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Homework #2 is posted and due 10/17 Exam key is posted

Altering DNA’s Shape can Alter Gene Expression. Homework #2 is posted and due 10/17 Exam key is posted. How is class going? The speed of lecture is: 1= too slow – 5= too fast After lecture I understand the material: 1= barely – 5= very well Class is enjoyable/interesting: 1= no – 5= yes

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Homework #2 is posted and due 10/17 Exam key is posted

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  1. Altering DNA’s Shape can Alter Gene Expression • Homework #2 is posted and due 10/17 • Exam key is posted

  2. How is class going? The speed of lecture is:1= too slow – 5= too fast After lecture I understand the material:1= barely – 5= very well Class is enjoyable/interesting:1= no – 5= yes The grade that I think I earned on exam 1=0–100

  3. Overview of transcriptional regulation Figure 11-2 Fig 11.2

  4. Mutations in the promoter show critical nucleotides Fig 11.4

  5. Gene Expression is controlled at all of these steps: • DNA packaging • Transcription • RNA processing and transport • RNA degradation • Translation • Post-translational Fig 16.1

  6. Fig 11.10 Different levels of DNA packaging

  7. Tightly packaged DNA is unavailable. DNA packaging changes as the need for different genes changes.

  8. Histones can be post-translationally modified, which affects their abililty to bind DNA. Fig 11.12

  9. Acetylation (-COCH3): post-translational modifications of the histones loosen DNA binding

  10. Acetylation of histones (-COCH3) causes a loosening of the DNA/histone bond…unpackaging the DNA.

  11. Four-stranded DNA: cancer, gene regulation and drug developmentby Julian Leon Huppert Philosophical Transactions of the Royal Society A: Mathematical, Physical and Engineering Sciences Triennial Issue of 'Chemistry and Engineering’DOI: 10.1098/rsta.2007.0011 Published: September 13, 2007

  12. Four-stranded DNA forms between sequences of guanines…G-quadruplexes 4 strand DNA Fig 1

  13. Four-stranded DNA forms between sequences of guanines…G-quadruplexes 4 strand DNA Fig 1

  14. The G-quadruplexes can form from 4, 2, or 1 DNA strand. 4 strand DNA Fig 2

  15. During DNA replication, the ends of the DNA are not completely copied. Fig 7.11

  16. Telomeres are non-gene DNA at the ends of DNA strands. Telomeres are shortened during DNA replication.

  17. Telomeres can be lengthened by telomerase. Fig 7.26

  18. The telomeric cap structure is one place where G-quadruplexes can be found

  19. Telomeres are non-gene DNA at the ends of DNA strands. Short telomeres will cause cells to stop replicating or cell death. The critical size is unknown.

  20. Drugs that can block the action of telomerase, by binding the G-quadruplexes, are being investigated to treat cancer.

  21. Eukaryotic promoters often contain G-rich areas Fig 11.3

  22. G-quadruplex in promoters 4 strand DNA Fig 5

  23. If the promoter is defined as 1 kbase upstream of the transcription start site: • Quadruplex motifs are significantly overrepresented relative to the rest of the genome, by almost an order of magnitude. • almost half of all known genes have a putative quadruplex-forming motif • By comparison, the TATA box motif—probably the best-known regulatory motif and a staple of undergraduate textbooks—is found in only approximately 10% of genes. Four-stranded DNA: cancer, gene regulation and drug development by Julian Leon Huppert in Philosophical Transactions of the Royal Society A: Mathematical, Physical and Engineering Sciences Triennial Issue of 'Chemistry and Engineering’ DOI: 10.1098/rsta.2007.0011 Published: September 13, 2007

  24. Oncogenes, the genes involved in cancer, are especially rich in potentially regulatory quadruplexes—69% of them have such motifs Four-stranded DNA: cancer, gene regulation and drug development by Julian Leon Huppert in Philosophical Transactions of the Royal Society A: Mathematical, Physical and Engineering Sciences Triennial Issue of 'Chemistry and Engineering’ DOI: 10.1098/rsta.2007.0011 Published: September 13, 2007

  25. Werner syndrome, which causes premature aging, is caused by the lack of a helicase that binds to G-quadruplexes. Four-stranded DNA: cancer, gene regulation and drug development by Julian Leon Huppert in Philosophical Transactions of the Royal Society A: Mathematical, Physical and Engineering Sciences Triennial Issue of 'Chemistry and Engineering’ DOI: 10.1098/rsta.2007.0011 Published: September 13, 2007

  26. G-quadruplex ligands TMPyP4 BRACO-19 Down regulates telomerase and some oncogene transcription G-quadruplex telomestatin 4 strandDNAFig 6 Specifically binds to telomeres, naturally occurring in Streptomyces anulatus

  27. Model of specific G-quadruplex ligand binding to G-quadruplex and a specific DNA sequence 4 strand DNA Fig 7

  28. Altering DNA’s Shape can Alter Gene Expression • Homework #2 is posted and due 10/17 • Exam key is posted

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