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1 & 2) Transcription vs. Translation  DNA  mRNA; nucleus  Making a protein; cytoplasm 3) How many tRNA nucleotides form an anticodon? 33.

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Presentation on theme: "1 & 2) Transcription vs. Translation  DNA  mRNA; nucleus  Making a protein; cytoplasm 3) How many tRNA nucleotides form an anticodon? 33."— Presentation transcript:

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2 1 & 2) Transcription vs. Translation  DNA  mRNA; nucleus  Making a protein; cytoplasm 3) How many tRNA nucleotides form an anticodon? 33

3 1) If you knew the amino acid sequence, can you know the DNA code that coded for them?  Work backwards! Amino acid  tRNA anticodon  mRNA codon  DNA template 2) How could 1 change in DNA alter the formation of the translated protein?? (What is this called btw?)  Example: DNA: AGC CGA (original)  4 legged DNA AGC GGA (mutation)  no legs for your Rocky! 

4  The sequences of bases in DNA are like the letters of a coded message… what would happen if a few of those letters changed accidentally, altering the message??  Could the cell still understand its meaning?  Mutation: a mistake or variation in the bases of DNA- mutations are heritable changes in genetic information.

5  Some harmful; Some not  Remember DNA replicates during the S phase of interphase (prior to mitosis). If an error occurs during this process, DNA polymerase usually fixes the mistake. A mutation is the FAILURE of the DNA repair system to fix the error.

6 Point mutations: gene mutations that involve changes in one or a few nucleotides  Substitution: 1 base is changed to a different base in the DNA sequence *think substitute teacher (switch)  Frameshift (Insertion or Deletion): 1 base is inserted or removed from the DNA sequence *think adding another teacher to the room or removing the teacher completely (not going to happen! )

7 Substitution- 1 base gets replaced w/ another Ex: ACCTG AACTG Can lead to change in the codon  change in amino acid  change in protein  change in trait EX: change in protein can cause normal red blood cells to have crescent (sickle shape)

8 Fig. 17-22 Wild-type hemoglobin DNA mRNA Mutant hemoglobin DNA mRNA 3 3 3 3 3 3 5 5 5 5 5 5 CCTT T T G G A A A A AA A GG U Normal hemoglobinSickle-cell hemoglobin Glu Val

9  Silent mutations have no effect on the amino acid produced by a codon because of redundancy in the genetic code  Missense mutations still code for an amino acid, but not necessarily the right amino acid  Nonsense mutations change an amino acid codon into a stop codon, nearly always leading to a nonfunctional protein Copyright © 2008 Pearson Education Inc., publishing as Pearson Benjamin Cummings

10 Fig. 17-23a Wild type 3 DNA template strand 3 3 5 5 5 mRNA Protein Amino end Stop Carboxyl end A instead of G 3 3 3 U instead of C 5 5 5 Stop Silent (no effect on amino acid sequence)

11 Fig. 17-23b Wild type DNA template strand 3 5 mRNA Protein 5 Amino end Stop Carboxyl end 5 3 3 T instead of C A instead of G 3 3 3 5 5 5 Stop Missense

12 Fig. 17-23c Wild type DNA template strand 3 5 mRNA Protein 5 Amino end Stop Carboxyl end 5 3 3 A instead of T U instead of A 3 3 3 5 5 5 Stop Nonsense

13 2) Frame Shift- when a base is either deleted or added. This means the READING FRAME is changed and the bases “downstream” will be regrouped = disastrous results. EX:  Deletion CCAGT  CCGT  Insertion CCAGT  CCAAGT Again, can lead to a change in codon…trait!!!

14  Huntington’s Disease - The triplet CAG is repeated. This adds a string of glutamines to the protein called huntington. This abnormal protein increases the level of p53 protein in brain cells causes their death by apoptosis. This degeneration causes uncontrolled movements, loss of intellectual faculties and emotional disturbance.  Muscular Dystrophy - CTC and CCTG repeats. This disease is characterized by the progressive weakness and degeneration of the skeletal muscles.

15  Insertion of 2 nucleotides (A & T) - 2566  Deletion of one C - 3659  Deletion of 3 nucleotides at 1654-1656  Generally results in abnormal amounts of salt which leads to a thick sticky mucus coating which coats cells - particularly the lungs.

16 Harmful Effects: Those that dramatically change protein structure or gene activity. *Example: Some cancers are the product of mutations that cause uncontrolled cell growth of cells. Beneficial Effects: Those that produce proteins with new or altered functions that may be useful to organisms in different/changing environments. *Example mutations have allowed for insects to resist chemical pesticides. Good for insects, bad for farmers & our food!

17  Mutagens are external agents that cause mutations. EX:  Radiation from x-rays, UV light  Viruses - human papilloma virus  Environmental poisons- tobacc0  Carcinogens-cancer causing chemical(s)

18  Cancer causing genes that can affect the division and differentiation of a cell. These may be turned “on” by the presence of a carcinogen and lead to cancer

19 Spontaneous change involving an entire chromosome or pieces of a chromosome More to come during Meiosis…..


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