2008 Control of Eukaryotic Genes.

AP Biology Control of Eukaryotic Genes.
Cellular Metabolism Chapter 4. Introduction Metabolism is many chemical reactionss Metabolism breaks down nutrients and releases energy= catabolism Metabolism.

Cellular Metabolism Chapter 4. Introduction Metabolism is many chemical reactionss Metabolism breaks down nutrients and releases energy= catabolism Metabolism.
Biotechnology pp. 258-264. WHAT IS IT?  Biotechnology : the application of technology to better use DNA and biology.

Biotechnology pp WHAT IS IT?  Biotechnology : the application of technology to better use DNA and biology.

Similar presentations

Ads by Google