BackCell Structure, Membrane Function, and Energy Transformations: Study Guide
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Chapter 4: A Tour of the Cell
Basic Features Shared by All Cells
Plasma Membrane: A selectively permeable barrier that encloses the cell, controlling the movement of substances in and out.
Cytoplasm: The jelly-like fluid inside the cell where organelles are suspended and most cellular activities occur.
Genetic Material (DNA/RNA): Contains instructions for cell function and heredity.
Ribosomes: Structures responsible for protein synthesis.
Eukaryotic Cellular Parts and Their Functions
Cell Wall: Rigid outer layer found in plants, fungi, and some protists; provides support and protection.
Cytoskeleton: Network of protein fibers (microfilaments, intermediate filaments, microtubules) that maintain cell shape, enable movement, and organize organelles.
Cilia and Flagella: Hair-like structures for movement; cilia are short and numerous, flagella are longer and usually singular or few.
Nucleus: Contains genetic material; includes the nuclear envelope (double membrane), chromatin/chromosomes (DNA), and nucleolus (site of ribosome assembly).
Ribosome: Site of protein synthesis; found free in cytoplasm or attached to rough ER.
Endoplasmic Reticulum (ER):
Rough ER: Studded with ribosomes; synthesizes and processes proteins.
Smooth ER: Lacks ribosomes; synthesizes lipids and detoxifies chemicals.
Vesicle: Small membrane-bound sac for transport and storage of substances.
Golgi Apparatus: Modifies, sorts, and packages proteins and lipids for secretion or delivery to other organelles.
Lysosome: Contains digestive enzymes to break down waste and cellular debris.
Peroxisome: Breaks down fatty acids and detoxifies harmful substances.
Vacuole:
Food Vacuole: Stores and digests food.
Central Vacuole (plants): Maintains cell pressure, stores nutrients and waste.
Contractile Vacuole (protists): Expels excess water.
Mitochondria: Site of aerobic cellular respiration; produces ATP.
Chloroplast: Site of photosynthesis in plants and algae.
Distinguishing Plant and Animal Cells
Plant Cells: Have cell walls, chloroplasts, and a large central vacuole.
Animal Cells: Lack cell walls and chloroplasts; have smaller vacuoles.
Prokaryotic Cellular Parts
Plasma Membrane: Controls entry and exit of substances.
Slime Layer (Capsule): Protective outer layer; helps evade immune system.
Fimbriae: Hair-like projections for attachment to surfaces.
Plasmid (DNA): Small, circular DNA molecules; often carry antibiotic resistance genes.
Ribosomes: Protein synthesis.
Cell Wall: Provides shape and protection.
Flagellum: Movement.
Cytoplasm: Site of metabolic activities.
Nucleoid Region: Area where the main DNA is located (not membrane-bound).
Prokaryotic vs. Eukaryotic Cells
Prokaryotic Cells: No nucleus, no membrane-bound organelles, generally smaller, single circular DNA.
Eukaryotic Cells: Have nucleus, membrane-bound organelles, larger, linear DNA in chromosomes.
Cell Junctions
Anchoring Junctions: Fasten cells together into strong sheets (e.g., desmosomes).
Gap Junctions: Channels that allow molecules to flow between cells (animal cells).
Tight Junctions: Prevent leakage of extracellular fluid between cells.
Plasmodesmata: Channels between plant cells for transport and communication.
Chapter 5: The Working Cell
Major Functions of the Cell Membrane
Acts as a barrier, maintaining the internal environment of the cell.
Regulates transport of substances in and out of the cell.
Facilitates communication with other cells via receptors.
Provides structural support and enables cell recognition.
Selective Permeability of the Cell Membrane
Allows some substances to cross more easily than others.
Small, nonpolar molecules (e.g., O2, CO2) pass freely; ions and large polar molecules require transport proteins.
Fluid Mosaic Model Components
Phospholipids: Form a bilayer with hydrophilic heads facing outward and hydrophobic tails inward, creating a semi-permeable membrane.
Transport Proteins: Facilitate movement of substances across the membrane (channels and carriers).
Receptor Proteins: Bind signaling molecules and initiate cellular responses.
Enzymes: Catalyze chemical reactions at the membrane surface.
Glycoproteins: Proteins with carbohydrate chains; involved in cell recognition and signaling.
Attachment Proteins: Anchor the membrane to the cytoskeleton and extracellular matrix.
Key Terms and Comparisons
Concentration Gradient: Difference in concentration of a substance across a space or membrane.
Diffusion vs. Osmosis:
Diffusion: Movement of molecules from high to low concentration.
Osmosis: Diffusion of water across a selectively permeable membrane.
Solvent vs. Solute:
Solvent: Substance that dissolves the solute (e.g., water).
Solute: Substance dissolved in the solvent (e.g., salt).
Passive Transport vs. Active Transport:
Passive Transport: No energy required; moves substances down their concentration gradient (e.g., diffusion, facilitated diffusion, osmosis).
Active Transport: Requires energy (ATP); moves substances against their concentration gradient.
Simple Diffusion vs. Facilitated Diffusion:
Simple Diffusion: Direct movement through the lipid bilayer.
Facilitated Diffusion: Movement via transport proteins.
Facilitated Diffusion vs. Active Transport:
Facilitated Diffusion: No energy required; down gradient.
Active Transport: Requires energy; against gradient.
Exocytosis vs. Endocytosis:
Exocytosis: Export of materials via vesicles fusing with the membrane.
Endocytosis: Import of materials by engulfing them in vesicles.
Phagocytosis, Pinocytosis, Receptor-Mediated Endocytosis:
Phagocytosis: "Cell eating"; engulfing large particles.
Pinocytosis: "Cell drinking"; engulfing fluids.
Receptor-Mediated Endocytosis: Specific uptake of molecules via receptor proteins.
Carrier Proteins, Channel Proteins, Aquaporins:
Carrier Proteins: Change shape to move molecules across membrane.
Channel Proteins: Form pores for specific molecules/ions.
Aquaporins: Specialized channels for water transport.
Effects of Tonicity on Cells
Solution Type | Effect on Animal Cells | Effect on Plant Cells |
|---|---|---|
Hypotonic | Cell swells and may burst (lysis) | Cell becomes turgid (normal) |
Isotonic | No net water movement; cell remains normal | Cell is flaccid |
Hypertonic | Cell shrinks (crenation) | Cell undergoes plasmolysis |
Chapter 6: How Cells Harvest Chemical Energy
Photosynthesis vs. Aerobic Cellular Respiration
Photosynthesis Equation:
Aerobic Cellular Respiration Equation:
Reactants and Products:
Photosynthesis: Reactants: CO2, H2O, light; Products: Glucose, O2
Respiration: Reactants: Glucose, O2; Products: CO2, H2O, ATP
Energy Flow: Photosynthesis stores energy in glucose; respiration releases energy from glucose to form ATP.
Glucose Metabolism and ATP Formation
Glucose is a primary energy source; its breakdown releases energy used to synthesize ATP, the cell's energy currency.
Glycolysis
Occurs in the cytoplasm.
End products: 2 pyruvate, 2 ATP, 2 NADH per glucose molecule.
Aerobic Cellular Respiration Steps
Pyruvate Oxidation: Pyruvate enters mitochondria and is converted to acetyl-CoA, producing NADH and CO2.
Krebs Cycle (Citric Acid Cycle): Produces NADH, FADH2, and ATP (energy carriers).
Electron Transport Chain (ETC): NADH and FADH2 donate electrons to the ETC in the inner mitochondrial membrane.
Oxidative Phosphorylation (Chemiosmosis): Electron flow drives proton pumping, creating a gradient used by ATP synthase to produce ATP.
Role of O2 in Aerobic Respiration
Oxygen acts as the final electron acceptor in the ETC, allowing the chain to continue and enabling ATP production.
Chapter 7: Photosynthesis: Using Light to Make Food
Autotrophs vs. Heterotrophs
Autotrophs (Producers): Organisms that make their own food from inorganic substances (e.g., plants, algae).
Heterotrophs (Consumers): Obtain nutrition by consuming other organisms (e.g., animals, fungi).
Photosynthesis Equation
Chloroplast Structure and Function
Stroma: Fluid-filled space where the Calvin cycle occurs.
Thylakoid: Membranous sacs containing chlorophyll; site of light reactions.
Granum: Stack of thylakoids.
Role of Chlorophyll
Chlorophyll absorbs light energy, driving the light reactions of photosynthesis.
Light Reactions vs. Calvin Cycle
Process | Inputs | Outputs |
|---|---|---|
Light Reactions (Light-dependent) | Light, H2O, ADP, NADP+ | O2, ATP, NADPH |
Calvin Cycle (Light-independent) | CO2, ATP, NADPH | Glucose (C6H12O6), ADP, NADP+ |
Light Reactions: Occur in thylakoid membranes; convert light energy to chemical energy (ATP, NADPH), release O2.
Calvin Cycle: Occurs in stroma; uses ATP and NADPH to fix CO2 into glucose.
Example: In green plants, photosynthesis in chloroplasts provides the glucose used in cellular respiration to generate ATP for cellular work.
Additional info: This guide expands on the learning objectives by providing definitions, comparisons, and context for each topic, ensuring a comprehensive review for exam preparation.