1 / 44

Molecular biology

Molecular biology. Course structure. Polymerase Chain Reaction RNA Isolation cDNA Synthesis Amplification Electrophoresis Transfection. Which molecules can be analyzed?. Genomic DNA mRNA. Nucleic acid chemistry.

takara
Download Presentation

Molecular biology

An Image/Link below is provided (as is) to download presentation Download Policy: Content on the Website is provided to you AS IS for your information and personal use and may not be sold / licensed / shared on other websites without getting consent from its author. Content is provided to you AS IS for your information and personal use only. Download presentation by click this link. While downloading, if for some reason you are not able to download a presentation, the publisher may have deleted the file from their server. During download, if you can't get a presentation, the file might be deleted by the publisher.

E N D

Presentation Transcript

  1. Molecular biology

  2. Course structure Polymerase Chain Reaction RNA Isolation cDNA Synthesis Amplification Electrophoresis Transfection

  3. Which molecules can be analyzed? • Genomic DNA • mRNA

  4. Nucleic acid chemistry DNA and RNA store and transfer genetic information in living organisms. • DNA: • – major constituent of the nucleus • – stable representation of an organism’s complete genetic makeup • RNA: • – found in the nucleus and the cytoplasm • – key to information flow within a cell

  5. Why purify genomic DNA? Many applications require purified DNA. Purity and amount of DNA required depends on intended application. Tissue typing for organ transplant Detection of pathogens Human identity testing Genetic research

  6. DNA purification challenges Separating DNA from other cellular components such as proteins, lipids, RNA, etc. Avoiding fragmentation of the long DNA molecules by mechanical shearing or the action of endogenous nucleases.Effectively inactivating endogenous nucleases and preventing them from digesting the genomic DNA is a key early step in the purification process. DNases can usually be inactivated by use of heat or chelating agents.

  7. DNA purification There are many DNA purification methods. In all cases, one must: Effectively disrupt cells or tissues(usually using detergent) Denature proteins and nucleoprotein complexes(a protease/denaturant) Inactivate endogenous nucleases(chelating agents) Purify nucleic acid target selectively(could involve RNases, proteases, selective matrix and alcohol precipitations)

  8. Total Cellular RNA • Messenger RNA (mRNA): 1-5% • Serves as a template for protein synthesis • • Ribosomal RNA (rRNA): >80% • Structural component of ribosomes • • Transfer RNA (tRNA): 10-15% • Translates mRNA information into the appropriate amino acid

  9. What RNA is needed for? Messenger RNA synthesis is a dynamic expression of the genome of an organism. As such, mRNA is central to information flow within a cell. • Size – examine differential splicing • Sequence – predict protein product • Abundance – measure expression levels • Dynamics of expression – temporal, developmental, tissue specificity

  10. RNA isolation

  11. RNA purification • Total RNA from biological samples • – Organic extraction • – Affinity purification • • mRNA from total RNA • – Oligo(dT) resins • • mRNA from biological samples • – Oligo(dT) resins

  12. Total RNA purification • Cells or tissue must be rapidly and efficiently disrupted • Inactivate RNases • Denature nucleic acid-protein complexes • RNA selectively partitioned from DNA and protein

  13. RNases • RNases are naturally occurring enzymes that degrade RNA • • Common laboratory contaminant (from bacterial and human sources) • • Also released from cellular compartments during isolation of RNA from biological samples • • Can be difficult to inactivate

  14. Protecting against RNases • Wear gloves at all times • • Use RNase-free tubes and pipette tips • • Use RNase-free chemicals • • Pre-treat materials with extended heat (180°C for several hours), wash with DEPC-treated water • • Supplement reactions with RNase inhibitors • • Include a chaotropic agent (guanidine) in the procedure that inactivate and precipitate RNases and other proteins

  15. Organic extraction of total RNA

  16. Advantages • Versatile - compatible with a variety of sample types • Scalable - can process small and large samples • Established and proven technology • Inexpensive • Disadvantages • Organic solvents • Not high-throughput • RNA may contain contaminating genomic DNA

  17. Affinity purification of total RNA

  18. Advantages • Eliminates need for organic solvents • Compatible with a variety of sample types (tissue, tissue culture cells, white blood cells, plant cells, bacteria, yeast, etc.) • DNase treatment eliminates contaminating genomic DNA • Excellent RNA purity and integrity

  19. RNA analysis Photometric measurement of RNA concentration UV 260 nm Conc=40xOD260

  20. Determination of the RNA concentration [RNA] μg/ml = A260 x dilution x 40.0 where A260 = absorbance (in optical densities) at 260 nm dilution = dilution factor (200) 40.0 = average extinction coefficient of RNA.

  21. cDNA Synthesis

  22. Template: • Total RNA • Poly (A)+ RNA • Specific RNA

  23. Oligo dT (18) synthesize complete cDNAs, beginning at the poly A+ tail and ending at the 5 end of the mRNA. Random hexamer Hybridizes somewhere along the mRNA Gene specific primers Specific mRNA but lower yields • Priming

  24. The reverse transcriptase from the avian myoblastosis virus (AMV-RT): Temperature optimum of activity at 45-50°C. Highly thermostable, can be used at temperatures up to 60°C. Demonstrates DNA exonuclease and RNase activities. The reverse transcriptase from the Moloney murine leukemia virus (MMLV-RT): The optimal working temperature is about 37°C, with a maximum of 42°C. Weaker RNase activity. Reverse Transcriptases (RTs)

  25. Most gene expression assays are based on the comparison of two or more samples and require uniform sampling conditions for comparison to be valid. Many factors can contribute to variability in the analysis of samples, making the results difficult to reproduce between experiments: Sample degradation, extraction efficiency, contamination, Sample concentration, RNA integrity, reagents, reverse transcription Housekeeping genes: ß-actin, ß-tubulin, GAPDH, have often been used as reference genesfor normalization. The expression ofthese genes is constitutively high and that a given treatment willhave no effect on the expression level. Normalization

  26. Amplification (PCR)The Polymerase Chain Reaction

  27. PCR – first described in mid 1980’s, Mullis (Nobel prize in 1993) • An in vitro method for the enzymatic synthesis of specific DNA sequences • Selective amplification of target DNA from a heterogeneous, complex DNA/cDNA population • Requires • Two specific oligonucleotide primers • Thermostable DNA polymerase (Taq DNA polymerase from Thermus aquaticus) • dNTP’s • Template DNA • MgCl2 • Sequential cycles of (generally) three steps (temperatures)

  28. MgCl2 (mM) 1.5 2 3 4 5 • Magnesium Chloride • (usually 0.5-5.0mM) • Magnesium ions have a variety of effects • Mg2+ acts as cofactor for Taq polymerase • Mg2+ binds DNA - affects primer/template interactions • Mg2+ influences the ability of Taq pol to interact with primer/template sequences • More magnesium leads to less stringency in binding

  29. Thermal cyclers Introduced in 1986. PCR cyclers available from many suppliers. 29 Reactions in tubes or 96-well micro-titre plates heated lids adjustable ramping times single/multiple blocks gradient thermocycler blocks thin walled tube,  volume,  cost  evaporation & heat transfer concerns0

  30. Temperature control in a PCR thermocycler 94 0C - denaturation 50 – 70 0C - primer annealing 72 0C - primer extension 94 0C - denaturation

  31. Step 1: Denaturation dsDNA to ssDNA Step 2: Annealing Primers onto template Step 3: Extension dNTPs extend 2nd strand Vierstraete 1999

  32. PCR Problems Mis-priming • Set up reactions on ice • Hot-start PCR –holding one or more of the PCR components until the first heat denaturation • Manually - delay adding polymerase • Polymerase antibodies • Touch-down PCR – set stringency of initial annealing temperature high, incrementally lower with continued cycling • PCR additives • 0.5% Tween 20 • 5% polyethylene glycol 400 • DMSO

  33. Primer Design • Typically 20 to 30 bases in length • Annealing temperature dependent upon primer sequence (~ 50% GC content) • Avoid secondary structure, particularly 3’ • Avoid primer complementarity (primer dimer)

  34. Primer Design Software Many free programs available online OLIGO PRIMER PrimerQuest

  35. Primer Design Software 35 • Many free programs available online • OLIGO • www.oligo.net • PrimerQuest • www.eu.idtdna.com/scitools/applications/primerquest • Primer3 • www.frodo.wi.mit.edu/primer3 • GeneWorks • www.geneworks.com.au • Yeast genome primer design • www.yeastgenome.org/cgi-bin/web-primer

  36. Primer Dimers • Pair of Primers 5’-ACGGATACGTTACGCTGAT-3’ 5’-TCCAGATGTACCTTATCAG-3’ • Complementarity of primer 3’ ends 5’-ACGGATACGTTACGCTGAT-3’ 3’-GACTATTCCATGTAGACCT-5’ • Results in PCR product Primer 1 5’-ACGGATACGTTACGCTGATAAGGTACATCTGGA-3’ 3’-TGCCTATGCAATGCGACTATTCCATGTAGACCT-5’ Primer 2

  37. Rules of thumb for PCR conditions • Add an extra 3-5 minute (longer for Hot-start Taq) to your cycle profile to ensure everything is denatured prior to starting the PCR reaction • Approximate melting temperature (Tm) = [(2 x (A+T)) +(4 x (G+C))]ºC • If GC content is < 50% start 5ºC beneath Tm for annealing temperature • If GC content ≥ 50% start at Tm for annealing temperature • Extension @ 72ºC: rule of thumb is ~500 nucleotide per minute. Use 3 minutes as an upper limit without special enzymes

  38. Typical PCR Temps/Times Initial denaturation 90o – 95o C 1 – 3 min Denature 90o – 95o C 0.5 – 1 min Primer annealing 45o – 65o C 0.5 – 1 min Primer extension 70o – 75o C 0.5 – 2 min Final extension 70o – 75o C 5 – 10 min Stop reaction 4o C or 10 mM EDTA Hold 25 – 40 cycles

  39. DNA Gel Electrophoresis

  40. Agarose is a polysaccharide consisting of a linear polymer (repeating units) of D-galactose and 3,6-anhydro L-galactose The movement of molecules through an agarose gel is dependent on the size and charge of molecules and the pore sizes present in the agarose gel. At neutral pH, molecules migrate toward the anode when an electric field is applied across the gel. Small, highly negatively charged molecules migrate faster through agarose gels than large, less negatively charged molecules. Rates can also be effected by the pore size of the agarose gel. Decreasing pore sizes increases the separation of small and large molecules during electrophoresis. Pore size can be decreased by increasing the percentage of agarose in the gel. Agarose

  41. TBE or TAE Buffers Tris helps to maintain a consistent pH of the solution. EDTA chelates divalent cations like magnesium. This is important because most nucleases require divalent cations for activity.

  42. Ethidium Bromide • A fluorescent dye is added to agarose gels. • It intercalates between the bases of DNA, allowing DNA fragments to be located in the gel under UV light. • The intensity of the band reflects the concentration • Because of its interaction with DNA, ethidium bromide is a powerful mutagen. Always handle all gels and gel equipment with gloves. Agarose gels with Ethidium Bromide must be disposed as hazardous waste in the labelled container.

  43. Add loading dye to all samples. Loading dye contains xylene cyanol as a tracking dye to follow the progress of the electrophoresis as well as glycerol to help the samples sink into the well.

More Related