Photosynthesis & Cellular Respiration Chapter 5 Photosynthesis & Cellular Respiration Energy & Living Things, Photosynthesis and Cellular Respiration
Energy in Living Things Building Molecules That Store Energy Metabolism: builds and breaks molecules Photosynthesis: conversion of light energy into chemical energy Autotrophs: organisms that use sunlight or inorganic molecules to produce organic matter These organisms include: Plants – use sunlight Prokaryotes – use chemicals flowing out of earth vents on the ocean floor
Breaking Down Food for Energy Chemical energy can also be transferred from one organic compound to another Ex. Hydrolysis using water to break bonds Heterotrophs: organisms who receive chemical energy from consuming organic matter Cellular respiration: releases energy that is contained in food to convert it to ATP (another form of energy) ATP is the source of energy for cells to carry out their daily activities for an organism to survive
Transfer of Energy to ATP Similar to burning coal or wood for heat Food energy is released in a series of enzyme-assisted chemical reactions The product from the previous reaction becomes the reactant in the next reaction until ATP is created Example: Starch is broken down into glucose and glucose is broken down into Carbon Dioxide & Water During the reaction: heat is released
ATP Adenosine triphosphate Removal of a phosphate group = energy Equation: H 2 O+ATP →ADP+P+ENERGY
Photosynthesis All the energy used by organisms is traced back to the sun Stages of Photosynthesis: Energy is captured from the sun Light Energy → Chemical Energy: temporarily stored in ATP and NADPH ATP and NADPH powers the formation of organic compounds with the use of CO2 Equation: 𝟔 𝐂𝐎 𝟐 +𝟔 𝑯 𝟐 𝑶 𝒍𝒊𝒈𝒉𝒕 𝑪 𝟔 𝑯 𝟏𝟐 𝑶 𝟔 +𝟔 𝑶 𝟐
Stage One: Absorption of Light Energy Light –Dependent Reactions Pigments Light absorbing substances Absorb only certain wavelengths and reflect all others Chlorophyll: absorbs blue & red, reflects green & yellow Plants contain chlorophyll, chlorophyll a & chlorophyll b Carotenoids: produce yellow and orange colors Absorbs and reflect different wavelengths than chlorophyll Enables plants to absorb more light during photosynthesis
Stage One: Continued Production of Oxygen Thylakoids: disk-shaped structure containing of clusters of pigments in the chloroplast of the cell Light strikes the thylakoids, energy is transferred to electrons and electrons move to higher levels Electrons move from chlorophyll to nearby molecules to initiate stage two of photosynthesis. These electrons are replaced by water molecules
Stage Two: The Conversion of Light Energy Electron Transport Chain (ETC): a series of molecules that electrons pass through along the thylakoid membrane Works around a concentration gradient – Hydrogen ions lose energy when they channel through a protein when the concentration builds within the cell, the ions diffuse out The ions are “recharged” when they assist in adding a phosphate group to ADP to make ATP (first ETC) In the 2nd ETC, electrons combine with hydrogen ions to create NADPH from NADP+ NADPH: electron carrier that provides high-energy electrons for stage three of photosynthesis Look at the summary at end of this stage
Stage Three: Storage of Energy Purpose: production of organic compounds from carbon atoms Carbon Dioxide Fixation: transfer of carbon dioxide to organic compounds (light-independent reaction) Calvin Cycle A CO2 molecule added to a five-carbon compound (3) Three 6-C compounds split into six 3-C compounds One 3-C sugar is used to make organic compound Five 3-C compounds are cycled through Draw Calvin Cycle
Factors That Affect Photosynthesis Increase Light Intensity Increases (until saturation) Carbon Dioxide concentration (until max) Decrease Slowed by the Calvin Cycle Unfavorable conditions for enzymes
Cellular Respiration – Cellular Energy Aerobic: metabolic processes that require O2 Anaerobic: metabolic processes that do not require O2 Equation of Cellular Respiration: 𝑪 𝟔 𝑯 𝟏𝟐 𝑶 𝟔 +𝟔 𝑶 𝟐 𝒆𝒏𝒛𝒚𝒎𝒆𝒔 𝟔 𝐂𝐎 𝟐 +𝟔 𝑯 𝟐 𝑶+𝑨𝑻𝑷
Stage One: Breakdown of Glucose Glycolysis: enzyme assisted anaerobic process that breaks down 6-C glucose into two 3-C pyruvate ions Step 1: In 3 rxns, phosphate groups from 2 ATP are transferred to a glucose molecule
Stage One: Breakdown of Glucose Step 2: In 2 rxns, glucose broken down into two 3- carbon compounds each with a phosphate
Stage One: Breakdown of Glucose Step 3: Two NADH molecules are produced and one more phosphate group is transferred to each 3-C compound
Stage One: Breakdown of Glucose Step 4: In 4 rxns, each 3-C compound →→pyruvate ion and four ATP molecules are produced
Summary of Glycolysis Uses 2 ATP to begin Produces 4 ATP Net gain: 2 ATP Glucose (6-Carbons) → Two 3-C pyruvate ions NADH and NAD+ are recycled
Stage Two: Production of ATP Oxygen present – pyruvate is converted to a 2-carbon compound in the mitochondrion Reaction produces: One molecule of CO2 One molecule of NADH One 2-C acetyl group attached to form acetyl-CoA Draw Krebs Cycle
Krebs Cycle A cycle beginning with acetyl-CoA to produce ATP Step 1: Acetyl-CoA attached to a 4-C compound to form a 6-C compound and release CoA Step 2: CO2 is released from 6-C compound forming a 5-C compound Electrons transferred to NAD+ to make NADH Draw Krebs Cycle
Krebs Cycle - Continued Step 3: Another CO2 is released forming a 4-C compound, an ATP molecule and NADH are produced Step 4: 4-C compound converted to a different 4-C compound. Electrons transferred to FAD to produce FADH2 Step 5: 4-C compound converted to the original 4-C compound that started the cycle NADH produced Draw Krebs Cycle
Electron Transport Chain Electrons are donated from NADH & FADH2 Located in the inner membrane of mitochondrion The energy of electrons are used to pump out hydrogen ions Concentration gradient is created - causes hydrogen ions to be pumped into the membrane The energy created adds a phosphate group to ADP to form ATP Products include: ATP and water molecules
Respiration in the Absence of Oxygen ETC cannot function – oxygen is the final electron acceptor NAD+ is recycled in other ways Fermentation: recycling of NAD+ using another form of organic hydrogen acceptor Lactic Acid Alcoholic
Lactic Acid Fermentation 3-C pyruvate converted to 3-C lactate Lactate: ion of its organic acid lactic acid Formed during intense workouts During the conversion: NAD+ and NADH are recycled No FADH2 Lactate expelled from muscles Draw on the board
Alcohol Fermentation 3-C pyruvate broken down to ethanol (2-C compound) Step 1: Pyruvate is converted to 2-C compound Carbon dioxide expelled Step 2: 2-C compound converted to ethanol During break down: NAD+ and NADH are recycled Draw on the board