DNA Structure and Function

Structure of DNA

The structure of DNA is fundamental to its role in heredity and cellular function. DNA is a double helix composed of two antiparallel strands of nucleotides.

• Nucleotides: Each nucleotide consists of a deoxyribose sugar, a phosphate group, and a nitrogenous base (adenine, thymine, cytosine, guanine).

• Bonds: Phosphodiester bonds link nucleotides within a strand; hydrogen bonds connect complementary bases between strands (A-T: 2 bonds, C-G: 3 bonds).

• Antiparallel Orientation: One strand runs 5' to 3', the other 3' to 5'.

Example: The classic Watson-Crick model describes the double helix structure.

DNA vs RNA

• Sugar: DNA contains deoxyribose; RNA contains ribose.

• Bases: DNA uses thymine; RNA uses uracil.

• Structure: DNA is double-stranded; RNA is usually single-stranded.

• Function: DNA stores genetic information; RNA functions in gene expression (mRNA, tRNA, rRNA).

Bacterial Transformation

Bacterial transformation is the process by which bacteria take up foreign DNA from their environment, leading to genetic change.

• Historical Example: Griffith's experiment demonstrated transformation in Streptococcus pneumoniae.

Gene Expression: Replication, Transcription, and Translation

DNA Replication

DNA replication is the process of copying DNA before cell division.

• Enzymes Involved: DNA polymerase, helicase, primase, ligase.

• Leading vs Lagging Strand: Leading strand synthesized continuously; lagging strand synthesized in Okazaki fragments.

• Requirements: Template DNA, primers, nucleotides.

• Location: Nucleus (eukaryotes), cytoplasm (prokaryotes).

• Fidelity: DNA polymerase proofreads; mistakes can cause mutations.

Equation:

Transcription

Transcription is the synthesis of RNA from a DNA template.

• Enzyme: RNA polymerase.

• Process: Initiation (promoter recognition), elongation (RNA synthesis), termination (stop signal).

• Product: Pre-mRNA (eukaryotes), mRNA (prokaryotes).

• Location: Nucleus (eukaryotes), cytoplasm (prokaryotes).

Equation:

mRNA Processing in Eukaryotes

• 5' Capping: Addition of a modified guanine nucleotide.

• Polyadenylation: Addition of a poly-A tail at the 3' end.

• Splicing: Removal of introns, joining of exons.

Translation

Translation is the process of synthesizing a protein from an mRNA template.

• Players: Ribosome, mRNA, tRNA, amino acids.

• Process: Initiation (start codon recognition), elongation (polypeptide synthesis), termination (stop codon).

• Location: Cytoplasm (both prokaryotes and eukaryotes).

Equation:

Signals for Initiation and Termination

• Transcription: Promoter (start), terminator (stop).

• Translation: Start codon (AUG), stop codons (UAA, UAG, UGA).

Central Dogma of Molecular Biology

The flow of genetic information is summarized as:

Mutations

• Types: Point mutations (silent, missense, nonsense), insertions, deletions, frameshift mutations.

• Most Deleterious: Frameshift and nonsense mutations often have the greatest impact.

Introns vs Exons

• Introns: Non-coding sequences removed during mRNA processing.

• Exons: Coding sequences that remain in mature mRNA.

Gene Expression Regulation

Levels of Gene Expression Control

• Pre-transcriptional: Chromatin structure (methylation, acetylation), transcription factors.

• Transcriptional: Promoter accessibility, enhancers/silencers.

• Post-transcriptional (pre-translation): mRNA splicing, mRNA lifespan, RNA interference (RNAi).

• Translational: Regulation of translation initiation.

• Post-translational: Protein modification (ubiquitin tagging, phosphorylation).

Epigenetic Inheritance

Epigenetic inheritance involves heritable changes in gene expression that do not alter the DNA sequence, such as DNA methylation and histone modification.

Chromosomes and Cell Division

Key Terms

• Homologous Chromosomes: Chromosome pairs with the same genes but possibly different alleles.

• Chromosome: DNA molecule with associated proteins, carrying genetic information.

• Chromatid: One of two identical halves of a replicated chromosome.

• Tetrad: Structure of four chromatids formed during meiosis I by synapsis of homologous chromosomes.

Meiosis vs Mitosis

Meiosis: Major Parts

• Meiosis I: Homologous chromosomes separate; crossing over occurs; cells become haploid.

• Meiosis II: Sister chromatids separate; similar to mitosis.

• Key Events: Tetrad formation, crossing over (prophase I), independent assortment (metaphase I).

• DNA Replication: Occurs before meiosis I, not before meiosis II.

Sources of Genetic Variation in Meiosis

• Crossing Over: Exchange of genetic material between homologous chromosomes.

• Independent Assortment: Random orientation of homologous pairs during metaphase I.

• Random Fertilization: Any sperm can fertilize any egg.

Summary Table: DNA, RNA, and Protein Synthesis

Additional info: The above notes expand on the review outline by providing definitions, process details, and context for each topic, ensuring a comprehensive study guide for exam preparation.