Topic 7 Flipped Video Playlist Link
Video Due Dates:
Check Planbook under Class Info Tab. It is hyperlinked at the top. I will edit the due dates here soon!
Check Planbook under Class Info Tab. It is hyperlinked at the top. I will edit the due dates here soon!
PowerPoints Topic 7 AHL
Presentation 1: DNA Structure
Presentation 2: DNA History
Presentation 3: DNA Packaging/Nucleosomes
Presentation 4: DNA Replication
Presentation 5: DNA Sequencing
Presentation 6: Non-coding DNA
Presentation 7: Transcription
Presentation 8: mRNA Processing
Presentation 9: Ribosomes and tRNA
Presentation 10: Translation
Presentation 11: Protein Structure and Destination
Presentation 12: Gene Expression
Presentation 13: Epigenetics
Presentation 2: DNA History
Presentation 3: DNA Packaging/Nucleosomes
Presentation 4: DNA Replication
Presentation 5: DNA Sequencing
Presentation 6: Non-coding DNA
Presentation 7: Transcription
Presentation 8: mRNA Processing
Presentation 9: Ribosomes and tRNA
Presentation 10: Translation
Presentation 11: Protein Structure and Destination
Presentation 12: Gene Expression
Presentation 13: Epigenetics
Notes Packets
Notes Packet 7.1 - DNA Structure and Replication | |
File Size: | 67 kb |
File Type: | docx |
Notes Packet 7.2 - Transcription | |
File Size: | 149 kb |
File Type: | docx |
Notes Packet 7.3 - Translation and Protein Structure | |
File Size: | 620 kb |
File Type: | docx |
Notes Packet 7.2 - Gene Expression | |
File Size: | 635 kb |
File Type: | docx |
Related Links Topics 2 and 7
» What is DNA? What is a Chromosome?
» Crash Course Biology #10: DNA Structure and Replication
» DNA Structure Slide Show
» The Discovery of the Molecular Structure of DNA
» The Double Helix (HHMI)
» Paired DNA Strands (HHMI)
» Chargaff's Ratio (HHMI)
» Hershey-Chase Experiments
» Hershey-Chase Experiments Summary
» Hershey-Chase Experiments Video
» DNA Replication Slide Show
» Meselson & Stahl and Kornberg Experiments
» DNA Replication (HHMI-advanced)
» DNA Replication Animation (DNA Learning Center)
» Visualizing Nucleosomes
» Restriction Enzymes and DNA Recombination
» Gel Electrophoresis Virtual Lab
» DNA Sequencing Animation
» PCR Animation (Wiley)
» PCR Animation (Learn Genetics)
» Transcription and mRNA Processing
» What is DNA? What is a Chromosome?
» Crash Course Biology #10: DNA Structure and Replication
» DNA Structure Slide Show
» The Discovery of the Molecular Structure of DNA
» The Double Helix (HHMI)
» Paired DNA Strands (HHMI)
» Chargaff's Ratio (HHMI)
» Hershey-Chase Experiments
» Hershey-Chase Experiments Summary
» Hershey-Chase Experiments Video
» DNA Replication Slide Show
» Meselson & Stahl and Kornberg Experiments
» DNA Replication (HHMI-advanced)
» DNA Replication Animation (DNA Learning Center)
» Visualizing Nucleosomes
» Restriction Enzymes and DNA Recombination
» Gel Electrophoresis Virtual Lab
» DNA Sequencing Animation
» PCR Animation (Wiley)
» PCR Animation (Learn Genetics)
» Transcription and mRNA Processing
7.1 DNA structure and replication
Essential idea: The structure of DNA is ideally suited to its function.
Nature of science:
Making careful observations—Rosalind Franklin’s X-ray diffraction provided crucial evidence that DNA is a double helix. (1.8)
Understandings:
Applications and skills:
Theory of knowledge:
Aims:
Guidance:
7.2 Transcription and gene expression
Essential idea: Information stored as a code in DNA is copied onto mRNA.
Nature of science:
Looking for patterns, trends and discrepancies—there is mounting evidence that the environment can trigger heritable changes in epigenetic factors. (3.1)
Understandings:
Application and skills:
Guidance:
Theory of knowledge:
7.3 Translation
Essential idea: Information transferred from DNA to mRNA is translated into an amino acid sequence.
Nature of science:
Developments in scientific research follow improvements in computing—the use of computers has enabled scientists to make advances in bioinformatics applications such as locating genes within genomes and identifying conserved sequences. (3.7)
Understandings:
Application and skills:
Guidance:
Essential idea: The structure of DNA is ideally suited to its function.
Nature of science:
Making careful observations—Rosalind Franklin’s X-ray diffraction provided crucial evidence that DNA is a double helix. (1.8)
Understandings:
- Nucleosomes help to supercoil the DNA.
- DNA structure suggested a mechanism for DNA replication.
- DNA polymerases can only add nucleotides to the 3’ end of a primer.
- DNA replication is continuous on the leading strand and discontinuous on the lagging strand.
- DNA replication is carried out by a complex system of enzymes.
- Some regions of DNA do not code for proteins but have other important functions.
Applications and skills:
- Application: Rosalind Franklin’s and Maurice Wilkins’ investigation of DNA structure by X-ray diffraction.
- Application: Use of nucleotides containing dideoxyribonucleic acid to stop DNA replication in preparation of samples for base sequencing.
- Application: Tandem repeats are used in DNA profiling.
- Skill: Analysis of results of the Hershey and Chase experiment providing evidence that DNA is the genetic material.
- Skill: Utilization of molecular visualization software to analyse the association between protein and DNA within a nucleosome.
Theory of knowledge:
- Highly repetitive sequences were once classified as “junk DNA” showing a degree of confidence that it had no role. To what extent do the labels and categories used in the pursuit of knowledge affect the knowledge we obtain?
Aims:
- Aim 6: Students could design models to illustrate the stages of DNA replication.
Guidance:
- Details of DNA replication differ between prokaryotes and eukaryotes. Only the prokaryotic system is expected.
- The proteins and enzymes involved in DNA replication should include helicase, DNA gyrase, single strand binding proteins, DNA primase and DNA polymerases I and III.
- The regions of DNA that do not code for proteins should be limited to regulators of gene expression, introns, telomeres and genes for tRNAs.
7.2 Transcription and gene expression
Essential idea: Information stored as a code in DNA is copied onto mRNA.
Nature of science:
Looking for patterns, trends and discrepancies—there is mounting evidence that the environment can trigger heritable changes in epigenetic factors. (3.1)
Understandings:
- Transcription occurs in a 5’ to 3’ direction.
- Nucleosomes help to regulate transcription in eukaryotes.
- Eukaryotic cells modify mRNA after transcription.
- Splicing of mRNA increases the number of different proteins an organism can produce.
- Gene expression is regulated by proteins that bind to specific base sequences in DNA.
- The environment of a cell and of an organism has an impact on gene expression.
Application and skills:
- Application: The promoter as an example of non-coding DNA with a function.
- Skill: Analysis of changes in the DNA methylation patterns.
Guidance:
- RNA polymerase adds the 5´ end of the free RNA nucleotide to the 3´ end of the growing mRNA molecule.
Theory of knowledge:
- The nature versus nurture debate concerning the relative importance of an individual’s innate qualities versus those acquired through experiences is still under discussion. Is it important for science to attempt to answer this question?
7.3 Translation
Essential idea: Information transferred from DNA to mRNA is translated into an amino acid sequence.
Nature of science:
Developments in scientific research follow improvements in computing—the use of computers has enabled scientists to make advances in bioinformatics applications such as locating genes within genomes and identifying conserved sequences. (3.7)
Understandings:
- Initiation of translation involves assembly of the components that carry out the process.
- Synthesis of the polypeptide involves a repeated cycle of events.
- Disassembly of the components follows termination of translation.
- Free ribosomes synthesize proteins for use primarily within the cell.
- Bound ribosomes synthesize proteins primarily for secretion or for use in lysosomes.
- Translation can occur immediately after transcription in prokaryotes due to the absence of a nuclear membrane.
- The sequence and number of amino acids in the polypeptide is the primary structure.
- The secondary structure is the formation of alpha helices and beta pleated sheets stabilized by hydrogen bonding.
- The tertiary structure is the further folding of the polypeptide stabilized by interactions between R groups.
- The quaternary structure exists in proteins with more than one polypeptide chain.
Application and skills:
- Application: tRNA-activating enzymes illustrate enzyme–substrate specificity and the role of phosphorylation.
- Skill: Identification of polysomes in electron micrographs of prokaryotes and eukaryotes.
- Skill: The use of molecular visualization software to analyse the structure of eukaryotic ribosomes and a tRNA molecule.
Guidance:
- Names of the tRNA binding sites are expected as well as their roles.
- Examples of start and stop codons are not required.
- Polar and non-polar amino acids are relevant to the bonds formed between R groups.
- Quaternary structure may involve the binding of a prosthetic group to form a conjugated protein.