Difference between revisions of "17.05.26"
imported>Myeongji Park (Created page with "<p><strong>Lecture 3 - Genomics</strong></p> <p>* What is <u>Genomics</u>?<br /> ► We should remember two things.<br /> - 'T' =...") |
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| − | <p><strong>Lecture 3 - Genomics</strong></p> | + | <p><span style="font-size:14px"><strong>Lecture 3 - Genomics</strong></span></p> |
<p>* What is <u>Genomics</u>?<br /> | <p>* What is <u>Genomics</u>?<br /> | ||
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- After assmbling genome of one species, we can use it as reference genome.<br /> | - After assmbling genome of one species, we can use it as reference genome.<br /> | ||
<br /> | <br /> | ||
| − | ► MRCA : most recent common ancestor -> we can predict </p> | + | ► MRCA : most recent common ancestor -> we can predict similarity between different species.</p> |
| + | |||
| + | <hr /> | ||
| + | <p> </p> | ||
| + | |||
| + | <p> </p> | ||
| + | |||
| + | <p>** Summary **</p> | ||
| + | |||
| + | <p>(1) Genomics is changing the paradigm of biology.<br /> | ||
| + | (2) Geno-Pheno associated mutation is the key.<br /> | ||
| + | (3) Close species provide exact variants for pin-pointing mutation sites.<br /> | ||
| + | (4) Efficient reference to resequencing data comparison will be a useful bioinformatics methodology.<br /> | ||
| + | <br /> | ||
| + | <br /> | ||
| + | </p> | ||
| + | |||
| + | <hr /> | ||
| + | <p><strong><span style="font-size:14px">Presentation 1. "5<sup>th</sup> generation sequencing"</span></strong></p> | ||
| + | |||
| + | <p>► Design own model of sequencing.</p> | ||
| + | |||
| + | <p>► Idea<br /> | ||
| + | (1) different H-bond of bases -> nanosensor based on DNA helicase -> sort AT, GC base pairing + measure change of current based on difference of size (pyrimidine vs. purine)<br /> | ||
| + | (2) detect decresing ATP, incresing ADP, and Pi.<br /> | ||
| + | (3) using dsDNA -> break bond -> sequencing</p> | ||
| + | |||
| + | <p> </p> | ||
| + | |||
| + | <p>[[ 1._Lecture ]]</p> | ||
Latest revision as of 22:18, 31 May 2017
Lecture 3 - Genomics
* What is Genomics?
► We should remember two things.
- 'T' = 7 billion persons (species diversity) + 7 billion bases (variability in one person)
► Every life or species have genome, and variation of each genome is different.
* GEP/T graph.
► Geno + Enviro -> Pheno/Trait (almost cases are disease)
- Prediction is conducted by experiment, bioinformatics, etc.
► The challenge : As life is so complicated, prediction is so hard. We have to consider environmetal complexity with genomic complexity.
- Possible solution : using AI based on big data.
► Solutions
(1) Exact large amount of data.
- It is so important.
- typing (cheap and efficient) : simple test, approximation (not 100% prediction).
- sequencing (ultimate) : almost 100% prediction, digital device, it can have error (we don't know reason of error), ex) hardware.
(2) Need principle, law, and algorithms.
- We need to know related principle when we face to some facts.
(3) Big computer.
* Genome sequencing.
► 2nd generation : multiple molecule -> approximation
► 3rd generation : single molecule
► 4th generation : nanopore + membrane
► Base calling : computer notifies types of bases.
► NSG Data analysis : mapping based on reference gene.
* Close species comparative genomics.
► If we sequencing genome of new species, we have to find and get right right samples.
- we should pick sample which has interesting phenotype.
- And then, set up experimental design.
► Gene assembly : assemble gene fragments after putting the known gene between the intereted gene fragments.
- expensive
- After assmbling genome of one species, we can use it as reference genome.
► MRCA : most recent common ancestor -> we can predict similarity between different species.
** Summary **
(1) Genomics is changing the paradigm of biology.
(2) Geno-Pheno associated mutation is the key.
(3) Close species provide exact variants for pin-pointing mutation sites.
(4) Efficient reference to resequencing data comparison will be a useful bioinformatics methodology.
Presentation 1. "5th generation sequencing"
► Design own model of sequencing.
► Idea
(1) different H-bond of bases -> nanosensor based on DNA helicase -> sort AT, GC base pairing + measure change of current based on difference of size (pyrimidine vs. purine)
(2) detect decresing ATP, incresing ADP, and Pi.
(3) using dsDNA -> break bond -> sequencing
