Proven mnemonics โ fast to learn, hard to forget.
๐งฌ Genetics
A pairs with T, G pairs with C
DNA Base Pairing Rules
Chargaff's rules โ the foundation of DNA structure
In DNA: Adenine always pairs with Thymine (2 hydrogen bonds). Guanine always pairs with Cytosine (3 hydrogen bonds). "AT the GC" โ a way to remember both pairs.
A
Adenine pairs with Thymine โ 2 hydrogen bonds
T
Thymine pairs with Adenine
G
Guanine pairs with Cytosine โ 3 hydrogen bonds
C
Cytosine pairs with Guanine
๐งฌ Genetics
Dominant masks Recessive
Dominance Rule
Dominant vs recessive โ one simple rule
Dominant alleles (capital letter) always express when present. Recessive alleles (lowercase) only express when homozygous (two copies). Dd looks like DD.
๐งฌ Genetics
DNA โ RNA โ Protein
Central Dogma of Molecular Biology
The central dogma โ information only flows one direction
DNA is transcribed into mRNA, which is translated into protein. Transcription happens in the nucleus. Translation happens at the ribosome.
๐งฌ Genetics
"Genotype is Genes, Phenotype is Physical"
Genotype vs Phenotype
Genotype and phenotype โ easy G vs P distinction
Genotype = the actual alleles an organism carries (e.g., Bb). Phenotype = what you can observe (e.g., brown hair). Same phenotype can have different genotypes.
๐งฌ Genetics
X-linked: sons get it from mom
X-Linked Inheritance Pattern
X-linked recessive โ why sons are affected more than daughters
Males have only one X (XY). A single recessive allele on that X expresses. Females need two copies (XX) to show the trait. Carrier moms pass it to 50% of sons.
Two classic Punnett square crosses every genetics student must know
Monohybrid cross (Tt ร Tt): 1 TT : 2 Tt : 1 tt genotype, 3 dominant : 1 recessive phenotype. Test cross: cross unknown dominant with homozygous recessive (tt) โ if any recessive offspring, unknown was heterozygous.
Incomplete vs Codominance
Incomplete dominance: RR + WW โ RW (pink). Codominance: both show (AB blood type).
Incomplete vs Codominance
Two exceptions to simple dominant-recessive inheritance
Incomplete dominance: neither allele fully dominant โ blend. Red + White = Pink snapdragon. Codominance: both alleles fully expressed simultaneously. Blood type AB: both A and B antigens present on red blood cells. Neither masks the other.
Meiosis vs Mitosis
Meiosis makes gametes (sperm/egg) with half the chromosomes (haploid, n)
Meiosis vs Mitosis
The critical difference between cell division for body cells vs sex cells
Mitosis: 1 cell โ 2 identical diploid cells (2n). For growth and repair. Meiosis: 1 cell โ 4 haploid gametes (n). For reproduction. Meiosis has two rounds of division (Meiosis I and II). Crossing over in Meiosis I creates genetic diversity.
Sex-Linked Inheritance
Sex-linked traits: females are XX, males are XY. Sons get X from mom, Y from dad.
Sex-Linked Inheritance
Why X-linked conditions affect males more than females
Males (XY) only have one X chromosome โ if it carries a recessive allele, the trait is expressed (no second X to mask it). Females (XX) need two copies of the recessive allele to be affected. Color blindness and hemophilia are classic X-linked recessive examples.
Types of Mutations
Mutations: point mutation changes one base. Frameshift (insertion/deletion) shifts everything after it.
Types of Mutations
Two categories of DNA mutations โ one is usually more damaging
Point mutation: one nucleotide substituted. May be silent (same amino acid), missense (different amino acid), or nonsense (creates stop codon). Frameshift: insertion or deletion shifts the reading frame โ completely different amino acid sequence from that point on โ usually nonfunctional protein.
Hardy-Weinberg Equilibrium
Hardy-Weinberg: pยฒ + 2pq + qยฒ = 1. No evolution if population is in equilibrium.
Hardy-Weinberg Equilibrium
The baseline โ a non-evolving population's allele frequencies stay constant
p = frequency of dominant allele, q = frequency of recessive allele. p + q = 1. Genotype frequencies: pยฒ (homozygous dominant) + 2pq (heterozygous) + qยฒ (homozygous recessive) = 1. Equilibrium requires: large population, random mating, no mutation, no migration, no selection.
Polygenic Inheritance
Polygenic traits: controlled by many genes โ bell curve distribution (height, skin color)
Polygenic Inheritance
When multiple genes together control one trait โ produces a range, not categories
Unlike simple Mendelian traits (tall/short), polygenic traits show continuous variation. Height, skin color, intelligence, weight โ all influenced by many gene loci plus environment. When you graph the population, you get a normal distribution (bell curve). Environment also plays a significant role.