Home bio Genetics is the study of heredity and how traits are passed from parents to offspring. Gregor Mendel is known as the “Father of Genetics.” Why did Mendel use pea plants? * Easy to grow * Short generation time * Many visible traits * Can self-pollinate or cross-pollinate * Produce many offspring Examples of traits studied: * Flower colour * Seed shape * Plant height ⸻ VOCABULARY Gene * A segment of DNA that controls a trait. Allele * Different forms of the same gene. Example: P = purple flowers p = white flowers Dominant Allele * Expressed whenever it is present. * Represented by a capital letter. Example: P = purple Recessive Allele * Only expressed when two copies are present. * Represented by a lowercase letter. Example: p = white Genotype * Genetic makeup of an organism. Examples: PP Pp pp Phenotype * Physical appearance of an organism. Examples: Purple flower White flower Homozygous * Two identical alleles. Examples: PP pp Heterozygous * Two different alleles. Example: Pp Pure Breeding * Homozygous for a trait. Gamete * Sex cell (sperm or egg). ⸻ MENDEL’S LAWS Law of Dominance * A dominant allele masks a recessive allele. Example: Pp = Purple flower Law of Segregation * Alleles separate during gamete formation. * Each gamete receives only one allele. Example: Parent = Pp Gametes: P p Law of Independent Assortment * Different genes assort independently during meiosis. ⸻ MONOHYBRID CROSSES A monohybrid cross studies one trait. Example: P = Purple p = White Cross: Pp × Pp Punnett Square INCOMPLETE DOMINANCE Neither allele completely dominates. Example: Snapdragons RR = Red WW = White RW = Pink Cross: RW × RW Genotype Ratio: 1 RR : 2 RW : 1 WW Phenotype Ratio: 1 Red : 2 Pink : 1 White CODOMINANCE Both alleles are expressed equally. Example: AB Blood Type Genotype: IAIB Phenotype: AB MULTIPLE ALLELES More than two alleles exist in a population. Example: ABO Blood Group Alleles: IA IB i BLOOD TYPES Type A Genotypes: IAIA or IAi Type B Genotypes: IBIB or IBi Type AB Genotype: IAIB Type O Genotype: ii Can Type A and Type B Parents Have a Type O Child? Yes. If: Father = IAi Mother = IBi Possible Blood Types: AB A B O CELL CYCLE Purpose: * Growth * Repair * Replacement of cells Stages: G1 S G2 Mitosis Cytokinesis INTERPHASE G1 Phase Cell grows and carries out normal functions. S Phase DNA replication occurs. G2 Phase Cell prepares for division. MITOSIS Purpose: Growth and repair. Produces: 2 genetically identical diploid cells. PROPHASE Events: * Chromosomes condense * Nuclear membrane disappears * Nucleolus disappears * Spindle fibres form METAPHASE Events: * Chromosomes line up at the equator ANAPHASE Events: * Sister chromatids separate TELOPHASE Events: * Nuclear membranes reform * Chromosomes uncoil CYTOKINESIS Division of the cytoplasm. Animal Cells: Cleavage furrow forms. Plant Cells: Cell plate forms. CHROMOSOME STRUCTURE Chromosome consists of: * Two sister chromatids * One centromere DIPLOID VS HAPLOID Diploid (2n) * Two sets of chromosomes * Human body cells * 46 chromosomes Haploid (n) * One set of chromosomes * Human gametes * 23 chromosomes HOMOLOGOUS CHROMOSOMES Chromosome pairs that: * Carry the same genes * One comes from the mother * One comes from the father Humans have 23 homologous pairs. MEIOSIS Purpose: Produce gametes. Produces: 4 genetically unique haploid cells. MEIOSIS I Separates homologous chromosomes. CROSSING OVER Occurs during Prophase I. Definition: Exchange of DNA between homologous chromosomes. Importance: Creates genetic variation. RANDOM ASSORTMENT Occurs during Metaphase I. Definition: Homologous pairs line up randomly. Importance: Creates unique chromosome combinations. MEIOSIS II Separates sister chromatids. MITOSIS VS MEIOSIS Mitosis * 2 cells produced * Diploid * Genetically identical * Growth and repair Meiosis * 4 cells produced * Haploid * Genetically different * Produces gametes NONDISJUNCTION Failure of chromosomes to separate properly during meiosis. Can result in extra or missing chromosomes. DOWN SYNDROME Cause: Extra chromosome 21. Chromosome Number: 47 Usually caused by nondisjunction during meiosis. DNA DNA = Deoxyribonucleic Acid Shape: Double Helix Function: Stores genetic information. NUCLEOTIDE Three Components: * Phosphate Group * Deoxyribose Sugar * Nitrogenous Base NITROGENOUS BASES Adenine (A) Thymine (T) Cytosine (C) Guanine (G) COMPLEMENTARY BASE PAIRING A pairs with T C pairs with G DNA REPLICATION Purpose: Make identical copies of DNA. Location: Nucleus Result: Two identical DNA molecules. TRANSCRIPTION Purpose: Create mRNA from DNA. Location: Nucleus DNA → mRNA Remember: RNA uses Uracil (U) instead of Thymine (T). TRANSLATION Purpose: Make proteins. Location: Ribosome mRNA is read and amino acids are joined together to form a protein. MUTATIONS A mutation is a change in DNA sequence. Types: * Deletion * Duplication * Inversion * Translocation DELETION DNA segment removed. DUPLICATION DNA segment repeated. INVERSION DNA segment reversed. TRANSLOCATION DNA segment moves to another chromosome. SEX-LINKED TRAITS Traits located on sex chromosomes. Most are located on the X chromosome. RED-GREEN COLOUR BLINDNESS Inheritance: X-linked recessive. XC = Normal Vision Xc = Colour Blind Male: XcY Colour blind boys inherit the allele from their mother because fathers pass a Y chromosome to their sons. TAY-SACHS DISEASE Cause: Missing enzyme that breaks down lipids in nerve cells. Inheritance: Autosomal recessive. Treatment: No cure currently available. SICKLE CELL ANEMIA Cause: Mutation in hemoglobin gene. Effects: * Sickle-shaped red blood cells * Reduced oxygen transport * Blocked blood vessels Inheritance: Autosomal recessive. HUNTINGTON’S DISEASE Cause: Dominant mutation. Effects: * Nervous system degeneration * Loss of motor control * Cognitive decline Inheritance: Autosomal dominant. KARYOTYPE A photograph of chromosomes arranged in pairs. Used to: * Determine sex * Detect chromosome abnormalities * Diagnose genetic disorders PEDIGREE A family tree used to track inheritance patterns. Symbols: Square = Male Circle = Female Shaded = Has trait CLONING Producing genetically identical organisms. Uses: * Research * Agriculture * Medicine * Conservation GENETIC COUNSELLING Provides information about: * Inherited disorders * Family risk * Testing options AMNIOCENTESIS Prenatal test in which amniotic fluid is sampled and fetal cells are analyzed. Can detect: * Genetic disorders * Chromosomal disorders GMOs Genetically Modified Organisms. Definition: Organisms whose DNA has been altered through biotechnology. Advantages: * Increased crop yield * Disease resistance * Pest resistance Disadvantages: * Ethical concerns * Environmental concerns DNA REPLICATION → TRANSCRIPTION → TRANSLATION DNA (Nucleus) ↓ Replication DNA Copy DNA ↓ Transcription mRNA mRNA ↓ Translation Protein Final Product: Protein RESPIRATORY SYSTEM Function: * Brings oxygen into the body * Removes carbon dioxide * Works with the circulatory system to supply cells with oxygen Why do organisms require oxygen and produce carbon dioxide? Oxygen is required for cellular respiration. Cellular Respiration: Glucose + Oxygen → Energy (ATP) + Carbon Dioxide + Water Cells use oxygen to release energy from food. Carbon dioxide is produced as a waste product and must be removed. ⸻ PATHWAY OF AIR Nasal Cavity ↓ Pharynx ↓ Larynx ↓ Trachea ↓ Bronchi ↓ Bronchioles ↓ Alveoli ⸻ NASAL CAVITY Functions: * Warms air * Moistens air * Filters air Nasal Hairs: * Trap large particles Mucus: * Traps dust and microorganisms Blood Capillaries: * Warm incoming air ⸻ PHARYNX Common passageway for: * Air * Food Also called the throat. ⸻ UVULA Functions: * Prevents food from entering nasal cavity * Helps with speech ⸻ EPIGLOTTIS Functions: * Covers trachea during swallowing * Prevents choking ⸻ LARYNX Also called the voice box. Contains vocal cords. ⸻ TRACHEA Also called the windpipe. Contains cartilage rings that prevent collapse. Lined with: * Cilia * Mucus ⸻ CILIA Tiny hair-like structures. Function: * Sweep mucus upward toward throat ⸻ BRONCHI Two branches of the trachea leading to lungs. Right Bronchus → Right Lung Left Bronchus → Left Lung ⸻ BRONCHIOLES Smaller branches inside lungs. Lead to alveoli. ⸻ ALVEOLI Tiny air sacs. Site of gas exchange. Adaptations: * Thin walls * Moist surface * Large surface area * Rich blood supply Gas Exchange: Oxygen moves: Alveoli → Blood Carbon Dioxide moves: Blood → Alveoli By diffusion. ⸻ BREATHING MECHANICS Two main muscles: 1. Diaphragm 2. Intercostal Muscles ⸻ INHALATION (INSPIRATION) Diaphragm: * Contracts * Moves downward Intercostal Muscles: * Contract * Lift ribs upward Result: * Chest cavity volume increases * Pressure decreases * Air enters lungs ⸻ EXHALATION (EXPIRATION) Diaphragm: * Relaxes * Moves upward Intercostal Muscles: * Relax Result: * Chest cavity volume decreases * Pressure increases * Air leaves lungs ⸻ MEDULLA OBLONGATA Located in the brainstem. Function: * Controls breathing rate Responds to: * Carbon dioxide levels More CO₂: * Faster breathing Less CO₂: * Slower breathing ⸻ LUNG VOLUMES Tidal Volume * Normal amount of air breathed in and out Inspiratory Reserve Volume * Extra air inhaled after normal breath Expiratory Reserve Volume * Extra air exhaled after normal breath Residual Volume * Air remaining in lungs after maximum exhalation Vital Capacity * Maximum amount of air exhaled after deepest breath Total Lung Capacity * Total amount of air lungs can hold ⸻ CIRCULATORY SYSTEM Functions: * Transport oxygen * Transport nutrients * Remove wastes * Maintain homeostasis * Transport hormones Humans have a CLOSED circulatory system. Blood remains inside vessels. ⸻ BLOOD VESSELS ARTERIES Function: * Carry blood away from heart Characteristics: * Thick walls * High pressure * Small lumen * No valves Usually oxygen-rich Exception: Pulmonary artery ⸻ VEINS Function: * Carry blood toward heart Characteristics: * Thin walls * Low pressure * Large lumen * Valves present Usually oxygen-poor Exception: Pulmonary vein ⸻ CAPILLARIES Smallest blood vessels. Functions: * Gas exchange * Nutrient exchange * Waste exchange Walls are one cell thick. ⸻ HEART STRUCTURE Blood Flow: Body ↓ Vena Cava ↓ Right Atrium ↓ Right Ventricle ↓ Pulmonary Artery ↓ Lungs ↓ Pulmonary Vein ↓ Left Atrium ↓ Left Ventricle ↓ Aorta ↓ Body ⸻ HEART CHAMBERS Right Atrium * Receives deoxygenated blood Right Ventricle * Pumps blood to lungs Left Atrium * Receives oxygenated blood Left Ventricle * Pumps blood to body ⸻ SEPTUM Wall separating left and right sides of heart. Prevents mixing of blood. ⸻ HEART VALVES Function: * Prevent backflow of blood Types: Atrioventricular (AV) Valves Pulmonary Semilunar Valve Aortic Semilunar Valve ⸻ SA NODE Sinoatrial Node Known as: * Natural pacemaker Initiates heartbeat. ⸻ AV NODE Atrioventricular Node Receives signal from SA node. Delays impulse slightly. Allows ventricles to fill before contraction. ⸻ BLOOD Components: 1. Plasma 2. Red Blood Cells 3. White Blood Cells 4. Platelets ⸻ PLASMA Liquid component of blood. Functions: * Transport nutrients * Transport hormones * Transport wastes ⸻ RED BLOOD CELLS (ERYTHROCYTES) Function: * Carry oxygen Contain: * Hemoglobin ⸻ HEMOGLOBIN Protein in red blood cells. Function: * Binds oxygen Allows oxygen transport. ⸻ WHITE BLOOD CELLS (LEUKOCYTES) Function: * Fight infection * Defend body Part of immune system. ⸻ PLATELETS Function: * Blood clotting Prevent blood loss. ⸻ BLOOD PRESSURE Force of blood against artery walls. Measured using: Sphygmomanometer Example: 120/80 120 = Systolic Pressure 80 = Diastolic Pressure ⸻ SYSTOLIC PRESSURE Pressure when heart contracts. ⸻ DIASTOLIC PRESSURE Pressure when heart relaxes. ⸻ HYPERTENSION High blood pressure. Can increase risk of: * Stroke * Heart attack * Kidney disease ⸻ STROKE VOLUME Amount of blood pumped per heartbeat. ⸻ CARDIAC OUTPUT Amount of blood pumped per minute. Formula: Cardiac Output = Heart Rate × Stroke Volume ⸻ ECG Electrocardiogram Measures electrical activity of heart. Used to detect: * Irregular heartbeat * Heart damage ⸻ PULMONARY CIRCULATION Heart → Lungs → Heart Purpose: * Oxygenate blood ⸻ SYSTEMIC CIRCULATION Heart → Body → Heart Purpose: * Deliver oxygen to tissues ⸻ HOMEOSTASIS DURING EXERCISE Body responds by: * Increasing heart rate * Increasing breathing rate * Increasing cardiac output * Redirecting blood to muscles * Sweating to cool body Purpose: Maintain stable internal conditions. ⸻ DIGESTIVE SYSTEM Functions: * Break down food * Absorb nutrients * Eliminate waste ⸻ DIGESTIVE TRACT Mouth ↓ Pharynx ↓ Esophagus ↓ Stomach ↓ Small Intestine ↓ Large Intestine ↓ Rectum ↓ Anus ⸻ MECHANICAL DIGESTION Physical breakdown of food. Examples: * Chewing * Churning ⸻ CHEMICAL DIGESTION Chemical breakdown of food using enzymes. Examples: * Amylase * Pepsin ⸻ SALIVA Functions: 1. Moistens food 2. Contains amylase Amylase begins carbohydrate digestion. ⸻ TONGUE Functions: 1. Forms bolus 2. Pushes food for swallowing ⸻ ESOPHAGUS Moves food to stomach. Uses: Peristalsis ⸻ PERISTALSIS Wave-like muscular contractions. Move food through digestive tract. ⸻ STOMACH Functions: * Stores food * Mixes food * Begins protein digestion Produces: * HCl * Pepsin * Mucus ⸻ HCl Hydrochloric Acid Functions: * Kills bacteria * Activates pepsin ⸻ PEPSIN Function: * Digests proteins ⸻ MUCUS Function: * Protects stomach lining ⸻ CHYME Semi-liquid food mixture leaving stomach. ⸻ HEARTBURN Cause: Stomach acid enters esophagus. Usually caused by weakened cardiac sphincter. ⸻ SMALL INTESTINE Main site of: * Digestion * Absorption Adaptations: * Long length * Folds * Villi * Microvilli Large surface area increases absorption. ⸻ DUODENUM First section. Functions: * Receives bile * Receives pancreatic enzymes * Most chemical digestion ⸻ JEJUNUM Main nutrient absorption. ⸻ ILEUM Final nutrient absorption. ⸻ VILLI Finger-like projections. Function: Increase surface area. ⸻ LIVER Functions: * Produces bile * Processes nutrients * Detoxifies blood ⸻ GALL BLADDER Functions: * Stores bile * Releases bile into small intestine ⸻ PANCREAS Functions: * Produces digestive enzymes * Produces bicarbonate ⸻ BILE Function: Emulsifies fats. Breaks large fat droplets into smaller droplets. Makes fat digestion easier. ⸻ DIGESTION OF CARBOHYDRATES Mouth: * Amylase begins digestion Small Intestine: * Pancreatic amylase continues digestion End Product: Glucose ⸻ DIGESTION OF PROTEINS Stomach: * Pepsin begins digestion Small Intestine: * Trypsin continues digestion End Product: Amino Acids ⸻ DIGESTION OF LIPIDS Small Intestine: * Bile emulsifies fats * Lipase digests fats End Product: Fatty Acids + Glycerol ⸻ EVOLUTION Evolution: Change in populations over time. Individuals do NOT evolve. Populations evolve. ⸻ DARWIN Proposed: Natural Selection Book: On the Origin of Species ⸻ WALLACE Independently developed theory of natural selection. ⸻ LAMARCK Proposed: Inheritance of acquired characteristics Example: Giraffes stretch necks and pass longer necks to offspring. This theory is incorrect. ⸻ NATURAL SELECTION Requirements: 1. Variation 2. Overproduction 3. Competition 4. Differential Survival 5. Reproduction Result: Adaptation ⸻ ADAPTATION Inherited characteristic that increases survival and reproduction. ⸻ SELECTIVE ADVANTAGE A characteristic that improves survival or reproduction. Example: Antibiotic resistance ⸻ SELECTIVE PRESSURE Environmental factor that influences survival. Examples: * Predators * Disease * Climate * Competition ⸻ VARIATION Differences among individuals in a population. Sources: * Mutation * Crossing Over * Random Assortment ⸻ MUTATION Ultimate source of new alleles. Creates genetic variation. ⸻ FOSSIL Preserved remains or traces of organisms. ⸻ FOSSIL RECORD Collection of fossils showing evolutionary history. Provides evidence for evolution. ⸻ RADIOACTIVE DATING Uses radioactive isotopes to determine fossil age. ⸻ UNIFORMITARIANISM Proposed by Lyell. Earth changes gradually over long periods of time. ⸻ CATASTROPHISM Proposed by Cuvier. Earth shaped by sudden catastrophic events. ⸻ BIOGEOGRAPHY Study of species distribution around Earth. Provides evidence for evolution. ⸻ EMBRYOLOGY Study of embryos. Similar embryos suggest common ancestry. ⸻ HOMOLOGOUS STRUCTURES Same evolutionary origin. Different functions. Example: Human arm Whale flipper Bat wing Evidence of common ancestry. ⸻ ANALOGOUS STRUCTURES Different origins. Same function. Example: Bird wing Insect wing Not evidence of close ancestry. ⸻ VESTIGIAL STRUCTURES Structures with little or no function. Examples: * Human appendix * Whale pelvis Evidence of evolution. ⸻ MIMICRY One species resembles another. Example: Syrphid fly resembles wasp. Provides protection. ⸻ ARTIFICIAL SELECTION Humans select traits. Examples: * Dog breeding * Crop breeding ⸻ DIRECTIONAL SELECTION One extreme phenotype favored. Graph shifts in one direction. ⸻ STABILIZING SELECTION Average phenotype favored. Extremes selected against. ⸻ DISRUPTIVE SELECTION Both extremes favored. Middle selected against. ⸻ GENETIC DRIFT Random change in allele frequencies. Most significant in small populations. ⸻ FOUNDER EFFECT Small group starts new population. Different allele frequencies from original population. ⸻ BOTTLENECK EFFECT Population drastically reduced. Loss of genetic variation. ⸻ GENE FLOW Movement of alleles between populations. Occurs through migration. ⸻ NON-RANDOM MATING Individuals choose specific mates. Can reduce variation. ⸻ SPECIES A group of organisms that can interbreed in nature and produce fertile offspring. ⸻ SPECIATION Formation of new species. ⸻ ALLOPATRIC SPECIATION Requires: Geographic isolation Example: Mountain separates populations. ⸻ SYMPATRIC SPECIATION Occurs without geographic isolation. ⸻ PRE-ZYGOTIC ISOLATION Prevents fertilization. Examples: * Different mating seasons * Different mating songs * Different habitats ⸻ POST-ZYGOTIC ISOLATION Occurs after fertilization. Example: Sterile hybrids Example: Mule DIVERSITY Prokaryotes vs Eukaryotes PROKARYOTES * No nucleus * No membrane-bound organelles * Circular DNA * Smaller * Examples: Eubacteria, Archaebacteria EUKARYOTES * Nucleus present * Membrane-bound organelles * Linear chromosomes * Larger * Examples: Protists, Fungi, Plants, Animals Three Differences: 1. Nucleus vs no nucleus 2. Organelles vs no organelles 3. Larger vs smaller ⸻ Taxonomy Kingdom Phylum Class Order Family Genus Species Mnemonic: King Philip Came Over For Good Soup ⸻ Binomial Nomenclature Genus + Species Example: Homo sapiens Rules: * Genus capitalized * Species lowercase * Italicized Purpose: * Universal naming system * Avoids confusion * Shows relationships ⸻ Dichotomous Key Used to identify organisms using paired choices. Example: 1a Has wings → Step 2 1b No wings → Step 3 ⸻ Six Kingdoms 1. Archaebacteria 2. Eubacteria 3. Protista 4. Fungi 5. Plantae 6. Animalia ⸻ VIRUSES Virus Structure: * DNA or RNA * Capsid * Attachment proteins * Sometimes envelope Why Viruses Are Not Living: * Not made of cells * Cannot reproduce independently * No metabolism * Need host cell ⸻ DNA Virus vs RNA Virus DNA Virus: * Contains DNA * More stable RNA Virus: * Contains RNA * Mutates faster ⸻ Lytic Cycle Attachment ↓ Penetration ↓ Replication ↓ Assembly ↓ Lysis Host cell bursts. ⸻ Lysogenic Cycle Attachment ↓ Penetration ↓ Integration into host DNA ↓ Host reproduces ↓ Virus DNA copied Cell survives initially. ⸻ ARCHAEBACTERIA Characteristics: * Prokaryotic * Unicellular * Extreme environments Three Groups: Methanogens * Produce methane Halophiles * Salt-loving Thermoacidophiles * Hot acidic environments ⸻ EUBACTERIA Characteristics: * Prokaryotic * Peptidoglycan cell wall * Binary fission Examples: * E. coli * Streptococcus ⸻ Binary Fission DNA Replication ↓ Cell Growth ↓ Cell Division ↓ Two Identical Cells ⸻ Conjugation DNA transfer through pilus. Importance: * Genetic variation * Antibiotic resistance ⸻ Antibiotic Resistance Mutation ↓ Antibiotic kills susceptible bacteria ↓ Resistant bacteria survive ↓ Resistant bacteria reproduce Natural Selection ⸻ PROTISTS Characteristics: * Eukaryotic * Mostly unicellular * Aquatic Three Groups: Animal-like * Amoeba * Paramecium Plant-like * Algae * Euglena Fungus-like * Slime molds ⸻ Amoeba * Uses pseudopods * Phagocytosis ⸻ Algae * Photosynthetic * Oxygen producer ⸻ Euglena * Chloroplasts * Flagellum * Photosynthesis * Can also feed heterotrophically ⸻ Malaria Cause: Plasmodium Kingdom: Protista ⸻ FUNGI Characteristics: * Eukaryotic * Heterotrophic * Chitin cell walls * Reproduce with spores Examples: * Mushrooms * Mold * Yeast ⸻ External Digestion Release enzymes ↓ Digest food outside body ↓ Absorb nutrients ⸻ Fungi vs Plants FUNGI * Heterotrophic * Chitin * No chloroplasts PLANTS * Autotrophic * Cellulose * Chloroplasts ⸻ PLANTS Biodiversity vs Monoculture BIODIVERSITY * Many species * Stable ecosystem * Disease resistance MONOCULTURE * One crop species * Low diversity * Disease risk ⸻ Bryophytes Definition: Nonvascular plants Examples: * Mosses * Liverworts Characteristics: * No xylem * No phloem * Need water for reproduction ⸻ Vascular Plants Contain: * Xylem * Phloem ⸻ Xylem Function: Water and minerals Direction: Roots → Leaves ⸻ Phloem Function: Sugars Direction: Throughout plant ⸻ Alternation of Generations Sporophyte (2n) ↓ meiosis Spores (n) ↓ Gametophyte (n) ↓ Gametes ↓ fertilization Zygote (2n) ↓ Sporophyte ⸻ Moss Life Cycle Spores ↓ Gametophyte ↓ Egg + Sperm ↓ Zygote ↓ Sporophyte ↓ Capsule ↓ Spores Know: * Capsule * Sporophyte * Gametophyte * Spores ⸻ Fern Life Cycle Fern ↓ Sori ↓ Spores ↓ Prothallus ↓ Gametes ↓ Fertilization ↓ Young Fern Know: * Frond * Sori * Sporangia * Prothallus ⸻ Gymnosperms Characteristics: * Naked seeds * Cones * Wind pollination * Evergreen Examples: * Pine * Spruce * Fir ⸻ Angiosperms Characteristics: * Flowers * Fruit * Seeds enclosed Examples: * Apple tree * Rose * Maple ⸻ Flower Structure Anther * Produces pollen Pollen Grain * Male gamete Stigma * Receives pollen Style * Connects stigma and ovary Ovary * Contains ovules Ovule * Female gamete Petals * Attract pollinators ⸻ Plant Tissues Meristematic * Growth Dermal * Protection Ground * Photosynthesis * Storage Vascular * Transport ⸻ Leaf Structure Blade * Main leaf surface Petiole * Connects leaf to stem Cuticle * Reduces water loss Palisade Mesophyll * Photosynthesis Spongy Mesophyll * Gas exchange Veins * Xylem + Phloem ⸻ Stomata Openings in leaves. Functions: * Gas exchange * Water loss ⸻ Guard Cells Control opening and closing of stomata. ⸻ Transpiration Water loss from leaves. Functions: * Pulls water upward * Cools plant * Moves minerals ⸻ Simple vs Compound Leaves Simple: * One blade Compound: * Multiple leaflets ⸻ Monocots vs Dicots MONOCOTS * 1 cotyledon * Parallel veins * Fibrous roots * Flower parts in 3s Examples: Corn Grass DICOTS * 2 cotyledons * Net veins * Taproot * Flower parts in 4s or 5s Examples: Bean Maple ⸻ Seeds Contain: * Embryo * Stored food * Seed coat Functions: * Protection * Survival * Dispersal ⸻ Seed Dispersal Wind * Dandelion Water * Coconut Animals * Burrs Explosive * Touch-me-not ⸻ Fruit vs Vegetable Fruit: * Comes from ovary * Contains seeds Examples: Tomato Apple Pepper Vegetable: * Root, stem, leaf, or flower Examples: Carrot Celery Broccoli ⸻ Factors Affecting Plant Growth 1. Light 2. Water 3. Carbon dioxide 4. Temperature 5. Soil nutrients 6. Oxygen 7. Soil pH 8. Space 9. Pollinators 10. Disease and pests

bio Genetics is the study of heredity and how traits are passed from parents to offspring. Gregor Mendel is known as the “Father of Genetics.” Why did Mendel use pea plants? * Easy to grow * Short generation time * Many visible traits * Can self-pollinate or cross-pollinate * Produce many offspring Examples of traits studied: * Flower colour * Seed shape * Plant height ⸻ VOCABULARY Gene * A segment of DNA that controls a trait. Allele * Different forms of the same gene. Example: P = purple flowers p = white flowers Dominant Allele * Expressed whenever it is present. * Represented by a capital letter. Example: P = purple Recessive Allele * Only expressed when two copies are present. * Represented by a lowercase letter. Example: p = white Genotype * Genetic makeup of an organism. Examples: PP Pp pp Phenotype * Physical appearance of an organism. Examples: Purple flower White flower Homozygous * Two identical alleles. Examples: PP pp Heterozygous * Two different alleles. Example: Pp Pure Breeding * Homozygous for a trait. Gamete * Sex cell (sperm or egg). ⸻ MENDEL’S LAWS Law of Dominance * A dominant allele masks a recessive allele. Example: Pp = Purple flower Law of Segregation * Alleles separate during gamete formation. * Each gamete receives only one allele. Example: Parent = Pp Gametes: P p Law of Independent Assortment * Different genes assort independently during meiosis. ⸻ MONOHYBRID CROSSES A monohybrid cross studies one trait. Example: P = Purple p = White Cross: Pp × Pp Punnett Square INCOMPLETE DOMINANCE Neither allele completely dominates. Example: Snapdragons RR = Red WW = White RW = Pink Cross: RW × RW Genotype Ratio: 1 RR : 2 RW : 1 WW Phenotype Ratio: 1 Red : 2 Pink : 1 White CODOMINANCE Both alleles are expressed equally. Example: AB Blood Type Genotype: IAIB Phenotype: AB MULTIPLE ALLELES More than two alleles exist in a population. Example: ABO Blood Group Alleles: IA IB i BLOOD TYPES Type A Genotypes: IAIA or IAi Type B Genotypes: IBIB or IBi Type AB Genotype: IAIB Type O Genotype: ii Can Type A and Type B Parents Have a Type O Child? Yes. If: Father = IAi Mother = IBi Possible Blood Types: AB A B O CELL CYCLE Purpose: * Growth * Repair * Replacement of cells Stages: G1 S G2 Mitosis Cytokinesis INTERPHASE G1 Phase Cell grows and carries out normal functions. S Phase DNA replication occurs. G2 Phase Cell prepares for division. MITOSIS Purpose: Growth and repair. Produces: 2 genetically identical diploid cells. PROPHASE Events: * Chromosomes condense * Nuclear membrane disappears * Nucleolus disappears * Spindle fibres form METAPHASE Events: * Chromosomes line up at the equator ANAPHASE Events: * Sister chromatids separate TELOPHASE Events: * Nuclear membranes reform * Chromosomes uncoil CYTOKINESIS Division of the cytoplasm. Animal Cells: Cleavage furrow forms. Plant Cells: Cell plate forms. CHROMOSOME STRUCTURE Chromosome consists of: * Two sister chromatids * One centromere DIPLOID VS HAPLOID Diploid (2n) * Two sets of chromosomes * Human body cells * 46 chromosomes Haploid (n) * One set of chromosomes * Human gametes * 23 chromosomes HOMOLOGOUS CHROMOSOMES Chromosome pairs that: * Carry the same genes * One comes from the mother * One comes from the father Humans have 23 homologous pairs. MEIOSIS Purpose: Produce gametes. Produces: 4 genetically unique haploid cells. MEIOSIS I Separates homologous chromosomes. CROSSING OVER Occurs during Prophase I. Definition: Exchange of DNA between homologous chromosomes. Importance: Creates genetic variation. RANDOM ASSORTMENT Occurs during Metaphase I. Definition: Homologous pairs line up randomly. Importance: Creates unique chromosome combinations. MEIOSIS II Separates sister chromatids. MITOSIS VS MEIOSIS Mitosis * 2 cells produced * Diploid * Genetically identical * Growth and repair Meiosis * 4 cells produced * Haploid * Genetically different * Produces gametes NONDISJUNCTION Failure of chromosomes to separate properly during meiosis. Can result in extra or missing chromosomes. DOWN SYNDROME Cause: Extra chromosome 21. Chromosome Number: 47 Usually caused by nondisjunction during meiosis. DNA DNA = Deoxyribonucleic Acid Shape: Double Helix Function: Stores genetic information. NUCLEOTIDE Three Components: * Phosphate Group * Deoxyribose Sugar * Nitrogenous Base NITROGENOUS BASES Adenine (A) Thymine (T) Cytosine (C) Guanine (G) COMPLEMENTARY BASE PAIRING A pairs with T C pairs with G DNA REPLICATION Purpose: Make identical copies of DNA. Location: Nucleus Result: Two identical DNA molecules. TRANSCRIPTION Purpose: Create mRNA from DNA. Location: Nucleus DNA → mRNA Remember: RNA uses Uracil (U) instead of Thymine (T). TRANSLATION Purpose: Make proteins. Location: Ribosome mRNA is read and amino acids are joined together to form a protein. MUTATIONS A mutation is a change in DNA sequence. Types: * Deletion * Duplication * Inversion * Translocation DELETION DNA segment removed. DUPLICATION DNA segment repeated. INVERSION DNA segment reversed. TRANSLOCATION DNA segment moves to another chromosome. SEX-LINKED TRAITS Traits located on sex chromosomes. Most are located on the X chromosome. RED-GREEN COLOUR BLINDNESS Inheritance: X-linked recessive. XC = Normal Vision Xc = Colour Blind Male: XcY Colour blind boys inherit the allele from their mother because fathers pass a Y chromosome to their sons. TAY-SACHS DISEASE Cause: Missing enzyme that breaks down lipids in nerve cells. Inheritance: Autosomal recessive. Treatment: No cure currently available. SICKLE CELL ANEMIA Cause: Mutation in hemoglobin gene. Effects: * Sickle-shaped red blood cells * Reduced oxygen transport * Blocked blood vessels Inheritance: Autosomal recessive. HUNTINGTON’S DISEASE Cause: Dominant mutation. Effects: * Nervous system degeneration * Loss of motor control * Cognitive decline Inheritance: Autosomal dominant. KARYOTYPE A photograph of chromosomes arranged in pairs. Used to: * Determine sex * Detect chromosome abnormalities * Diagnose genetic disorders PEDIGREE A family tree used to track inheritance patterns. Symbols: Square = Male Circle = Female Shaded = Has trait CLONING Producing genetically identical organisms. Uses: * Research * Agriculture * Medicine * Conservation GENETIC COUNSELLING Provides information about: * Inherited disorders * Family risk * Testing options AMNIOCENTESIS Prenatal test in which amniotic fluid is sampled and fetal cells are analyzed. Can detect: * Genetic disorders * Chromosomal disorders GMOs Genetically Modified Organisms. Definition: Organisms whose DNA has been altered through biotechnology. Advantages: * Increased crop yield * Disease resistance * Pest resistance Disadvantages: * Ethical concerns * Environmental concerns DNA REPLICATION → TRANSCRIPTION → TRANSLATION DNA (Nucleus) ↓ Replication DNA Copy DNA ↓ Transcription mRNA mRNA ↓ Translation Protein Final Product: Protein RESPIRATORY SYSTEM Function: * Brings oxygen into the body * Removes carbon dioxide * Works with the circulatory system to supply cells with oxygen Why do organisms require oxygen and produce carbon dioxide? Oxygen is required for cellular respiration. Cellular Respiration: Glucose + Oxygen → Energy (ATP) + Carbon Dioxide + Water Cells use oxygen to release energy from food. Carbon dioxide is produced as a waste product and must be removed. ⸻ PATHWAY OF AIR Nasal Cavity ↓ Pharynx ↓ Larynx ↓ Trachea ↓ Bronchi ↓ Bronchioles ↓ Alveoli ⸻ NASAL CAVITY Functions: * Warms air * Moistens air * Filters air Nasal Hairs: * Trap large particles Mucus: * Traps dust and microorganisms Blood Capillaries: * Warm incoming air ⸻ PHARYNX Common passageway for: * Air * Food Also called the throat. ⸻ UVULA Functions: * Prevents food from entering nasal cavity * Helps with speech ⸻ EPIGLOTTIS Functions: * Covers trachea during swallowing * Prevents choking ⸻ LARYNX Also called the voice box. Contains vocal cords. ⸻ TRACHEA Also called the windpipe. Contains cartilage rings that prevent collapse. Lined with: * Cilia * Mucus ⸻ CILIA Tiny hair-like structures. Function: * Sweep mucus upward toward throat ⸻ BRONCHI Two branches of the trachea leading to lungs. Right Bronchus → Right Lung Left Bronchus → Left Lung ⸻ BRONCHIOLES Smaller branches inside lungs. Lead to alveoli. ⸻ ALVEOLI Tiny air sacs. Site of gas exchange. Adaptations: * Thin walls * Moist surface * Large surface area * Rich blood supply Gas Exchange: Oxygen moves: Alveoli → Blood Carbon Dioxide moves: Blood → Alveoli By diffusion. ⸻ BREATHING MECHANICS Two main muscles: 1. Diaphragm 2. Intercostal Muscles ⸻ INHALATION (INSPIRATION) Diaphragm: * Contracts * Moves downward Intercostal Muscles: * Contract * Lift ribs upward Result: * Chest cavity volume increases * Pressure decreases * Air enters lungs ⸻ EXHALATION (EXPIRATION) Diaphragm: * Relaxes * Moves upward Intercostal Muscles: * Relax Result: * Chest cavity volume decreases * Pressure increases * Air leaves lungs ⸻ MEDULLA OBLONGATA Located in the brainstem. Function: * Controls breathing rate Responds to: * Carbon dioxide levels More CO₂: * Faster breathing Less CO₂: * Slower breathing ⸻ LUNG VOLUMES Tidal Volume * Normal amount of air breathed in and out Inspiratory Reserve Volume * Extra air inhaled after normal breath Expiratory Reserve Volume * Extra air exhaled after normal breath Residual Volume * Air remaining in lungs after maximum exhalation Vital Capacity * Maximum amount of air exhaled after deepest breath Total Lung Capacity * Total amount of air lungs can hold ⸻ CIRCULATORY SYSTEM Functions: * Transport oxygen * Transport nutrients * Remove wastes * Maintain homeostasis * Transport hormones Humans have a CLOSED circulatory system. Blood remains inside vessels. ⸻ BLOOD VESSELS ARTERIES Function: * Carry blood away from heart Characteristics: * Thick walls * High pressure * Small lumen * No valves Usually oxygen-rich Exception: Pulmonary artery ⸻ VEINS Function: * Carry blood toward heart Characteristics: * Thin walls * Low pressure * Large lumen * Valves present Usually oxygen-poor Exception: Pulmonary vein ⸻ CAPILLARIES Smallest blood vessels. Functions: * Gas exchange * Nutrient exchange * Waste exchange Walls are one cell thick. ⸻ HEART STRUCTURE Blood Flow: Body ↓ Vena Cava ↓ Right Atrium ↓ Right Ventricle ↓ Pulmonary Artery ↓ Lungs ↓ Pulmonary Vein ↓ Left Atrium ↓ Left Ventricle ↓ Aorta ↓ Body ⸻ HEART CHAMBERS Right Atrium * Receives deoxygenated blood Right Ventricle * Pumps blood to lungs Left Atrium * Receives oxygenated blood Left Ventricle * Pumps blood to body ⸻ SEPTUM Wall separating left and right sides of heart. Prevents mixing of blood. ⸻ HEART VALVES Function: * Prevent backflow of blood Types: Atrioventricular (AV) Valves Pulmonary Semilunar Valve Aortic Semilunar Valve ⸻ SA NODE Sinoatrial Node Known as: * Natural pacemaker Initiates heartbeat. ⸻ AV NODE Atrioventricular Node Receives signal from SA node. Delays impulse slightly. Allows ventricles to fill before contraction. ⸻ BLOOD Components: 1. Plasma 2. Red Blood Cells 3. White Blood Cells 4. Platelets ⸻ PLASMA Liquid component of blood. Functions: * Transport nutrients * Transport hormones * Transport wastes ⸻ RED BLOOD CELLS (ERYTHROCYTES) Function: * Carry oxygen Contain: * Hemoglobin ⸻ HEMOGLOBIN Protein in red blood cells. Function: * Binds oxygen Allows oxygen transport. ⸻ WHITE BLOOD CELLS (LEUKOCYTES) Function: * Fight infection * Defend body Part of immune system. ⸻ PLATELETS Function: * Blood clotting Prevent blood loss. ⸻ BLOOD PRESSURE Force of blood against artery walls. Measured using: Sphygmomanometer Example: 120/80 120 = Systolic Pressure 80 = Diastolic Pressure ⸻ SYSTOLIC PRESSURE Pressure when heart contracts. ⸻ DIASTOLIC PRESSURE Pressure when heart relaxes. ⸻ HYPERTENSION High blood pressure. Can increase risk of: * Stroke * Heart attack * Kidney disease ⸻ STROKE VOLUME Amount of blood pumped per heartbeat. ⸻ CARDIAC OUTPUT Amount of blood pumped per minute. Formula: Cardiac Output = Heart Rate × Stroke Volume ⸻ ECG Electrocardiogram Measures electrical activity of heart. Used to detect: * Irregular heartbeat * Heart damage ⸻ PULMONARY CIRCULATION Heart → Lungs → Heart Purpose: * Oxygenate blood ⸻ SYSTEMIC CIRCULATION Heart → Body → Heart Purpose: * Deliver oxygen to tissues ⸻ HOMEOSTASIS DURING EXERCISE Body responds by: * Increasing heart rate * Increasing breathing rate * Increasing cardiac output * Redirecting blood to muscles * Sweating to cool body Purpose: Maintain stable internal conditions. ⸻ DIGESTIVE SYSTEM Functions: * Break down food * Absorb nutrients * Eliminate waste ⸻ DIGESTIVE TRACT Mouth ↓ Pharynx ↓ Esophagus ↓ Stomach ↓ Small Intestine ↓ Large Intestine ↓ Rectum ↓ Anus ⸻ MECHANICAL DIGESTION Physical breakdown of food. Examples: * Chewing * Churning ⸻ CHEMICAL DIGESTION Chemical breakdown of food using enzymes. Examples: * Amylase * Pepsin ⸻ SALIVA Functions: 1. Moistens food 2. Contains amylase Amylase begins carbohydrate digestion. ⸻ TONGUE Functions: 1. Forms bolus 2. Pushes food for swallowing ⸻ ESOPHAGUS Moves food to stomach. Uses: Peristalsis ⸻ PERISTALSIS Wave-like muscular contractions. Move food through digestive tract. ⸻ STOMACH Functions: * Stores food * Mixes food * Begins protein digestion Produces: * HCl * Pepsin * Mucus ⸻ HCl Hydrochloric Acid Functions: * Kills bacteria * Activates pepsin ⸻ PEPSIN Function: * Digests proteins ⸻ MUCUS Function: * Protects stomach lining ⸻ CHYME Semi-liquid food mixture leaving stomach. ⸻ HEARTBURN Cause: Stomach acid enters esophagus. Usually caused by weakened cardiac sphincter. ⸻ SMALL INTESTINE Main site of: * Digestion * Absorption Adaptations: * Long length * Folds * Villi * Microvilli Large surface area increases absorption. ⸻ DUODENUM First section. Functions: * Receives bile * Receives pancreatic enzymes * Most chemical digestion ⸻ JEJUNUM Main nutrient absorption. ⸻ ILEUM Final nutrient absorption. ⸻ VILLI Finger-like projections. Function: Increase surface area. ⸻ LIVER Functions: * Produces bile * Processes nutrients * Detoxifies blood ⸻ GALL BLADDER Functions: * Stores bile * Releases bile into small intestine ⸻ PANCREAS Functions: * Produces digestive enzymes * Produces bicarbonate ⸻ BILE Function: Emulsifies fats. Breaks large fat droplets into smaller droplets. Makes fat digestion easier. ⸻ DIGESTION OF CARBOHYDRATES Mouth: * Amylase begins digestion Small Intestine: * Pancreatic amylase continues digestion End Product: Glucose ⸻ DIGESTION OF PROTEINS Stomach: * Pepsin begins digestion Small Intestine: * Trypsin continues digestion End Product: Amino Acids ⸻ DIGESTION OF LIPIDS Small Intestine: * Bile emulsifies fats * Lipase digests fats End Product: Fatty Acids + Glycerol ⸻ EVOLUTION Evolution: Change in populations over time. Individuals do NOT evolve. Populations evolve. ⸻ DARWIN Proposed: Natural Selection Book: On the Origin of Species ⸻ WALLACE Independently developed theory of natural selection. ⸻ LAMARCK Proposed: Inheritance of acquired characteristics Example: Giraffes stretch necks and pass longer necks to offspring. This theory is incorrect. ⸻ NATURAL SELECTION Requirements: 1. Variation 2. Overproduction 3. Competition 4. Differential Survival 5. Reproduction Result: Adaptation ⸻ ADAPTATION Inherited characteristic that increases survival and reproduction. ⸻ SELECTIVE ADVANTAGE A characteristic that improves survival or reproduction. Example: Antibiotic resistance ⸻ SELECTIVE PRESSURE Environmental factor that influences survival. Examples: * Predators * Disease * Climate * Competition ⸻ VARIATION Differences among individuals in a population. Sources: * Mutation * Crossing Over * Random Assortment ⸻ MUTATION Ultimate source of new alleles. Creates genetic variation. ⸻ FOSSIL Preserved remains or traces of organisms. ⸻ FOSSIL RECORD Collection of fossils showing evolutionary history. Provides evidence for evolution. ⸻ RADIOACTIVE DATING Uses radioactive isotopes to determine fossil age. ⸻ UNIFORMITARIANISM Proposed by Lyell. Earth changes gradually over long periods of time. ⸻ CATASTROPHISM Proposed by Cuvier. Earth shaped by sudden catastrophic events. ⸻ BIOGEOGRAPHY Study of species distribution around Earth. Provides evidence for evolution. ⸻ EMBRYOLOGY Study of embryos. Similar embryos suggest common ancestry. ⸻ HOMOLOGOUS STRUCTURES Same evolutionary origin. Different functions. Example: Human arm Whale flipper Bat wing Evidence of common ancestry. ⸻ ANALOGOUS STRUCTURES Different origins. Same function. Example: Bird wing Insect wing Not evidence of close ancestry. ⸻ VESTIGIAL STRUCTURES Structures with little or no function. Examples: * Human appendix * Whale pelvis Evidence of evolution. ⸻ MIMICRY One species resembles another. Example: Syrphid fly resembles wasp. Provides protection. ⸻ ARTIFICIAL SELECTION Humans select traits. Examples: * Dog breeding * Crop breeding ⸻ DIRECTIONAL SELECTION One extreme phenotype favored. Graph shifts in one direction. ⸻ STABILIZING SELECTION Average phenotype favored. Extremes selected against. ⸻ DISRUPTIVE SELECTION Both extremes favored. Middle selected against. ⸻ GENETIC DRIFT Random change in allele frequencies. Most significant in small populations. ⸻ FOUNDER EFFECT Small group starts new population. Different allele frequencies from original population. ⸻ BOTTLENECK EFFECT Population drastically reduced. Loss of genetic variation. ⸻ GENE FLOW Movement of alleles between populations. Occurs through migration. ⸻ NON-RANDOM MATING Individuals choose specific mates. Can reduce variation. ⸻ SPECIES A group of organisms that can interbreed in nature and produce fertile offspring. ⸻ SPECIATION Formation of new species. ⸻ ALLOPATRIC SPECIATION Requires: Geographic isolation Example: Mountain separates populations. ⸻ SYMPATRIC SPECIATION Occurs without geographic isolation. ⸻ PRE-ZYGOTIC ISOLATION Prevents fertilization. Examples: * Different mating seasons * Different mating songs * Different habitats ⸻ POST-ZYGOTIC ISOLATION Occurs after fertilization. Example: Sterile hybrids Example: Mule DIVERSITY Prokaryotes vs Eukaryotes PROKARYOTES * No nucleus * No membrane-bound organelles * Circular DNA * Smaller * Examples: Eubacteria, Archaebacteria EUKARYOTES * Nucleus present * Membrane-bound organelles * Linear chromosomes * Larger * Examples: Protists, Fungi, Plants, Animals Three Differences: 1. Nucleus vs no nucleus 2. Organelles vs no organelles 3. Larger vs smaller ⸻ Taxonomy Kingdom Phylum Class Order Family Genus Species Mnemonic: King Philip Came Over For Good Soup ⸻ Binomial Nomenclature Genus + Species Example: Homo sapiens Rules: * Genus capitalized * Species lowercase * Italicized Purpose: * Universal naming system * Avoids confusion * Shows relationships ⸻ Dichotomous Key Used to identify organisms using paired choices. Example: 1a Has wings → Step 2 1b No wings → Step 3 ⸻ Six Kingdoms 1. Archaebacteria 2. Eubacteria 3. Protista 4. Fungi 5. Plantae 6. Animalia ⸻ VIRUSES Virus Structure: * DNA or RNA * Capsid * Attachment proteins * Sometimes envelope Why Viruses Are Not Living: * Not made of cells * Cannot reproduce independently * No metabolism * Need host cell ⸻ DNA Virus vs RNA Virus DNA Virus: * Contains DNA * More stable RNA Virus: * Contains RNA * Mutates faster ⸻ Lytic Cycle Attachment ↓ Penetration ↓ Replication ↓ Assembly ↓ Lysis Host cell bursts. ⸻ Lysogenic Cycle Attachment ↓ Penetration ↓ Integration into host DNA ↓ Host reproduces ↓ Virus DNA copied Cell survives initially. ⸻ ARCHAEBACTERIA Characteristics: * Prokaryotic * Unicellular * Extreme environments Three Groups: Methanogens * Produce methane Halophiles * Salt-loving Thermoacidophiles * Hot acidic environments ⸻ EUBACTERIA Characteristics: * Prokaryotic * Peptidoglycan cell wall * Binary fission Examples: * E. coli * Streptococcus ⸻ Binary Fission DNA Replication ↓ Cell Growth ↓ Cell Division ↓ Two Identical Cells ⸻ Conjugation DNA transfer through pilus. Importance: * Genetic variation * Antibiotic resistance ⸻ Antibiotic Resistance Mutation ↓ Antibiotic kills susceptible bacteria ↓ Resistant bacteria survive ↓ Resistant bacteria reproduce Natural Selection ⸻ PROTISTS Characteristics: * Eukaryotic * Mostly unicellular * Aquatic Three Groups: Animal-like * Amoeba * Paramecium Plant-like * Algae * Euglena Fungus-like * Slime molds ⸻ Amoeba * Uses pseudopods * Phagocytosis ⸻ Algae * Photosynthetic * Oxygen producer ⸻ Euglena * Chloroplasts * Flagellum * Photosynthesis * Can also feed heterotrophically ⸻ Malaria Cause: Plasmodium Kingdom: Protista ⸻ FUNGI Characteristics: * Eukaryotic * Heterotrophic * Chitin cell walls * Reproduce with spores Examples: * Mushrooms * Mold * Yeast ⸻ External Digestion Release enzymes ↓ Digest food outside body ↓ Absorb nutrients ⸻ Fungi vs Plants FUNGI * Heterotrophic * Chitin * No chloroplasts PLANTS * Autotrophic * Cellulose * Chloroplasts ⸻ PLANTS Biodiversity vs Monoculture BIODIVERSITY * Many species * Stable ecosystem * Disease resistance MONOCULTURE * One crop species * Low diversity * Disease risk ⸻ Bryophytes Definition: Nonvascular plants Examples: * Mosses * Liverworts Characteristics: * No xylem * No phloem * Need water for reproduction ⸻ Vascular Plants Contain: * Xylem * Phloem ⸻ Xylem Function: Water and minerals Direction: Roots → Leaves ⸻ Phloem Function: Sugars Direction: Throughout plant ⸻ Alternation of Generations Sporophyte (2n) ↓ meiosis Spores (n) ↓ Gametophyte (n) ↓ Gametes ↓ fertilization Zygote (2n) ↓ Sporophyte ⸻ Moss Life Cycle Spores ↓ Gametophyte ↓ Egg + Sperm ↓ Zygote ↓ Sporophyte ↓ Capsule ↓ Spores Know: * Capsule * Sporophyte * Gametophyte * Spores ⸻ Fern Life Cycle Fern ↓ Sori ↓ Spores ↓ Prothallus ↓ Gametes ↓ Fertilization ↓ Young Fern Know: * Frond * Sori * Sporangia * Prothallus ⸻ Gymnosperms Characteristics: * Naked seeds * Cones * Wind pollination * Evergreen Examples: * Pine * Spruce * Fir ⸻ Angiosperms Characteristics: * Flowers * Fruit * Seeds enclosed Examples: * Apple tree * Rose * Maple ⸻ Flower Structure Anther * Produces pollen Pollen Grain * Male gamete Stigma * Receives pollen Style * Connects stigma and ovary Ovary * Contains ovules Ovule * Female gamete Petals * Attract pollinators ⸻ Plant Tissues Meristematic * Growth Dermal * Protection Ground * Photosynthesis * Storage Vascular * Transport ⸻ Leaf Structure Blade * Main leaf surface Petiole * Connects leaf to stem Cuticle * Reduces water loss Palisade Mesophyll * Photosynthesis Spongy Mesophyll * Gas exchange Veins * Xylem + Phloem ⸻ Stomata Openings in leaves. Functions: * Gas exchange * Water loss ⸻ Guard Cells Control opening and closing of stomata. ⸻ Transpiration Water loss from leaves. Functions: * Pulls water upward * Cools plant * Moves minerals ⸻ Simple vs Compound Leaves Simple: * One blade Compound: * Multiple leaflets ⸻ Monocots vs Dicots MONOCOTS * 1 cotyledon * Parallel veins * Fibrous roots * Flower parts in 3s Examples: Corn Grass DICOTS * 2 cotyledons * Net veins * Taproot * Flower parts in 4s or 5s Examples: Bean Maple ⸻ Seeds Contain: * Embryo * Stored food * Seed coat Functions: * Protection * Survival * Dispersal ⸻ Seed Dispersal Wind * Dandelion Water * Coconut Animals * Burrs Explosive * Touch-me-not ⸻ Fruit vs Vegetable Fruit: * Comes from ovary * Contains seeds Examples: Tomato Apple Pepper Vegetable: * Root, stem, leaf, or flower Examples: Carrot Celery Broccoli ⸻ Factors Affecting Plant Growth 1. Light 2. Water 3. Carbon dioxide 4. Temperature 5. Soil nutrients 6. Oxygen 7. Soil pH 8. Space 9. Pollinators 10. Disease and pests

GENETICS

Genetics is the study of heredity and how traits are passed from parents to offspring.

Gregor Mendel is known as the “Father of Genetics.”

Why did Mendel use pea plants?

Easy to grow
Short generation time
Many visible traits
Can self-pollinate or cross-pollinate
Produce many offspring

Examples of traits studied:

Flower colour
Seed shape
Plant height

⸻

VOCABULARY

Gene

A segment of DNA that controls a trait.

Allele

Different forms of the same gene.

Example:

P = purple flowers

p = white flowers

Dominant Allele

Expressed whenever it is present.
Represented by a capital letter.

Example:

P = purple

Recessive Allele

Only expressed when two copies are present.
Represented by a lowercase letter.

Example:

p = white

Genotype

Genetic makeup of an organism.

Examples:

Phenotype

Physical appearance of an organism.

Examples:

Purple flower

White flower

Homozygous

Two identical alleles.

Examples:

Heterozygous

Two different alleles.

Example:

Pure Breeding

Homozygous for a trait.

Gamete

Sex cell (sperm or egg).

⸻

MENDEL’S LAWS

Law of Dominance

A dominant allele masks a recessive allele.

Example:

Pp = Purple flower

Law of Segregation

Alleles separate during gamete formation.
Each gamete receives only one allele.

Example:

Parent = Pp

Gametes:

Law of Independent Assortment

Different genes assort independently during meiosis.

⸻

MONOHYBRID CROSSES

A monohybrid cross studies one trait.

Example:

P = Purple

p = White

Cross:

Pp × Pp

Punnett Square

INCOMPLETE DOMINANCE

Neither allele completely dominates.

Example:

Snapdragons

RR = Red

WW = White

RW = Pink

Cross:

RW × RW

Genotype Ratio:

1 RR : 2 RW : 1 WW

Phenotype Ratio:

1 Red : 2 Pink : 1 White

CODOMINANCE

Both alleles are expressed equally.

Example:

AB Blood Type

Genotype:

IAIB

Phenotype:

MULTIPLE ALLELES

More than two alleles exist in a population.

Example:

ABO Blood Group

Alleles:

BLOOD TYPES

Type A

Genotypes:

IAIA or IAi

Type B

Genotypes:

IBIB or IBi

Type AB

Genotype:

IAIB

Type O

Genotype:

Can Type A and Type B Parents Have a Type O Child?

Yes.

If:

Father = IAi

Mother = IBi

Possible Blood Types:

CELL CYCLE

Purpose:

Growth
Repair
Replacement of cells

Stages:

Mitosis

Cytokinesis

INTERPHASE

G1 Phase

Cell grows and carries out normal functions.

S Phase

DNA replication occurs.

G2 Phase

Cell prepares for division.

MITOSIS

Purpose:

Growth and repair.

Produces:

2 genetically identical diploid cells.

PROPHASE

Events:

Chromosomes condense
Nuclear membrane disappears
Nucleolus disappears
Spindle fibres form

METAPHASE

Events:

Chromosomes line up at the equator

ANAPHASE

Events:

Sister chromatids separate

TELOPHASE

Events:

Nuclear membranes reform
Chromosomes uncoil

CYTOKINESIS

Division of the cytoplasm.

Animal Cells:

Cleavage furrow forms.

Plant Cells:

Cell plate forms.

CHROMOSOME STRUCTURE

Chromosome consists of:

Two sister chromatids
One centromere

DIPLOID VS HAPLOID

Diploid (2n)

Two sets of chromosomes
Human body cells
46 chromosomes

Haploid (n)

One set of chromosomes
Human gametes
23 chromosomes

HOMOLOGOUS CHROMOSOMES

Chromosome pairs that:

Carry the same genes
One comes from the mother
One comes from the father

Humans have 23 homologous pairs.

MEIOSIS

Purpose:

Produce gametes.

Produces:

4 genetically unique haploid cells.

MEIOSIS I

Separates homologous chromosomes.

CROSSING OVER

Occurs during Prophase I.

Definition:

Exchange of DNA between homologous chromosomes.

Importance:

Creates genetic variation.

RANDOM ASSORTMENT

Occurs during Metaphase I.

Definition:

Homologous pairs line up randomly.

Importance:

Creates unique chromosome combinations.

MEIOSIS II

Separates sister chromatids.

MITOSIS VS MEIOSIS

Mitosis

2 cells produced
Diploid
Genetically identical
Growth and repair

Meiosis

4 cells produced
Haploid
Genetically different
Produces gametes

NONDISJUNCTION

Failure of chromosomes to separate properly during meiosis.

Can result in extra or missing chromosomes.

DOWN SYNDROME

Cause:

Extra chromosome 21.

Chromosome Number:

Usually caused by nondisjunction during meiosis.

DNA

DNA = Deoxyribonucleic Acid

Shape:

Double Helix

Function:

Stores genetic information.

NUCLEOTIDE

Three Components:

Phosphate Group
Deoxyribose Sugar
Nitrogenous Base

NITROGENOUS BASES

Adenine (A)

Thymine (T)

Cytosine (C)

Guanine (G)

COMPLEMENTARY BASE PAIRING

A pairs with T

C pairs with G

DNA REPLICATION

Purpose:

Make identical copies of DNA.

Location:

Nucleus

Result:

Two identical DNA molecules.

TRANSCRIPTION

Purpose:

Create mRNA from DNA.

Location:

Nucleus

DNA → mRNA

Remember:

RNA uses Uracil (U) instead of Thymine (T).

TRANSLATION

Purpose:

Make proteins.

Location:

Ribosome

mRNA is read and amino acids are joined together to form a protein.

MUTATIONS

A mutation is a change in DNA sequence.

Types:

Deletion
Duplication
Inversion
Translocation

DELETION

DNA segment removed.

DUPLICATION

DNA segment repeated.

INVERSION

DNA segment reversed.

TRANSLOCATION

DNA segment moves to another chromosome.

SEX-LINKED TRAITS

Traits located on sex chromosomes.

Most are located on the X chromosome.

RED-GREEN COLOUR BLINDNESS

Inheritance:

X-linked recessive.

XC = Normal Vision

Xc = Colour Blind

Male:

XcY

Colour blind boys inherit the allele from their mother because fathers pass a Y chromosome to their sons.

TAY-SACHS DISEASE

Cause:

Missing enzyme that breaks down lipids in nerve cells.

Inheritance:

Autosomal recessive.

Treatment:

No cure currently available.

SICKLE CELL ANEMIA

Cause:

Mutation in hemoglobin gene.

Effects:

Sickle-shaped red blood cells
Reduced oxygen transport
Blocked blood vessels

Inheritance:

Autosomal recessive.

HUNTINGTON’S DISEASE

Cause:

Dominant mutation.

Effects:

Nervous system degeneration
Loss of motor control
Cognitive decline

Inheritance:

Autosomal dominant.

KARYOTYPE

A photograph of chromosomes arranged in pairs.

Used to:

Determine sex
Detect chromosome abnormalities
Diagnose genetic disorders

PEDIGREE

A family tree used to track inheritance patterns.

Symbols:

Square = Male

Circle = Female

Shaded = Has trait

CLONING

Producing genetically identical organisms.

Uses:

Research
Agriculture
Medicine
Conservation

GENETIC COUNSELLING

Provides information about:

Inherited disorders
Family risk
Testing options

AMNIOCENTESIS

Prenatal test in which amniotic fluid is sampled and fetal cells are analyzed.

Can detect:

Genetic disorders
Chromosomal disorders

GMOs

Genetically Modified Organisms.

Definition:

Organisms whose DNA has been altered through biotechnology.

Advantages:

Increased crop yield
Disease resistance
Pest resistance

Disadvantages:

Ethical concerns
Environmental concerns

DNA REPLICATION → TRANSCRIPTION → TRANSLATION

DNA (Nucleus)

↓ Replication

DNA Copy

DNA

↓ Transcription

mRNA

↓ Translation

Protein

Final Product:

Protein

RESPIRATORY SYSTEM

Function:

Brings oxygen into the body
Removes carbon dioxide
Works with the circulatory system to supply cells with oxygen

Why do organisms require oxygen and produce carbon dioxide?

Oxygen is required for cellular respiration.

Cellular Respiration:

Glucose + Oxygen → Energy (ATP) + Carbon Dioxide + Water

Cells use oxygen to release energy from food.

Carbon dioxide is produced as a waste product and must be removed.

⸻

PATHWAY OF AIR

Nasal Cavity

↓

Pharynx

↓

Larynx

↓

Trachea

↓

Bronchi

↓

Bronchioles

↓

Alveoli

⸻

NASAL CAVITY

Functions:

Warms air
Moistens air
Filters air

Nasal Hairs:

Trap large particles

Mucus:

Traps dust and microorganisms

Blood Capillaries:

Warm incoming air

⸻

PHARYNX

Common passageway for:

Air
Food

Also called the throat.

⸻

UVULA

Functions:

Prevents food from entering nasal cavity
Helps with speech

⸻

EPIGLOTTIS

Functions:

Covers trachea during swallowing
Prevents choking

⸻

LARYNX

Also called the voice box.

Contains vocal cords.

⸻

TRACHEA

Also called the windpipe.

Contains cartilage rings that prevent collapse.

Lined with:

Cilia
Mucus

⸻

CILIA

Tiny hair-like structures.

Function:

Sweep mucus upward toward throat

⸻

BRONCHI

Two branches of the trachea leading to lungs.

Right Bronchus → Right Lung

Left Bronchus → Left Lung

⸻

BRONCHIOLES

Smaller branches inside lungs.

Lead to alveoli.

⸻

ALVEOLI

Tiny air sacs.

Site of gas exchange.

Adaptations:

Thin walls
Moist surface
Large surface area
Rich blood supply

Gas Exchange:

Oxygen moves:

Alveoli → Blood

Carbon Dioxide moves:

Blood → Alveoli

By diffusion.

⸻

BREATHING MECHANICS

Two main muscles:

Diaphragm
Intercostal Muscles

⸻

INHALATION (INSPIRATION)

Diaphragm:

Contracts
Moves downward

Intercostal Muscles:

Contract
Lift ribs upward

Result:

Chest cavity volume increases
Pressure decreases
Air enters lungs

⸻

EXHALATION (EXPIRATION)

Diaphragm:

Relaxes
Moves upward

Intercostal Muscles:

Relax

Result:

Chest cavity volume decreases
Pressure increases
Air leaves lungs

⸻

MEDULLA OBLONGATA

Located in the brainstem.

Function:

Controls breathing rate

Responds to:

Carbon dioxide levels

More CO₂:

Faster breathing

Less CO₂:

Slower breathing

⸻

LUNG VOLUMES

Tidal Volume

Normal amount of air breathed in and out

Inspiratory Reserve Volume

Extra air inhaled after normal breath

Expiratory Reserve Volume

Extra air exhaled after normal breath

Residual Volume

Air remaining in lungs after maximum exhalation

Vital Capacity

Maximum amount of air exhaled after deepest breath

Total Lung Capacity

Total amount of air lungs can hold

⸻

CIRCULATORY SYSTEM

Functions:

Transport oxygen
Transport nutrients
Remove wastes
Maintain homeostasis
Transport hormones

Humans have a CLOSED circulatory system.

Blood remains inside vessels.

⸻

BLOOD VESSELS

ARTERIES

Function:

Carry blood away from heart

Characteristics:

Thick walls
High pressure
Small lumen
No valves

Usually oxygen-rich

Exception:

Pulmonary artery

⸻

VEINS

Function:

Carry blood toward heart

Characteristics:

Thin walls
Low pressure
Large lumen
Valves present

Usually oxygen-poor

Exception:

Pulmonary vein

⸻

CAPILLARIES

Smallest blood vessels.

Functions:

Gas exchange
Nutrient exchange
Waste exchange

Walls are one cell thick.

⸻

HEART STRUCTURE

Blood Flow:

Body

↓

Vena Cava

↓

Right Atrium

↓

Right Ventricle

↓

Pulmonary Artery

↓

Lungs

↓

Pulmonary Vein

↓

Left Atrium

↓

Left Ventricle

↓

Aorta

↓

Body

⸻

HEART CHAMBERS

Right Atrium

Receives deoxygenated blood

Right Ventricle

Pumps blood to lungs

Left Atrium

Receives oxygenated blood

Left Ventricle

Pumps blood to body

⸻

SEPTUM

Wall separating left and right sides of heart.

Prevents mixing of blood.

⸻

HEART VALVES

Function:

Prevent backflow of blood

Types:

Atrioventricular (AV) Valves

Pulmonary Semilunar Valve

Aortic Semilunar Valve

⸻

SA NODE

Sinoatrial Node

Known as:

Natural pacemaker

Initiates heartbeat.

⸻

AV NODE

Atrioventricular Node

Receives signal from SA node.

Delays impulse slightly.

Allows ventricles to fill before contraction.

⸻

BLOOD

Components:

Plasma
Red Blood Cells
White Blood Cells
Platelets

⸻

PLASMA

Liquid component of blood.

Functions:

Transport nutrients
Transport hormones
Transport wastes

⸻

RED BLOOD CELLS (ERYTHROCYTES)

Function:

Carry oxygen

Contain:

Hemoglobin

⸻

HEMOGLOBIN

Protein in red blood cells.

Function:

Binds oxygen

Allows oxygen transport.

⸻

WHITE BLOOD CELLS (LEUKOCYTES)

Function:

Fight infection
Defend body

Part of immune system.

⸻

PLATELETS

Function:

Blood clotting

Prevent blood loss.

⸻

BLOOD PRESSURE

Force of blood against artery walls.

Measured using:

Sphygmomanometer

Example:

120/80

120 = Systolic Pressure

80 = Diastolic Pressure

⸻

SYSTOLIC PRESSURE

Pressure when heart contracts.

⸻

DIASTOLIC PRESSURE

Pressure when heart relaxes.

⸻

HYPERTENSION

High blood pressure.

Can increase risk of:

Stroke
Heart attack
Kidney disease

⸻

STROKE VOLUME

Amount of blood pumped per heartbeat.

⸻

CARDIAC OUTPUT

Amount of blood pumped per minute.

Formula:

Cardiac Output = Heart Rate × Stroke Volume

⸻

ECG

Electrocardiogram

Measures electrical activity of heart.

Used to detect:

Irregular heartbeat
Heart damage

⸻

PULMONARY CIRCULATION

Heart → Lungs → Heart

Purpose:

Oxygenate blood

⸻

SYSTEMIC CIRCULATION

Heart → Body → Heart

Purpose:

Deliver oxygen to tissues

⸻

HOMEOSTASIS DURING EXERCISE

Body responds by:

Increasing heart rate
Increasing breathing rate
Increasing cardiac output
Redirecting blood to muscles
Sweating to cool body

Purpose:

Maintain stable internal conditions.

⸻

DIGESTIVE SYSTEM

Functions:

Break down food
Absorb nutrients
Eliminate waste

⸻

DIGESTIVE TRACT

Mouth

↓

Pharynx

↓

Esophagus

↓

Stomach

↓

Small Intestine

↓

Large Intestine

↓

Rectum

↓

Anus

⸻

MECHANICAL DIGESTION

Physical breakdown of food.

Examples:

Chewing
Churning

⸻

CHEMICAL DIGESTION

Chemical breakdown of food using enzymes.

Examples:

Amylase
Pepsin

⸻

SALIVA

Functions:

Moistens food
Contains amylase

Amylase begins carbohydrate digestion.

⸻

TONGUE

Functions:

Forms bolus
Pushes food for swallowing

⸻

ESOPHAGUS

Moves food to stomach.

Uses:

Peristalsis

⸻

PERISTALSIS

Wave-like muscular contractions.

Move food through digestive tract.

⸻

STOMACH

Functions:

Stores food
Mixes food
Begins protein digestion

Produces:

HCl
Pepsin
Mucus

⸻

HCl

Hydrochloric Acid

Functions:

Kills bacteria
Activates pepsin

⸻

PEPSIN

Function:

Digests proteins

⸻

MUCUS

Function:

Protects stomach lining

⸻

CHYME

Semi-liquid food mixture leaving stomach.

⸻

HEARTBURN

Cause:

Stomach acid enters esophagus.

Usually caused by weakened cardiac sphincter.

⸻

SMALL INTESTINE

Main site of:

Digestion
Absorption

Adaptations:

Long length
Folds
Villi
Microvilli

Large surface area increases absorption.

⸻

DUODENUM

First section.

Functions:

Receives bile
Receives pancreatic enzymes
Most chemical digestion

⸻

JEJUNUM

Main nutrient absorption.

⸻

ILEUM

Final nutrient absorption.

⸻

VILLI

Finger-like projections.

Function:

Increase surface area.

⸻

LIVER

Functions:

Produces bile
Processes nutrients
Detoxifies blood

⸻

GALL BLADDER

Functions:

Stores bile
Releases bile into small intestine

⸻

PANCREAS

Functions:

Produces digestive enzymes
Produces bicarbonate

⸻

BILE

Function:

Emulsifies fats.

Breaks large fat droplets into smaller droplets.

Makes fat digestion easier.

⸻

DIGESTION OF CARBOHYDRATES

Mouth:

Amylase begins digestion

Small Intestine:

Pancreatic amylase continues digestion

End Product:

Glucose

⸻

DIGESTION OF PROTEINS

Stomach:

Pepsin begins digestion

Small Intestine:

Trypsin continues digestion

End Product:

Amino Acids

⸻

DIGESTION OF LIPIDS

Small Intestine:

Bile emulsifies fats
Lipase digests fats

End Product:

Fatty Acids + Glycerol

⸻

EVOLUTION

Evolution:

Change in populations over time.

Individuals do NOT evolve.

Populations evolve.

⸻

DARWIN

Proposed:

Natural Selection

Book:

On the Origin of Species

⸻

WALLACE

Independently developed theory of natural selection.

⸻

LAMARCK

Proposed:

Inheritance of acquired characteristics

Example:

Giraffes stretch necks and pass longer necks to offspring.

This theory is incorrect.

⸻

NATURAL SELECTION

Requirements:

Variation
Overproduction
Competition
Differential Survival
Reproduction

Result:

Adaptation

⸻

ADAPTATION

Inherited characteristic that increases survival and reproduction.

⸻

SELECTIVE ADVANTAGE

A characteristic that improves survival or reproduction.

Example:

Antibiotic resistance

⸻

SELECTIVE PRESSURE

Environmental factor that influences survival.

Examples:

Predators
Disease
Climate
Competition

⸻

VARIATION

Differences among individuals in a population.

Sources:

Mutation
Crossing Over
Random Assortment

⸻

MUTATION

Ultimate source of new alleles.

Creates genetic variation.

⸻

FOSSIL

Preserved remains or traces of organisms.

⸻

FOSSIL RECORD

Collection of fossils showing evolutionary history.

Provides evidence for evolution.

⸻

RADIOACTIVE DATING

Uses radioactive isotopes to determine fossil age.

⸻

UNIFORMITARIANISM

Proposed by Lyell.

Earth changes gradually over long periods of time.

⸻

CATASTROPHISM

Proposed by Cuvier.

Earth shaped by sudden catastrophic events.

⸻

BIOGEOGRAPHY

Study of species distribution around Earth.

Provides evidence for evolution.

⸻

EMBRYOLOGY

Study of embryos.

Similar embryos suggest common ancestry.

⸻

HOMOLOGOUS STRUCTURES

Same evolutionary origin.

Different functions.

Example:

Human arm

Whale flipper

Bat wing

Evidence of common ancestry.

⸻

ANALOGOUS STRUCTURES

Different origins.

Same function.

Example:

Bird wing

Insect wing

Not evidence of close ancestry.

⸻

VESTIGIAL STRUCTURES

Structures with little or no function.

Examples:

Human appendix
Whale pelvis

Evidence of evolution.

⸻

MIMICRY

One species resembles another.

Example:

Syrphid fly resembles wasp.

Provides protection.

⸻

ARTIFICIAL SELECTION

Humans select traits.

Examples:

Dog breeding
Crop breeding

⸻

DIRECTIONAL SELECTION

One extreme phenotype favored.

Graph shifts in one direction.

⸻

STABILIZING SELECTION

Average phenotype favored.

Extremes selected against.

⸻

DISRUPTIVE SELECTION

Both extremes favored.

Middle selected against.

⸻

GENETIC DRIFT

Random change in allele frequencies.

Most significant in small populations.

⸻

FOUNDER EFFECT

Small group starts new population.

Different allele frequencies from original population.

⸻

BOTTLENECK EFFECT

Population drastically reduced.

Loss of genetic variation.

⸻

GENE FLOW

Movement of alleles between populations.

Occurs through migration.

⸻

NON-RANDOM MATING

Individuals choose specific mates.

Can reduce variation.

⸻

SPECIES

A group of organisms that can interbreed in nature and produce fertile offspring.

⸻

SPECIATION

Formation of new species.

⸻

ALLOPATRIC SPECIATION

Requires:

Geographic isolation

Example:

Mountain separates populations.

⸻

SYMPATRIC SPECIATION

Occurs without geographic isolation.

⸻

PRE-ZYGOTIC ISOLATION

Prevents fertilization.

Examples:

Different mating seasons
Different mating songs
Different habitats

⸻

POST-ZYGOTIC ISOLATION

Occurs after fertilization.

Example:

Sterile hybrids

Example:

Mule

DIVERSITY

Prokaryotes vs Eukaryotes

PROKARYOTES

No nucleus
No membrane-bound organelles
Circular DNA
Smaller
Examples: Eubacteria, Archaebacteria

EUKARYOTES

Nucleus present
Membrane-bound organelles
Linear chromosomes
Larger
Examples: Protists, Fungi, Plants, Animals

Three Differences:

Nucleus vs no nucleus
Organelles vs no organelles
Larger vs smaller

⸻

Taxonomy

Kingdom

Phylum

Class

Order

Family

Genus

Species

Mnemonic:

King Philip Came Over For Good Soup

⸻

Binomial Nomenclature

Genus + Species

Example:

Homo sapiens

Rules:

Genus capitalized
Species lowercase
Italicized

Purpose:

Universal naming system
Avoids confusion
Shows relationships

⸻

Dichotomous Key

Used to identify organisms using paired choices.

Example:

1a Has wings → Step 2

1b No wings → Step 3

⸻

Six Kingdoms

Archaebacteria
Eubacteria
Protista
Fungi
Plantae
Animalia

⸻

VIRUSES

Virus Structure:

DNA or RNA
Capsid
Attachment proteins
Sometimes envelope

Why Viruses Are Not Living:

Not made of cells
Cannot reproduce independently
No metabolism
Need host cell

⸻

DNA Virus vs RNA Virus

DNA Virus:

Contains DNA
More stable

RNA Virus:

Contains RNA
Mutates faster

⸻

Lytic Cycle

Attachment

↓

Penetration

↓

Replication

↓

Assembly

↓

Lysis

Host cell bursts.

⸻

Lysogenic Cycle

Attachment

↓

Penetration

↓

Integration into host DNA

↓

Host reproduces

↓

Virus DNA copied

Cell survives initially.

⸻

ARCHAEBACTERIA

Characteristics:

Prokaryotic
Unicellular
Extreme environments

Three Groups:

Methanogens

Produce methane

Halophiles

Salt-loving

Thermoacidophiles

Hot acidic environments

⸻

EUBACTERIA

Characteristics:

Prokaryotic
Peptidoglycan cell wall
Binary fission

Examples:

E. coli
Streptococcus

⸻

Binary Fission

DNA Replication

↓

Cell Growth

↓

Cell Division

↓

Two Identical Cells

⸻

Conjugation

DNA transfer through pilus.

Importance:

Genetic variation
Antibiotic resistance

⸻

Antibiotic Resistance

Mutation

↓

Antibiotic kills susceptible bacteria

↓

Resistant bacteria survive

↓

Resistant bacteria reproduce

Natural Selection

⸻

PROTISTS

Characteristics:

Eukaryotic
Mostly unicellular
Aquatic

Three Groups:

Animal-like

Amoeba
Paramecium

Plant-like

Algae
Euglena

Fungus-like

Slime molds

⸻

Amoeba

Uses pseudopods
Phagocytosis

⸻

Algae

Photosynthetic
Oxygen producer

⸻

Euglena

Chloroplasts
Flagellum
Photosynthesis
Can also feed heterotrophically

⸻

Malaria

Cause:

Plasmodium

Kingdom:

Protista

⸻

FUNGI

Characteristics:

Eukaryotic
Heterotrophic
Chitin cell walls
Reproduce with spores

Examples:

Mushrooms
Mold
Yeast

⸻

External Digestion

Release enzymes

↓

Digest food outside body

↓

Absorb nutrients

⸻

Fungi vs Plants

FUNGI

Heterotrophic
Chitin
No chloroplasts

PLANTS

Autotrophic
Cellulose
Chloroplasts

⸻

PLANTS

Biodiversity vs Monoculture

BIODIVERSITY

Many species
Stable ecosystem
Disease resistance

MONOCULTURE

One crop species
Low diversity
Disease risk

⸻

Bryophytes

Definition:

Nonvascular plants

Examples:

Mosses
Liverworts

Characteristics:

No xylem
No phloem
Need water for reproduction

⸻

Vascular Plants

Contain:

Xylem
Phloem

⸻

Xylem

Function:

Water and minerals

Direction:

Roots → Leaves

⸻

Phloem

Function:

Sugars

Direction:

Throughout plant

⸻

Alternation of Generations

Sporophyte (2n)

↓ meiosis

Spores (n)

↓

Gametophyte (n)

↓

Gametes

↓ fertilization

Zygote (2n)

↓

Sporophyte

⸻

Moss Life Cycle

Spores

↓

Gametophyte

↓

Egg + Sperm

↓

Zygote

↓

Sporophyte

↓

Capsule

↓

Spores

Know:

Capsule
Sporophyte
Gametophyte
Spores

⸻

Fern Life Cycle

Fern

↓

Sori

↓

Spores

↓

Prothallus

↓

Gametes

↓

Fertilization

↓

Young Fern

Know:

Frond
Sori
Sporangia
Prothallus

⸻

Gymnosperms

Characteristics:

Naked seeds
Cones
Wind pollination
Evergreen

Examples:

Pine
Spruce
Fir

⸻

Angiosperms

Characteristics:

Flowers
Fruit
Seeds enclosed

Examples:

Apple tree
Rose
Maple

⸻

Flower Structure

Anther

Produces pollen

Pollen Grain

Male gamete

Stigma

Receives pollen

Style

Connects stigma and ovary

Ovary

Contains ovules

Ovule

Female gamete

Petals

Attract pollinators

⸻

Plant Tissues

Meristematic

Growth

Dermal

Protection

Ground

Photosynthesis
Storage

Vascular

Transport

⸻

Leaf Structure

Blade

Main leaf surface

Petiole

Connects leaf to stem

Cuticle

Reduces water loss

Palisade Mesophyll

Photosynthesis

Spongy Mesophyll

Gas exchange

Veins

Xylem + Phloem

⸻

Stomata

Openings in leaves.

Functions:

Gas exchange
Water loss

⸻

Guard Cells

Control opening and closing of stomata.

⸻

Transpiration

Water loss from leaves.

Functions:

Pulls water upward
Cools plant
Moves minerals

⸻

Simple vs Compound Leaves

Simple:

One blade

Compound:

Multiple leaflets

⸻

Monocots vs Dicots

MONOCOTS

1 cotyledon
Parallel veins
Fibrous roots
Flower parts in 3s

Examples:

Corn

Grass

DICOTS

2 cotyledons
Net veins
Taproot
Flower parts in 4s or 5s

Examples:

Bean

Maple

⸻

Seeds

Contain:

Embryo
Stored food
Seed coat

Functions:

Protection
Survival
Dispersal

⸻

Seed Dispersal

Wind

Dandelion

Water

Coconut

Animals

Burrs

Explosive

Touch-me-not

⸻

Fruit vs Vegetable

Fruit:

Comes from ovary
Contains seeds

Examples:

Tomato

Apple

Pepper

Vegetable:

Root, stem, leaf, or flower

Examples:

Carrot

Celery

Broccoli

⸻

Factors Affecting Plant Growth

Light
Water
Carbon dioxide
Temperature
Soil nutrients
Oxygen
Soil pH
Space
Pollinators
Disease and pests