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Regulation of Gene expression

Regulation of Gene expression. Gene Regulation. Learning Goals: To know and explain: Constitutive ( house keeping) vs. Controllable genes OPERON structure and its role in gene regulation Regulation of Eukaryotic Gene Expression at different levels: DNA methylation

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Regulation of Gene expression

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  1. Regulation of Gene expression

  2. Gene Regulation Learning Goals: To know and explain: • Constitutive ( house keeping) vs. Controllable genes • OPERON structure and its role in gene regulation • Regulation of Eukaryotic Gene Expression at different levels: DNA methylation Histone modifications(Chromatin Remodeling) Increasing the number of gene copies (gene amplification) Changing the rate of initiation of transcription Alternate splicing mRNA stability Changing the rate of initiation of translation Protein stability Hormonal regulation • 11-Regulation by protein stability

  3. Gene Regulation What makes one cell different from another cell? • Regulation not only involves which genes are active or inactive, but also determines the level of activity and the amount of protein that is available in a cell. • Genes which are always active are called constitutive genes, or housekeeping genes.

  4. Control Mechanisms Over 20,000 human genes – but not all are needed as proteins at the same time • It would be energy inefficient to synthesize all of them all the time! • Thus, gene regulation: • The turning on or off of specific genes as required by an organism • But there are still housekeeping genes: • Genes that are continually transcribed and translated because they are vital to the organism’s life functions • And to help, there are transcription factors: • Proteins that bind to DNA that needs to be transcribed to help RNA polymerase bind and transcribe more easily

  5. Gene regulation Gene expression/ regulation can occur at 4 levels: Transcriptional Post-transcriptional Translational Post-translational A promoter is a region of DNA that attracts the RNA polymerase complex to bind and begin transcription.

  6. Gene regulation Regulation in prokaryotes Regulation is required when switching metabolic pathway dependent upon what nutrients are available 3 levels of regulation: During transcription During translation After protein synthesis

  7. Gene regulation OPERON: In prokaryotes, an area that includes a promoter and many genes clustered together under control of a single promoter Genes involved in the same metabolic pathway are often found in the same operon. Genes can be expressed in a single mRNA strand called polycistronic mRNA. **Polycistronic – multiple gene products on the same piece of DNA.

  8. OPERON in gene regulation of prokaryotes Definition:a few genes that are controlled collectively by one promoter Its structure:Each Operon is consisted of few structural genes( cistrons) and some cis-acting element such as promoter (P) and operator (O). Its regulation:There areone or more regulatory gene outside of the Operon that produce trans-acting factors such as repressor or activators. Classification: 1- Catabolic (inducible) such as Lac OPERON 2- Anabolic (repressible) such as ara OPERON 3- Other types An operator is a DNA segment that turns the gene "on" or "off." It interacts with proteins that increase the rate of transcription or block transcription from occurring.

  9. General structure of an OPERON

  10. The lacOperon • E.Coli can adjust gene expression according to the sugar is available. • Genes that encode the enzymes for are needed to break down lactose are found in the lacoperon. The lacoperon consists of a coding region and a regulatory region • Also contains: • Promoter • Operator- a DNA sequence to which a protein binds to inhibit transcription initiation (repressor) • The CAP is a DNA sequence to which a specific protein also binds. The binding of CAP increases the rate of transcription of a gene or genes.

  11. The activity of an Operon in the presence or the absence of repressor No repressor With repressor Figure 8.13

  12. To summarize… Lac Operon • Inducible operon • Repressor (LacI) is usually ON the operator • Repressor changes shape and falls off when the inducer (lactose) binds to the repressor, allowing transcription Trp Operon • Repressible operon • Repressor is usually OFF the operator • Co-repressor (tryptophan) changes the repressor’s shape so it can attach to the operator, blocking transcription

  13. Gene Regulation in Eukaryotes

  14. Gene Regulation in Eukaryotes • Regulation is much more complex: • Pre-transcriptional • Transcriptional • Post-transcriptional • Translational • Post translational

  15. 1- Control at DNA level by DNA methylation • Heterochromatin isthe most tightly packaged form of DNA.transcriptionally silent, different from cell to cell • Methylation is related to the Heterochromatin formation • Small percentages of newly synthesized DNAs (~3% in mammals) are chemically modified by methylation. • Methylation occurs most often in symmetrical CG sequences. • Transcriptionally active genes possess significantly lower levels of methylated DNA than inactive genes. • Methylation results in a human disease called fragile X syndrome; FMR-1 gene is silenced by methylation.

  16. 2- Control at DNA level by Histone modifications(Chromatin Remodeling) • Acetylationby HATs and coactivators leads to euchromatin formation • Methylationby HDACs and corepressors leads to heterochromatin formation

  17. 3-Control at DNA level by gene amplification Repeated rounds of DNA replication yield multiple copies of a particular chromosomal region.

  18. 4- Control at transcription initiation By using different sequences (promoter, enhancer or silencer sequences) and factors, the rate of transcription of a gene is controlled gene X promoter gene control region for gene X

  19. 5- Control at mRNA splicing (alternate splicing) (four exons) 1 4 2 3 1, 2 & 4 1, 2 & 3 cell 2 cell 1 Calcitonin gene-related peptide 61 32 amino acids Reduces bone resorption 37 amino acids Vasodilator

  20. 6- Control at mRNA stability • Some hormones which enhance the production of proteins also increase the half life of the protein’s mRNA. • Estrogen : ovalbumin t1/2 from 2- 5hr to >24hr • Prolactin : casein t1/2 from 5 hr to 92hr

  21. 7- Control at initiation of translation 3’ UTR 5’ UTR AUG UAA Specific sequences make specific secondary structures Specific protein factors bind to these secondary structures

  22. COOH NH NH2 NH2 CO CO NH 8-Regulation by protein stability • Ubiquitin-dependent proteolysis. Cyclins control of cell cycle. • Protein molecule is tagged for degradation by attachment of a 20 kDa protein, ubiquitin ATP + 26S proteasome Doomed protein molecule • ubiquitin protein ligase • The stability of a protein depends upon its N-terminal amino acid (the N-end rule). • N-terminal : For example arginine , lysine : protein t1/2 = 3 min • N-terminal : For example methionine, alanine, : t1/2 >20 hrs.

  23. Regulation by water soluble Hormones

  24. Regulation by lipid soluble Hormones Steroid hormones pass through the cell membrane and bind cytoplasmic receptors, which together bind directly to DNA and regulate gene expression.

  25. Insert your summary here.......

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