Transcription: From DNA to RNA

avatar
Created by
Sukaina Mustaf

Cards (28)

  • Transcription
    Synthesis of RNA using a DNA template
  • Synthesis of RNA using a DNA template

    Transcription is the process of creating an RNA copy of a gene sequence in DNA. It's the first step in gene expression, where the information in DNA is transferred to RNA.
  • Role of RNA Polymerase
    RNA polymerase is the key enzyme in transcription. Its roles include:
    1. Initiation
    2. Elongation
    3. Termination
  • Initiation:

    • Recognizes and binds to the promoter region of DNA
    • Unwinds a short section of the DNA double helix
  • Elongation:

    • Moves along the template DNA strand
    • Adds complementary RNA nucleotides to the growing RNA chain
    • Forms phosphodiester bonds between nucleotides
  • Termination:

    • Recognizes termination sequences in DNA
    • Releases the newly synthesized RNA molecule
  • Role of Hydrogen Bonding and Complementary Base Pairing in Transcription
    Hydrogen bonding and complementary base pairing are crucial for the accuracy of transcription.
  • Complementary Base Pairing
    During transcription, RNA nucleotides pair with DNA nucleotides according to specific rules:
    • Adenine (A) in DNA pairs with Uracil (U) in RNA
    • Thymine (T) in DNA pairs with Adenine (A) in RNA
    • Cytosine (C) in DNA pairs with Guanine (G) in RNA
    • Guanine (G) in DNA pairs with Cytosine (C) in RNA
  • Hydrogen bonds form between complementary base pairs:

    • A-U pairs form two hydrogen bonds
    • G-C pairs form three hydrogen bonds
  • These hydrogen bonds are weak individually, but collectively they ensure:

    1. Specificity in base pairing
    2. Stability of the DNA-RNA hybrid during transcription
    3. Easy separation of RNA from DNA template after transcription
  • Importance of A-U Pairing
    The pairing of Adenine (A) on the DNA template strand with Uracil (U) on the RNA strand is a key feature that distinguishes RNA from DNA:
    1. It maintains the complementary base pairing principle
    2. It allows for slight differences in structure between RNA and DNA
    3. It may play a role in the cell's ability to distinguish between RNA and DNA
  • Stability of DNA Templates
    DNA's stability is crucial for maintaining genetic information integrity over time. This stability allows DNA to serve as a reliable template for transcription repeatedly without altering its base sequence.
  • Key points about DNA template stability:

    1. Chemical Stability
    2. Repair Mechanisms
    3. Redundancy
  • Repair Mechanisms:

    • Cells have various DNA repair systems to fix damages
    • These include nucleotide excision repair, base excision repair, and mismatch repair
  • Chemical Stability:

    • DNA's deoxyribose sugar is more stable than RNA's ribose sugar
    • The double-helix structure provides protection to the bases
  • Redundancy:

    • Having two strands provides a backup copy if one strand is damaged
  • What must DNA do in non-dividing somatic cells throughout the cell's lifetime?
    Remain stable
  • Why is stability of DNA important in non-dividing somatic cells?

    It ensures accurate transcription of genes when needed
  • How does DNA stability contribute to the cell's function over time?

    It helps the cell maintain its proper function
  • What does the preservation of genetic information allow for in non-dividing somatic cells?

    Potential future cell divisions
  • What are the key reasons for DNA stability in non-dividing somatic cells?

    • Ensures accurate transcription of genes
    • Maintains proper cell function over time
    • Preserves genetic information for future cell divisions
  • Transcription as a Process Required for Gene Expression

    Transcription is the first and a crucial step in gene expression. It's the process where the information in DNA is transferred to RNA, which can then be translated into proteins or function directly as non-coding RNA.
  • Key points about transcription and gene expression:
    1. Selective Gene Expression:
    2. Regulation at Transcription Level
    3. Transcription Factors
  • Selective Gene Expression:

    • Not all genes in a cell are expressed at any given time
    • Different cell types express different sets of genes
    • Gene expression can change in response to environmental cues or developmental stages
  • Regulation at Transcription Level:

    • Transcription is a key control point for gene expression
    • Genes can be switched "on" (activated) or "off" (repressed) at the transcription stage
  • Transcription Factors
    • Proteins that bind to specific DNA sequences to control gene expression
    • They can enhance or repress transcription of specific genes
  • Mechanisms of Transcriptional Regulation:

    1. Promoter Control: RNA polymerase binding to the promoter can be enhanced or inhibited
    2. Enhancers and Silencers: DNA sequences that can increase or decrease transcription of specific genes
    3. Chromatin Remodeling: Changes in DNA packaging can make genes more or less accessible for transcription
  • The ability to regulate gene expression at the transcription level allows cells to respond quickly to changes in their environment or developmental cues.