Slide 1

• Topic: Genetics and Evolution - Molecular Basis of Inheritance - Transcription of protein coding gene
• Introduction to the process of transcription
  • Definition: Transcription is the process of synthesizing RNA from a DNA template
  • Key players in transcription: DNA, RNA polymerase, and transcription factors
• Importance of transcription: It is the first step in gene expression and plays a critical role in protein synthesis

Slide 2

• Steps involved in transcription
  1. Initiation:
     • RNA polymerase binds to the promoter region on DNA
     • DNA strands separate to form an open complex
  2. Elongation:
     • RNA polymerase moves along the template DNA strand
     • Incorporation of complementary RNA nucleotides to form a growing RNA chain
  3. Termination:
     • RNA polymerase reaches the terminator region
     • Release of the RNA transcript and detachment of the RNA polymerase

Slide 3

• Promoters and regulatory sequences
  • Promoter region: Specific DNA sequence that signals the beginning of a gene
  • Elements within the promoter region:
    • TATA box (consensus sequence) binds to transcription factors
    • Transcription start site (TSS) marks the site of transcription initiation
  • Regulatory sequences: Enhancers and silencers that control gene expression

Slide 4

• Transcription factors
  • Definition: Proteins that bind to DNA and regulate gene expression
  • Types of transcription factors:
    1. General transcription factors: Required for transcription initiation
    2. Specific transcription factors: Enhance or repress transcription through binding to enhancers or silencers
  • Importance: Transcription factors determine which genes are transcribed in a specific cell type

Slide 5

• RNA polymerases
  • Types of RNA polymerases:
    • RNA polymerase I: Transcribes rRNA genes
    • RNA polymerase II: Transcribes protein-coding genes (mRNAs)
    • RNA polymerase III: Transcribes tRNA genes and other non-coding RNAs
  • RNA polymerase II structure:
    • Consists of multiple subunits including the catalytic subunit responsible for RNA synthesis

Slide 6

• Transcription unit
  • Definition: The DNA sequence that is transcribed into RNA
  • Components of a transcription unit:
    • Promoter region
    • Transcribed region
    • Terminator region
  • Transcription unit may contain multiple genes

Slide 7

• Transcription process in prokaryotes
  • Simpler transcription machinery
  • Only one RNA polymerase (RNA polymerase holoenzyme)
  • Transcription and translation occur simultaneously in the cytoplasm

Slide 8

• Transcription process in eukaryotes
  • More complex transcription machinery
  • Three different RNA polymerases
  • Transcription occurs in the nucleus while translation occurs in the cytoplasm
  • RNA processing steps:
    • Capping of the 5’ end
    • Addition of a poly(A) tail at the 3’ end
    • Removal of introns through splicing

Slide 9

• Transcription factors in eukaryotes
  • Specific transcription factors bind to enhancers and silencers
  • Mediator complex acts as a bridge between transcription factors, RNA polymerase II, and the promoter region
  • Coactivators and corepressors interact with transcription factors to regulate gene expression

Slide 10

• Regulation of transcription
  • Transcriptional activators enhance gene expression
  • Transcriptional repressors inhibit gene expression
  • Regulatory sequences and transcription factors play a critical role in the regulation of transcription
  • Gene expression can be influenced by various factors such as environmental cues, hormones, and cellular signaling pathways

Slide 11

• Regulation of gene expression
  • Gene expression can be regulated at different levels:
    1. Transcriptional regulation: Control of gene expression during transcription
    2. Post-transcriptional regulation: Control of gene expression after transcription
    3. Translational regulation: Control of gene expression during protein synthesis
    4. Post-translational regulation: Control of gene expression after protein synthesis

Slide 12

• Transcriptional regulation
  • Transcription factors play a major role in transcriptional regulation
  • Activators: Enhance transcription by binding to enhancers and promoting the assembly of the transcription initiation complex
  • Repressors: Inhibit transcription by binding to silencers and preventing the assembly of the transcription initiation complex

Slide 13

• DNA methylation
  • Addition of a methyl group to the DNA molecule
  • Methylation can silence gene expression by:
    • Blocking the binding of transcription factors to the promoter region
    • Recruiting repressor proteins
  • Methylation patterns can be heritable and influenced by environmental factors

Slide 14

• Histone modification
  • Histones are proteins that DNA wraps around to form chromatin
  • Modifications of histones can affect gene expression:
    • Acetylation: Opens up chromatin and promotes transcription
    • Methylation: Can either promote or inhibit transcription, depending on the site and degree of methylation
    • Phosphorylation: Can activate or repress transcription, depending on the context

Slide 15

• Post-transcriptional regulation
  • Regulation of gene expression after transcription
  • Key players in post-transcriptional regulation:
    • RNA processing factors: Involved in splicing, capping, and polyadenylation
    • RNA-binding proteins: Regulate mRNA stability, localization, and translation
    • MicroRNAs (miRNAs): Bind to complementary sequences in mRNA and inhibit translation

Slide 16

• Translational regulation
  • Control of gene expression during protein synthesis
  • Translational regulation can occur at various steps:
    • Accessibility of ribosome binding sites
    • Interaction between the ribosome and mRNA
    • Availability of amino acids and energy for translation
  • Regulatory proteins and RNA molecules can influence translation efficiency

Slide 17

• Post-translational regulation
  • Control of gene expression after protein synthesis
  • Examples of post-translational modifications:
    • Phosphorylation: Can change protein activity or stability
    • Ubiquitination: Marks proteins for degradation
    • Glycosylation: Adds sugar molecules to proteins, affecting their function
  • Post-translational modifications can regulate protein localization, stability, and activity

Slide 18

• Gene expression and development
  • Gene expression is tightly regulated during development
  • Differential gene expression: Different cells express different sets of genes
  • Key regulators of development:
    • Homeobox genes: Control body plan and segment identity
    • Transcription factors specific to certain cell types
  • Mutations in developmental genes can lead to developmental disorders

Slide 19

• Examples of transcriptional regulation
  • Lac operon in E. coli:
    • Contains genes involved in lactose metabolism
    • Activated by an inducer molecule (lactose) and an activator protein (CAP)
    • Repressed by a repressor protein (LacI) in the absence of lactose
  • Flower development in Arabidopsis thaliana:
    • Different transcription factors control the expression of genes responsible for petal, sepal, and stamen development
    • Mutations in these transcription factors can result in abnormal flower development

Slide 20

• Summary
  • Transcription is the process of synthesizing RNA from a DNA template
  • Transcription factors and RNA polymerase are essential for gene expression
  • Transcriptional regulation involves the interaction between regulatory sequences, transcription factors, and chromatin modifications
  • Post-transcriptional, translational, and post-translational regulation also play important roles in gene expression
  • Gene expression is crucial for development, and its dysregulation can lead to diseases and disorders

Slide 21

• Transcriptional regulation in cancer
  • Dysregulation of transcriptional processes can contribute to the development of cancer
  • Oncogenes: Genes that promote cancer by enhancing transcription or inhibiting apoptosis
  • Tumor suppressor genes: Genes that regulate transcription to prevent uncontrolled cell growth
  • Examples: Activation of oncogenic transcription factors like MYC, inactivation of tumor suppressors like p53

Slide 22

• Methods to study transcription
  • mRNA sequencing (RNA-seq)
    • Identifies and quantifies transcript levels
    • Helps to identify differentially expressed genes
  • Chromatin immunoprecipitation (ChIP)
    • Identifies binding sites of transcription factors and epigenetic modifications
  • Reporter gene assays
    • Measure gene expression using a reporter gene like GFP
  • Transcriptional reporter mouse models
    • Enable tracking and visualization of gene expression in a living organism

Slide 23

• Transcriptional regulation and drug development
  • Understanding transcriptional regulation can aid in the development of targeted therapies
  • Promising approaches:
    • Small molecule inhibitors targeting specific transcription factors
    • RNA-based therapies using antisense oligonucleotides
    • Epigenetic modulators to alter gene expression patterns
  • Examples: Targeting estrogen receptor in breast cancer, using epigenetic drugs like demethylating agents

Slide 24

• Transcriptional regulation during immune response
  • Gene expression in immune cells is highly regulated
  • Transcription factors like NF-κB and AP-1 play key roles
  • Activation of immune response genes in response to pathogens
  • Examples: Upregulation of cytokines, chemokines, and major histocompatibility complex (MHC) genes

Slide 25

• Transcriptional regulation in stem cells
  • Stem cells have the ability to differentiate into various cell types
  • Specific transcription factors control stem cell identity and fate
  • Pluripotency factors (e.g., Oct4, Sox2, Nanog) maintain stemness
  • Differentiation factors activate lineage-specific genes
  • Example: Induced pluripotent stem cells (iPSCs) obtained by reprogramming differentiated cells using transcription factors

Slide 26

• Transcriptional regulation of circadian rhythms
  • Circadian rhythms are biological processes that follow a 24-hour cycle
  • Transcription factors like CLOCK and BMAL1 drive the expression of clock genes
  • Clock genes regulate various physiological processes, including sleep-wake cycles, metabolism, and hormone production
  • Example: Upregulation of Period (Per) and Cryptochrome (Cry) genes during the dark phase

Slide 27

• Transcriptional regulation in plant development
  • Plants use transcriptional regulation for various developmental processes
  • Hormones like auxin, cytokinin, and gibberellin modulate gene expression patterns
  • Transcription factors like LEAFY control flower development
  • Environmental cues can also affect gene expression in plants (e.g., light-regulated genes)

Slide 28

• Transcriptional regulation in neurodevelopment
  • Precise transcriptional regulation is crucial for proper brain development
  • Transcription factors like Pax6, Emx2, and Otx2 control neuronal differentiation and regional identity
  • Dysregulation of transcription factors can lead to neurodevelopmental disorders
  • Examples: Mutations in Foxp2 associated with speech/language impairments, mutations in MeCP2 causing Rett syndrome

Slide 29

• Transcriptional regulation and evolution
  • Changes in gene expression patterns contribute to evolutionary adaptation
  • Regulatory mutations can alter transcription factor binding sites or regulatory sequences
  • Gene duplication events can lead to the divergence of gene expression patterns
  • Example: Evolution of the Hox gene clusters in vertebrates, influencing body plan development

Slide 30

• Conclusion
  • Transcription is a fundamental process in gene expression
  • Transcriptional regulation plays a key role in diverse biological processes
  • Understanding transcriptional regulation can aid in various fields, including medicine, molecular biology, and evolutionary biology
  • Further research is needed to uncover the intricacies of transcriptional regulation and its implications for human health and disease