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Summary of Eukaryotic Gene Expression

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Presentation on theme: "Summary of Eukaryotic Gene Expression"— Presentation transcript:

1 Summary of Eukaryotic Gene Expression

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5 Video: The Epigenetics of Identical Twins
Genetic Science Learning Center

6 Embryonic Development of Multicellular Organisms
Section 18.4

7 Embryonic Development: Zygote  Organism
Cell Division: large # identical cells through mitosis Cell Differentiation: cells become specialized in structure & function Morphogenesis: “creation of form” – organism’s shape

8 Determination: irreversible series of events that lead to cell differentiation

9 Cytoplasmic determinants: maternal substances in egg distributed unevenly in early cells of embryo

10 Induction: cells triggered to differentiate
Cell-Cell Signals: molecules produced by one cell influences neighboring cells Eg. Growth factors

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12 Pattern formation: setting up the body plan (head, tail, L/R, back, front)

13 Morphogens: substances that establish an embryo’s axes

14 Homeotic genes: master control genes that control pattern formation (eg. Hox genes)

15 Evolving Switches, Evolving Bodies
HHMI Short Film

16 Pitx1 Gene = Homeotic/Hox Gene
Stickleback Fish Humans Development of pelvic bone Development of anterior structures, brain, structure of hindlimb Mutation may cause clubfoot, polydactyly (extra fingers/toes), upper limb deformities

17 Role of Apoptosis Most of the embryonic cells are produced in excess
Cells will undergo apoptosis (programmed cell death) to sculpture organs and tissues Carried out by caspase proteins

18 Cancer results from genetic changes that affect cell cycle control
Section 18.5

19 Control of Cell Cycle: Proto-oncogene = stimulates cell division
Tumor-suppressor gene = inhibits cell division Mutations in these genes can lead to cancer

20 Proto-Oncogene Oncogene
Gene that stimulates normal cell growth & division Mutation in proto-oncogene Cancer-causing gene Effects: Increase product of proto- oncogene Increase activity of each protein molecule produced by gene

21 Proto-oncogene  Oncogene

22 Genes involved in cancer:
Ras gene: stimulates cell cycle (proto- oncogene) Mutations of ras occurs in 30% of cancers p53 gene: tumor-suppresor gene Functions: halt cell cycle for DNA repair, turn on DNA repair, activate apoptosis (cell death) Mutations of p53 in 50+% of cancers

23 Cancer results when mutations accumulate (5- 7 changes in DNA)
Active oncogenes + loss of tumor-suppressor genes The longer we live, the more likely that cancer might develop

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26 Summary Embryonic development occurs when gene regulation proceeds correctly Cancer occurs when gene regulation goes awry

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