Biology Midterm 2 PDF

[Midterm 2] \[3.3→ 6.3b\] 1\. Enzyme Inhibition - Definition: [Types of Inhibition: ] Competitive Inhibition: - The inhibitor competes directly with the substrate for the enzyme\'s active site. - Prevents substrate binding by occupying the active site. Noncompetitive Inhibition: - The inhibitor binds to a site other than the active site (allosteric site). - This alters the enzyme\'s structure, reducing its ability to catalyze the reaction. 2\. Feedback Inhibition [Definition: ] - The product of an enzyme-catalyzed pathway acts as a regulator for the reaction, typically by binding to an allosteric site. - This is a form of allosteric regulation. [Purpose: ] - Conserves cellular resources by halting the pathway when sufficient product is formed. 3\. Effects of Temperature and pH on Enzyme Activity [Optimal Conditions: ] - Each enzyme has specific optimal temperature and pH values for maximum efficiency. - Typically: - Temperature: Often matches the physiological temperature of the organism. - pH: For intracellular enzymes, near neutral pH (\~7). For extracellular enzymes, the pH optimum may vary. [Effects of Deviations from Optimum:] - pH Changes: - Affects the charged groups in the amino acids of the enzyme. - Can alter enzyme structure and reduce activity. - Temperature Changes: - Below Optimum:Reaction rates increase as temperature rises toward the optimal level. - Above Optimum: High temperatures cause denaturation of the enzyme (loss of structural integrity), decreasing reaction rates. [4. Specific Temperature Effects on Enzyme Activity] Heat-Sensitive Enzymes: - Example: Enzymes controlling melanin production. - In warmer body regions, these enzymes may denature, leading to visible effects such as temperature-sensitive pigmentation. Illustrative Figures (Referenced): Figure 3.26:A diagram of a method of enzyme reaction Description automatically generated with medium confidence Demonstrates feedback inhibition in a metabolic pathway. Figure 3.27: ![](media/image2.png)Shows how pH changes affect charged groups in enzyme amino acids. Figure 3.28: Depicts the relationship between temperature and enzyme activity, including denaturation at high temperatures. A diagram of a curve with Gateway Arch in the background Description automatically generated 1\. Selectively Permeable Membranes Functions: - Separate internal and external environments. - Selectively exchange molecules and ions. - Permeable to water but impermeable to most other molecules. - Components: - Phospholipids, glycolipids, sterols (cholesterol, ergosterols, phytosterols). - Membrane proteins: integral (transmembrane) and peripheral. 2\. Fluid Mosaic Model - Membranes are fluid lipid bilayers where proteins float. Key Properties of Membranes: - Fluidity dependent on lipid composition and temperature. - Unsaturated fatty acids increase fluidity (due to kinks). - Sterols buffer membrane fluidity by: - Preventing excessive movement at high temperatures. - Preventing tight packing at low temperatures. 3\. Properties of Water and Phospholipids Water: - Polar molecule, forms hydrogen bonds. - Excellent solvent for hydrophilic (polar) molecules. - Hydrophobic molecules (e.g., lipids) disrupt water structure, driving membrane formation. Phospholipids: - Amphipathic with hydrophilic heads and hydrophobic tails. - Form bilayers in aqueous solutions. Passive Transport - Driven by diffusion, requiring no energy. - Simple Diffusion: - - Movement from high to low concentration directly across the membrane. - - Small, uncharged molecules (e.g., O₂, CO₂) move easily. - - Large or charged molecules face significant barriers. 1\. Types of Passive Transport - Facilitated Diffusion: - Requires transporter proteins (e.g., channels or carriers). - Moves substances down their concentration gradient. - Stops when concentration gradient = 0. - Osmosis: - Diffusion of water across a selectively permeable membrane. - Water moves from hypotonic (low solute) to hypertonic (high solute) solutions. 2\. Active Transport - Moves molecules against concentration gradients using energy (ATP). Primary Active Transport: - Transport protein hydrolyzes ATP directly (e.g., Na⁺/K⁺ pump). - Maintains electrochemical gradients. Secondary Active Transport: - Uses gradients created by primary transport. - Includes symport (same direction) and antiport (opposite directions). 3\. Bulk Transport Exocytosis: - Vesicles fuse with the plasma membrane to secrete substances. Endocytosis: - - Internalization of external materials via vesicles. Types: - Pinocytosis: Non-specific uptake of fluids (\"cell drinking\"). - Phagocytosis: Uptake of large particles (\"cell eating\"). - Receptor-Mediated Endocytosis: Specific uptake via receptor-clathrin interactions. - Cell Signaling Key Steps: - Reception: Signal molecule binds to receptor. - Transduction: Signal relayed via intracellular cascades (e.g., phosphorylation). - Response: Cellular activity altered (e.g., enzyme activation, gene expression). - Termination: Signal turned off after response. Signaling Pathways: - Amplification occurs as one signal activates multiple downstream molecules. - Involves kinases (add phosphates) and phosphatases (remove phosphates). 5\. Signal Transduction Examples Epinephrine (Adrenaline): - Triggers glycogen breakdown in liver cells, increasing blood glucose levels. - Demonstrates amplification via second messengers (e.g., cAMP). - Physiological Responses to Adrenaline:\*\* - Increased heart rate, energy burst, dilated pupils, and gene expression changes. Notes on Oxidation, Reduction, and Cellular Respiration Oxidation Definition: The partial or full loss of electrons from a substance. - The substance that loses electrons is called the \*\*electron donor\*\* and is \*\*oxidized\*\*. - Example: In glucose metabolism, the carbon atom has partially lost electrons because oxygen is more electronegative, leading to the oxidation of carbon. - Representation: Dark shading indicates increased electron density around atoms. Reduction - Definition: The partial or full gain of electrons by a substance. - The substance that gains electrons is the \*\*electron acceptor\*\* and is reduced. - Example: Oxygen gains electrons (reduced) in a reaction with hydrogen atoms. Redox Reactions - Coupled Reactions: Oxidation and reduction occur simultaneously in redox reactions. - Example: Combustion and cellular respiration are redox reactions. Electron Carriers - NAD+ (Oxidized form): Accepts 2 electrons and 1 proton to become NADH (Reduced form). - FAD (Oxidized form): Accepts 2 electrons and 2 protons to become FADH2 (Reduced form). Example of Redox Reactions Reduction: - NAD+ + 2e⁻ + H⁺ → NADH - FAD + 2e⁻ + 2H⁺ → FADH2 - Oxidation\*\*: - NADH → NAD+ + 2e⁻ + H⁺ - FADH2 → FAD + 2e⁻ + 2H⁺ Cellular Respiration (C6H12O6 + 6O2 → 6CO2 + 6H2O + energy) - Stage 1: Glycolysis (in the cytosol) - Stage 2: Pyruvate oxidation and citric acid cycle (in mitochondria) - Stage 3: Oxidative phosphorylation (in mitochondria) Combustion vs. Cellular Respiration Notes on the Citric Acid Cycle and Oxidative Phosphorylation Citric Acid Cycle (Krebs Cycle or Tricarboxylic Acid Cycle) - Function: Acetyl groups are completely oxidized to CO2, with electrons removed in a series of oxidation reactions. Electron Carriers: Electrons are accepted by NAD+ and FAD, reducing them to NADH and FADH2. ATP Production: Some ATP is produced by substrate-level phosphorylation. Products of Citric Acid Cycle (Per Acetyl Group) - 2 CO2 - 1 ATP - 3 NADH - 1 FADH2 Summary of Citric Acid (Kreb) Cycle Reaction: - 1 acetyl-CoA + 3 NAD+ + 1 FAD + 1 ADP + 1 Pi + 2 H2O - 2 CO2 + 3 NADH + 1 FADH2 + 1 ATP + 3 H+ + 1 CoA At the End of the Citric Acid Cycle (for 2 Acetyl-CoA molecules): 2 ATP 6 NADH 2 FADH2 Electron Transport Chain and Oxidative Phosphorylation - - Flow of Energy in Cellular Respiration: - Stage 1 (Glycolysis): Glucose is oxidized to produce ATP and reduced electron carriers (NADH). - Stage 2 (Pyruvate Oxidation and Citric Acid Cycle): Acetyl-CoA enters the citric acid cycle, producing more NADH, FADH2, and ATP. - Stage 3 (Oxidative Phosphorylation): NADH and FADH2 donate electrons to the electron transport chain, leading to ATP synthesis. Notes on Fermentation, Anaerobic Respiration, and Oxygen\'s Role Fermentation - Occurs in eukaryotic cells under low oxygen levels. - Pathway of respiration that oxidizes fuel molecules in the absence of oxygen - Types of Fermentation: 1\. Lactate Fermentation: - Electrons from NADH are transferred to pyruvate, producing lactic acid and NAD+. - Occurs in animals and bacteria. 2\. Alcoholic Fermentation: - Electrons from NADH are transferred to pyruvate, producing ethanol and NAD+. - Occurs in plants and fungi. Fermentation yields only 2 ATP because products (lactic acid, ethanol) are not fully oxidized, retaining chemical energy. Pathways of Pyruvate Metabolism - Aerobic Conditions: - Pyruvate → Acetyl-CoA → Citric Acid Cycle → Electron Transport Chain (ETC). - Anaerobic Conditions - Pyruvate is metabolized via fermentation pathways (lactic acid or ethanol fermentation). Anaerobic Respiration - Performed by bacteria and archaea lacking mitochondria. - Use alternative terminal electron acceptors like sulfate, nitrate, or ferric ion. - Generates ATP without O2. Lifestyles Dictated by Oxygen - Strict Anaerobes: Cannot grow in oxygen\'s presence. - Strict Aerobes: Require oxygen for growth. - Facultative Aerobes: Can grow with or without oxygen (can switch to fermentative pathways). Paradox of Aerobic Life - Oxygen is required for electron transport but is inherently dangerous. - Produces \*\*reactive oxygen species (ROS) like superoxide and hydrogen peroxide, which are strong oxidizing agents and harmful to cells. Defence Against Reactive Oxygen Species Enzymatic Defenses: - Superoxide dismutase: Converts superoxide to hydrogen peroxide. - Catalase: Converts hydrogen peroxide to water and oxygen. - Non-Enzymatic Defenses: Antioxidants like vitamin C and vitamin E neutralize ROS. Reduction of Oxygen to Water - O2 is reduced stepwise to water during electron transport, forming intermediate ROS, which are potentially harmful if not neutralized. Electron Transfer System and Oxidative Phosphorylation Overview - Electron Transport Chain (ETC): Converts potential energy in NADH and FADH2 into a proton-motive force. - Proton gradient drives ATP synthesis via ATP synthase. Electron Carriers - Stages 1-2: Glucose is oxidized, producing NADH and FADH2. - Stage 3 (Oxidative Phosphorylation): NADH and FADH2 donate electrons to the ETC, leading to large-scale ATP production. Electron Transport Chain (ETC) Components - Protein Complexes: - Complex I: Accepts electrons from NADH. - Complex II: Accepts electrons from FADH2. - Complex III: Transfers electrons to cytochrome c. - Complex IV: Reduces oxygen to form water. Shuttle Carriers: - Coenzyme Q (CoQ): Transfers electrons between complexes I/II and III. - Cytochrome c: Transfers electrons to complex IV. Process Electron Flow: - Electrons move spontaneously from NADH/FADH2 through the ETC to oxygen. - Oxygen acts as the final electron acceptor and is reduced to form water. Proton Pumping: - Complexes I, III, and IV pump protons (H+) from the mitochondrial matrix to the intermembrane space, creating a proton gradient. ATP Synthesis: - Protons flow back into the matrix through ATP synthase, driving the conversion of ADP + Pi to ATP. Key Molecules and Steps - NADH and FADH2: Electron donors. - Oxygen: Final electron acceptor, reduced to H2O. - Prosthetic Groups: Within protein complexes, cycle between oxidized and reduced states to facilitate electron transfer. - CoQH2: Transfers electrons from complexes I/II to III. - ATP Synthase: Uses proton-motive force to produce ATP. Summary of ETC - NADH/FADH2 → ETC → O2 → H2O + ATP. - Proton gradient is the energy source for ATP synthesis. What you need to know: - Where in the cell it takes place - Key inputs (e.g. glucose, ATP, NAD+) - Key outputs (pyruvate, ATP, NADH) - Overall phases - Understand what types of reactions are taking place at different steps of the pathway (e.g. redox, anabolic, catabolic, phosphorylation) - One key enzyme - Phosphofructokinase catalyzes the second ATP-consuming step of the pathway Dependency upon Presence of Oxygen - In anaerobic respiration, the terminal electron acceptor is not oxygen. Fermentation - In eukaryotic cells, low oxygen levels result in fermentation. - Fermentation is the pathway of respiration that oxidizes fuel molecules in the absence of oxygen. - Two types of fermentation exist: lactate fermentation and alcohol fermentation. Paradox of Aerobic Life - Although many organisms cannot exist without oxygen because it is required for electron transport, oxygen itself is inherently dangerous to all forms of life. - Reactive oxygen species (ROS) include superoxide and hydrogen peroxide, which are strong oxidizing agents. Reduction of Oxygen to Water - The conversion of O2 to water occurs stepwise, resulting in the formation of intermediate ROS, which are potentially harmful. Defence against Reactive Oxygen Species - Antioxidant defence system includes: - Enzymes such as superoxide dismutase and catalase. - Non Enzymes such as antioxidants like vitamin C and vitamin E. Chapter 6 - Photosynthesis Chlorophylls and Carotenoids - Chlorophylls are the major photosynthetic pigments in plants, green algae, and cyanobacteria. - Chlorophyll b and carotenoids are accessory pigments that donate excitation energy to chlorophyll a via inductive resonance. - Light absorbed by carotenoids and chlorophylls drives photosynthesis. - Absorption spectrum: The amount of light absorbed by a pigment at different wavelengths. - Action spectrum: Graph showing the effectiveness of each wavelength in driving photosynthesis. Engelmann's Experiment (1883) - Theodor Engelmann used a glass prism to project a spectrum of light onto algae with aerobic bacteria. - Bacteria clustered where algae produced the most oxygen, in areas of blue, violet, and red light. - Resulted in an action spectrum for photosynthesis. Two Stages of Photosynthesis - Light reactions: Capture light energy to synthesize ATP and NADPH. - Calvin cycle: Uses NADPH and ATP to fix CO2 into carbohydrates. Major Components of a Photosystem - Antenna complex: Absorbs light using chlorophyll a, chlorophyll b, and carotenoids; transfers energy to the reaction center via inductive resonance. - Reaction center: Contains specialized chlorophyll a molecules (P680 in PSII and P700 in PSI). - Primary electron acceptor: Pheophytin in PSII. Photosystems I and II - Photosystems consist of pigments and proteins involved in photoreduction. - Photosystem II (PSII): - P680 chlorophyll molecules absorb light and become excited (P680\*). - P680 is oxidized to P680+ by the primary electron acceptor (Pheophytin). - Pheophytin transfers electrons to plastoquinone (PQ), which shuttles them to the cytochrome complex. - P680+ regains an electron from water oxidation in the water-splitting complex, releasing O2 and H+. - Photosystem I (PSI): - P700 chlorophyll molecules absorb light and are involved in reducing NADP+ to NADPH. Photosynthetic Electron Transport Chain - Links PSII and PSI, enabling electron flow from water to NADP+. - Provides the energy needed to extract electrons from water and reduce NADP+ to NADPH. - When photons of light hit an object, they can be: reflected, transmitted, or absorbed. - For light to be used as energy, it must be absorbed. The energy of the photon is transferred to an electron in a molecule. - Energy transfer moves the electron from its grounded state to an excited state. Pigments Absorb Photons - Pigments are molecules that absorb photons of specific wavelengths. - Key feature for light absorption: a conjugated system of carbon atoms covalently bonded with alternating single and double bonds. - Differences in the arrangement of conjugated systems and chemical structures determine the wavelengths absorbed by each pigment. - A pigment's color results from the wavelengths of light it does not absorb. Pigments - Pigments are highly efficient at absorbing visible light due to their structure and excitable electrons. - Example: Chlorophyll is a photosynthetic pigment. Electromagnetic Spectrum - High energy to low energy: Gamma rays → X-rays → UV → Visible light → Infrared → Microwaves → Radio waves. - Visible light spectrum ranges from 400 nm (violet) to 700 nm (red). Fates of an Excited-State Electron - The electron returns to its ground state, releasing energy as heat or light of a longer wavelength (fluorescence). - Energy from the excited electron in one pigment molecule is transferred to a neighboring pigment via inductive resonance. - The excited-state electron is transferred to a nearby electron-accepting molecule (photoreduction). All three processes occur following light absorption by photosynthetic pigments. - Photosynthesis uses light energy to convert carbon from CO2 gas into organic molecules. - Oxygen is released as a by-product from the oxidation of water (H2O) during the process. - Photosynthesis provides the source of all food we consume, either directly or indirectly. Overall Reaction - CO2 + H2O → O2 + Organic molecules - Metabolic Classification of Organisms - Autotrophs: Produce organic molecules from inorganic sources (e.g., CO2, water). - Photoautotrophs: Use light energy for photosynthesis (e.g., cyanobacteria, vascular plants). - Chemoautotrophs: Use energy from chemical compounds. - Heterotrophs: Depend on organic molecules from other organisms for energy. - Examples: Animals, most bacteria. Photoautotrophs: Primary Producers of Earth - Convert sunlight into chemical energy. - Use energy to assemble complex organic molecules from inorganic materials. - Organic molecules provide energy for themselves and other organisms. Two Stages of Photosynthesis Light Reactions - Light energy absorbed by pigments is converted into ATP and NADPH. - Oxygen is released as a by-product of water oxidation. - Calvin Cycle - ATP and NADPH from light reactions provide energy and reducing power. - Fixes carbon from CO2 to synthesize carbohydrates. - Photosynthesis as a Redox Reaction - Synthesis of carbohydrates from CO2 requires energy from sunlight. - Reduction occurs when a molecule gains electrons and energy. - Oxidation occurs when a molecule loses electrons and releases energy. Location of Photosynthesis - In eukaryotes (e.g., higher plants, algae), photosynthesis occurs in chloroplasts.

Biology Midterm 2 PDF

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