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Date: March 18, 2016 Aim #64: How is protein shape determined? HW: 1)Protein Synthesis Review Worksheets (2) 2)Genetics Test next Tuesday (p.5) & Wednesday (p.1 & p.7)!! Review Monday morning 7:30AM in Room 142 Castle Learning Review posted (optional) Do Now: Warm-Up Notebook DateTitle of Activity Page # 3/18Protein Synthesis 109
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Aim #64: How is protein shape determined?
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Hormone All are proteins with a specific shape that determines their function. 1) What do enzymes, antibodies, hormones, hemoglobin and membrane proteins have in common? AntibodiesHemoglobin Enzymes
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2) What determines a protein’s Shape? A protein’s shape is determined by its sequence of amino acids.
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What happens after translation of the genetic code? Proteins do not remain as single strands of amino acids, rather the amino acids chain gets folded into a specific shape. This shape is determined by the ORDER of the amino acids in the chain.
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3) Protein Shape: A. The DNA base sequence (order) determines the sequence of amino acids. B.The sequence (order) of amino acids in a protein determine its shape. C. The shape of a protein determines its activity.
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4) Transcription & Translation: The processes of transcription and translation, lead to the final shape of a protein. Therefore it is the genetic code: DNA base sequence that ultimately determine a protein’s sequence of amino acids. A – TU C – GG Tryptophan C – GG
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5) Mutations Mutations (changes in the genetic code) that can lead to changes in the amino acid sequence and ultimately to the overall shape of the protein. Why?
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6) What causes mutations errors in DNA replication? Chemicals UV Radiation X-Ray radiation
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Mutated Proteins It changes the amino acids sequence which determines protein shape
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7) How does a mutated protein affect a cell? The mutated protein may have a different shape and disrupt its normal activity.
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8) Types of Mutation Substitution Deletion Insertion Inversion Original DNA Strand
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9) Copy the Normal DNA Strand: DNA CCT CAA GAT GCG RNA AA Sequence GGA GUU CUA CGC Gly – Val – Leu - Arg
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10) Substitution Mutation Substitution – One nitrogenous base is substituted for another. DNA CCC CAA GAT GCG mRNAGGG GUU CUA CGC AAGly – Val – Leu - Arg
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11) Deletion Mutation Deletion – One nitrogenous base is deleted (removed). DNA CTC AAG ATG CG mRNAGAG UUC UAC GC AAGlu – Phe – Tyr
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12) Insertion Mutations Insertion – Extra nitrogenous bases are added to the genetic code. DNA CCT CTA AGA TGC G mRNAGGA GAU UCU ACG C AAGly - Asp – Ser - Thr
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13) Inversion Mutation Inversion – The genetic code is inverted or reversed. DNA CCT CAA TAG GCG mRNAGGA GUU AUC CGC AA Gly – Val – Ile - Arg
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Sickle Cell Anemia
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14) Point and Frame Shift Mutations Point mutation A change in ONE nitrogenous base, the overall number of bases stays the same (Substitution or Inversion) Frame shift mutation A change in the number of overall nitrogenous bases in the genetic code (Addition or Deletion)
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What type of mutation is it?
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Use the chart to complete your hand out
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