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What makes DNA Computing possible?. Great advances in molecular biology PCR (Polymerase Chain Reaction) DNA Selection by affinity DNA Filtering DNA Gel Electroforesis DNA Denaturation Renaturation DNA Restriction Enzymes DNA Sequencing
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What makes DNA Computing possible? • Great advances in molecular biology • PCR (Polymerase Chain Reaction) • DNA Selection by affinity • DNA Filtering • DNA Gel Electroforesis • DNA Denaturation Renaturation • DNA Restriction Enzymes • DNA Sequencing • Ability to produce massive numbers of DNA molecules with specified sequence and size
What is a typical methodology of DNA Computing? • Encoding: Map problem instance onto set of biological molecules and molecular biology protocols • Molecular Operations: Let molecules react to form potential solutions • Extraction/Detection: Use protocols to extract result in molecular form
What are the basics from molecular biology that I need to know to understand DNA computing?
3’ OH 5’ C Minor Groove 34 Å 5’ 3’ Sugar-Phosphate Backbone Major Groove 5’ 3’ Nitrogenous Base C 5’ 3’ 0H Central Axis 20 Å
(-) (+) (+) (-) to Sugar-Phosphate Backbone (+) (-) to Sugar-Phosphate Backbone Guanine Cytosine Hydrogen Bond INTER-STRAND HYDROGEN BONDING (+) (-) (-) (+) to Sugar-Phosphate Backbone to Sugar-Phosphate Backbone Adenine Thymine
Enzymes of Molecular Biology • DNA Polymerase • DNA Ligase, Helicase, Topoisomerase • DNA Repair Ezymes • DNA Recombinase • Reverse Transcriptase • Restriction Enzymes • Nuclease
DNA Replication • DNA is a double-helical molecule • Each strand of the helix must be copied in complementary fashion by DNA polymerase • Each strand is a template for copying • DNA polymerase requires template and primer • Primer: an oligonucleotide that pairs with the end of the template molecule to form dsDNA • DNA polymerases add nucleotides in 5'-3' direction
DNA Ligase ’ ’ ’ ’ ’ ’ Ligase Joins 5' phosphate to 3' hydroxyl
Restriction Enzymes • Bacteria have learned to "restrict" the possibility of attack from foreign DNA by means of "restriction enzymes" • Type II and III restriction enzymes cleave DNA chains at selected sites • Enzymes may recognize 4, 6 or more bases in selecting sites for cleavage • An enzyme that recognizes a 6-base sequence is a "six-cutter"
5’ P - - OH 3’ EcoRI - P 5’ 3’ OH - HindIII AluI HaeIII RESTRICTION ENDONUCLEASES
Recombinant DNA Technology • Cleavage DNA at specific sites by restriction enzymes,which greatly • facilitates the isolation and manipulation of individual DNA. • Rapidsequencing of all the nucleotides in a purified DNA fragment, • which makes it possible to determine the boundaries of a gene and the • amino acid sequence it encodes. • Nucleic acid hybridization, which makes it possible to find a specific • sequence of DNA or RNA. • DNA cloning, whereby a single DNA molecule can be copied to • generate billions of identical molecules. • DNA engineering, by which DNA sequences are altered to make • Modified versions of genes, which are reinserted back into cell.
5’ P - - OH 3’ EcoRI - P 5’ 3’ OH - HindIII AluI HaeIII RESTRICTION ENDONUCLEASES
Electrode Samples Slower Gel Buffer Electrode Faster GEL ELECTROPHORESIS – Separation of DNA fragments