Chapter 3 Energy, Chemical Reactions, and Cellular Respiration
Formation of Citrate Step 1 Citric Cycle (Krebs Cycle)
Step 1 of the citric acid cycle uses the first enzyme to combine an acetyl CoA molecule produced in the intermediate stage with a molecule of oxaloacetate to form citrate. (Note that the addition of a hydrogen ion to citrate forms citric acid.) The first step of this cycle gives this enzymatic pathway its name.
Thermodynamics
The study of energy transformations
Import Molecules in Chemical Energy Storage
Triglycerides, glucose, ATP
Multienzyme Complex
a group of enzymes that are physically attached to each other through noncovalent bonds to form the complex; work in a sequence reaction
Organic Cofactors (coenzyme)
not attached to the enzyme and have specific functions in assisting the enzyme
Cytosol
semifluid contents of the cell; viscous, syruplike fluid medium with dissolved solutes in the cytoplasm
Biochemists
study the chemical composition/physical principles of living cells/organisms
Products
substances formed from reactants by subsequent chemical reaction; written on right side of equations
Catalysts
substances that accelerate chemical reactions
Inhibitors
substances that bind to an enzyme and turn it off, thus preventing it from catalyzing the reaction; temporarily turns off to prevent overproduction of the product
Chemical Equation
summary of changes to the molecular structure when a chemical reaction occurs; components of equation are called reactants and products; (Ex: A+B->C; Ca^2+ +2Cl- -> CaCl2); the number of elements on one side of the equation is equal to the number of elements on the other side of the equation, in a balanced chemical equation
Laws of Thermodynamics
1) energy can not be created nor destroyed, only transformed/converted from one form to another; 2) each time you convert one form of energy to another, some energy is converted to heat; never 100% conversion of one form to another
Net number of ATP molecules that can be produced from oxidation of a glucose molecule under anaerbonic conditions
2 ATP molecule
Net ATP produced from 1 glucose molecule from cellular respiration
30 ATP
Total ATP produced from 1 glucose molecule
38 ATP
Electron Transport Chain
A sequence of H+ pumps and electron carrier; ATP synthase allows passage of H+ from the outer compartment back into the matrix; during this, kinetic energy from the flow of H+ downs concentration gradient is harnessed to bond Pi to ADP to form ATP;
Exchange Synthesis
Atoms, molecules, ions, or electrons are exchanged between two chemical structures (AB+C -> A+BC)
Ketoacids
Byproduct of fatty acid metabolism
Glucose
C6H12O6; Disassembled during cellular respiration, the chem reaction is: C6H12O6+602-> 6CO2+6H20
Step 6 Citric Cycle (Krebs Cycle)
CoA removed, ATP formed. Step 6 of the citric acid cycle involves the removal of CoA and the formation of ATP through substrate-level phosphorylation.
Mitochondrion
Double-membraned organelle where aerobic cellular respirationoccurs
Activation Energy (Ea)
Energy required to break existing chemical bonds for the chemical reaction to proceed
Induced-Fit Model
Entry of the substrate into the active site induces the conformation (structure) of the enzyme to change slightly, resulting in an even closer fit bet
Chemical reactions can be classified by the relative amounts of chemical energy associate with the reactants and products
Exergonic and endergonic
Step 7 Citric Cycle (Krebs Cycle)
FAD reduced to FADH2. Step 7 of the citric acid cycle occurs through the action of a dehydrogenase that transfers hydrogens to FAD to form FADH2.
Four Stages of Cellular Respiration
Glycolysis, intermediate stage, citric acid cycle, and the electron transport system
Step 9 Citric Cycle (Krebs Cycle)
NAD+ reduced to NADH, oxaloacetate regenerated. Step 9 of the citric acid cycle is catalyzed by a dehydrogenase that transfers hydrogen to NAD+ to form NADH. Oxaloacetate (OAA) is regenerated in this final step.
Steps 4-5 Citric Cycle (Krebs Cycle)
NAD+ reduced to NADH. Steps 4 and 5 of the citric acid cycle occur through two different dehydrogenase enzymes that participate in the transfer of hydrogen to NAD+ to form NADH. CoA is also attached during step 5.
NAD+ (oxidized form of NAD+)
Reduced from NADH because NAD+ has gained H+ and 2 e-
Regulation of Citric Acid Cycle
Regulation of the citric acid cycle occurs primarily at the enzyme in the first step of the citric acid cycle (citrate synthase). The levels of NADH, ATP, and pathway intermediates are the primary regulators of citrate synthase activity. A low level of NADH, ATP, and pathway intermediates indicates that cellular energy demands are high. This results in increased activity of citrate synthase and the citric acid cycle.
Glycolysis Steps 1-5
Steps 1 through 5 of glycolysis involve splitting glucose into two molecules of glyceraldehyde 3-phosphate (G3P) through the action of the first five enzymes. ATP is "invested" when kinase enzymes transfer Pi from ATP to glucose and the breakdown products of glucose (steps 1 and 3). Thus, an investment of 2 ATP molecules occur at these steps
Glycolysis Steps 6-7
Steps 6 and 7 of glycolysis occur twice in oxidation of a glucose molecule. Step 6 involves transferring an unattached Pi to the substrate (so this molecule now has two phosphates), and two hydrogen atoms are released to NAD+ to form an NADH (and H+). This transfer of hydrogen is catalyzed by a dehydrogenase enzyme. In step 7, the original Pi is transferred to ADP to form ATP through substrate-level phosphorylation by a kinase enzyme.
Glycolysis Steps 8-10
Steps 8 through 10 of glycolysis also occur twice. These steps involve converting the molecule produced in step 7 to an isomer (step 8) and then the loss of water molecule. The remaining Pi (on phosphenolpyruvate) is transferred to ADP to form ATP through substrate-level phosphorylation by a kinase enzyme (step 10), forming the final product of pyruvate
Step 2 Citric Cycle (Krebs Cycle)
Water removed from citrate and reattached. Steps 2 and 3 of the citric acid cycle form an isomer by removing a water molecule from citrate and then reattaching it to a different location on the molecule.
Step 8 Citric Cycle (Krebs Cycle)
Water removed. Step 8 of the citric acid cycle is the removal of water.
Allosteric Site/Inhibitor
a specific receptor on the enzyme that is not the active site; binding a noncompetitive inhibitor to the allosteric site induces a conformational change in the enzyme with an accompanying change in the shape of the enzyme's active site
Optimal Temperature
activity of human enzymes increases with a rise in body temperature and continues to rise until 104 F
Metabolism
all chemical reactions taking place in the body, including anabolic and catabolic reactions
Reactants
are substrates or substances that are present prior to the start of the chemical reaction; written on left side of equation
Heat (Kinetic Energy)
associated with random motion of atoms, ions, or molecules; usually considered a unstable form of energy, or waste product that accompanies all changes in energy form; measured as temperature
Inorganic Cofactors
attached to the enzyme and are required for their normal function
Enzymes
biologically active catalysts that facilitate chemical changes in the human body by decreasing the activation energy of millions of chemical changes that occur every second; globular protein with a depressed region that serves as the active site; produced by protein synthesis processes within cells; increases reaction rate
Catabolism (Catabolic Reations)
breakdown of complex molecules into simpler molecules
Pyruvate Dehydrogenase
brings together pyruvate and a molecule of conenzyme A (CoA) to form acetyl CoA (2 carbon molecule with CoA attached)
Decarbonization
carboxyl group (1 carbon atom and two oxygen atoms) release pyruvate as CO2; energy is released during Decarbonization as 2 hydrogen atoms (2 electrons+ 2 hydrogen ions) are transferred to the coenzyme NAD+ to form NADH( and H+); the acetyl CoA then enters the citric cycle
Catalyzed Reaction
chemical reaction with an enzyme
Uncatalyzed Reaction
chemical reaction without an enzyme
ATP Cycling
continous formation/breakdown of ATP; involves (1) ATP formation from ADP and Pi(free phosphate), which is energy requiring (endergonic) reaction (2) ATP splitting into ADP and Pi(phoshate free) which is energy releasing (exergonic) reaction
Citric Cycle (Krebs Cycle)
cyclic metabolic pathway that occurs through the activity of 9 enzymes located in the matrix of the mitochondria; During the citric acid cycle, the acetyl CoA produced in the intermediate stage is converted to two CO2 molecules and a CoA molecule is released. Energy is transferred to form 1 ATP molecule, 3 NADH molecules, and 1 FADH2 molecule during one "turn" of the citric acid cycle; requires oxygen; 2 CO2 molecules produced per turn of cycle; key enzyme in regulation citrate synthetase
Concentration Gradient
difference in the concentration of a substance between two areas
Substrate Level Phosphorylation
direct method of synthesizing ATP
Noncompetitive Inhibitor
doesn't resemble the substrate, functions to inhibit the enzyme by binding to the site on the enzyme other than the active site; not influnced by the concentration of the substrate
ATP Production
each NADH generates 3 ATP and each FADH2 generates 2 ATP; able to calc specific number of ATP molecules produced in breakdown of glucose molecules by knowing: specific number of energy molecules (ATP, NADH, FADH2) that are generated from the glucose breakdown in each stage of cellular respiration; and the specific number at ATP generated by oxidation of each coenzyme in the electron transport system (NADH=3 ATP, FADH=2 ATP)
Metabolic (Biochemical) Pathway
each enzyme catalyzes one progressive change to its specific substrate molecule and then releases the product; the product of one enzyme becomes the substrate of the next enzyme
Radiant Energy (Kinetic Energy)
energy of electromagnetic waves traveling in the universe; pigment: melanin; Ex: gamma rays
Kinetic Energy
energy of motion; can be converted into potential energy
Chemical Energy
energy stored in a molecule's chemical bonds, most important form of energy in the human body; used for the energy requiring processes of movement, synthesis of a molecule, and establishment of concentration gradients;form of potential energy
-ase
enzyme
Denatures
enzyme permanently loses function/weaken the intramolecular bonds that hold enzyme's protein structure when temp is greater than 104 F (40 C); may occur from changes in the pH
Optimal pH
enzymes function most efficiently between pH 6-8
Oxidation-Reduction Reaction (Redox Reaction)
exchange reaction involving transfer of electron from one chemical to another; Ex: nicotinamide adenine dinucleotide (NAD+; reduced form is NADH); Loses Electrons is Oxidized Gains Electrons is Reduced
Most catabolic reactions release energy meaning that they are also
exergonic
Mechanical Energy (Kinetic Energy)
exhibited by an object in motion due to applied forces; Ex; muscle contraction for walking
Beta Oxidation
fatty acids are enzymatically changed two carbon units at a time to form acetyl CoA
Pyruvate
final product of glycolysis; if oxygen is available, pyruvate enters mitochondria to complete aerobic breakdown (carbon dioxide/water); if oxygen is not available, pyruvate is converted into lactate
Glycolysis
first stage of cellular respiration in which glucose is partially catabolized to form pyruvate and transfer energy to form ATP molecule; glucose is boken down in this pathway into two pyruvate molecules with an accompanying energy transfer to form a net production of 2 ATP molecules and 2 NADH molecules; occurs in the cytosol and does NOT require oxygen; requires ATP to continue
Anabolism (Anabolic Reaction)
formation of large, complex molecules from simple molecules
GER
gains electron is reduced
Oxidative Phosphorylation
indirect method of synthesizing ATP; the energy is first released to coenzymes, which transfer the energy to form ATP
Decomposition Reaction
initial large molecule is digested (broken down) into smaller structures (AB-> A+B); all decomp reactions are collectively referred to as catabolism or catabolic reactions; Ex: hydrolysis reaction
Matrix
inner most space of the mitochondria; multienzyme complex of intermediate stage and the enzyme of citric acid cycle metabolic pathway resides inside the matrix
Exergonic Reactions
involve reactants at the start of a reaction that have more potential energy within their chemical bonds than do the products that are formed; energy released during the course of breakdown reactions; decomposition reactions are exergonic; catabolic reations
Endergonic Reactions
involve reactants that have less energy within chemical bonds than do the products; energy must be supplied to proceed; synthesis reaction is endergonic
Irreversible Reaction
involves reactants converted to product at the rate that yields a net loss of reactants and a net gain in product; many actions are irreversible ; A+B->AB or AB-> A+B
Electron Transport System
involves the transfer of electrons (energy) from the coenzymes NADH and FADH2 that are produced during the first 3 stages of cellular respiration. The energy released from these coenzymes is used to form ATP; majority of energy that was originally in the glucose molecule and transferred to coenzymes is now released from the coenzymes and transferred to form the high energy bond bewteen ADP and Pi as ATP is synthesized; final stage; occurs in inner/cristae membrane
Intermediate Stage/Pyruvate Dehydrogenase of Glycolysis
link between metabolic processes of glycolysis (first stage) and citric acid cycle (third stage); this stage is catalyzed by a multienzyme complex called pyruvate dehydrogenase; occurs in the mitochondrion and requires oxygen; involves a multienzyme complex that converts pyruvate to acetyl C0A and 1 CO2; after cycle occurs twice, a total of 2 NADH molecule are formed
Structure of the Electron Transport System
located in the inner folded membrane (cristae) of the mitochondria; molecules embedded in the cristae of mitochondria: H+ (proton) pumps ( proteins that transport H+ from the matrix to the outer membrane; maintains H+ gradient), electron carriers, and ATP synthase enzymes
Triglycerides (Chemical Energy: form of potential energy)
longterm energy storage in adipose connective tissue
LEO
loses electrons is oxidized
Reaction Rate
measure of how quickly a chemical reaction takes place; rate determines the amount of products formed per unit of time; a primary factory that influences the reaction rate is the energy required to break the chemical bonds in a molecule so that new bonds can form products; energy required to break down existing chemical bonds for chemical reactions to proceed is activation energy; chemical reaction occurs when sufficient energy is supplied to overcome the activation energy
Summary of Glycolysis
metabolic process that occurs in the cytosol with/without oxygen; glucose is initial substrate and pyruvate is final product; net transfer of energy is the formation of 2 ATP/2 NADH molecules
Nictotinamide Adenine Dinucleotide (NAD+) Molecule
modified dinucleotide that is linked at the phosphates and contains nicotinamide (nitrogenous base not found in DNA or RNA) and adenine; important in ATP synthesis
Protein
most enzymes are globular; range from small proteins composed of 60 amino acids to large proteins composed of 2500 amino acids
Electrical Energy (Kinetic Energy)
movement of charge particles; Ex: electricity
Cellular Respiration
multistep metabolic pathway whereby organic molecules (glucose, fatty acids, amino acids) are disassembled (broken down) in a controlled manner by a series of enzymes; during disassembly, potential energy stored in the molecule's chemical bonds is released; the energy is used to make new bonds between ADP and Pi(free phosphate) to form ATP;
Cofactor
nonprotein that may be inorganic/organic chemical structure attached to an enzyme that aids in the enzyme function
Reduction
occurs as a molecule, atom, or ion gains an electron and becomes reduced; a hydrogen ion and an electron are added to a structure during a chemical reaction
Oxidation
occurs as a molecule, atom, or ion loses an electron becoming oxidized
Saturation
occurs when so much substrate is present that all enzyme molecules are actively engaged in the chemical reaction, resulting in no further (notable) increase in reaction rate
Sound Energy (Kinetic Energy)
occurs when the compression of molecules move in liquid, solid, or gas is cause by vibrating an object; Ex: vocal cords
Glucose Oxidation
occurs within cells thru cellular respiration and is a step by step enzymatic breakdown of glucose with the accompanying release of energy to synthesize ATP; if oxygen is available, glucose is completely broken down and carbon dioxide and water are formed
Chemical Reaction
process during which chemical bonds of a molecule are broken and new ones are formed
Reversible Reaction
reactants become products at a rate equal to products becoming reactants; no net change in concentration in either reactants or products, and the reaction is in a state equilibrium; A+B->AB, A+B<-AB
Regulation of Glycolysis
regulated thru negative feedback; ATP acts as an allosteric inhibitor to turn off phosphofructokinase (PFK); as ATP levels increase in cell cytosol, ATP binding inhibits PFK, and glycolytic pathway is progressively shut down. In contrast, as ATP decreases, glycolysis increases
NADH (reduced form of NAD+)
release of H+ and 2 e-
When glucose is oxidize, it_________ chemical energy
releases
Dephosphorylation
removal of a phosphate group; enzymes that remove phosphates are called phosphatases
Competitive Inhibitor
resembles the substrate and binds to the active site of the enzyme; influenced by the concentration of substrate
Over time products/reactants are formed at the same rate, the reaction is
reversible
Carbonic Acid Reaction
reversible reaction in the human body that occurs when carbon dioxide and water combine to form carbonic acid; this formed carbonic acid is unstable
Mitochondria
small organelles within the cell
Potential Energy
stored energy; can be converted into kinetic energy
ATP (Chemical Energy: form of potential energy)
stored in all cells in limited amounts and is produced continuously and used immediately for cells' energy requiring processes
Glucose (Chemical Energy: form of potential energy)
stored in the liver/muscle tissue in the form of polymer glycogen
Phosphorylation
the addition of a phosphate group to a molecule; may turn on some enzymes and turn off other; enzymes that add phosphate are generally phosphorlyases/kinases
Energy
the capacity to do work; has no mass and does not take up space
Carbonic Anhydrase
the enzyme that converts carbon dioxide and water into carbonic acid
Active Site of an Enzyme
the region of an enzyme where substrate molecules bind
Kinase Enzymes
transfer phosphate groups, usually from ATP to another molecule
Synthesis Reaction
two or more atoms, ions, or molecules are combined to form a larger chemical structure (A+B-> AB); Ex; dehydration synthesis; anabolism is the collective term for all synthesis reactions in the body
