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DNA: code introduction
1. DNA: code introduction
DNA (Deoxyribonucleic Acid) is known as the code of life, a (fairly) fault-tolerant digital code. It contains the building blocks of plant and human life.
All 20 human amino acids can be created with these building blocks and are used to make complex molecules called proteins which make enzymes.
Together, proteins and enzymes control almost everything that happens in life from conception through life until death.
2. Base pairs
The four possible base pairs are:
adenine (A)
guanine (G)
thymine (T)
cytosine (C)
Since there are four bases, each can represent one of four vales, or 2 bits if coded information.
3. Backbone
Each base pair can be connected to the backbone.
4. Custom fit
Whenever two backbones are paired, each base pair can only fit with one of the other base pairs.
5. Digital code
Three base pairs specify one amino acid. Since each base pair represents 2 bits of information, a group of three pairs, called a codon, can represent 2
or one of 64 encodings.
6. DNA code
DNA is a fault-tolerant, digital code.
There is a lot of research into inferring higher level grammars for the low level DNA codes.
7. Base pairs
The four possible base pairs are called
adenine (A),
guanine (G),
thymine (T), and
cytosine (C).
8. Bases
The four bases of DNA are arranged along a sugar-phosphate backbone in a particular order called the DNA sequence.
This sequence of base pairs encodes all genetic instructions for an organism.
A gene is a segment of a DNA molecule located in a specific chromosome. A gene contains the information necessary for protein synthesis.
9. Parings
Each of the four nucleotides pairs with another nucleotide.
The base adenine (A) pairs with the base thymine (T).
The base cytosine (C) pairs with the base guanine (G).
10. Double helix
The DNA is coiled in a double-helix (i.e., twisted ladder) shape. If the DNA from one human cell were fully uncoiled, it would be 6 feet long.
11. Codons
The digital code of base pairs divided into triplets called codons.
There are 4 * 4 * 4 = 64 possible codons. Some are start codes, some are stop codes, some allow for fault tolerance or overlapping codes, etc.
12. Amino acids
All 20 human amino acids can be created with these codons. Some codons are start/stop triplets that are used during copying.
13. Proteins
The 20 human amino acids are used to make complex molecules called proteins.
14. Enzymes
Proteins make enzymes.
15. Proteins and enzymes
Together, proteins and enzymes control almost everything that happens in life from conception through life until death.
16. Genome project
The Genome project mapped the entire sequence of human DNA.
17. Human genome
Here are the first 25 lines of Chromosome 1.
GATCAATGAGGTGGACACCAGAGGCGGGGACTTGTAAATAACACTGGGCTGTAGGAGTGA
TGGGGTTCACCTCTAATTCTAAGATGGCTAGATAATGCATCTTTCAGGGTTGTGCTTCTA
TCTAGAAGGTAGAGCTGTGGTCGTTCAATAAAAGTCCTCAAGAGGTTGGTTAATACGCAT
GTTTAATAGTACAGTATGGTGACTATAGTCAACAATAATTTATTGTACATTTTTAAATAG
CTAGAAGAAAAGCATTGGGAAGTTTCCAACATGAAGAAAAGATAAATGGTCAAGGGAATG
GATATCCTAATTACCCTGATTTGATCATTATGCATTATATACATGAATCAAAATATCACA
CATACCTTCAAACTATGTACAAATATTATATACCAATAAAAAATCATCATCATCATCTCC
ATCATCACCACCCTCCTCCTCATCACCACCAGCATCACCACCATCATCACCACCACCATC
ATCACCACCACCACTGCCATCATCATCACCACCACTGTGCCATCATCATCACCACCACTG
TCATTATCACCACCACCATCATCACCAACACCACTGCCATCGTCATCACCACCACTGTCA
TTATCACCACCACCATCACCAACATCACCACCACCATTATCACCACCATCAACACCACCA
CCCCCATCATCATCATCACTACTACCATCATTACCAGCACCACCACCACTATCACCACCA
CCACCACAATCACCATCACCACTATCATCAACATCATCACTACCACCATCACCAACACCA
CCATCATTATCACCACCACCACCATCACCAACATCACCACCATCATCATCACCACCATCA
CCAAGACCATCATCATCACCATCACCACCAACATCACCACCATCACCAACACCACCATCA
CCACCACCACCACCATCATCACCACCACCACCATCATCATCACCACCACCGCCATCATCA
TCGCCACCACCATGACCACCACCATCACAACCATCACCACCATCACAACCACCATCATCA
CTATCGCTATCACCACCATCACCATTACCACCACCATTACTACAACCATGACCATCACCA
CCATCACCACCACCATCACAACGATCACCATCACAGCCACCATCATCACCACCACCACCA
CCACCATCACCATCAAACCATCGGCATTATTATTTTTTTAGAATTTTGTTGGGATTCAGT
ATCTGCCAAGATACCCATTCTTAAAACATGAAAAAGCAGCTGACCCTCCTGTGGCCCCCT
TTTTGGGCAGTCATTGCAGGACCTCATCCCCAAGCAGCAGCTCTGGTGGCATACAGGCAA
CCCACCACCAAGGTAGAGGGTAATTGAGCAGAAAAGCCACTTCCTCCAGCAGTTCCCTGT
CTGAGCTGCTGTCCTTGGACTTGAAGAAGCTTCTGGAACATGCTGGGGAGGAAGGAAGAC
ATTTCACTTATTGAGTGGCCTGATGCAGAACAGAGACCCAGCTGGTTCACTCTAGTTCGG
http://www.sacred-texts.com/dna/hgp011k.htm (as of 1997)
18. Human DNA
One copy of a human DNA consists of a sequence of 3.2 billion base pairs, or nucleotides.
A typical human body has 50 to 100 trillion cells.
Every person has a unique DNA that contains the genetic code that makes you what you are.
19. Pages of text
How much DNA information can be printed on one page?
A page has 50 lines of 60 characters/nucleotides (i.e., "A", "T", "G", or "C").
3,000 characters/nucleotides per page .
A ream (500 pages) is about 1-1/2 inches tall.
4,000 pages per foot.
Print out all of the DNA of one human.
100,000,000,000,000 copies (100 trillion)
20. DNA
Your DNA consists of over
3,000,000,000 (3 billion) nucleotides (i.e., over
6,000,000,000 (6 billion) bits of information encoded as "
A", "
C", "
G", or "
T",) encoded in (almost) all of about
100,000,000,000,000 (100 trillion) cells in your body.
Who owns your
DNA?
21. Chains
A
chain is a linked structure with one link connected to the next link.
Remove a link, the chain falls apart.
Security is as strong as the weakest link.
Mathematical theories have similar characteristics.
22. DNA
DNA is a linked chain of nucleotides.
Proteins are a linked chain of amino acids.
23. Transcription
24. DNA chains
3 Billion nucleotides.
Enlarge the cell nucleus to the size of a basketball.
The DNA is like 120 miles of fishing line inside the basketball.
You have to be able to unwind it to find the code segment you need, transcribe it, and wind it back up, without tangling.
25. BLAST
BLAST (Basic Local Alignment Search Tool), as defined by Wikipedia:
In bioinformatics, BLAST (basic local alignment search tool)is an algorithm for comparing primary biological sequence information, such as the amino-acid sequences of proteins or the nucleotides of DNA and/or RNA sequences.
26. Webb Miller
Miller has been developing algorithms and software for analyzing DNA sequences and related types of data from molecular genetics. He is one of the authors of BLAST.[6][7] He also develops methods for aligning long DNA sequences and extracting functional information from them. Webb Miller has made important contributions to the analysis of many vertebrate genomes. He is regarded as one of the pioneers in the field of computational biology.
27. End of page