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Gene Regulation and Expression

Gene Regulation and Expression. Learning Objectives. Describe gene regulation in prokaryotes. Explain how most eukaryotic genes are regulated. Relate gene regulation to development in multicellular organisms. Prokaryotic Gene Regulation.

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Gene Regulation and Expression

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  1. Gene Regulation and Expression

  2. Learning Objectives • Describegene regulation in prokaryotes. • Explainhow most eukaryotic genes are regulated. • Relategene regulation to development in multicellular organisms.

  3. Prokaryotic Gene Regulation DNA-binding proteins in prokaryotes regulate genes by controlling transcription. One of the keys to gene transcription in bacteria is the organization of genes into operons.

  4. The Lac Operon When lactose is not present, the lac genes are turned off by regulatory proteins that bind to DNA and block transcription.

  5. Promoters and Operators Located in front of the operon’s three genes are two regulatory regions: A promoter An operator

  6. The Lac Repressor Blocks Transcription When the lac repressor binds to the O region, RNA polymerase cannot reach the lac genes to begin transcription. Repressor protein

  7. Lactose Turns On the Operon When lactose is added to the medium, it diffuses into the cell and attaches to the lac repressor. RNA polymerase Lactose Repressor protein with changed shape

  8. Eukaryotic Gene Regulation A typical eukaryotic gene has a TATA box.

  9. Transcription Factors By binding DNA sequences in the regulatory regions of eukaryotic genes, transcription factors control the expression of those genes.

  10. Cell Specialization Complex gene regulation in eukaryotes is what makes differentiation and specialization possible.

  11. RNA Interference Small RNA molecules that do not belong to any of the major groups of RNA play a powerful role in regulating gene expression. They do so by interfering with mRNA.

  12. RNA Interference The small interfering RNA molecules fold into double-stranded hairpin loops. The dicer enzyme cuts the double strands into microRNA (miRNA).

  13. RNA Interference The two strands of the loops separate. One of the miRNA pieces attaches to a cluster of proteins, forming a silencing complex.

  14. RNA Interference Blocking gene expression by means of an miRNA silencing complex is known as RNA interference.

  15. The Promise of RNAi Technology The discovery of RNAi has made it possible for researchers to switch genes on and off at will, simply by inserting double-stranded RNA into cells. It may provide new ways to treat and perhaps even cure diseases.

  16. Genetic Control of Development Regulating gene expression is important in shaping how a multicellular organism develops. Each of the specialized cell types found in the adult originates from the same fertilized egg cell.

  17. Homeotic, Homeobox, and Hox Genes Homeotic genes regulate organ development. Homeobox genes code for transcription factors. Hox genes determine the identities of each body segment.

  18. Environmental Influences Environmental factors can affect gene regulation. Metamorphosis is an example of how organisms can regulate gene expression in response to change in their environment.

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