1 / 29

Regulation of Gene Expression Ch. 16.1-16.2;16.4-16.5

Regulation of Gene Expression Ch. 16.1-16.2;16.4-16.5. 1 Embryo  200 Cell Types. From a single embryo, 200 types of cells can be produced ( differentiation ) Diversity comes from genes being turned off Expression of the genes lead to specialization of the cell

leiko
Download Presentation

Regulation of Gene Expression Ch. 16.1-16.2;16.4-16.5

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. Regulation of Gene ExpressionCh. 16.1-16.2;16.4-16.5

  2. 1 Embryo 200 Cell Types • From a single embryo, 200 types of cells can be produced (differentiation) • Diversity comes from genes being turned off • Expression of the genes lead to specialization of the cell • Transcriptional regulation controlling the expression of genes • post-transcriptional effect mRNA • Translational protein translation • Post-translational life span/activity of protein

  3. Regulation in Prokaryotes • Adjust biochemistry quickly as environment changes • Jacob and Monod extensive studies into the effects of lactose on expression of lactase genes • Operon regulatory sequence in DNA for a specific gene(s) + the genes • Regulatory proteins bind to operons to promote or inhibit the transcription of transcription unit (single mRNA coded in the operon)

  4. Regulation of an Operon • Operator section at the start of the operon • Activator protein attaches to operator to promote expression • Repressor protein attaches to operator to inhibit expression • Gene coding for regulatory proteins (activators/repressors) are called regulatory genes • Non-regulating proteins come from structural genes

  5. The lac Operon • 3 genes: • lacZ codes for β-galactosidase; breaks lactose into glucose + glactose • lacYcodes for permease; actively transports lactose into the cell • lacA codes for transacetylase; We don’t know what it does • Negatively regulated • Regulator gene lacI codes for Lac repressor • Limits lac expression when lactose is absent (normal) • When lactose is added, it is made into allolactose(inducer for lac operon) • Inhibits lac repressor by binding to it

  6. Lac Operon Part II; Positive Regulation • Lac operon is repressed in the presence of lactose if glucose is also added. Why? • Glucose is a better source of energy • Converting lactose into usable sugars (glucose) requires energy • CAP (catabolite activator protein) activator synthesized in an inactive form; activated by cAMP (produced when glucose is absent) • Active form binds to CAP site at the lac operon promoter allowing RNA Poly to attach • If we add glucose, cAMP levels drop so CAP is deactivated and RNA Poly can bind to the DNA

  7. trp Operon and Protein Synthesis • Some proteins, like tryptophan, must be synthesized when not present to be absorbed • trp Operon codes enzymes needed to make tryptophan; regulated by trpR (repressor) that is normally inactive; trp operon used to make tryptophan • When tryptophan levels are high, the repressor is active and trp operon is blocked (repressible operon) • Tryptophan is a corepressor; activates repressor

  8. Regulation in Eukaryotes • Eukaryotes do not have operons; regulatory gene are spread across the genome (side effect of variation) • Eukaryotes use all forms of gene regulation: • Transcriptional Regulation • Post-transcriptional regulation • Translational regulation • Post-translational regulation

  9. Transcriptional Regulation • Promoter region of DNA upstream (~25bp) from the transcription unit • TATA Box 7-bp sequence 5’-TATAAAA-3’ • TFs (transcription factors) recognize TATA and bind to it; then RNA Poly II can bind • Further upstream are the regulator sequences (promoter proximal elements) in the promoter proximal region • Regulatory proteins bind here to enhance or repress transcription

  10. Activators and Transcription • RNA Poly II + TFs transcription initiation complex; not that efficient • Activators proteins that help the complex attach and start translation • Activators can be specific (one cell type for one gene) or general (multiple genes in all cell types) which are also called Housekeeping genes • Enhancer regions on the DNA can increase transcription rate by interacting with activators (act as coactivators) by bending DNA into a loop

  11. Motifs in DNA Binding Proteins • Domains structures in a protein made from the combination of secondary folding options (helix, sheet, coil) • Ex. Helix-helix-coil-helix • Motif specialized domains conserved in different types of proteins • DNA interacting Motifs: • Helix-turn-helix DNA binding region of protein • Zinc Finger finger shape with zinc ion; bind to DNA grooves • Leucine zipper dimers held together by hydrophobic regions; bind to major groove of DNA

  12. Combinational Gene Regulation • Regulation of most genes in more complex than just activation or repression • Genes can have multiple activators and repressors • These regulation points between different genes overlap and follow the stronger influence • Gene A is regulated by enhancer regions 1, 2 and 3; Gene B is regulated by enhancer 2, 3, and 4 • Activators on 2 and 3 will produce A and B proteins • Repressors on 3, and 4 will limit B protein a great deal and A proteins a little bit

  13. Coordinated Regulation • Proteins can be regulated in complex organisms across many types of tissues through chemical signals (hormones) • Steroid Hormone Response Element region in gene that hormone-receptor complex binds to • Allows regulation in several cell types very quickly

  14. Methylation of DNA • DNA methylation adding methyl (-CH3) to cytosine bases • Turn off gene (silencing) by blocking access to promoter region • Epigenetics change in gene expression but no change in the DNA itself • Hemoglobin turned off in all other cell types this way • Genomic Imprinting silencing of one of two alleles during development • Methylated allele is not expressed

  15. Chromatin Structure • Histones can block access to DNA and thus regulate it • Chromatin remodeling changing its structure • Nucleosome remodeling complex moves histones along DNA or reshapes them to open a region • Adding Acetyl Groups (CH3CO-) weakens the interactions between the histones and DNA • Methylation of Histones marks histones wrapped with deactivated DNA

  16. Gene Regulation in Development • Gene regulation is most important during early development; determine the cell-types and physiology of the organism • Regulation sensitive to both time (must all happen in the right order and within a certain window) and place (location in embryo determines location in body) • Understanding comes from our model organisms: • Fruit fly, nematode worm, zebrafish, and house mouse

  17. From Zygote to Fetus • After fertilization, a zygote develops into a fetus through several mechanisms • Mitosis need lots of cells • Movement of cells cells need to form the right shape • Induction cell of a certain type needs neighboring cells to respond to get a result • Determination totipotent cells becomes specific cell types • Differentiation cell types become finalized so tissue and systems can be made

  18. Hold Up Mr. Nucleus…Cytoplasm has something to say… • Not all regulation of a zygote comes from the nucleus • Zygote’s cytoplasm is from the egg used at fertilization • Cytoplasmic determinants • mRNA strands and proteins in cytoplasm of egg also regulate the zygote • Not reproduced during cell divisions; First divisions of zygote separate determinants asymmetrically so each daughter as an uncontrolled amount • Only really take effect during the first few divisions but can last till tissues form • Inherited only on the maternal side

  19. Induction • Major step in the process of determination • Signal molecules from very specific cells (inducers) sent to receptor cells • Two methods: • Signal released and travels short distances to receptors • Cell-to-Cell contact between proteins in the membranes of inducers and receptors

  20. Differentiation • Determination narrows the type of cells possible and differentiation limits to one cell type • Genes required for cell type are left on while other genes are “turned off” • Master regulatory genes promote the transcription of proteins needed to specialize the cell • myoD master gene regulates MyoD transcription factors which promotes skeletal muscle proteins

  21. Physical Position and Regulation • Pattern formation arrangement of organs in the body • Discovered studying the effects of mutations on the embryogenesis of fruit flies • Particular genes control the body plan for all complex organism • Steps required: • Determine front, back, head, and tail (ventral, dorsal, anterior, and posterior) of embryo • Divided zygote into segments • Use segments to map out body plan

  22. Maternal-Effect Genes • Expressed when egg is produced by the mother; mRNAs made from the bicoid gene • Control the anterior-to-posterior polarity of the egg (front to back) • Bicoid protein is produced and the highest conc. marks the anterior (head) and drops as move along to the posterior (butt) which has the lowest conc.

  23. Segmentation Genes • 24 genes divide embryo into regions • 3 Types: • Gap Genes form segments along A-P axis; broad regions • Pair-rule Genes divide broad regions with units of two segments each • Segment polarity Genes sets the boundaries for each segment; each segments needs an A-P axis

  24. Homeotic Genes • Genes specify which segment becomes what; where are the legs, eyes, wings, etc… • Hox genes • 8 Hox genes in fruit flies • Actually occur in order on chromosome (AP) • Found in all animals and is highly conserved • Homeo-Box region in all homeotic genes that codes for its specific homeodomain(TF for its protein)

  25. Genes and Cancer • 2 types of Cancer • Familial Cancer inherited; common with breast, colon, and testicular cancers • Sporadic Cancer occur randomly; more common form; can happen from viruses altering DNA • All cancer is a multi-step process; need several key mutations • 3 Classes of Genes effect cancer frequency: • Proto-oncogens • Tumor suppressor genes • microRNA genes • (not covering this)

  26. Proto-Oncogenes • Genes that stimulate cell division in regular healthy cells • Code for growth factors, signal receptors, transduction components, and TFs • When mutated, they can become overactive oncogens • Only one allele needs mutated to take effect • Mutation in the promoter • Mutation in the transcription unit • Translocation moves gene to a more active promoter or enhancer • Virus adds genes that activate or enhance a gene

  27. Tumor Suppressor Genes • Code for proteins that inhibit cell division • Keep Proto-oncogenes repressed • TP53 codes for p53 that inhibits CDKs used to pass the G1/S checkpoint • If mutated, p53 can’t inhibit division • p53 mutations are in 50% of all cancers • Both alleles must be inactive for a tumor suppressor gene to lose function

  28. Homework • Suggested Homework: • Test Your Knowledge Ch. 16 • Actual Homework: • Discuss the Concepts #1 • Interpret the Data Ch. 16 • Design the Experiment Ch. 16

  29. Assignments for Next Week • PPT Presentations on Ch. 18: • Groups of 3; 12-15 mins long • Topics: • DNA Cloning and Building DNA Libraries • Gel Electrophoresis, Southern Blot, Northern Blot, and Western Blot • DNA Cloning and Bacteria Transformation for Protein Synthesis • BLAST Program and How it is Used • Papers on Ch. 19: • 3 page paper discussing the following: • Darwin’s Journey • Data and Experiments by Darwin • World Reaction to Darwin’s Theories • Basic Principles of Evolution • DO NOT answer these section by section. These are the BIG IDEAS you paper must discuss. It should be a summary of Darwin’s life and impact on Biology

More Related