Hoja de repaso: Genetics Fundamentals and Cell Division

📋 Course Outline

1. ADN et information génétique
2. Structure de l’ADN et nucléotides
3. Réplication, chromosomes et caryotype
4. Mitose, méiose et transmission génétique
5. Synthèse des protéines et code génétique
6. Mutations, brassage et génétique mendélienne

📖 1. ADN et information génétique

🔑 Key Concepts & Definitions

• ADN : Nucleic acid that stores hereditary information in living cells.
• Information génétique : Set of instructions carried by genes that determines traits through protein synthesis.
• Gène : DNA segment that contains the information needed to produce a functional product, often a protein.

📝 Essential Points

• The genetic information is encoded in the order of nucleotides along DNA.
• Genes are located on chromosomes and are transmitted from parents to offspring.
• Changes in DNA sequence can modify the information and lead to genetic variation or disease.

💡 Memory Hook

DNA = “sequence = message”: order of letters carries the instructions.

📖 2. Structure de l’ADN et nucléotides

🔑 Key Concepts & Definitions

• Double hélice : DNA structure formed by two antiparallel strands wound around each other.
• Nucléotide : DNA building block composed of a phosphate group, a deoxyribose sugar, and a nitrogenous base.
• Antiparallélisme : Orientation property where the two DNA strands run in opposite 5'→3' directions.

📝 Essential Points

• Each strand has a sugar-phosphate backbone with bases pointing inward toward the other strand.
• Complementary base pairing occurs via hydrogen bonds between bases on opposite strands.
• In DNA, the sugar is deoxyribose and the bases are A, T, G, C.

💡 Memory Hook

Antiparallel = “5' faces 3'”: opposite directions on the two strands.

📖 3. Réplication, chromosomes et caryotype

🔑 Key Concepts & Definitions

• Réplication de l’ADN : Process where DNA is copied so that each daughter cell receives a complete DNA set.
• Chromosome : Organized DNA-protein structure that packages DNA into the nucleus.
• Caryotype : Ordered representation of chromosomes from a cell, used to identify number and structure.

📝 Essential Points

• DNA replication is semiconservative: each new DNA molecule contains one old strand and one newly synthesized strand.
• Chromosomes carry genes and are duplicated before cell division.
• A caryotype is used to detect chromosomal abnormalities such as changes in chromosome number or structure.

💡 Memory Hook

Semiconservative = “half old, half new” for each daughter DNA.

📖 4. Mitose, méiose et transmission génétique

🔑 Key Concepts & Definitions

• Mitose : Cell division that produces two genetically identical diploid daughter cells.
• Méiose : Cell division that produces four genetically different haploid gametes.
• Transmission génétique : Passing of genetic information from one generation to the next through cell division and gametes.

📝 Essential Points

• Mitosis maintains chromosome number (diploid → diploid) and preserves genetic identity.
• Meiosis reduces chromosome number (diploid → haploid) to form gametes.
• Genetic diversity arises during meiosis through recombination and independent assortment of chromosomes.

💡 Memory Hook

Mitosis = “same”; Meiosis = “different + half number”.

📖 5. Synthèse des protéines et code génétique

🔑 Key Concepts & Definitions

• Synthèse des protéines : Cellular process that builds proteins from information carried by genes.
• Code génétique : Rule mapping codons (triplets) to amino acids during translation.
• Codon : Triplet of nucleotides on mRNA that specifies an amino acid or a stop signal.

📝 Essential Points

• The genetic message is read in triplets (codons) along mRNA.
• Some codons correspond to amino acids, and specific codons signal termination of translation.
• The order of codons determines the order of amino acids in the protein.

💡 Memory Hook

Codons are “3-letter words” that translate into amino acids.

📖 6. Mutations, brassage et génétique mendélienne

🔑 Key Concepts & Definitions

• Mutation génétique : Heritable change in DNA sequence that can alter gene function or regulation.
• Brassage génétique : Generation of genetic diversity by recombination and independent assortment during meiosis.
• Génétique mendélienne : Study of inheritance patterns based on alleles and their transmission across generations.

📝 Essential Points

• Mutations can be point changes or larger alterations, and they may be neutral, harmful, or beneficial.
• Brassage increases variation by producing new allele combinations in gametes.
• Mendelian inheritance uses allele dominance relationships to predict offspring phenotypes and genotypes.

💡 Memory Hook

Brassage = “new mixes” of alleles; Mendel = “predict mixes” with dominance.

⚠️ Common Pitfalls & Confusions

1. Confusing DNA replication (semiconservative) with conservative or dispersive models can lead to wrong answers.
2. Mixing up strand directions (5'→3' vs 3'→5') often causes errors in describing synthesis.
3. Thinking that meiosis produces identical gametes instead of genetically different ones is a common mistake.
4. Assuming each nucleotide codes for an amino acid rather than using codons (triplets) leads to incorrect translation questions.
5. Confusing dominance with codominance: codominance means both alleles are expressed, not only one.

✅ Exam Checklist

1. Define DNA, gene, and genetic information and explain how sequence relates to traits.
2. Describe DNA double-helix structure, nucleotide composition, and antiparallel orientation.
3. State the semiconservative nature of DNA replication and connect replication to chromosome duplication.
4. Explain what mitosis and meiosis do to chromosome number and genetic identity.
5. Link gene information to protein synthesis via transcription and translation concepts.
6. Use the genetic code idea: codons are triplets that specify amino acids or stop signals.
7. Explain what mutations are and how they can change genetic information.
8. Describe how meiosis creates genetic diversity through recombination and independent assortment.
9. Apply Mendelian inheritance logic to monohybrid and dihybrid crosses using dominance/codominance concepts.
10. Predict outcomes for inheritance patterns and interpret genealogical trees using allele transmission logic.