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Control of Eukaryotic Genes

Control of Eukaryotic Genes. The BIG Questions…. How are genes turned on & off in eukaryotes? How do cells with the same genes differentiate to perform completely different, specialized functions?. Development: cellular level. Cell division Differentiation

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Control of Eukaryotic Genes

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  1. Control of Eukaryotic Genes

  2. The BIG Questions… • How are genes turned on & off in eukaryotes? • How do cells with the same genes differentiate to perform completely different, specialized functions?

  3. Development: cellular level • Cell division • Differentiation • cells become specialized in structure & function • if each kind of cell has the same genes, how can they be so different • shutting off of genes = loss of totipotency • Morphogenesis • “creation of form” = give organism shape • basic body plan • polarity • one end is different than the other • symmetry • left & right side of body mirror each other • asymmetry • pssst, look at your hand…

  4. Development: step-by-step • Gamete formation • Fertilization • Cleavage (cell division, mitosis) • Gastrulation (morphogensis) • Organ formation (differentiation) • Growth & tissue formation (differentiation)

  5. Evolution of gene regulation • Prokaryotes • single-celled • evolved to grow & divide rapidly • must respond quickly to changes in external environment • exploit transient resources • Gene regulation • turn genes on & off rapidly • flexibility & reversibility • adjust levels of enzymes for synthesis & digestion

  6. Cell signaling • Regulating the expression of genes that affect the developmental fate of the cell

  7. Gastrulation • zygote  blastula  gastrula How you looked as a blastula…

  8. Gastrulation • Cells change size & shape: sheets of cells expand & fold inward & outward Changes in cellshape involvereorganizationof cytoskeleton

  9. Stem cells pluripotent cells

  10. Evolution of gene regulation • Eukaryotes • multicellular • evolved to maintain constant internal conditions while facing changing external conditions • homeostasis • regulate body as a whole • growth & development • long term processes • specialization • turn on & off large number of genes • must coordinate the body as a whole rather than serve the needs of individual cells

  11. Master control genes • Homeotic genes • master regulatory genes • in flies these genes identify body segments & then turn on other appropriate genes to control further development of those body sections

  12. Homeotic genes • Mutations to homeotic genes produce flies with such strange traits as legs growing from the head in place of antennae. • structures characteristic of a particular part of the animal arise in wrong place antennapedia flies

  13. Homeobox DNA • Master control genes evolved early • Conserved for hundreds of millions of years • Homologous homeobox genes in fruit flies & vertebrates • kept their chromosomal arrangement

  14. Evolutionary Constraints on Development • Basic body plans of the major animal groups have not changed due to a limited number of homeotic genes (master genes) • These genes have imposed limits • taxonomic / evolutionary • physical • architectural

  15. Points of control • The control of gene expression can occur at any step in the pathway from gene to functional protein 1. packing/unpacking DNA 2. transcription 3. mRNA processing 4. mRNA transport 5. translation 6. protein processing 7. protein degradation

  16. 1. DNA packing How do you fit all that DNA into nucleus? • DNA coiling & folding • double helix • nucleosomes • chromatin fiber • looped domains • chromosome from DNA double helix to condensed chromosome

  17. 8 histone molecules Nucleosomes • “Beads on a string” • 1st level of DNA packing • histone proteins • 8 protein molecules • positively charged amino acids • bind tightly to negatively charged DNA DNA packing movie

  18. DNA packing as gene control • Degree of packing of DNA regulates transcription • tightly wrapped around histones • no transcription • genes turned off • heterochromatin darker DNA (H) = tightly packed • euchromatin lighter DNA (E) = loosely packed H E

  19. DNA methylation • Methylation of DNA blocks transcription factors • no transcription  genes turned off • attachment of methyl groups (–CH3) to cytosine • C = cytosine • nearly permanent inactivation of genes • ex. inactivated mammalian X chromosome = Barr body

  20. Histone acetylation • Acetylation of histones unwinds DNA • loosely wrapped around histones • enables transcription • genes turned on • attachment of acetyl groups (–COCH3) to histones • conformational change in histone proteins • transcription factors have easier access to genes

  21. 2. Transcription initiation • Control regions on DNA • promoter • nearby control sequence on DNA • binding of RNA polymerase & transcription factors • “base” rate of transcription • enhancer • distant control sequences on DNA • binding of activator proteins • “enhanced” rate (high level) of transcription Control of transcription movie

  22. Model for Enhancer action • Enhancer DNA sequences • distant control sequences • Activator proteins • bind to enhancer sequence & stimulates transcription • Silencer proteins • bind to enhancer sequence & block gene transcription Turning on Gene movie

  23. Transcription complex Activator Proteins • regulatory proteins bind to DNA at distant enhancer sites • increase the rate of transcription Enhancer Sites regulatory sites on DNA distant from gene Enhancer Activator Activator Activator Coactivator E F B RNA polymerase II H TFIID A Coding region T A T A Core promoter and initiation complex Initiation Complex at Promoter Site binding site of RNA polymerase

  24. 3. Post-transcriptional control • Alternative RNA splicing • variable processing of exons creates a family of proteins

  25. 4. Regulation of mRNA degradation • Life span of mRNA determines amount of protein synthesis • mRNA can last from hours to weeks RNA processing movie

  26. NEW! RNA interference • Small interfering RNAs (siRNA) • short segments of RNA (21-28 bases) • bind to mRNA • create sections of double-stranded mRNA • “death” tag for mRNA • triggers degradation of mRNA • cause gene “silencing” • post-transcriptional control • turns off gene = no protein produced siRNA

  27. Hot…Hotnew topicin biology Action of siRNA dicerenzyme mRNA for translation siRNA double-stranded miRNA + siRNA breakdownenzyme (RISC) mRNA degraded functionally turns gene off

  28. 1990s | 2006 RNA interference RNAi http://www.pbs.org/wgbh/nova/body/rnai.html “for their discovery of RNA interference —gene silencing by double-stranded RNA” Craig Mello U Mass Andrew Fire Stanford

  29. 5. Control of translation • Block initiation of translation stage • regulatory proteins attach to 5' end of mRNA • prevent attachment of ribosomal subunits & initiator tRNA • block translation of mRNA to protein

  30. Control of Translation • http://www.hhmi.org/biointeractive/translation-advanced-detail

  31. 6-7. Protein processing & degradation • Protein processing • folding, cleaving, adding sugar groups, targeting for transport • Protein degradation • ubiquitin tagging • proteasome degradation Protein processing movie

  32. 1980s | 2004 Ubiquitin • “Death tag” • mark unwanted proteins with a label • 76 amino acid polypeptide, ubiquitin • labeled proteins are broken down rapidly in "waste disposers" • proteasomes Aaron Ciechanover Israel Avram Hershko Israel Irwin Rose UC Riverside

  33. Proteasome • Protein-degrading “machine” • cell’s waste disposer • breaks down any proteins into 7-9 amino acid fragments • cellular recycling

  34. Gene Regulation 7 6 protein processing & degradation 1 & 2. transcription - DNA packing - transcription factors 3 & 4. post-transcription - mRNA processing - splicing - 5’ cap & poly-A tail - breakdown by siRNA 5. translation - block start of translation 6 & 7. post-translation - protein processing - protein degradation 5 4 initiation of translation mRNAprocessing 2 1 initiation of transcription mRNA protection 4 mRNA splicing 3

  35. Epigenetics For more than a decade, scientists have had access to a reference human genome. Now, the equivalent for the epigenome has been published, in a collection of papersappearing on 18 February in Nature and several other journals.

  36. Researchers looked for features including chemical tweaks to DNA that prime genes to be switched on or off, and alterations to the 'histone' proteins around which DNA is wrapped. Chemical or structural modifications to histones can affect which genes the cellular machinery translates into proteins and which remain silent. Such epigenetic changes can dramatically affect a cell’s behaviour and function. • The epigenomes also contain hints of how epigenetic changes could be involved in diseases, including cancer, Alzheimer's disease and autoimmune diseases. • Taken together, the work demonstrates how a cell’s epigenome is complex and exquisitely arranged — just like a Beethoven symphony.

  37. Epigenome The Symphony in Your Cells • Nature Video • http://www.nature.com/news/epigenome-the-symphony-in-your-cells-1.16955

  38. Gene Control in Eukaryotes • X-Inactivation

  39. XH XHXh Xh X-inactivation • Female mammals inherit 2 X chromosomes • one X becomes inactivated during embryonic development • condenses into compact object = Barr body • which X becomes Barr body is random • patchwork trait = “mosaic” patches of black tricolor catscan only befemale patches of orange

  40. Turn yourQuestion Genes on!

  41. Gene Regulation in Eukaryotes • http://www.hhmi.org/biointeractive/regulation-eukaryotic-dna-transcription

  42. Gene Regulation 7 6 1 & 2. _________________ - ____________________ - ____________________ 3 & 4. _________________ - ____________________ - ____________________ - ____________________ - ____________________ 5. _________________ - ____________________ ____________________ 6 & 7. _________________ - ____________________ - ____________________ 5 4 2 1 4 3

  43. Kim Foglia • As always a huge thank you to Kim for her most most most excellent work

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