Genes, Proteins, Transcription & Translation

1. Genes, Proteins, Transcription & Translation Ch. 11.4-11.5

2. Review • DNA Structure • What does a double helix consist of? • What are the base pairing rules? • What are the steps of Replication • DNA strands unzip • Help of replication bubbles • New bases attached to old strand • New strand formed

3. Objectives • Trace info flow from DNA --> protein • Describe DNA transcription • Describe how RNA is translated to protein

4. Protein Synthesis Analogy • The synthesis of proteins from genes is a two-step process: • As in house construction, first the plans must be found in the planning dept. and photocopied. (Transcription) • The blueprints are taken to a construction site, read, and “translated” into walls, roof, etc. (Translation)

5. The DNA Alphabet • Language of genes • written in sequence of bases on DNA strand • Each base is a “letter” • How many letters in the “gene” alphabet? • Each gene is a “sentence” • Human’s have 30,000 to 35,000 genes!

6. The Human Genome: Our Instruction Book Cool Facts! • 3 billion letters long! • We consist of 100 trillion cells! • Every cell contains copies of DNA (3 billion letters!) • DNA in one cell is about 6 feet in length (if unraveled).

7. How do scientists do it?Sequencing the Genome

8. Why do we care about proteins? • Proteins are body’s worker molecules • Involved in structure (hair, muscles, enzymes, etc) • Here is one example and a brief summary of how proteins are made . . . • Online Activity 11.4

9. The Information FlowProtein Synthesis in a Nutshell • DNA --> RNA --> Protein • RNA: • Ribonucleic Acid • RNA contains the base Uracil (U) INSTEAD of Thymine(T) • What will A on the DNA pair with on the RNA if there is no T? • U! • If you have an A look for the T. If no T, then use U.

10. Protein Synthesis Transcription & Translation2 steps • Transcription: • Messenger RNA (mRNA) transcribes message from DNA • Message contains directions on how to make protein • Pairs with one strand of DNA bases • Remember, U pairs with T • Exits nucleus with directions for making proteins • Same message, different form

11. Protein Synthesis Transcription & Translation 2. Converting nucleic acid language (mRNA) into amino acid language • mRNA meets up with Transfer RNA (tRNA) • tRNA = the interpreter • Attaches to ribosome

12. tRNA deciphers language by reading codons on mRNA • Codon: • a three-base “word” • Codes for one amino acid • Translation: • Converts nucleic acid language into amino acid language • Russian to English • How does the translation of codons work?

13. Understanding Codons on the mRNA • Each codon stands for a particular amino acid • How do we read this table? • If mRNA has a codon AUG, what is the amino acid? • methionine • What about CAG? • glutamine • What about CCC? • proline • What about UGA? • List of the 20 amino acids

15. Protein Synthesis continued • tRNA’s match up with appropriate codons on mRNA. • They bring amino acids with them • Amino acids connect and form polypeptide (protein)

16. Proteins and mRNA

17. Candy Factory Analogy

18. What it all means • With the help of ribosomes, mRNA is converted into individual amino acids • These amino acids form a polypeptide • This determines who you are and how your body operates! • Hopefully these short animations will make this process more clear . . . • Activity 11.5 • Narrated short animation • Wisconsin site with animation • Lewport's animation • Protein synthesis activity with overhead projector - building a chain . . . • Protein synthesis activity –moving around the classroom