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Molecular Biology I. Some basic concepts. Aspects to Cover. DNA: structure, replication. RNA: transcription and processing. Protein: translation. Gene Expression: levels of transcription and translation. Common Techniques: DNA quantitation Gel electrophoresis Southern/ Northern blot
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Molecular Biology I Some basic concepts
Aspects to Cover DNA: structure, replication RNA: transcription and processing Protein: translation Gene Expression: levels of transcription and translation Common Techniques: DNA quantitation Gel electrophoresis Southern/ Northern blot Gene cloning Polymerase chain reaction (PCR) Quantitative Real-time PCR
DNA - Molecular Structure Deoxyribonucleic acid (DNA) is the genetic code that exists within every cell. Consists of two associated strands that wind together in a helical fashion. It is often described as a double helix.
DNA - Molecular Structure Each strand is a linear polymer in which the monomers (deoxynucleotides), are linked together by means of phosphodiester bonds. A single nucleotide subunit consists of a deoxyribose sugar joined to a phosphate group. Attached to the other side of the sugar molecule is one of four nitrogen bases.
Nitrogen Base Pairing Purines Pyrimidines
5`end 3`end DNA Double Helix 3`end 5`end
DNA – The Genetic Code Genotype wild type Phenotype normal DNA is essential for all living organisms. The genetic code (genotype) determines how an organism looks and functions (phenotype) The more complex the organism the larger the genome Genotype db/db Phenotype obese
“Central Dogma” Central dogma describes information flow from DNA→RNA→protein Protein considered the functional unit within the cell
Introns Promoter 5` 3` 1 4 2 3 5 Gene Structure of Genomic DNA Exon Promoter: regulatory sequences that, together with transcription factors, determine the amount of gene expression Gene: coding and regulatory elements that combine to result in a protein Introns: intervening sequences that do not encode the protein structure Exons: sequences within the gene that encode the protein structure Transcription: process to produce RNA from the gene
RNA – From gene to protein There is more than one type of ribonucleic acid... Messenger RNA (mRNA): carries the genetic information out of the nucleus for protein synthesis. Transfer RNA (tRNA): decodes the information from mRNA. Ribosomal RNA (rRNA): constitutes 50% of a ribosome, which is a molecular assembly involved in protein synthesis. Catalytic/ functional RNAs: involved in reactions in the cell.
DNA 5` ATGCGTTAGACTTGACACTGACTAC 3` 3` TACGCAATCTGAACTGTGACTGATG 3` RNA synthesis mRNA 5` AUGCGUUAGACUUGACACUGACUAC 3` RNA DNA mRNA – The Cellular Messenger RNA is similar to single stranded DNA sense strand sense strand antisense strand Sugar is ribose rather than deoxyribose RNA has same sequence as DNA sense strand Uracil (U) replaces thymidine (T) RNA is complementary to DNA antisense strand Carries the ‘message’ to protein construction centers - ribosomes
mRNAProcessing Pre-mRNA is transcribed from DNA in nucleus by RNA polymerase Splicing removes introns from pre-mRNA to create mRNA mRNA is transported from the nucleus to the rough endoplasmic reticulum (rER) Protein is translated from the RNA at the cytoplasm at the ribosome
Protein Translation Occurs at ribosomes using mRNA as template and tRNA for assembly of protein building blocks – amino acids Amino acids polymerise in the order determined by the sequence of mRNA mRNA arranged in codons – 3 bases tRNA contains specific amino acids for particular anticodons Polymerisation of amino acids occurs until a stop codon is read Ribosome shuffles along mRNA to next codon
Decoding the genetic code 20 common amino acids, 1 start codon (Met - AUG), 3 stop codons (UAA, UAG, UGA) Each amino acid is encoded by one or more codons – degenerate code RNA to protein: one possible sequence Protein to RNA: many possible sequences
“Gene Expression” Expression refers to both RNA and protein Gene expression is regulated at both the transcriptional and translational levels – RNA and protein expression don’t always correlate A single gene does not always produce a single protein
Hypothalamus Ob-R NPY -ve -ve -ve Adipocytes Leptin Background Leptin (Ob)
Alternate splicing of Ob-R Ob-RL and Ob-RS are identical in mRNA up until exon 18 Ob-RL uses exon 18a & 18b and Ob-RS uses exon 18 a Different stop codon result in different proteins Ob-RS Ob-RL
Ob-RS Ob-RL Extracellular Transmembrane Intracellular Leptin Receptor – Ob-R G T
Summary Small changes at the DNA level can produce drastic changes at the protein level Translation decodes the information from the gene/mRNA into a protein – the functional endpoint of gene expression DNA replicates itself at every cell division, placing a copy of itself in every cell in every organism Transcription and translation are independently regulated – mRNA and protein levels are not necessarily correlated Transcription produces a copy of the DNA called RNA
1.60 Absorbance 0 200 350 Wavelength (nm) DNA/RNA Quantitation DNA/RNA can be extracted from virtually any tissue using special chemicals and purification procedures Once extracted, DNA/RNA can be dissolved in water and used for a variety of different techniques – PCR etc Spectrophotometer can analyse the spectral properties of the nucleic acid A260/A280 = 1.8 A260 = 1.0 50 mg/ml 260 280 Similarly for RNA A260/A280 = 2.0 A260 = 1.0 40 mg/ml
Gel Electrophoresis DNA can originate from a variety of sources: genomic DNA - from organisms plasmid DNA - circular, cloned fragments amplified DNA - specific fragments from PCR Knowing the size of the DNA is beneficial in identifying the fragments – distance migrated is inversely proportional to the size of the molecule DNA size is usually measured in numbers of base pairs: bp (1 – 1000) kb (thousands of bp) Mb (millions of bp)
- 1 kb 500 bp ~400 bp 400 bp 300 bp ~250 bp 200 bp 100 bp + Gel Electrophoresis DNA size approximated by electrophoresis through agarose and comparison with fragments of known size DNA moves according to size – small fragments more faster than large fragments Due to phosphate backbone DNA has negative charge Load DNA onto gel Apply electric current to gel (100 V) Negatively charged DNA migrates to positive electrode
Gel Electrophoresis Standard methodology resolves relatively small DNA molecules (0.1-50kb) • % agarose determines range of DNA sizes resolved • 0.3% w/v resolves DNA of 5-50 kb • 2.0% w/v resolves DNA of 0.1-2 kb Ethidium bromide used to stain DNA – binds and fluoresces under UV illumination