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Protein Synthesis Notes Genetic information (genes) coded in DNA provide all the information needed to assemble proteins. If DNA cannot leave the nucleus – How can it get the instructions out to make the proteins needed to survive?????? RNA Contains the sugar ribose instead of deoxyribose. 2. Single-stranded instead of double stranded. 3. Contains uracil in place of thymine. 1. RNA Contains: 1. Adenine 2. Cytosine 3. Guanine 4. Uracil (not Thymine) Three Main Types of RNA 1. Messenger RNA (mRNA) - Carries copies of instructions, for the assembly of amino acids into proteins, from DNA to the ribosome (serve as “messenger”) * Made in the nucleus Three Main Types of RNA 2.Ribosomal RNA (rRNA) – Makes up the major part of ribosomes, which is where proteins are made. * made in the nucleolus 1 ribosome = 4 molecules of rRNA and 82 proteins Ribosomal RNA Three Main Types of RNA 3. Transfer RNA (tRNA) – Transfers (carries) amino acids to ribosomes as specified by codons in the mRNA 2 Steps to Make a Protein 1. Transcription 2. DNA → RNA Translation RNA → Protein (Chain of amino acids) Proteins Proteins are made up of a chain of amino acids. Step 1: Transcription Transcription - Process in which part of the nucleotide sequence of DNA is copied into a complementary sequence in RNA. RNA polymerase, enzyme that separates the DNA strands. RNA polymerase then uses one strand of DNA as a template from which nucleotides are assembled into a strand of RNA Step 1:How does RNA Polymerase know where to start and stop making an RNA copy of DNA? RNA Polymerase will only bind to regions of DNA known as promoters, which have specific base sequences. Promoters are “signals” in DNA that tell the enzyme where to bind, to start transcription. Similar signals called Repressors tell transcription to stop. Editing mRNA (pre-mRNA) Many RNA molecules require a bit of editing before they are ready to go into action. The DNA of eukaryotic genes contains sequences of nucleotides, called introns (intruders), that are not involved in coding for proteins. The DNA sequences that code for proteins are called exons. They are “expressed” in the synthesis of proteins. Editing mRNA 1. When RNA molecules are formed, both the introns and the exons are copied from the DNA. 2. The introns are cut out of RNA molecules. 3. The remaining exons are then spliced back together to form the final mRNA. (the exons can be spliced together in diff sequences to produce diff mRNA’s = diff proteins) We have 25,000 genes but produce more than 100,000 diff proteins = splicing Transcription: DNA → RNA Transcription Animation http://www- class.unl.edu/biochem/gp2/m_biology/animation/ gene/gene_a2.html http://207.207.4.198/pub/flash/26/transmenu_s.s wf (very good but need to skip some parts) http://www.youtube.com/watch?v=983lhh20rGY After Transcription The mRNA (already edited) leaves the nucleus and travels to the ribosomes in the cytoplasm. mRNA, Codons 1. How the code is read: a. b. c. Every 3 bases on mRNA is called a codon. Every codon codes for an amino acid (building block of protein) Amino acids are abbreviated most times by using the first 3 letters of the amino acid’s name. Met = methonine Leu = leucine Regulation of Protein Synthesis Start codons: found at the beginning of a protein Only one - AUG (methionine) Stop codons: found at the end of a protein (end of a polypeptide chain) Three stop codons that do not code for any amino acid therefore making the process stop : UAA, UAG,UGA Slide # 10 Reading the Codon Chart Examples: AUG = Methionine CAU = Histidine UAG = Stop First Position Try these: Answers: GCU: Alanine UAC: Tyrosine CUG: Leucine UUA: Leucine Jan 2006 Third Position This chart only works for mRNA codons. Step 2: Translation Translation - Decoding of a mRNA message into a protein (amino acid chain) Takes place on ribosomes in cytoplasm Steps of Translation 1. Begins when an mRNA molecule in the cytoplasm attaches to a ribosome. 2. As each codon of the mRNA molecule moves through the ribosome, the proper amino acid is brought into the ribosome by tRNA. Steps of Translation: tRNA Each tRNA contains: 1. 2. An amino acid Three unpaired bases. Steps of Translation: tRNA Anticodon Each tRNA molecule has three unpaired bases called the anticodon, which are complementary to one mRNA codon. 3. The ribosome forms a peptide bond between the first and second amino acids. 4. The polypeptide chain continues to grow until the ribosome reaches a stop codon on the mRNA molecule and a protein has been made. Translation Animations http://207.207.4.198/pub/flash/26/transmenu_ s.swf (very good animation!) http://www.youtube.com/watch?v=983lhh20r GY Slide # 12 Translation Nucleus mRNA Lysine Phenylalanine t RNA Methionine Anticodon Ribosome mRNA Start codon Go to Section: Jan 2006 Translation Slide # 13 Growing polypeptide chain The Polypeptide “Assembly Line” Ribosome tRNA Lysine tRNA mRNA Completing the Polypeptide mRNA Ribosome Go to Section: Jan 2006 Translation direction Roles of RNA and DNA The cell uses the vital DNA “master plan” to prepare RNA “blueprints.” The DNA molecule remains within the safety of the nucleus, while RNA molecules go to the protein-building sites in the cytoplasm— the ribosomes. Mutations (12-4) Mutation – changes in the genetic material (like mistakes in copying or transcribing) Types of Mutations Chromosomal Mutations - Involve changes in the number or structure of chromosomes. Ex. Downs Syndrome Gene Mutations Mutations that produce changes in a single gene. Types of Gene Mutations 1. Point Mutations - affect a single nucleotide, or point in the DNA sequence, usually by substituting one nucleotide for another. Examples include: Substitution – one base is changed to another Original: AUGUAC → Met – Tyr Mutated: AUGUAG → Met – Stop (causes the amino acid chain to stop protein production early) Types of Gene Mutations 2. Frameshift Mutations - Mutation that shifts the “reading” frame of the genetic message by inserting or deleting a nucleotide. Examples include: – Insertions – A base is inserted into the DNA sequence. – Deletions - A base is removed from the DNA sequence. Original: The fat cat ate the wee rat. Frame Shift: The fat caa tet hew eer at. The faa tca tat eth ewe era t. (Frame shift mutations affect all subsequent amino acids!) Significance of Mutations Many mutations have little or no effect on the expression of genes. Mutations may be harmful and may be the cause of many genetic disorders and cancer. Source of genetic variability in a species (may be highly beneficial). Beneficial Mutations Beneficial mutations may produce proteins with new or altered activities that can be useful to organisms in different or changing environments. Plant and animal breeders often take advantage of such beneficial mutations. The condition in which an organism has extra sets of chromosomes is called polyploidy. Often larger and stronger than diploid plants. Gene Regulation (12-5) Only a fraction of the genes in a cell are “expressed” at any given time (An “expressed” gene = exons= genes that are actually transcribed into RNA) How does the cell determine which gene will be expressed and which will remain ‘silent’? Promoters allow RNA polymerase to bind to begin transcription. Repressors prevent RNA polymerase from binding to go through transcription. Other DNA sequences (regulatory sites) act to turn on/off a gene Typical Gene Structure Section 12-5 Regulatory sites Promoter (RNA polymerase binding site) Start transcription DNA strand Stop transcription Gene Regulation (12-5) A. Not all genes are active (expressed) at the same time. 1. Why: Because the cell would produce many molecules it did NOT need – waste of energy and raw materials 2. Gene expression (protein synthesis) is when the product of a gene (specific protein) is being actively produced by a cell. a. some genes are – rarely expressed -adrenaline b. some genes are – constantly expressed – hair growth, blood pressure c. some genes are – expressed for a time, then turned off (cyclical) -- estrogen Gene Regulation The expression of genes can also be influenced by environmental factors such as temperature, light, chemicals, etc. Development and Differentiation Regulation of gene expression is important in shaping the way an organism develops, shaping the way cells undergo differentiation, by controlling which genes are expressed and which are repressed. . A series of genes call Hox Genes control the differentiation of cells in the embryo.