Studied by 3 peopleDefine: Lipids, What are their roles?
Water-insoluble molecules that are soluble in organic solvents
Roles Include:
Membranes
Energy Storage
Signalling
Fat-soluble vitamins
Define: Fatty Acids
Hydrocarbon chains ending with carboxylic acid groups
Key Roles:
Used for fuel
Act as building blocks for membrane lipids
How do saturated and unsaturated fatty acids differ?
Saturated: Only single bonds
Unsaturated: One or More Double Bonds (Double bonds may be CIS or TRANS)
What are some ways to name fatty acids?
Systematic: all-cis-Δ9 , Δ12 , Δ15-octadecatrienoate
Common: alpha-Linolenate
Number of Carbons/Number of Unsaturated Bonds: 18:3
Is the conformation of double bonds usually cis or trans?
Cis
What determines the properties of fatty acid chains and lipids?
Chain length and degree of saturation
How does chain length affect melting point?
Longer chains have higher melting points
How does saturation affect melting point?
Unsaturated (double bonds) decrease melting points (when compared to saturated acids with the same chain length)
How are fatty acids stored?
Triacyclglycerols
Descibe: Triacylglycerols
Efficient storage - hydrophobic and nearly anhydrous
Adipose cells are specialized for storage and mobilization of triacylglycerols. Adipose tissue also provides insulation
What are the components of glycerolipids?
Fatty acid(s)
Platform (glycerol, sphingosine, cerebroside)
Phosphate (usually)
Alcohol (usually)
What are the components of sphingolipids?
Fatty acid
Sphingosine
Phosphate
Alcohol
What are the components of glycolipids?
Fatty acid
Cerebroside (glycolipid)
Sugar unit (glucose or galactose)
What are the components of phosphoglycerolipids?
Fatty acids
Glycerol
Phosphate
Could have alcohol, or no alcohol
Describe: Steroids
Most common steroid: cholesterol
Important for membrane fluidity
Not found in prokaryotes, but in all animal membranes
Define: Liposomes
Lipid vesicles, made from a bilayer membrane that surrounds an inner aqueous compartment
Describe: Eukaryotic Membranes
Membranes contain lipids and proteins, carbohydrates can be attached to lipids or proteins.
Singer and Nicholson proposed the Fluid-Mosaic Model of membranes
What factors affect membrane fluidity?
Heat increases fluidity
Cold decreases fluidity
Unsaturated membranes are more fluid
Saturated membranes are more rigid
Describe: The permeability of lipid bilayers
Lipid bilayers are impermeable to ions and most polar molecules.
This allows the concentrations of an ion inside and outside the cell to be very different e.g. for sodium, 14 mM and 143 mM.
The control of transport across membranes, is one of the key functions of the membrane (barrier). Ion gradients are important for cells.
Describe: Lipid Modifications of Proteins
These modify the biochemical properties of the protein.
Generally, lipid modifications allow for the association with a hydrophobic environment like the membrane.
The lipid portion can insert into the hydrophobic interior of the membrane.
The protein is then localized to the membrane surface for its function
Immediate donor of free energy, but not long term storage
Describe: Membrane Proteins
Plasma membranes need to conduct the traffic of molecules in/out of cells, they contain proteins that do this.
Membrane proteins can be integral, peripheral, or can be covalently attached via a lipid molecule.
What do most membrane proteins use to cross the membrane?
α helices, they are non-polar and associate with the hydrocarbon core of the lipid bilayer
Describe the use of β strands to cross the membrane
The β strands form a single β sheet with a pore in the center.
ex) porin from the outer membrane of bacteria
True or False: Just part of the protein can be embedded in the membrane, they do not always cross the membrane
True. prostaglandin H2 synthase-1 (outer membrane) is an example of this.
Describe: prostaglandin H2 synthase-1
Catalyzes the conversion of arachidonic acid into prostaglandin H2
Arachidonic acid moves from the lipid membrane to the enzyme active site via hydrophobic channel
Prostaglandin H2 promotes inflammation and gastric acid secretions
How do drugs like aspirin/ibuprofen combat prostaglandin H2 synthase-1 activity?
They donate an acetyl group to Ser 350, which blocks the hydrophobic channel
Describe the potassium ion channel
The potassium ion channel transports potassium ions specifically and quickly. The channel is wider at the cell interior and narrows for the selectivity filter.
Ions with a radius larger than 1.5 Å cannot pass through.
Four binding sites within the channel allow for repulsion and flow of ions through the channel.
Sodium ions, with an ionic radius of 0.95 Å, are smaller than potassium ions. But the energy required to lose their solvation shell and pass through is too great, and they do not pass.
Describe: Digestion throughout the body
Mouth
homogenization to aqueous slurry
enzymes in saliva: amylase, lipase
Stomach
denatures proteins with low pH (stimulates secretin)
denatured proteins better substrates for pepsin (a protease)
Pancreas
releases NaHCO3 to neutralize acid
releases digestive enzymes to digest proteins, lipids and carbohydrate
Gall bladder
releases bile salts required to digest lipids
Define: Protease
Active form. Cleaves proteins
Define: Zymogen
Inactive form. Proteases do not cleave proteins that they are not supposed to cleave – including themselves
Stored in granules near the cell membrane, get released and then activated (usually by cleavage)
True or False: Pepsinogen can self-activate
True
Describe: Digestion of Proteins
Proteases cleave proteins, zymogens are inactive proteases.
Many of the proteases are dissolved in the lumen of the intestines
Peptidases that can cleave oligopeptides are attached to the outside surface of intestinal cells.
Transporters pass the amino acids and di- and tripeptides into the cells and out into the blood stream
Describe: Digestion of Carbohydrates
α-amylase
cleaves α-1,4 bonds
cannot cleave α-1,6 bonds, nor too close
Maltase, α-glucosidase, α-dextrinase
complete the hydrolysis of starch.
Other carbohydrate-cleaving enzymes are sucrase and lactase, both on the surface of intestinal cells.
Describe: Digestion of Lipids
Mostly triacylglycerols
Forms emulsion in the stomach
Enhanced by bile salts (amphipathic)
Lipases cleave off two of the fatty acids
Fatty acids and monoacylglycerols form micelles
Micelles absorbed across the plasma membrane
What are chylomicrons?
2000 Å in diameter
Transport triacylglycerols, proteins, phospholipids, cholesterol, and fat-soluble vitamins
Define: Metabolism
Metabolism is a series of linked chemical reactions that transforms one molecule to another as required by the organism. This provides required molecules or energy for the organism
Define: Catabolism
Breakdown
fuel molecules → CO 2 + H2 O + useful energy
Define: Anabolism
Building
simple molecules + energy → complex molecules
Define: Amphibolic
Both biosynthetic and degradative
True or False: Degradative and biosynthetic pathways generally occur together
False. Degradative and biosynthetic pathways are generally separate, \n allowing for control.
Glucose is an important metabolic fuel, what is the final product?
CO2
Describe: ATP
Energy-rich because of the phosphoanhydride bonds
Can be used to drive other reactions
Is an immediate donor of free energy in biological systems but is not used for long term storage
Describe: Oxidation-Reduction
Oxidation
Loss of the electrons
Reduction
Gain of electrons
The most reduced molecule has the most energy that can be liberated by oxidation. This is why fatty acids have more energy per carbon atom than glucose
Define: Activated Carriers
ATP can be thought of as an “activated carrier” of the phosphoryl group. Other molecules are activated carriers of electrons and two-carbon fragments.
To carry:
electrons in fuel oxidation: pyridine nucleotides or flavins e.g. nicotinamide adenine dinucleotide (NADH), flavin adenine dinucleotide (FADH2 )
electrons in biosynthesis: the reduced form of nicotinamide adenine dinucleotide phosphate (NADPH)
two-carbon fragments: acetyl-coenzyme A (acetyl-CoA)
Describe: Regulation of Metabolism
Metabolism is regulated through the control of
Amounts of enzymes
how fast they are synthesized • how fast they are degraded
Their catalytic activities
allosteric control e.g. feedback inhibition
reversible covalent modification
the accessibility of substrates
compartmentalization in eukaryotes
flux of substrates between compartments
What is energy charge?
Many metabolic reactions are controlled by the energy status of the cell (energy charge)
Most cells have values between 0.80 and 0.95 for energy charge
What coordinates metabolism between different tissues?
Hormones
Describe: Glycolysis
Sequence of reactions converting glucose to two molecules of pyruvate
Occurs in two stages:
Trapping and preparation
Goal is to trap glucose in the cell and transform into a molecules that can be better broken down (fructose-1,6-biphosphate then glyceraldehyde 3-phosphate)
Oxidation to Pyruvate
Transfer of phosphate from substrate to ADP (makes ATP)
Formation of pyruvate
Outline the steps of Glycolysis
Trapping and Preparation
Glucose (Kinase transfers phosphoryl group from ATP to glucose)
Glucose 6-Phosphate
Fructose 6-Phosphate (Kinase transfers phosphoryl group from ATP)
Fructose 1,6-biphosphate
Two products formed: Glyceraldehyde 3-phosphate (used in the next step) and Dihydroxyacetone phosphate
Oxidation to pyruvate
Glyceraldehyde 3-Phosphate is oxidized and a Pi reduction of NAD+ occurs to form 1,3-Biphosphoglycerate
Kinase transfers phosphoryl group from 1,3-BPG to ADP, forms 3-Phosphoglycerate
2-Phosphoglycerate
Phosphoenolpyruvate (and H2O)
Kinase transfers phosphoryl group from Phosphoenolpyruvate to ADP, forms Pyruvate
What are the major classes of enzymes? How are enzymes labelled accordingly?
Oxidoreductases
Transferases
Hydrolases
Lyases
Isomerases
Ligases
Translocases
Labelled EC #.#.#.# where the first number corresponds to the type of enzyme above
Describe: Alcoholic Fermentation
Anaerobic fermentation of pyruvate to ethanol. (Acetaldehyde intermediate)
Describe: Lactic Acid Fermentation
Anaerobic fermentation of pyruvate to lactate (later protonated to lactic acid)
Describe: Regulation of Glycolysis
Occurs at hexokinase, phosphofructokinase, and pyruvate kinase steps
All three steps are IRREVERSIBLE
Tissue Specific
Controlled by allosteric effectors or covalent modification
Describe: Regulation of Phosphofructokinase
Most Important Regulation
Allosteric inhibition by ATP
Inhibition can be reversed by AMP
1st committed step
Step: Fructose 6-phosphate to Fructose 1,6-biphosphate
Describe: Regulation of Hexokinase
Product inhibition by Glucose 6-phosphate
Glucose 6-phosphate is not solely used for glycolysis
Step: Glucose to Glucose 6-phosphate
Describe: Regulation of Pyruvate Kinase
Energy Charge of Cell
ATP and Pyruvate are made
Allosteric Inhibition by ATP
Activation by Fructose 1,6-Biphosphate
Step: Phosphoenolpyruvate to Pyruvate
Describe: Regulation in Muscle
Phosphofructokinase and Hexokinase
Describe: Regulation of Phosphofructokinase in the Liver
ATP dependent (PH is not important like in muscle)
Citrate is a key building block
Fructose 2,6-biphosphate (feedforward stimulation)
Stimulated when glucose is high
Describe: Regulation of Hexokinase in the Liver
Glucose 6-phosphate used in liver to synthesize glycogen and fatty acids
Mainly carried out by hexokinase IV
Isozyme
No product inhibition
Km is 50X greater than Hexokinase
Define: Isozyme
Catalyze same reaction
Different kinetics or regulation
Different primary structure
Describe: Regulation of Pyruvate Kinase in the Liver
Several isozymes involved
L form in liver
M form in muscle and brain
L form
Allosteric inhibition by ATP and Alanine
Inhibition by reversible phosphorylation
Describe: Regulation by Substrate Availability
Glut 1 *and 3 are always on (Basal Glucose uptake)
Glut 2 only on when Glu is high (In pancreas, insulin regulation)
Glut 4 amount in PM increases with high endurance training
Glut 5 (Fructose transporter)
Describe: Gluconeogenesis
Conversion from pyruvate to glucose
Other molecules join when converted to intermediates.
Lactate from lactic acid fermentation in muscles
Amino acids from proteins
Glycerol from triacylglycerols
Occurs mainly in the liver
Outline the steps of Glucogenesis
Pyruvate
Pyruvate carboxylase transforms pyruvate to oxaloacetate
Phosphoenolpyruvate carboxylkinase transforms oxaloacetate to phosphoenolpyruvate
Enolase transforms phosphoenolpyruvate to 2-phosphoglycerate
Phosphoglycerate mutase transforms 2-phosphoglycerate to 3-phosphoglycerate
Phosphoglycerate kinase transforms 3-phosphoglycerate into 1,3-Biphosphoglycerate
Glyceraldehyde 3-phosphate dehydrogenase transforms glyceraldehyde 3-phosphate to Glyceraldehyde 3-phosphate (also produces glycerol: dihydroxyacetone phosphate)
Aldolase transforms glyceraldehyde 3-phosphate to fructose 1,6-biphosphate
Fructose 1,6-biphosphotase + Water makes Fructose 6-phosphate + Phosphate
Phosphoglucose isomerase makes glucose 6-phosphate
Glucose 6-phosphotase + Water makes Glucose + Phosphate
What are the differences between Gluconeogenesis and Glycolysis?
Pyruvate to phosphoenolpyruvate is 2 steps in gluconeogenesis and 1 step in glycolysis
Use of Phosphatases to REMOVE phosphate groups in Gluconeogenesis:
Fructose 1,6 phosphate to fructose 6-phosphate (Fructose 1,6-biphosphotase)
Glucose 6-phosphate to glucose (Glucose 6-phosphotase)
Gluconeogenesis USES 4 ATP and 2 GTP, Glycolysis PRODUCES 2 ATP
Describe: Regulation of Gluconeogenesis and Glycolysis
Fructose 1,6-biphosphotase is key.
Reciprocal to phosphofructokinase
( also Citrate and Acetyl-CoA from TCA and H+ from hydrolysis of ATP)
Fructose 1,6-biphosphotase is inhibited by fructose 2,6-biphosphate (formation catalyzed by phosphofructokinase)
Describe: Synthesis and Degradation of Fructose 2,6-bisphosphate
Glucagon stimulated PKA when blood glucose is scarce. FBPase2 is activated. Glycolysis is inhibited, gluconeogenesis is stimulated.
High levels of fructose 6-phosphate stimulate phosphoprotein phosphatase. Glycolysis is stimulated, and gluconeogenesis is inhibited.
*Both controlled by a single Serine residue (phosphoserine)
Where does gluconeogenesis end in most tissues?
At glucose 6-phosphate. Conversion to glucose occurs mostly in the liver
Can both Gluconeogenesis and Glycolysis occur at once?
No. One pathway is active while the other is inactive.
Describe the transformation of pyruvate under anaerobic and aerobic conditions.
Under anaerobic conditions: Conversion to lactic acid or ethanol (depending on organism)
Under aerobic conditions: Conversion into acetyl CoA, which enters the TCA
What is Acetyl-CoA?
Activated carrier of two-carbon units in TCA
What reaction links glycolysis and TCA? Is it reversible or irreversible? Where does it occur?
The bridge reaction. Irreversible. Occurs in the mitochondrial matrix.
Describe: Pyruvate Dehydrogenase Complex
Produced from a reaction with pyruvate, CoA, and NAD+
Consists of Pyruvate dehydrogenase (E1) component, Dihydrolipoyl transacetylase (E2), and Dihydrolipoyl dehydrogenase (E3)
8 E2 timers (24 total) forms the core.
6 a/B dimers (12 total) are on the face of the cube (2 on each face)
6 (a2/B2) dimers (24 total) line the edges of the cube (2 on each edge)
Outline the Steps of Acetyl CoA formation catalyzed by Pyruvate Dehydrogenase Complex
Decarboxylation (step 1): rate limiting step, catalyzed by E1
Oxidation (steps 2/3): catalyzed by E1
Formation of acetyl CoA (step 4): catalyzed by E2
Lipoamide regeneration (step 5): catalyzed by E3
Describe the movement/role of lipoamide with the pyruvate dehydrogenase complex
Lipoamide moves from one active site to another. (E2 surface to E1 to E2 to E3, back to E2 surface)
Substrate cannot diffuse away.
High local concentration of substrate.
Minimizes side reactions.
Increases rate of overall reaction.
Once Acetyl CoA forms, what occurs?
Glucose CANNOT be regenerated. Acetyl CoA goes on to oxidation by TCA cycle or incorporation in lipids for lipid synthesis.
Describe: Regulation of Pyruvate Dehydrogenase Complex
Allosteric on E2 and E3 (acetyl CoA and NADH)
Covalent Phosphorylation on E1
Describe the differences in the pyruvate dehydrogenase complex at high and low energies
High energy: ATP, NADH, acetyl CoA All inhibit PDH By stimulating kinase
Low energy: ADP and pyruvate inhibit kinase and Ca2+ and hormones stimulate Phosphatase
Describe: Clinical disruptions of pyruvate metabolism
TPP deficiency - low content in rice, more problems with white and polished rice
Beriberi: neurological and cardiovascular disorder (cause by a limited intake of food, malnutrition, famine - thiamine deficiency)
Metal Toxicity (Arsenic/Mercury): high affinity for SH groups in close proximity blocks the reaction
Provide an overview of the TCA cycle:
Cycle: acetyl-CoA reacts with a product of the previous cycle
Two carbons go to CO2
One ATP from ADP and Pi
Eight electrons – Most of the energy from oxidation is carried by these electrons.
Two stages:
Oxidizes two carbon atoms; gathers energy-rich electrons
Regenerates oxaloacetate; makes one ATP; gathers energy-rich electrons in NADH and FADH2
Each reaction of TCA is catalyzed
Outline the reactions of the TCA cycle
First Stage:
Catalyzed by Citrate synthase to form Citrate (condensation of Oxaloacetate then Citryl CoA hydrolysis)
Catalyzed by Aconitase to form Isocitrate (dehydration of citrate, then hydration of cis-aconitase)
Catalyzed by Isocitrate dehydrogenase to form α-Ketoglutarate (oxidation of isocitrate, formation of NADH, then decarboxylation of oxalosuccinate)
Catalyzed by α-ketoglutarate dehydrogenase complex to form Succinyl CoA, CO2 and NADH. (oxidation of α-ketoglutarate, then decarboxylation)
First Stage Complete, C4 molecules formed
Second Stage:
Catalyzed by Succinyl-CoA synthetase to form Succinate (Substrate-level phosphorylation to form ATP or GTP)
Catalyzed by Succinate dehydrogenase to form Fumarate (oxidation of succinate, forms FADH2)
Catalyzed by Fumarase to form Malate (Hydration of fumarate)
Catalyzed by Malate dehydrogenase to form Oxaloacetate (oxidation of malate, forms NADH + H+)
3 NADH, 1 FADH2, and 1 ATP are formed. 2 H2O are used, 2 CO2 are released.
Describe the specificity/Induced fit of citrate synthase in the first reaction of TCA
Sequential reaction: Oxaloacetate first, then acetyl-CoA
Changes conformation upon binding to each, first induced fit, then a preference over hydrolysis of acetyl-CoA. After cleavage CoA leaves which prevents wasteful cleavage of acetyl-CoA.
Does the TCA cycle occur under anerobic, aerobic, or both conditions?
STRICTLY AEROBIC! NADH and FADH2 are not regenerated without oxygen.
Describe: Regulation of the TCA Cycle
May need to replenish oxaloacetate (e.g. during exercise)
Pyruvate carboxylase also for gluconeogenesis
Requires acetyl-CoA
Regulated by energy charge
High – make glucose
Low – run TCA cycle
Anaplerotic reaction – “fills up” or replenishes pathway
Within the cycle allosteric enzymes: Isocitrate dehydrogenase and α-Ketoglutarate dehydrogenase regulate:
α-Ketoglutarate dehydrogenase catalyzes the rate determining step
Inhibition of isocitrate dehydrogenase leads to increased citrate which inhibits phosphofructokinase and glycolysis (INTERACTION BETWEEN PATHWAYS!)
Does the oxidized form of a substance have a lower or higher affinity for electrons than protons (H2)?
The oxidized form of a substance has a LOWER affinity for electrons than protons.
Does a strong reducing agent (like NADH) accept or donate electrons?
Strong reducing agents DONATE electrons
Does a strong reducing agent (like O2) accept or donate electrons?
Strong oxidizing agents ACCEPT electrons
What does negative reduction potential mean?
What does positive reduction potential mean?
What is the free energy difference from NADH to O2 (electron transport chain)
220 kJ/mol (enough to make 7 ATP from ADP)
What is the electron transport chain?
Electrons exchanged through groups in the active sites of enzymes to produce O2
NADH-Q oxidoreductase (COMPLEX 1) /Succinate-Q reductase (FADH2) (COMPLEX 2)
Ubiquinone (Q)
Q-cytochrome C oxidoreductase (COMPLEX 3)
Cytochrome C
Cytochrome C oxidase (COMPLEX 4)
What is the role of iron in the electron transport chain?
Iron in the electron transport chain is found in two forms: iron sulfur clusters (in complexes I and II, NADH-Q reductase and Succinate-Q reductase), and as part of heme in cytochromes
Iron goes from ferric (Fe3+) to ferrous (Fe2+) thus reduction potential depends on environment and iron can be involved in many steps
What is the role of copper in the electron transport chain?
Copper goes from Cu2+ to Cu+ in cytochrome c oxidase
What is the role of Coenzyme Q in the electron transport chain?
Coenzyme Q (Ubiquinone) accepts electrons from complexes 1/2 (NADH-Q reductase and Succinate-Q reductase)
Hydrophobic
Carries protons and electrons
Describe: Proton Pumps in the Electron Transport Chain
3 proton pumps: Complex 1 (NADH-Q-oxidoreductase), Complex 2 (Q-cytochrome C oxidoreductase), Complex 4 (Cytochrome C oxidase)
Pump electrons across the inner mitochondrial membrane from the matrix to the intermembrane space
What is the link between the electron transport chain and the TCA cycle?
Complex 2 contains succinate dehydrogenase as an integral protein in inner mitochondrial membrane (all other TCA enzymes are in the matrix)
Oxidative phosphorylation (e- transport chain) occurs in the inner mitochondrial membrane
Describe the structure of mitochondria
Inner Membrane: Tightly controlled, impermeable
Outer Membrane: Many channels, voltage dependent anion channels
Cristae: Increase in surface area
Define: Proton Motive Force (Δp)
Link between electron transport and ATP synthesis provided by a H+ gradient (chemiosmotic hypothesis) Δp = chemical gradient and charge gradient
TCA in matrix, provides e- ; electron transport chain in the membrane creates H+ gradient to the intermembrane space which is used to make ATP when flowing back
Define: ATP Synthase
T=tight, L=loose, O=open
1: T makes ATP but does not release
2: after rotation T becomes O
3: it now releases ATP
4: ADP and Pi can enter
5: L state traps substrates for next turn
Describe: NAD+ for Glycolysis
Glycolysis in cytoplasm, oxidative phosphorylation in mitochondria
Membrane impermeable to NAD+ (or NADH)
Shuttles e.g. regenerate NAD+
Yield is only 1.5 ATP (not the 2.5 ATP from NADH) because shuttle uses FAD.
Runs against NADH concentration gradient
Important in muscle to sustain high rate of oxidative phosphorylation
Note
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