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Control of Gene Expression

Control of Gene Expression. Chapter 16. Contolling Gene Expression. What does that mean? Regulating which genes are being expressed transcribed/translated i.e. made into proteins Not all genes are expressed all of the time. Controlling Gene Expression.

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Control of Gene Expression

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  1. Control of Gene Expression Chapter 16

  2. Contolling Gene Expression What does that mean? • Regulating which genes are being expressed • transcribed/translated • i.e. made into proteins • Not all genes are expressed all of the time

  3. Controlling Gene Expression Why do cells control gene expression? • Each cell in an organism contains the exact same set of DNA (i.e. 6 billion bp, ~30,000 genes) • What is the difference, then, between a skin cell and a nerve cell? • The proteins found within the cell, i.e. the genes that are expressed • Allows for the process of differentiation

  4. Controlling Gene Expression • All organisms regulate when and for how long a gene is on • This regulation allows for the conservation of energy • In eukaryotes differential gene expression is what creates the different cell types • Too much or too little expression can lead to disease, aging, etc.

  5. Control of Genes • Regulatory proteins interact with DNA, RNA or other proteins to control the expression of genes • Transcription factors are regulatory proteins which interact with DNA at specific sequences to regulate gene activity Two types of control: • Negative control slows down or stops gene activity • Positive control promotes gene activities

  6. Gene Control in Prokaryotes • No nucleus separates DNA from ribosomes in cytoplasm • Translation occurs even before mRNA transcripts are finished • Control functionally related genes together by grouping them into units called Operons • E.g. enzymes in a biosynthesis pathway

  7. Operons in Prokaryotes • Consist of a Regulatory Gene, Operator, Promoter and the Structural genes they control • Transcription of these genes is initiated by one promoter, and controlled by a single operator • Transcribes as 1 unit, and a single mRNA is made, which is later translated into one polypeptide, which is later cleaves into individual proteins - polycistronic

  8. Polycistronic Expression

  9. Inducible Operon - Lac Operon • Encodes genes necessary to process lactose • Not needed unless lactose is present • If there is no lactose: Lac Operon Regulatory gene Operator Structural genes not transcribed RNA Polymerase Repressor

  10. Inducible Operon - Lac Operon What happens when lactose is present? Need to make lactose-digesting enzymes Lactose binds allosterically to regulatory protein:

  11. Inducible vs. Repressible Operons Inducible operon (e.g. Lac operon) • usually functions in catabolic pathways, digesting nutrients to simpler molecules • produce enzymes only when nutrient is available • cell avoids making proteins that have nothing to do Repressible operon (e.g. Tryp operon) • usually functions in anabolic pathways synthesizing end products • when end product is present cell allocates resources to other uses

  12. Eukaryotic Gene Expression • MUCH more complicated that prokaryotic control • Most genes in eukaryotic cells are turned off at any given point • Only 5-10% of genes are being expressed at any point • Controlling gene expression occurs at several different points in the process:

  13. Mechanisms of Gene Control in Eukaryotes

  14. Chromatin Structure • Eukaryotic DNA wraps around histones, is further structured into nucleosomes • Promoters inaccessible • Chromatin remodelingmakes gene promoters more accessible • Activators recruit remodeling complexes that displace nucleosomes • Activators recruit enzyme that acetylates and loosens histone assocation with DNA

  15. Chromatin Remodeling

  16. Eukaryotic gene organization Transcription unit of gene Enhancer Promoter Exon Intron Intron Exon Exon DNA Regulatory sequences TATA box 5' UTR 3' UTR

  17. Transcription in Eukaryotes • Transcription factors bind to the TATA sequence within the promoter of gene to be transcribed • RNA polymerase binds to the transcription factors (initiates low levels of transcription) • Activators bind to enhancer sequences (may be located far from the gene) • Activators bind to RNA polymerase and trigger it to begin transcription (high level of transcription)

  18. Transcription in Eukaryotes Initial general transcription factor The first general transcription factor recognizes and binds to the TATA box of a protein-coding gene’s promoter. 1 DNA TATA box Site where transcription starts Promoter Additional general transcription factors RNA polymerase Additional general transcription factors and then RNA polymerase add to the complex, and then transcription begins. 2 DNA Transcription begins Transcription complex

  19. Controlling transcription in Eukaryotes

  20. Transcription regulation in Eukaryotes DNA sequences Proteins Transcription factors Activators Inhibitors • Promoters • Enhancers • Other regulatory sequences

  21. Eukaryotic Gene Expression • Regulates cell cycle • Controls development (Homeo box genes) • Controls differentiation ….and lots, lots more!

  22. Apoptosis • Programmed cell death • Signals unleash molecular weapons of self-destruction • Cancer cells do not commit suicide on cue

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