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Regulation of Gene Expression

Explore various mechanisms used to regulate gene expression across prokaryotic and eukaryotic systems, with a focus on operons, transcription factors, and viral gene regulation strategies. Understand how cellular and viral genes interact in gene expression control.

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Regulation of Gene Expression

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  1. 11 Regulation of Gene Expression

  2. Chapter 11 Regulation of Gene Expression • Key Concepts • 11.1 Several Strategies Are Used to Regulate Gene Expression • 11.2 Many Prokaryotic Genes Are Regulated in Operons • 11.3 Eukaryotic Genes Are Regulated by Transcription Factors and DNA Changes • 11.4 Eukaryotic Gene Expression Can Be Regulated after Transcription

  3. Chapter 11 Opening Question How does CREB regulate the expression of many genes?

  4. Concept 11.1 Several Strategies Are Used to Regulate Gene Expression • Gene expression is tightly regulated. • Gene expression may be modified to counteract environmental changes, or gene expression may change to alter function in the cell. • Constitutiveproteins are actively expressed all the time. • Inducible genes are expressed only when their proteins are needed by the cell.

  5. Figure 11.1 Potential Points for the Regulation of Gene Expression

  6. Concept 11.1 Several Strategies Are Used to Regulate Gene Expression • Genes can be regulated at the level of transcription. • Gene expression begins at the promoter where transcription is initiated. • In selective gene transcription a “decision” is made about which genes to activate. • Two types of regulatory proteins—also called transcription factors—control whether a gene is active.

  7. Concept 11.1 Several Strategies Are Used to Regulate Gene Expression • These proteins bind to specific DNA sequences near the promoter: • Negative regulation—a repressor protein prevents transcription • Positive regulation—an activatorprotein binds to stimulate transcription

  8. Figure 11.2 Positive and Negative Regulation (Part 1)

  9. Figure 11.2 Positive and Negative Regulation (Part 2)

  10. Concept 11.1 Several Strategies Are Used to Regulate Gene Expression • Acellular viruses use gene regulation to take over host cells. • A phage injects a host cell with nucleic acid that takes over synthesis. • New viral particles (virions) appear rapidly and are soon released from the lysed cell. • This lytic cycle is a typical viral reproductive cycle—in a lysogenic phase, the viral genome is incorporated into the host genome and is replicated too.

  11. Concept 11.1 Several Strategies Are Used to Regulate Gene Expression • A bacteriophage may contain DNA or RNA and may not have a lysogenic phase. • The lytic cycle has two stages: • Earlystage—promoter in the viral genome binds host RNA polymerase and adjacent viral genes are transcribed • Early genes shut down transcription of host genes, and stimulate viral replication and transcription of viral late genes. • Host genes are shut down by a posttranscriptional mechanism. • Viral nucleases digest the host’s chromosome for synthesis in new viral particles.

  12. Concept 11.1 Several Strategies Are Used to Regulate Gene Expression • Latestage—viral late genes are transcribed • They encode the viral capsid proteins and enzymes to lyse the host cell and release new virions. • The whole process from binding and infection to release of new particles takes about 30 minutes.

  13. Figure 11.3 A Gene Regulation Strategy for Viral Reproduction

  14. Concept 11.1 Several Strategies Are Used to Regulate Gene Expression • Human immunodeficiency virus (HIV) is a retrovirus with single-stranded RNA. • HIV is enclosed in a membrane from the previous host cell—it fuses with the new host cell’s membrane. • After infection, RNA-directed DNA synthesis is catalyzed by reverse transcriptase. • Two strands of DNA are synthesized and reside in the host’s chromosome as a provirus.

  15. Figure 11.4 The Reproductive Cycle of HIV

  16. Concept 11.1 Several Strategies Are Used to Regulate Gene Expression • Host cells have systems to repress the invading viral genes. • One system uses transcription “terminator” proteins that interfere with RNA polymerase. • HIV counteracts this negative regulation with Tat (Transactivator of transcription), which allows RNA polymerase to transcribe the viral genome.

  17. Figure 11.5 Regulation of Transcription by HIV (Part 1)

  18. Figure 11.5 Regulation of Transcription by HIV (Part 2)

  19. Concept 11.2 Many Prokaryotic Genes Are Regulated in Operons • Prokaryotes conserve energy by making proteins only when needed. • In a rapidly changing environment, the most efficient gene regulation is at the level of transcription. • E. coli must adapt quickly to food supply changes. Glucose or lactose may be present.

  20. Concept 11.2 Many Prokaryotic Genes Are Regulated in Operons • Uptake and metabolism of lactose involve three proteins: • -galactoside permease—a carrier protein that moves sugar into the cell • -galactosidase—an enzyme that hydrolyses lactose • -galactoside transacetylase—transfers acetyl groups to certain -galactosides • If E. coli is grown with glucose but no lactose present, no enzymes for lactose conversion are produced.

  21. Concept 11.2 Many Prokaryotic Genes Are Regulated in Operons • If lactose is predominant and glucose is low, E. coli synthesizes all three enzymes. • If lactose is removed, synthesis stops. • A compound that induces protein synthesis is an inducer. • Gene expression and regulating enzyme activity are two ways to regulate a metabolic pathway.

  22. Figure 11.6 Two Ways to Regulate a Metabolic Pathway

  23. Concept 11.2 Many Prokaryotic Genes Are Regulated in Operons • Structural genes specify primary protein structure—the amino acid sequence. • The three structural genes for lactose enzymes are adjacent on the chromosome, share a promoter, and are transcribed together. • Their synthesis is all-or-none.

  24. Concept 11.2 Many Prokaryotic Genes Are Regulated in Operons • A gene cluster with a single promoter is an operon—the one that encodes for the lactose enzymes is the lac operon. • An operator is a short stretch of DNA near the promoter that controls transcription of the structural genes. • Inducible operon—turned off unless needed • Repressible operon—turned on unless not needed

  25. Figure 11.7 The lac Operon of E. coli

  26. Concept 11.2 Many Prokaryotic Genes Are Regulated in Operons • The lac operon is only transcribed when a -galactoside predominates in the cell: • A repressor protein is normally bound to the operator, which blocks transcription. • In the presence of a -galactoside, the repressor detaches and allows RNA polymerase to initiate transcription. • The key to this regulatory system is the repressor protein.

  27. Figure 11.8 The lac Operon: An Inducible System (Part 1)

  28. Figure 11.8 The lac Operon: An Inducible System (Part 2)

  29. Concept 11.2 Many Prokaryotic Genes Are Regulated in Operons • A repressible operon is switched off when its repressor is bound to its operator. • However, the repressor only binds in the presence of a co-repressor. • The co-repressor causes the repressor to change shape in order to bind to the promoter and inhibit transcription. • Tryptophan functions as its own co-repressor, binding to the repressor of the trp operon.

  30. Figure 11.9 The trp Operon: A Repressible System (Part 1)

  31. Figure 11.9 The trp Operon: A Repressible System (Part 2)

  32. Concept 11.2 Many Prokaryotic Genes Are Regulated in Operons • Difference in two types of operons: • In inducible systems—a metabolic substrate (inducer) interacts with a regulatory protein (repressor); the repressor cannot bind and allows transcription. • In repressible systems—a metabolic product (co-repressor) binds to regulatory protein, which then binds to the operator and blockstranscription.

  33. Concept 11.2 Many Prokaryotic Genes Are Regulated in Operons • Generally, inducible systems control catabolic pathways—turned on when substrate is available • Repressible systems control anabolic pathways—turned on until product concentration becomes excessive

  34. Concept 11.2 Many Prokaryotic Genes Are Regulated in Operons • Sigma factors—other proteins that bind to RNA polymerase and direct it to specific promoters • Global gene regulation: Genes that encode proteins with related functions may have a different location but have the same promoter sequence—they are turned on at the same time. • Sporulation occurs when nutrients are depleted—genes are expressed sequentially, directed by a sigma factor.

  35. Table 11.1 Transcription in Bacteria and Eukaryotes

  36. Concept 11.3 Eukaryotic Genes Are Regulated by Transcription Factors and DNA Changes • Transcription factors act at eukaryotic promoters. • Each promoter contains a core promoter sequence where RNA polymerase binds. • TATA box is a common core promoter sequence—rich in A-T base pairs. • Only after general transcription factors bind to the core promoter, can RNA polymerase II bind and initiate transcription.

  37. Figure 11.10 The Initiation of Transcription in Eukaryotes (Part 1)

  38. Figure 11.10 The Initiation of Transcription in Eukaryotes (Part 2)

  39. Concept 11.3 Eukaryotic Genes Are Regulated by Transcription Factors and DNA Changes • Besides the promoter, other sequences bind regulatory proteins that interact with RNA polymerase and regulate transcription. • Some are positive regulators—activators; others are negative—repressors. • DNA sequences that bind activators are enhancers, those that bind repressors are silencers. • The combination of factors present determines the rate of transcription.

  40. In-Text Art, Ch. 11, p. 216

  41. Concept 11.3 Eukaryotic Genes Are Regulated by Transcription Factors and DNA Changes • Transcription factors recognize particular nucleotide sequences: • NFATs (nuclear factors of activated T cells) are transcription factors that control genes in the immune system. • They bind to a recognition sequence near the genes’ promoters. • The binding produces an induced fit—the protein changes conformation.

  42. Figure 11.11 A Transcription Factor Protein Binds to DNA

  43. Concept 11.3 Eukaryotic Genes Are Regulated by Transcription Factors and DNA Changes • Gene expression can be coordinated, even if genes are far apart on different chromosomes. • They must have regulatory sequences that bind the same transcription factors. • Plants use this to respond to drought—the scattered stress response genes each have a specific regulatory sequence, the dehydration response element. • During drought, a transcription factor changes shape and binds to this element.

  44. Figure 11.12 Coordinating Gene Expression

  45. Concept 11.3 Eukaryotic Genes Are Regulated by Transcription Factors and DNA Changes • Gene transcription can also be regulated by reversible alterations to DNA or chromosomal proteins. • Alterations can be passed on to daughter cells. • These epigenetic changes are different from mutations, which are irreversible changes to the DNA sequence.

  46. Concept 11.3 Eukaryotic Genes Are Regulated by Transcription Factors and DNA Changes • Some cytosine residues in DNA are modified by adding a methyl group covalently to the 5′ carbon—forms 5′-methylcytosine • DNA methyltransferase catalyzes the reaction—usually in adjacent C and G residues. • Regions rich in C and G are called CpG islands—often in promoters

  47. Figure 11.13 DNA Methylation: An Epigenetic Change (Part 1)

  48. Figure 11.13 DNA Methylation: An Epigenetic Change (Part 2)

  49. Concept 11.3 Eukaryotic Genes Are Regulated by Transcription Factors and DNA Changes • This covalent change in DNA is heritable: • When DNA replicates, a maintenance methylase catalyzes formation of 5′-methylcytosine in the new strand. • However, methylation pattern may be altered—demethylase can catalyze the removal of the methyl group.

  50. Concept 11.3 Eukaryotic Genes Are Regulated by Transcription Factors and DNA Changes • Effects of DNA methylation: • Methylated DNA binds proteins that are involved in repression of transcription—genes tend to be inactive (silenced). • Patterns of DNA methylation may include large regions or whole chromosomes.

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