1 / 27

The Code of Life: Topic 3

The Code of Life: Topic 3. Gene expression (protein synthesis). What's in your genes?. Genes are sequences of nucleotides along DNA strands. Genes (100s-1000s of nucleotides long) code for polypeptides. Your genotype is the actual sequence of DNA that you inherited from your parents.

avel
Download Presentation

The Code of Life: Topic 3

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. The Code of Life: Topic 3 Gene expression (protein synthesis)

  2. What's in your genes? • Genes are sequences of nucleotides along DNA strands. • Genes (100s-1000s of nucleotides long) code for polypeptides. • Your genotype is the actual sequence of DNA that you inherited from your parents. • The expression of those genes results in your phenotype, or how you look.

  3. The big question… How do we go from this to this? DNA An organism

  4. The Central Dogma DNA RNA Polypeptide Protein Universal genetic code of life

  5. RNA • There are 3 major structural differences between RNA and DNA. • There are 3 types of RNA involved in gene expression (protein synthesis): • mRNA • rRNA • tRNA

  6. Types of RNA mRNA rRNA tRNA

  7. Gene expression (protein synthesis) Overview

  8. Transcription: copying DNA's message • DNA is stored safely in the nucleus, but proteins are made in the cytoplasm. • RNA carries the instructions for proteins out of the nucleus to the cytoplasm. • The first step is transcription.

  9. Stages of transcription • Three stages: • Initiation • Elongation • Termination • Important notes: • RNA polymerase does all the work • The end product is called a primary RNA transcript • The primary transcript is then modified before leaving the nucleus.

  10. Practice transcribing… If your DNA strand says this… TACAGGTCAGACTTC What will your complementary RNA strand say? AUGUCCAGUCUGAAG

  11. Before the RNA transcript can leave the nucleus, it has to be processed. Step 1: Cap and tail • 5’ cap (GTP): • Provides stability to the mRNA • Point of attachment for a small subunit of the ribosome during translation. • 3’ poly-A tail: • Provides stability to the mRNA • Appears to control the movement of mRNA across the nuclear membrane.

  12. Step 2: RNA splicing 1. removes introns 2. joins exons, creating an mRNA molecule with a continuous coding sequence.

  13. After transcription comes translation (protein synthesis) Transcription Translation

  14. Review: Types of RNA mRNA rRNA tRNA

  15. Translation • During translation, the code carried in mRNA is "translated" into amino acids. • There are 4 nucleotides and 20 amino acids. • Clearly, the nucleotides must be combined somehow in 20 different ways. • mRNA is "read" as codons, combinations of 3 nucleotides. • One codon, AUG, always signals that start of a gene sequence. • Three codons (UAA, UAG, and UGA) are stop signals, ending the formation of a polypeptide. Take a moment to look at your chart. What observations can you make about this code?

  16. Translating practice • What amino acid does each of the following codons correspond to? AAA GCA UGU CAG Lysine • Try these with the wheel: • CCC • AGU • UCA • GUC Alanine Cysteine Proline Glutamine Serine Serine Valine

  17. tRNA: a closer look

  18. Translation: Initiation • The 5' cap of mRNA attaches to a a small ribosome subunit. • The initiator tRNA has the anticodon for the start codon (AUG) on mRNA. • The initiator tRNA always carries the amino acid methionine (MET). • After the initiator tRNA hydrogen bonds to the mRNA, a large ribosomal subunit also attaches.

  19. Translation: Elongation • Amino acids are added on sequentially when the appropriate tRNA matches with the next mRNA codon. • Each new tRNA bonds its anticodon to the complementary codon on the mRNA. • The amino acid from the old tRNA gets passed to the new amino acid on the new tRNA. They form a peptidebond.

  20. Translation: Termination • Once the stop codon of a sequence is reached, the whole complex comes apart and there is now a new polypeptide.

  21. Summary

  22. Imagine the first line is the message in DNA and the rest of the lines are the same message carried in RNA. What is going on? Pinpoint SPECIFIC errors. How do those errors affect the message? thesunwashotbuttheoldmandidnotgethishat the sun was hot but the old man did not get his hat the sun was hot but the ole man did not get his hat the sun was hot but the old man did not get his cat the sun was hot but the old ma. did not get his hat thd esu nwa sho tbu tth eol dma ndi dno tge thi sha t DNA message mRNA message versions (as codons)

  23. Mutations • Mutation - any change in the DNA sequence • Causes of mutations: • Errors in DNA replication (permanent error; 1 in every 100,000,000 bases) • Mutagens • UV light • Radiation • Chemicals • There are 2 major categories of mutations: • Point mutations • Frameshift mutations

  24. mRNA transcribed from normal DNA Point mutations are base pair substitutions.A base pair substitution is when the wrong nucleotide is substituted for the correct one. mRNA transcribed from mutated DNA These mutations may be:silent (no effect, usually last nucleotide in a codon) missense (results in a different amino acid, effect depends on the properties of the new amino) nonsense (premature stop codon)

  25. mRNA transcribed from normal DNA • Frameshift mutation • Insertion • Deletion • In this case the entire sequence after the insertion or deletion is shifted by a whole nucleotide. • After the mutation, none of the amino acids are correct**. • Result: non-functioning polypeptide. mRNA transcribed from mutated DNA ** RARE case of three nucleotides being deleted.

  26. http://www-mic.ucdavis.edu/sklab/genetic%20recomb.htm

More Related