Aerobic/ anaerobic respiration

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biology
Darcey Griffiths
Fichas por Darcey Griffiths, actualizado hace 2 meses
Darcey Griffiths
Creado por Darcey Griffiths hace 2 meses
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Aerobic Respiration The release of large amounts of energy made available as ATP- produced from breakdown of molecules, w/ oxygen as terminal electron acceptor
Anaerobic Respiration breakdown of molecules in the absence of oxygen , releasing relatively little energy, making a small amount of ATP by substrate- level phosphorylation. There’s obligate aerobes, facultative anaerobes and obligate anaerobes
Anaerobic respiration breakdown of molecules in the absence of oxygen , releasing relatively little energy, making a small amount of ATP by substrate- level phosphorylation. There’s obligate aerobes, facultative anaerobes and obligate anaerobes
Dehydrogenation The removal of one or more hydrogen atoms from a molecule
Decarboxylation The removal of a carboxyl group from a molecule, releasing CO2.
Metabolism all reactions of an organism- respiration= metabolic pathway- sequence of enzyme controlled reactions where product of one reaction is substrate for the next- reactions of respiration= catabolic- break down energy rich macromolecules eg glucose + fatty acids
Metabolism pt 2 in respiration C-C, C-H and C-OH bonds are broken- lower energy bonds formed. Energy difference allows phosphorylation of ADP to ATP- ATP does not ‘produce’ energy- but when hydrolysed releases energy. Energy= available to use by cell or is lost as heat.
Oxidative phosphorylation occurs on inner membranes of mitochondria in aerobic respiration- energy for making ATP comes from oxidation- reduction reactions- released in the transfer of electrons- along a chain of electron carrier molecules.
Photophosphorylation Photophosphorylation- occurs in thylakoid membranes of the chloroplasts in the light- dependent stage of photosynthesis- energy for making ATP comes from light- is released in transfer of electrons along a chain of electron carrier molecules- photophosphorylation does not occur in respiration.
Substrate level phosphorylation Substrate level phosphorylation- occurs when phosphate groups are transferred from donor molecules e.g. glycerate 3- phosphate to ADP to make ATP in glycolysis or when enough energy is released from a reaction to bind ADP to inorganic phosphate eg in krebs.
More on respiration- processes/ aerobic formula Processes that require energy- active transport, movement, formation of complex molecules eg proteins- comes from respiration Formula for aerobic respiration of glucose C6H1206 +6CO2—> 6CO2 +6H2O+ energy (ATP) Glucose + oxygen—> carbon dioxide + water But can also use lipids and proteins in respiration
ATP Critical molecule in energy transfer- Ribose and adenine part of molecule together is called adenosine Energy carrying molecule- if we react ATP with water the end phosphate can leave-this reaction releases energy- energy can then be used for processes in the cell
ATP- more Reacting ATP with water is an example of a hydrolysis reaction catalysed with with ATP hydrolase also called ATPase ATP + water —> ADP + Pi + energy At end of the reaction made adenosine diphosphate (ADP) and released phosphate ion Given symbol Pi- i tells us it’s inorganic- not bonded to a carbon containing molecule -2 processes in respiration that can reform ATP- substrate level phosphorylation and oxidative phosphorylation- oxidative phosphorylation produces the vast majority of ATP during respiration
ATP formation Once ATP is hydrolyzed has to be reformed to be used again ATP is formed in respiration in the energy stored in glucose- when ATP is reformed- energy from glucose is used is used to add a phosphate ion back on to ADP- process is called phosphorylation
ATP formation- more Cells use energy in glucose to produce ATP in respiration- during respiration a large no. chemical reactions gradually break down the glucose molecule- during some of these reactions a hydrogen ion is released - dehydrogenation or oxidation reaction- hydrogen ion has 2 electrons- hydrogen ions are rich in energy- can be used to form large quantities of ATP- takes place during oxidative phosphorylation- when H= is released it’s added to a molecule called a hydrogen carrier- good example- coenzyme NAD- by adding hydrogen with its 2 electrons to NAD - carry out a reduction reaction NAD + H —> NADH (reduced NAD)
Glycolysis overview At different stages, energy contained within glucose can be transferred to other molecules Energy transfer can take place in 2 different ways- in some reactions the energy transferred can be used to produce a molecule of ATP directly releasing energy- energy is used to form a molecule of ATP from ADP and Pi (substrate level phosphorylation) - Or hydrogen and 2 electrons can be removed from a molecule- (dehydrogenation/ oxidation - hydrogen and 2 electrons are transferred to a hydrogen carrier such as coenzyme NAD, forming reduced NAD- reduced NAD is then used used later to produce ATP in process called oxidative phosphorylation.
Where does glycolysis take place + why Glycolysis takes place in the cytoplasm and does not require oxygen Glycolysis consists of 10 different reactions but we learn a simplified version Initial stage of both aerobic and anaerobic respiration- occurs in cytoplasm as glucose can’t pass through mitochondrial membrane- but even if it could- enzymes for breakdown= not present in mitochondria- so glucose could not be metabolised
Glycolysis- steps pt 1 glucose molecule is phosphorylated by addition of 2 phosphate groups using 2 molecules of ATP- ATP molecules each transfer 1 phosphate onto the glucose molecule- makes hexose diphosphate As a result- phosphorylated molecule= more reactive- less AE required for enzyme controlled reactions- also more polar than glucose= less likely to diffuse out of cell Hexose diphosphate converted to 2 molecules of triose phosphate- a 3 carbon sugar, glyceraldehyde-3- phosphate
Glycolysis pt 2 Hydrogen is removed from the triose phosphate molecules- a dehydrogenation/ oxidation reaction- triose molecules oxidised to form pyruvate- this hydrogen is added onto NAD forming reduced NAD (hydrogen carrier molecule). - Also each phosphate group on triose phosphate is added to ADP, converting these molecules to ATP- so for each triose phosphate molecule 2 molecules of ATP is produced-4 ATP molecules produced overall- this is an example of substrate level phosphorylation- happens without redox reactions along electron transport chain- produces pyruvate
Overall products of glycolysis At start used 2 ATP molecules but produced 4 ATP molecules at end- net yield- 2 ATP Produced 2 reduced molecules of reduced NAD- will be used in a later stage of respiration called oxidative phosphorylation- if O2 available each has potential for synthesis of an additional 3 molecules of ATP- making 6 altogether from electron transport chain Released 2 molecules of Pyruvate Doesn’t seem to have released too much energy- because pyruvate still contains a great deal of energy- gradually released during later stages of respiration in krebs cycle- if O2 is available
Link reaction- overview What happens after glycolysis depends on amount of oxygen present- in absence of oxygen anaerobic respiration takes place in the cytoplasm If oxygen is present then cell carries out aerobic respiration- takes place in mitochondria- has a double membrane- internal region of a mitochondria= mitochondrial matrix
Link reaction overview pt2 Pyruvate molecules produced by glycolysis are actively transported from cytoplasm into mitochondrial matrix- at this point the pyruvate molecules take part in the link reaction Link reaction formula Pyruvate + coenzyme A —> acetyl coenzyme A + carbon dioxide (at same time) NAD —> reduced NAD
Link reaction- steps pt1 Pyruvate contains 3 C atoms - pyruvate now reacts with enzyme called coenzyme A- pyruvate molecule splits- A 2 C group is added to coenzyme A, forms acetyl coenzyme A- the remaining one carbon part of the pyruvate leaves as a molecule of CO2 At same time an oxidation reaction takes place- forms reduced NAD At end of a link reaction- got 3 products- one molecule of acetyl coenzyme A, one molecule of CO2, one molecule of reduced NAD
Link- REMEMBER REMEMBER- glycolysis produces 2 pyruvate molecules for each molecule of glucose- so the link reaction takes place twice for each molecule of glucose entering respiration- so produces 2x of each product
Link- pt 3 Also- during link reaction a CO2 molecule is released from the pyruvate- when CO2 is removed from a molecule- called decarboxylation reaction Because we have oxidation alongside decarboxylation during link reaction- called oxidative decarboxylation Link reaction doesn’t require O2
Krebs pt 1 Process liberates energy from C-C, C-H and C-OH bonds-produces ATP, containing the energy held in chemical bonds of original glucose molecule Glucose has 6C atoms - during link reaction- 2 of those atoms have left as 2 CO2 molecules - remaining 4C atoms are now in 2 molecules of remaining acetyl coenzyme A Acetyl coenzyme A now enters next stage of respiration - Krebs cycle- takes place in the mitochondrial matrix Can divide krebs cycle into 2 main stages In 1st stage acetyl coenzyme A reacts with a 4 carbon molecule - the 2 carbon part of acetyl coenzyme A moves onto this molecule, creating a 6C molecule- at same time the coenzyme A and goes back to take part in the link reaction- 2nd stage- a whole series of chemical reactions takes place:
Krebs pt 2 For 6C molecule- First a decarboxylation reaction releases 1 CO2 molecule and a dehydrogenation reaction produces a molecule of reduced NAD- now have 5C molecule Another dehydrogenation reaction takes place- produces 1 molecule of reduced NAD/ another decarboxylation reaction- produces 1 CO2 molecule- 1 molecule of ATP also produced during krebs cycle- produced through substrate level phosphorylation Finally 2 more dehydrogenation reactions- produces 1 molecule of reduced FAD and 1 molecule of reduced NAD- coenzyme FAD is a hydrogen carrier similar to NAD
Krebs pt 3 NOTE- during these reactions we regenerate our starting molecule (the 4 C molecule)- allows krebs cycle to continue again When Kreb’s cycle operates once we make 1 molecule of ATP, 3 molecules of reduced NAD, 1 molecule of reduced FAD, also release 2 CO2 molecules. REMEMBER- 1 glucose molecule forms 2 pyruvate molecules in glycolysis So- per glucose- link reaction produces 2 molecules of acetyl coenzyme A- krebs cycle operates x2 Acetate group from og glucose molecule now completely broken down to CO2 and water. Krebs cycle does not require oxygen
Coming up to oxidative phosphorylation- what's happened so far So far in respiration created several molecules of reduced hydrogen carriers Next stage of respiration the reduced hydrogen carriers used to produce ATP- called oxidative phosphorylation Whole purpose of respiration is to generate ATP, However in reactions we’ve seen so far- only made net yield of 4 ATP molecules- per glucose- we produced a yield of 2 ATP molecules in glycolysis and 2 ATP molecules in 2 turns of Krebs cycle- These ATP molecules are formed by substrate level phosphorylation Also produced 12 molecules of reduced hydrogen carriers: 2 reduced NAD- glycolysis 2 reduced NAD link 6 reduced NAD, 2 reduced FAD- krebs
Oxidative phosphorylation- start When hydrogen carrier is reduced it gains a hydrogen ion and 2 electrons- 2 e’s contain a great deal of energy- used to create ATP in oxidative phosphorylation Inner mitochondrial membrane is folded into cristae- increases SA- inbetween 2 membranes we have inter membrane space On inner mitochondrial membrane- have 2 different sets of proteins- electron transport chain and ATP synthetase
Oxidative phosphorylation- steps pt 1 On inner mitochondrial membrane- have 2 different sets of proteins- electron transport chain and ATP synthetase Reduced NAD transfers high energy electrons to first protein in electron transport chain- first protein is reduced 2 electrons then pass to 2nd protein- 1st protein now oxidised- 2nd reduced KEY NOTE- as electrons move down the electrons transport chain, the electrons lose energy- used by electron transport chain proteins to pump protons (hydrogen ions) from matrix into intermembrane space
Oxidative phosphorylation- steps pt 2 Because inner membrane is impermeable to protons- protons build up in intermembrane space Electrons continue making way down chain in series of oxidation and reduction reactions- at each stage protons are pumped into the intermembrane space
Oxidative phosphorylation- steps- pt 3 At the end the 2 electrons have transferred all of their energy These 2 electrons now combine with oxygen and 2 hydrogen ions (protons) to make a molecule of water equation= 2 e- + ½ O2 + 2H+ —> H2O
Oxidative phosphorylation- steps pt4 Reduced FAD operates in the same way as reduced NAD- However, the electrons from reduced FAD enter the transport chain in the middle rather than the start As we said molecule of glucose generates 10 reduced NAD molecules and 2 reduced FAD molecules- so as a result of the electron transport chain, the concentration of protons is much greater in the intermembrane space than the matrix- proton gradient is now used to generate ATP
Reaches ATP synthetase pt 1 Enzyme ATP synthase is found on inner mitochondrial membrane- contains an ion channel through centre Protons now diffuse down the gradient through the ion channel into the matrix- this movement of protons is used by ATP synthase to generate ATP from ADP and Pi- process is called chemiosmosis - ADP+Pi→ ATP+ H2O At end protons combine with electrons and oxygen to form water- O2 from blood- taken to cells
Reaches ATP synthetase pt 2 Oxygen is described as the final (terminal) electron acceptor-essential as it removes protons and electrons- oxygen reduced by addition of hydrogen atoms and electrons to make water Cyanide is a non competitive inhibitor of the final carrier of the electron transport chain- in its presence electrons and protons can’t be transferred to water- accumulate and so electron transport chain no longer functions- proton gradient not maintained- ATP synthetase can’t produce ATP- cell dies quickly
Oxidative phosphorylation - ATP products In theory oxidative phosphorylation can provide 34 molecules of ATP per glucose molecule- but depends on conditions Substrate level phosphorylation in glycolysis and the krebs cycle provides only 4 ATP molecules per glucose- so oxidative phosphorylation provides a vast majority of ATP in aerobic respiration
Oxidative phosphorylation general products ATP is the major product of oxidative phosphorylation, as it is the premier energy molecule of the cell. Oxidative phosphorylation also produces NAD+, FAD, and water.
Anaerobic respiration no oxygen to remove atoms from reduced NAD and make water- electron transport chain cannot function- no oxidative phosphorylation- no ATP formed- no O2- no reduced NAD can be reoxidised - no NAD regenerated to pick up more hydrogen consequently- link and Krebs can't take place- only glycolysis is possible
Anaerobic respiration- how does glycolysis continue For glycolysis to continue- pyruvate and hydrogen must be constantly removed and NAD must be regenerated Done how? Pyruvate accepts hydrogen from reduced NAD - 2 different anaerobic pathways to remove hydrogen from reduced NAD- both in cytoplasm
2 anaerobic pathways- path1 In animals- muscle cells may not get sufficient O2 during vigorous exercise-when deprived of O2 pyruvate= hydrogen acceptor- converted to lactate- regenerating NAD- lactate can build in muscle cells or be transported to liver- converted back to glucose or stored as glycogen- if O2 later becomes available- lactate can be respired to CO2 and water- releasing energy it contains
2 anaerobic pathways- path2 In various microorganisms eg yeast and in plant cells under certain conditions eg roots in waterlogged soils- pyruvate is converted o CO2 and to ethanal, a hydrogen acceptor- converted by decarboxylase- Ethanal is reduced to ethanol and NAD is regenerated in alcoholic fermentation ( a process in which some sugars (as glucose) are converted into alcohol and carbon dioxide by the action of various yeasts, molds, or bacteria or carbohydrate materials) pathway= irreversible- even if O2 becomes available again ethanol is not broken down- accumulates in cells- can rise to toxic concentrations
Energy budget aerobic respiration p 47- table shos how many H+ atoms and ATP molecules produced from 1 molecule of glucose- gives 2 turns of krebs cycle
How many ATP molecules overall respired 38 overall per glucose molecule- theoretical total- cell is generally not this efficient as- - ATP used to move pyruvate, ADP, reduced NAD and reduced FAD across mitochondrial membrane -Proton gradient may become compromised by proton leakage across the inner mitochondrial membrane, rather than passing through ATP synthetase Molecules may also leak through membranes on average 30-32 ATP molecules tend to be produced
Maths If a mole of glucose is combusted in oxygen- produces 2880 kJ energy required to make ATP= 30.6 kJ/mol-1- if theoretical max is considered- a mole of glucose makes 38 moles of ATP- equivalent to 30.6x38= 1162.8 kJ therefore efficiency of ATP production= energy made through ATP/ energy released in combustion= 1162.8/2880x 100= 40.4%
Anaerobic respiration- brief overview Without ATP synthetase associated with the electron transport system- the only ATP formed is in glycolysis makes 2 molecules of ATP per molecule of glucose by substrate level phosphorylation- small compared to 38 molecules of ATP produced during aerobic-
anaerobic more pt2 in anaerobic pyruvate not transferred to the mitochondria but is converted in the cytoplasm- to ethanol in plants or lactate in mammals-2H released in conversion of glucose to pyruvate reduces NAD - given up again in formation of ethanol in plant cells or lactate in animal cell- many different metabolic pathways have been identified in bacteria or archaea- many organic acids and alcohols produced by their fermentation
anaerobic respiration- maths Efficiency of ATP production= energy made available through ATP/ energy released in combustion x100= 30.6x2/2880x100=2.1% much less efficient
Alternative respiratory pathways Kreb's cycle- sometimes called metabolic hub as the Metabolic pathways of carbohydrates, lipids and proteins can feed into it and in some situations fats and proteins can be used as respiratory substrates - Acetyl Coenzyme A is a most significant molecule as it links the metabolism of the three types of macromolecule
Lipid pathways Triglyceride molecule has 2 parts-3 carbon glycerol part and on right - 3 fatty acids- fatty acids and glycerol= joined by 3 ester bonds- when triglycerides are digested - ester bonds= hydrolysed- release glycerol and fatty acid molecules- 3 carbon glycerol molecule enters glycolysis- converted to pyruvate- pyruvate then enters link reaction and krebs cycle as previously seen
Lipids pt 2 electric boogaloo fatty acid molecules broken down into 2 carbon units eg O H H H || | | | C C- C - C | | | | H H H H Start of a fatty acid chain- 2 units here each unit forms a molecule of acetyl coenzyme A
Lipids pt 3 Acetyl coenzyme A now enters the krebs cycle- fatty acids contain great amount of carbon to hydrogen bonds- forms very large number of acetyl coenzyme A molecules- so triglycerides contains great amount of energy- more than glucose
Protein- aerobic respiration pathway First protein must be hydrolysed to its individual amino acids during digestion- all proteins have an amino group- in first stage- amino group is removed- called deamination- carbon part of amino acid is then processed (entirety that isn't N-H-H)-
Protein- aerobic respiration pathway- pt 2 pathway of this depends on amino acid- some amino acids lead to production of pyruvate- others can be converted to molecules that're part of Krebs cycle- energy value of proteins is approx same as carbs
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