1 / 28

DNA,RNA,protein synthesis

DNA,RNA,protein synthesis. DNA Model / 3.1. Using Chapter 11 in the textbook, answer the first three questions on the activity sheet. (5min.) Create one model of 4 nucleotides as a table. Reminders: Label the front of all pieces as you cut them out.

kellsie
Télécharger la présentation

DNA,RNA,protein synthesis

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. DNA,RNA,protein synthesis

  2. DNA Model / 3.1 • Using Chapter 11 in the textbook, answer the first three questions on the activity sheet. (5min.) • Create one model of 4 nucleotides as a table. Reminders: • Label the front of all pieces as you cut them out. • Build the individual nucleotides first before you connect them. • Ask for confirmation before gluing or taping (#2-4)

  3. Deoxyribonucleic Acid. DNA is the code for making proteins. Proteins make you who you are  • Found in all cells!!!!!!!!!!! Only eukaryotes keep DNA in a nucleus. • What is it made of? The monomer of DNA is a nucleotide -deoxyribose, phosphate, and one base form a DNA nucleotide. • Draw one!

  4. The 4 nucleotides of DNAIf you are building a DNA model that contains 4 unique nucleotides, how many sugars would you need? How many phosphates? How many bases?

  5. Formation-Twisted Ladder or Double Helix • two nucleotides pair up in the middle to make a “rung” • Each “rung” must be the same size. • Therefore the base pairing rules are: • Adenine binds with Thymine • Guanine binds with Cytosine • These are held together by WEAK hydrogen bonds. • Strong bonds hold the sides together (sugar-phosphates)

  6. Hierarchy • Genome-the entire set of an organisms DNA • Chromosome-Chromatid-Chromatin-Gene-Codon-Nucleotide • As you move through this list the size gets smaller.

  7. DNA/RNA/Replication Diagram / 3.1 25 pts. • Read the sections labeled: DNA-The Double Helix Color diagram 1. Follow the colors in the reading. 10 min. • Read the section labeled: DNA Replication Color diagram 2. Follow all colors from the reading. 10 min. • Read the section labeled: Messenger RNA Color code diagram 3. Answer questions #1-18 in your notebook. 20 minutes.

  8. DNA Replication • Copying the entire set of DNA in an organism. • When would an organism need to replicate the DNA in cells? • In preparation for mitosis • IN THE NUCLEUS: • Each single strand of DNA acts as a template for the new strand. • Enzymes control DNA replication. DNA polymerase. • 2 DNA strands now consists of a new and old strand. This is called semi-conservative replication.

  9. RNA • Ribonucleic Acid – Read and highlight how RNA is different from DNA. • Color! • The monomer of RNA is a nucleotide. • ribose, phosphate, and one base form a RNA nucleotide. • Bases in RNA • Cytosine binds with Guanine • Adenine binds with Uracil (what??!!) • RNA is responsible for using the DNA code to create proteins. • RNA is single stranded most of the time so it can move in and out of the nucleus.

  10. Types of RNA • mRNA (messenger)-takes the message for proteins out of the nucleus • tRNA (transfer)-transfers in the amino acids • rRNA (ribosomal)-makes the ribosome

  11. Building A Protein • A gene is a sequence of nucleotide bases that code for a protein (a few hundred to thousands). • Nucleotides  codons  genes  proteins  traits • This process takes two steps: Transcription and Translation • DNA is transcribed (read) into RNA • RNA is translated into a protein

  12. Transcription • DNA is split and the code is copied into mRNA nucleotides are added. • Transcription must occur because DNA contains the instructions for making proteins but it CANNOT leave the nucleus • Transcription is controlled by enzymes in the nucleus. • This strand of mRNA nucleotides breaks off and moves to the ribosomes for translation. • What is a codon????

  13. Types of RNA • mRNA (messenger)-takes the message for proteins out of the nucleus • tRNA (transfer)-transfers in the amino acids • rRNA (ribosomal)-makes the ribosome

  14. Translation • Once the DNA has been transcribed into mRNA now we need to translate (change) it into proteins. • Translation occurs at the ribosome. • tRNA anti-codons match with the mRNA codons and bring in amino acids. • Amino acids are connected by peptide bonds (=polypeptide) • This continues until the “stop” codon is reached (UAA, UAG, UGA)

  15. Mutation Notes / 3.2 CTT TTA TAG TAG ATA CCA CAA AGG • Write the mRNA that would be transcribed from this gene. • What amino acids would form the protein coded by this gene? (use the chart) • What tRNA anticodons would bring the amino acids to the ribosome in translation?

  16. Mutation Notes / 3.2 CTT TTA TAG TAG ATC CCA CAA AGG A mutation occurred that changed substituted one nucleotide. • Write the mRNA that would be transcribed from this mutated gene. • What amino acids would form the protein coded by this gene? (use the chart) • Is the protein the same?

  17. Mutation Notes / 3.2 • Mutations result when a nucleotide or group of nucleotides is changed in DNA. • These “mistakes” can occur in replication, transcription or translation. • Mutations can be caused by heredity, mistakes, environmental factors such as UV, chemicals or X-rays. • Some mutations can be lethal. Some mutations are “silent”. Others may be beneficial (usually in smaller organisms)

  18. Point mutations – only one nucleotide is substituted. These may OR may not be harmful if the new codon codes for the same amino acid on the chart. Ex. Sickle Cell Anemia • Frameshift mutations-mutation causing the codons to be inappropriately grouped or shifted. • Addition or Deletion • These mutations are harmful! THE CAT ATE THE BIG RAT

  19. Summary • DNA mutations can happen during any process-replication, transcription or translation. • Mutations are not always harmful. • Frameshitfs are the most harmful mutations. • Any mutation is more harmful if it occurs early in the gene.

More Related