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WELCOME
Ph. D. CREDIT SEMINAR2016-17
ON
Department of Plant Breeding and Genetics
JNKVV, JABALPURM.P -482004
Presented by :Kanak SaxenaRoll No.-234
Guided by:Dr (smt.) Rajani
Bisen
Advances in Cereal Genomics and its application in crop improvement
CONTENTS
Introduction
Genomics
Need of Genomic research in cereal crops
Laboratories for Cereal Genomic Research in India
Genomics based approaches and techniques
Role of genomics in crop improvement
Achievements in Cereal Genomics
Case Study
Challenges in using genomics for breedingConclusion
References
(Genomics word was coined by Thomas Roderick in 1986.)(Study of structure & function of entire genome of a living organism)
(Study of the structure of entire genome of an organism)
(Study of the function of entire genome of an organism)
GENOMICS
Structural Genomics Functional Genomics
Comparative Genomics
(Study of the relationship of genome structure and function across different biological species or strains)
1980 – DNA markers (RFLP) 1983 – Karry Mullis invented the PCR technique, and Several
PCR based markers developed i.e. RAPD, AFLP, SSR, SNP, CAPS, STS, SCAR, EST, etc..
1986 – Leroy Hood and Lloyd Smith developed the first semi-automatic DNA sequencer
1990 – Development of Pyrosequencing by Pal Nyren 1990 – The U.S. National Institutes of Health (NIH) begins large-
scale sequencing trials on Mycoplasma , Escherichia coli, Caenorhabditis elegans, and Saccharomyces cerevisiae
1995 – Craig Venter, Hamilton Smith at The Institute for Genomic Research (TIGR) publish the first complete genome of a free-living organism, the bacterium Haemophilus influenzae
1996 – Sequence of saccharomyces cervisiae genome completed.
Nature Review, 2010 & Nature Biotechnology, 2001-2013
1998 – The genome of the 1st multi-cellular organism of the Round worm (Caenorhabditis elegans) was completed.
1999 – Sequence of first human chromosome (chromosome 22nd) 2000 – The first plant to be completely sequenced is that of the
Arabidopsis thaliana.
2001 – A draft sequence of the human genome is published.
2002 – Rice genome sequencing was completed
2003 – Human genome sequencing was completed
2004 – 454 Life Sciences markets a version of pyrosequencing machine developed. ‘454 Sequencing’ used in Barley this machine reduced sequencing costs 6-fold compared to automated Sanger sequencing methods.
Recently, 2012 – Wheat genome was sequenced – R. Brenchley et al. 2012 –Barley genome was sequenced – RKV et al.
Nature Review, 2010 & Nature Biotechnology, 2001-2013
Genome size, structure and genomic
resources of major cereal species
Rajeev K. Varsney et al (2013)
CROP BOTANICAL NAME GENOME SIZE(Mb)
RICE Oriza sativa 400
SORGHUM Sorghum bicolar 1000
MAIZE Zea mays 2500
BARLEY Hordeum vulgare 8000
BREAD WHEAT Ttriticum aestivum 16000
ESTIMATED GENOME SIZE OF MAJOR CEREAL CROPS
Rajeev K. Varsney et al (2013) Trends in biotechnology
Comparison of Rice with Cereal genomes
?WHY GENOMI
CS?
Through conventional breeding, selection for crop improvement is carried out on phenotypic character, which is the result of genotypic and environmental effects but by the use of molecular markers exact location of particular gene on chromosome can easily be identified.
Many potential genes that confer resistance have been mapped in most of the economically important cereal crops like Rice, Maize, Wheat, Sorghum and Barley.
QTLs identified and markers linked with the promising QTLs are useful resource for genomics assisted breeding. For ex. resistance to heat tolerance in wheat.
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Presence of all of the important genes and related markers will be very much helpful to identified and development of new cultivars as we desire - Varietal identification
Insertion and deletions are desirable or undesirable, easily be possible to identify with the sequencing of cereal crops.
Generated set of ESTs serves as a resource of high quality transcripts for gene discovery and development of markers associated with abiotic stress tolerance that will be helpful to facilitate cereal genomic breeding.
Laboratories for genomic research in India
National Research Centre for Plant Biotechnology, IARI, New Delhi
International Centre for Genetic Engineering & Biotechnology, New Delhi
Jawaharlal Nehru University , New Delhi
National Institute of Plant Genome Research, New Delhi
ICRISAT and DRR ,Hyderabad
International Institutes for Cereal Genomic Research
Genome Institutes/ Countries Involved
Rice GenomeJointly Mapped By IRRI, USA, China, Japan Scientist through International Rice Genome Sequence Project.
Wheat GenomeInternational Genome Research on Wheat by Mexico (CIMMYT), UK, USA & Japan
Arabidopsis Genome China, Japan, & USA
GENOMICS- BASED APPROACHES
Rajeev K. Varsney et al (2013)
Genomic technologies for high-throughput genome sequencing
Diversity Panel
1. ASS0CIATION MAPPING
Zhu et al., (2008)
A holistic approach, where genomics technologies including molecular markers, trasncriptomics, metabolomics, proteomics and bioinformatics are integrated with conventional breeding strategies for breeding crop plants resistant/ tolerant to biotic and abiotic stresses or improved for quality and yield.
3 Next generation sequencing (NGS) technologies Include various novel sequencing technologies for example
454/FLX (Roche Inc.), ABI SOLID (Applied Biosystems), Solexa (Illumina Inc.) etc. that have surpassed traditional Sanger sequencing in throughput and in cost-effectiveness for generating large-scale sequence data.
2 Genomic Assisted Breeding
Clone by clone sequencing also called as the directed sequencing of the BAC contigs.
The chromosomes were mapped
Then split up into sections
A rough map was drawn for each of these sections
Then the sections themselves were split into smaller bits.
Each of these smaller bits would be sequenced.
(BAC clones (80-100 kb long DNA fragments ) arranged in contigs.)
4. CLONE BY CLONE SEQUENCING
In this approach, genomic DNA is cut into pieces
Inserted into BAC vectors
Transformed into E. coli where they are replicated
The BAC inserts are isolated
Mapped to determine the order of each cloned fragment.
Each BAC fragment in the Golden Path is fragmented randomly into smaller pieces
Each piece is cloned into a plasmid
Sequenced on both strands.
These sequences are aligned so that identical sequences are overlapping.
5. SHOTGUN SEQUENCING METHOD
This is referred to as the Tiling Path.
Moto Ashikarc et al., (2009)
COMPARATIVE GENOMICS OF CEREALS
Several draft sequences of the rice genome are also available and are being extensively used for study of other cereal genomes
Analyzing & comparing genetic material from different species
Evolution, gene function, and inherited disease Understand the uniqueness between different species
HR- Highly repetitiveMR-Moderately repetitiveSL- Slow/ Low repetitiveGnSz – Genome sequenceSqCx- Sequence Complexity
Gupta, P. et al., (2009), PAU
ACHIEVEMENTS IN CEREAL GENOMICS
Major QTLs responsible for yield
Gupta, P. et al., (2009), PAU
Major QTLs responsible for grain protein and enzyme activity
Gupta, P. et al., (2009), PAU
Case study
GENOTYPE Station trials Multilocation evaluation
DBW 16, DBW 17, PBW 568 + Yr36/GpcB1 2009-10 2010-11
Advanced lines + Lr 34/Yr18 2009-10 2010-11
PBW 343 + Lr37/Yr17 2009-10 2010-11
HD 2733 + Lr37/Yr17 2009-10 2010-11
PBW 343+Yr+Lr gene(s) from Ae. umbellulata
2010-11 2011-12
PBW 343 + Lr24+Lr28+Yr10+Yr15 2011-12 2012-13
PBW 343+KB resistance+Yr40/Lr57
2011-12 2012-13
PBW 550, PBW 533 +Yr 10/Yr 15 2011-12 2012-13
Yield testing of Wheat MAS products(4 rust resistant genes pyramided)
Pyramiding of Lr 24, Lr 28, Yr 10 and Yr 15 in PBW 343 Gupta, P. et al., (2009), PAU
OryzaSNP Project <http://www.oryzasnp.org>
IR64 IA
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SNP scan >100 Mb/genome20 diverse genotypes
Zhu et al., (2009)
FUNCTIONAL SNP’S FOR TARGET TRAITS IN RICE
Bacterial blight xa5
Blast Pia, Pi9,Pita, Pizt
Tungro RTSV
Grain quality GBSS, Wx, SBE3, SSlla
Submergence tolerance
Sub1
Zhu et al., (2009)
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Golden RiceVariety :- Rice (Oriza sativa)Scientist:- Igno Potrycus & Peter Boyer.Produce :- β-varotene Precursor of Vit. A.
Golden rice was created by transforming rice with two beta-carotene biosynthesis genes:psy (phytoene synthase) from daffodil (Narcissus pseudonarcissus)
crtI (carotene desaturase) from the soil bacterium (Erwinia uredovora)
Ye, Xi et al., (2000)
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Original golden rice was called SGR1
Application of candidate gene strategy to identify CrtRB1 locus
Jiabing et al., (2014), Nature Genetics
GENETIC ENHANCEMENT OF NUTRITIONAL QUALITY OF GRAIN SORGHUM
Genetically enhancing the nutritional quality of grain sorghum by the introduction of genes encoding the methionine-rich maize beta-zein and the lysine-rich barley chymotrypsin inhibitor CI-2 proteins.
The goal to produce transgenic sorghum plants with elevated lysine and methionine contents.
A biolistic and Agrobacterium-mediated transformation protocol for selected grain sorghum lines was established. This would form the technological basis for nutritional quality improvement of grain sorghum.
A Grootboom and M M O’Kennedy (2013)
VARIETIES DEVELOPED THROUGH GENOMIC TECHNOLOGIES
Varshney et al.,(2006)
Challenges in using genomics for breeding
Precision phenotyping Density of genetic maps. Low heritability of traits. Contribution of regulatory variation Consideration of epistasis Technical skill Technical difficulties Cost investment issues
Genomics based technologies is producing enormous amounts of DNA sequence information that is opening up new experimental opportunities for functional genomics analysis.
The incorporation of metabolomic data and data from phenotype studies will close the loop and create the foundation for advanced knowledge.
The recent integration of advances in molecular biology, transgenic breeding and molecular marker applications with conventional plant breeding practices has created the foundation for genomic research.
Genomics will affect every aspect of cereal breeding and will modernize this old science, although genomic approaches will not succeed unless they are combined with traditional breeding programs.
CONCLUSION
Some of References
Jiang Y, Cai Z, Xie W, Long T, Yu H, Zhang Q. 2012. Rice functional genomics
research: Progress and implications for crop genetic improvement.
Biotechnology Advances (30) 1059–1070.
Sasaki T, Wu J, Mizuno H, Antonio BA, and Matsumoto T. 2008. The Rice Genome
Sequence as an Indispensable Tool for Crop Improvement. Chapter 1.1,
Springer-Verlag Berlin Heidelberg.
Tyagi AK, Mohanty A. 2000. Rice transformation for crop improvement and functional
genomics. Plant Science (158) 1–18.
Cai Q, Yuan Z, Chen M, Yin C, Luo Z, Zhao X, Liang W, Hu J & Zhang D.
2014. Jasmonic acid regulates spikelet development in rice. ISSN (online)
2041-1723.
Varshney R.K., Thiel T., Stein N., Langridge P., Graner A. Cereal Genomics. Cell Mol
Biol Lett 2004; 7: 537-546
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