Photosynthesis and Photosynthesis and Cellular RespirationCellular Respiration
• Almost all plants are photosynthetic autotrophs, as are some bacteria and protists– Autotrophs generate their own organic matter through
photosynthesis– Sunlight energy is transformed to energy stored in the
form of chemical bonds
(a) Mosses, ferns, andflowering plants
(b) Kelp
(c) Euglena (d) Cyanobacteria
THE BASICS OF PHOTOSYNTHESIS
ADP, ATP and ADP, ATP and Cellular Cellular
RespirationRespiration
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ATP
Making energy!
The pointis to make
ATP!
What Is ATP?What Is ATP?
Energy used by all CellsEnergy used by all Cells
Adenosine TriphosphateAdenosine Triphosphate
Organic molecule containing Organic molecule containing high-energy Phosphate bondshigh-energy Phosphate bonds
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Cells spend a lot of time making ATP!
What’s thepoint?
Thepoint is to make
ATP!
What Does ATP Do for You?What Does ATP Do for You?
It supplies YOU withIt supplies YOU with ENERGY!ENERGY!
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The energy needs of life
Organisms are endergonic systems What do we need energy for?
synthesis building biomolecules
reproduction movement active transport temperature regulation
ATP for energyATP powers cellular work- made in photosynthesis
amd cellular respiration A cell does three main kinds of work:
Mechanical work, beating of cilia, contraction of muscle cells, and movement of chromosomes(produces heat)
Transport work, pumping substances across membranes against the direction of spontaneous movement
Chemical work, driving endergonic reactions such as the synthesis of polymers from monomers
Chemical Structure of ATPChemical Structure of ATP
3 Phosphates
Ribose Sugar
Adenine Base
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How Do We Get Energy From How Do We Get Energy From ATP?ATP?
By breaking By breaking the high- the high- energy energy bonds bonds between the between the last two last two phosphates phosphates in ATPin ATP
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What is the Process Called?What is the Process Called?HYDROLYSIS (Adding HHYDROLYSIS (Adding H22O)O)
H2O
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How Does That Happen?How Does That Happen?
An An Enzyme!Enzyme!
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ATP
high energy bondsHow efficient!Build once,
use many ways
Adenosine Triphosphate modified nucleotide
AMP + Pi ADP
ADP + Pi ATP
How does ATP transfer energy?
PO–
O–
O
–O PO–
O–
O
–O PO–
O–
O
–O7.3
energy+PO–
O–
O
–O
ATP ADP
BONDS ALWAYS CONTAIN ENERGY!!!
WHEN YOU BREAK A BOND ENERGY IS RELEASED!!
FORMING A BOND TAKES ENERGY!!
ADPATP
How Does ATP Work? So what? Energy is stored in these bonds. So? The breaking of the chemical bond releases the
energy
ATP + H2O→ ADP + P + ENERGY ATP is made in photosynthesis and respiration!!!
ATP (adenosine triphosphate) is a a molecule that carries energy that cells can use.
How Does ATP Work? The bonds between phosphate groups can be
broken by hydrolysis which produces energy!!!
ATP has 3 phosphate groups The bond to the third bond is easily broken. When the third bond is broken, energy is released. Becomes ADP – no energy!!
ATP
Living economy Fueling the body’s economy
eat high energy organic molecules food = carbohydrates, lipids, proteins, nucleic acids
break them down catabolism = digest
capture released energy in a form the cell can use Need an energy currency
a way to pass energy around need a short term energy
storage molecule
Whoa! Hot stuff!
How is ATP Re-Made?How is ATP Re-Made?
The reverse of the previous process The reverse of the previous process occurs.occurs.
Another Enzyme Another Enzyme is used!is used!
ENERGY IS ENERGY IS NEEDEDNEEDED
ATP ATP SynthetaseSynthetaseCopyright Cmassengale
The ADP-ATP CycleThe ADP-ATP Cycle
ATP-ATP-asease
ATP ATP SynthetaSynthetasese
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ATP / ADP cycleCan’t store ATP too reactive transfers Pi too
easily only short term
energy storage carbohydrates &
fats are long term energy storage
ATP
ADP P+
7.3 kcal/mole
A working muscle recycles over 10 million ATPs per second
Whoa!Pass me
the glucose(and O2)!
respiration
When is ATP Made in the When is ATP Made in the Body?Body?
During a During a Process called Process called Cellular Cellular RespirationRespiration that takes that takes place in both place in both Plants & Plants & AnimalsAnimals
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High Energy Electrons and Molecules
Once the sun’s energy has been trapped and excited an electron, what happens to it?Electron Carrier: a molecule that picks up the electron and uses this energy to break apart bonds.Examples of electron carriers: NADP and ATPNADP captures two electrons of H and becomes NADPH.ADP becomes ATP!!!
Flashback January 20Flashback January 20
1. Write the equation for photosynthesis.1. Write the equation for photosynthesis. 2. Why are plants leaves green?2. Why are plants leaves green?
PhotosynthesisPhotosynthesis uses the energy of the sunlight to convert water and carbon dioxide(reactants) into high-energy sugars and oxygen(products)
Photosynthesis occurs in the parts of the chlorplasts.There are three parts involved.
Light Energy Harvested by Plants & Other Photosynthetic Autotrophs
6 CO2 + 6 H2O + light energy → C6H12O6 + 6 O2
THE SUN: WHY IS IT THE SUN: WHY IS IT IMPORTANT?IMPORTANT?
Source of light energySource of light energySource of heat energySource of heat energyGravitational attractionGravitational attraction
Source of radiationSource of radiationDay and nightDay and night
Source of all energy(electricity)Source of all energy(electricity)
Source of food for all organisms!!!!Source of food for all organisms!!!!
SUN’S SPECTRUMSUN’S SPECTRUM
Pigment and Light
Energy from the Sun travels to the Earth as light. We see sunlight as “white light” which is really different wavelengths(ROYGBIV).Plant gather the Sun’s energy with light-absorbing molecules called PIGMENTS.Pigments: photosynthetic organisms capture energy using pigments.Chlorophyll: pigments plants use to absorb light energy.Plant have different pigments.
WHYWHY ARE ARE PLA PLANTS NTS GREGREEN?EN?
Plant Cells have Green Chloroplasts
The thylakoid membrane of the chloroplast is impregnated with photosynthetic pigments (i.e., chlorophylls, carotenoids).
Chloroplasts absorb light energy and convert it to chemical energy. They absorb the reds and blue. Reflects the green.
That is why they look green.
LightReflected
light
Absorbedlight
Transmittedlight
Chloroplast
THE COLOR OF LIGHT SEEN IS THE COLOR NOT ABSORBED
Different pigments absorb light differently
Different Pigments– Chlorophyll a – green pigments in plants and
bacteria– Chlorophyll b in green algae– Carotenoids – orange, red, yellow when
chloroplast die in plants. Chlorophyll breaks down first in the fall so we see these colors.
– Xanthophyll – yellow pigments in lemons, corn, diatoms(protists)
Figure 7.7
Why are Chloroplast Important?
The chloroplasts absorb the Sun’s energy and use this energy to excite electrons which powers photosynthesis. To break apart water and carbon Dioxide, you must have energy!!!!
Monday January 23Monday January 23
Why are chloroplasts important to plants?Why are chloroplasts important to plants?
If plants have pigments other than green in If plants have pigments other than green in their chloroplasts, why are plants green?their chloroplasts, why are plants green?
Flashback Jan. 24Flashback Jan. 24
Sketch a chloroplast and label the parts.Sketch a chloroplast and label the parts.
Thylakoids:Thylakoids: flat compartments in the chloroplast that flat compartments in the chloroplast that contain chlorophyll. LIGHT DEPEDENT REACTION contain chlorophyll. LIGHT DEPEDENT REACTION occurs here.occurs here.GranaGrana: are stacks of thylakoids.: are stacks of thylakoids.StromaStroma: fluid that is all around the grana inside : fluid that is all around the grana inside the chorplast. LIGHT INDEPENDENT REACTION the chorplast. LIGHT INDEPENDENT REACTION occurs here.occurs here.
Parts of the Chloroplasts
Occurs in the membrane of the thylakoids
• Photosynthesis is the process by which autotrophic organisms use light energy to make sugar and oxygen gas from carbon dioxide and water
AN OVERVIEW OF PHOTOSYNTHESIS
Carbondioxide
Water Glucose Oxygengas
PHOTOSYNTHESIS
• The Calvin cycle makes sugar from carbon dioxide– ATP generated by the light
reactions provides the energy for sugar synthesis
– The NADPH produced by the light reactions provides the electrons for the reduction of carbon dioxide to glucose
LightChloroplast
Lightreactions
Calvincycle
NADP
ADP+ P
• The light reactions convert solar energy to chemical energy– Produce ATP & NADPH
AN OVERVIEW OF PHOTOSYNTHESIS
Photosystems: cluster of chlorophyll and proteins absorb the sun’s energy and generate the high energy electrons that are passed to the electron carrier molecules.
Their energy ends up in ATP and NADPH
Electron transport chains and Electron transport chains and photosystemsphotosystems
PhotosynthesisPhotosynthesis Step 1 – Light Dependent Reaction The light reactions convert solar energy to
chemical energy. Takes place in thylakoids. Photosystem II and electron transport 1. chlorophyll absorbs the sun’s energy. 2. Energy as electrons is moved along the
membrane(electron transport chain) 3. Water is split into H and O. O released as waste
through stoma. 4. H is pumped over and over again in the
membrane until they build up.
The O2 liberated by photosynthesis is made from the oxygen in water (H+ and e-)
Plants produce OPlants produce O22 gas by splitting H gas by splitting H22OO
Electron Transport Chain
When the electrons are excited from the light reaction, they are passed along the membrane through the protein pumps. They passed from Photosystem II to photosystem I.
Flashback Jan 25Flashback Jan 25
Get out your notes and the “Colors of Get out your notes and the “Colors of Autumn” and study.Autumn” and study.
You will have a QUIZ shortly!!You will have a QUIZ shortly!! Know which pigments cause which colors!Know which pigments cause which colors!
PhotosynthesisPhotosynthesisPhotosystem IPhotosystem I
1.1.1. Electrons from photosytem II are moved 1. Electrons from photosytem II are moved along the membrane to photosystem I.along the membrane to photosystem I.
2.2.2. Chlorophyll continues to absorb sunlight 2. Chlorophyll continues to absorb sunlight and free electrons.and free electrons.
3.3.3. Electrons are added to NADPH which is 3. Electrons are added to NADPH which is the energy carrier for the rest of the energy carrier for the rest of photosynthesis.photosynthesis.
4.4.4. The electrons are pumped through a 4. The electrons are pumped through a channel as part of an enzyme ATP channel as part of an enzyme ATP synthase to make ATP.synthase to make ATP.
Summary of Light-dependent Reaction
* Energy is captured from sunlight and transferred to electrons(electron transport chain).
Water molecule pulled apart to provide H ions.
The ions are used to make ATP and NADPH.
Need: sunlight and water Produce: energy carrying molecules
and oxygen(waste).
The production of ATP
Thylakoidcompartment(high H+)
Thylakoidmembrane
Stroma(low H+)
Light
Antennamolecul
es
Light
ELECTRON TRANSPORT
CHAIN
PHOTOSYSTEM
II
PHOTOSYSTE
M I
ATP
SYNTHASE
Summary—Light Dependent Reactions
a. Overall inputlight energy, H2O.
b. Overall output ATP, NADPH, O2.
Flashback January 26Flashback January 26
WHY is sunlight so important to a plant’s WHY is sunlight so important to a plant’s ability to make sugar?ability to make sugar?
There are organisms that can make their There are organisms that can make their own sugars miles deep inside of the ocean. own sugars miles deep inside of the ocean. How do you think these organisms do that How do you think these organisms do that without ANY sunlight? without ANY sunlight?
You may use your phone to look it up if you You may use your phone to look it up if you have it with you!have it with you!
• Step 2 – Light Independent Reaction – CALVIN CYCLE Occurs in the stroma.
• The Calvin cycle makes sugar from carbon dioxide
1.ATP generated by the light reactions provides the energy for sugar synthesis
2.The NADPH produced by the light reactions provides the electrons for the reduction of carbon dioxide to glucose. Carbon Dioxide is used to make a 6 carbon sugar called glucose.
– END GOAL – to break carbon dioxide down and combine into glucose!!! Need energy to do this!! That is why ATP and NADPH was made!!
AN OVERVIEW OF PHOTOSYNTHESIS
Light Independent Reaction Overview1. 6 Carbon dioxide added:Carbon Dioxide enters the plant from the atmosphere. Each CO2 bonds with a 5-carbon sugar.2. 12 Three-carbon molecules formed: ATP and NADPHuse enzymes in the stroma to split the six carbon into 3 carbon sugars. 3. 2 Three-carbon sugars removed to make a glucose: The other 3 carbon molecules (10) stay in cycle. When 2 leave, they form glucose.4. Three-carbon molecules recycled: Energy from ATP Change 3carbon molecules back into 5 carbon to start thecycle over again. *Energy provided by Light dependent reaction.The plants uses the carbohydrates to meet its energy needs to make all of the macromolecules that it needs(proteins, lipids,
carbs).
Overview Calvin Cycle
In put: ATP, NADPH, and Carbon dioxideOutput: GLUCOSE!!
The end goal – Make glucose from the SUN!!
Harvesting Chemical EnergyHarvesting Chemical Energy
Energy enters food chains (via autotrophs) Energy enters food chains (via autotrophs) we can look at how organisms use that we can look at how organisms use that energy to fuel their bodies.energy to fuel their bodies.
Plants and animals both use products of Plants and animals both use products of photosynthesis (glucose) for metabolic fuelphotosynthesis (glucose) for metabolic fuel
HeterotrophsHeterotrophs: must take in energy from : must take in energy from outside sources, cannot make their own outside sources, cannot make their own e.g. animalse.g. animals
. Photosystem II breaks down . Photosystem II breaks down water and produces what as a water and produces what as a
waste product?waste product?
A. Carbon DioxideA. Carbon Dioxide B. OxygenB. Oxygen C. WaterC. Water D. SugarD. Sugar
Which of the following is an energy carrier produced in
Photosystem I?
a. ATP c. ADP b. NAD d. All of the above
Where in plant cells are the energy-absorbing molecules for photosynthesis located?
A. stromaA. stroma B. ThylakoidsB. Thylakoids C. ATP synthaseC. ATP synthase D. MitochondriaD. Mitochondria
What happens to sugars that are made during photosynthesis?
A. They move directly into an electron A. They move directly into an electron transport chain.transport chain.
B. They go back into the Calvin CycleB. They go back into the Calvin Cycle C. They can be used for cellular C. They can be used for cellular
respirationrespiration D. They make ATP by bonding togetherD. They make ATP by bonding together
How does the Calvin Cycle differ from the light-
dependent reactions?
A. It takes place in the stromaA. It takes place in the stroma B. It takes place in the chloroplastB. It takes place in the chloroplast C. It requires lightC. It requires light D. It takes place in the thylakoidD. It takes place in the thylakoid
If Carbon-dioxide is removed from a plant’s environment, what would you
expect to happen to the plant’s production of high energy sugars?
A. More sugars producedA. More sugars produced B. Fewer sugars producedB. Fewer sugars produced C. Same number of sugars without the C. Same number of sugars without the
Carbon DioxideCarbon Dioxide D. Caron dioxide does not affect the D. Caron dioxide does not affect the
production of sugarproduction of sugar
Which pigment gives apples their ripe, rich color?
A. TanninsA. Tannins B. XanthocyaninsB. Xanthocyanins C. CarotenoidsC. Carotenoids D. Chlorophyll bD. Chlorophyll b
RELEASES CHEMICAL ENERGY RELEASES CHEMICAL ENERGY FROM SUGARS AND OTHER FROM SUGARS AND OTHER CARBON-BASED MOLECULES TO CARBON-BASED MOLECULES TO MAKE ATP WHEN OXYGEN IS MAKE ATP WHEN OXYGEN IS PRESENT!!!!PRESENT!!!!NO OXYGEN – FERMENTATION!!!!NO OXYGEN – FERMENTATION!!!!
Cellular RespirationCellular Respiration
The Purpose of Cellular Respiration
It is to make and break bonds to generate ATP and electrons.You end up with ATP, H ions and electrons.The electrons are sent to the Electron Transport Chain where they help to make ATP through ATP synthase.****Hydrogen ions are bonded with oxygen to make water which is used in photosynthesis.
HOW DO WE MAKE ATP?HOW DO WE MAKE ATP?
Just like in photosynthesis. ATP is made Just like in photosynthesis. ATP is made by pumping H across ATP synthase to by pumping H across ATP synthase to attach a P onto ADP. This is the goal of attach a P onto ADP. This is the goal of cellular respiration.cellular respiration.
Relationship between Photosynthesis and Cellular Respiration
The products on one are used for the other to produce ATP from the Sun!Creates the Carbon- Oxygen Cycle!!!
Carbon Oxygen Cycle
NADP and NAD
Photosynthesis use the electron carrier - NADP(nicotinmide adenine dinucleotide phosophate)Cellular respiration uses - NAD( nicotinmide adenine dinucleotide)
Cellular Respiration OverviewCellular Respiration Overview
Transformation of chemical energy in food Transformation of chemical energy in food into chemical energy cells can use: ATPinto chemical energy cells can use: ATP
These reactions proceed the same way in These reactions proceed the same way in plants and animals. Process is called plants and animals. Process is called cellular respirationcellular respiration
Overall Reaction:Overall Reaction: CC66HH1212OO66 + 6O + 6O22 → → 6CO 6CO22 + 6H + 6H22OO
Cellular Respiration Cellular Respiration
Glycolysis – Occurs before Cell. Resp.Glycolysis – Occurs before Cell. Resp. Krebs Cycle (Citric Acid Cycle)Krebs Cycle (Citric Acid Cycle) Electron Transport Chain (ETC)Electron Transport Chain (ETC)
Glucose
Glycolysis Krebs cycle
Electrontransport
Fermentation (without oxygen)
Alcohol or lactic acid
Overall ReactionOverall ReactionCC66HH1212OO66 + 6O + 6O22 → 6CO→ 6CO22 + 6H + 6H22O + 38 ATPO + 38 ATP
Overall this is a three stage processOverall this is a three stage process1.1. Glycolysis: before cellular respirationGlycolysis: before cellular respiration
• Occurs in the cytoplasmOccurs in the cytoplasm• Glucose is broken downGlucose is broken down
2.2. Krebs CycleKrebs Cycle• Breaks down pyruvate into CO2Breaks down pyruvate into CO2• Occurs in mitochondrial matrixOccurs in mitochondrial matrix
3.3. EElectron lectron TTransport ransport CChainhain• ATP is synthesized - Occurs in mito membraneATP is synthesized - Occurs in mito membrane
FlowchartFlowchartSection 9-2
Glucose(C6H1206)
+Oxygen
(02)
GlycolysisKrebsCycle
ElectronTransport
Chain
Carbon Dioxide
(CO2)+
Water(H2O)
+ATP
Cellular Respiration
Cellular Respiration OverviewCellular Respiration Overview
Breakdown of glucose begins in the Breakdown of glucose begins in the cytoplasm: the liquid matrix inside the cellcytoplasm: the liquid matrix inside the cell
After glycolysis, life diverges into two After glycolysis, life diverges into two forms and two pathwaysforms and two pathways Anaerobic cellular respiration (aka Anaerobic cellular respiration (aka
fermentation) No oxygen fermentation) No oxygen Aerobic cellular respiration I Oxygen needed!!Aerobic cellular respiration I Oxygen needed!!
ANAEROBIC VS. AEROBICANAEROBIC VS. AEROBIC
AnaerobicAnaerobic – no oxygen present – no oxygen present fermentation or lactic acid can be formed. fermentation or lactic acid can be formed. No oxygen then no cellular respiration.No oxygen then no cellular respiration.AerobicAerobic –oxygen present. If oxygen is –oxygen present. If oxygen is present , then cellular respiration can present , then cellular respiration can occur.occur.
Aerobic vs. AnaerobicAerobic vs. Anaerobic
Anaerobic Anaerobic DOES DOES NOTNOT require require oxygen-oxygen-
fermentationfermentation SimpleSimple fast fast produces smaller produces smaller
amounts of energy amounts of energy (ATP)(ATP)
Aerobic requires Aerobic requires oxygen – cellular oxygen – cellular respirationrespiration Yields Yields largelarge
amounts of amounts of energyenergy
What is this What is this energy molecule?energy molecule?
ATP, ATP, ATPATP, ATP, ATP
GlycolysisGlycolysis Glyco = glucoseGlyco = glucose Lysis = break downLysis = break down LOCATION: Occurs in the cytoplasmLOCATION: Occurs in the cytoplasm This stage occurs in BOTH aerobic and This stage occurs in BOTH aerobic and
anaerobic respirationanaerobic respiration Glucose breaks down into 2 pyruvate (2 Glucose breaks down into 2 pyruvate (2
ATP are also made) ATP are also made) Glucose is a 6-carbon sugar Glucose is a 6-carbon sugar Pyruvate is a 3-carbon molecule (there are two Pyruvate is a 3-carbon molecule (there are two
of them)of them)
Steps of Glycolysis
1.Two ATP molecules are used to energize a glucose molecule. 2. Glucose is split into 2 3 carbon molecules. Enzymes rearrange the molecules.3. Electrons are transferred to NADP. The carbon molecules are converted to pyurate which enters cellular respiration.
GlycolysisGlycolysis
End Product: Breaks glucose into 2 –3 End Product: Breaks glucose into 2 –3 carbon molecules called PYRUVIC ACID.carbon molecules called PYRUVIC ACID.
2 atoms of ATP are needed to breakdown 2 atoms of ATP are needed to breakdown this molecule.this molecule.
High energy electrons are passed to NAD High energy electrons are passed to NAD to form NADH(sent to ETC)to form NADH(sent to ETC)
4 ATPS are synthesized and 2 are used 4 ATPS are synthesized and 2 are used for a net gain of 2 ATPs.for a net gain of 2 ATPs.
Locatiom: CytoplasmLocatiom: Cytoplasm NO ONO O22 required required Energy YieldEnergy Yield net gain of net gain of 2 ATP 2 ATP at the at the
expense of 2 ATPexpense of 2 ATP 6-C glucose 6-C glucose TWO 3-C pyruvates TWO 3-C pyruvates Free eFree e-- and H and H++ combine with combine with organic ion organic ion
carrierscarriers called NAD called NAD++ NADH + H NADH + H++
(nicotinamide dinucleotide)Used in ETC. (nicotinamide dinucleotide)Used in ETC. Hydrogen attached to water.Hydrogen attached to water.
Glycolysis
Glucose
To the electron transport chain
Figure 9–Figure 9–3 Glycolysis3 Glycolysis
Glycolysis:
Step 1
2 Pyruvic acid
Glycolysis Reactants and ProductsGlycolysis Reactants and Products
ReactantsReactants 1 glucose 1 glucose Enzymes are neededEnzymes are needed 2 ATP are needed to start2 ATP are needed to start
ProductsProducts 2 Pyruvates (go to next 2 Pyruvates (go to next
step)step) 4 ATP (2 are gained)4 ATP (2 are gained) 2 NADH (go to ETC)2 NADH (go to ETC)
Really 10 steps with 10 different enzymes involved.
Main Goals of Krebs CycleMain Goals of Krebs Cycle
Transfer high energy electrons(NADPH Transfer high energy electrons(NADPH and FADH) to molecules that can carry and FADH) to molecules that can carry them to the electron transport chain.them to the electron transport chain.
* Form some ATP molecules.* Form some ATP molecules.
Citric Acid Production
Figure 9–6 Figure 9–6 The The Krebs CycleKrebs Cycle
Section 9-2
Mitochondrion
Krebs Cycle- MATRIXKrebs Cycle- MATRIX
Pyruvic acid(3carbon) enters Pyruvic acid(3carbon) enters mitochondria. In the innermost layer of mitochondria. In the innermost layer of mitochondria or the MATRIX pyruvic acid mitochondria or the MATRIX pyruvic acid are broken down into carbon dioxide and are broken down into carbon dioxide and acteyl CoA molecules.acteyl CoA molecules.
Acetyl- CoA combines with 4 carbon Acetyl- CoA combines with 4 carbon compounds forming a 6 carbon molecule compounds forming a 6 carbon molecule citric acid. Energy is released by breaking citric acid. Energy is released by breaking and reforming these bonds.and reforming these bonds.
Kreb CycleKreb Cycle
1. Pyruvate broken down1. Pyruvate broken down 2. Coenzyme A bonds to 2 carbon molecule2. Coenzyme A bonds to 2 carbon molecule 3. Citric Acid formed: 2 carbon bonded to 4 3. Citric Acid formed: 2 carbon bonded to 4
carbon. Coenzyme goes back to step 2.carbon. Coenzyme goes back to step 2. 4. Citric Acid brokendown: into 5 carbon sugar 4. Citric Acid brokendown: into 5 carbon sugar
carbon dioxide and NADHcarbon dioxide and NADH 5. 5 carbon sugar broken down: Into 4 carbon 5. 5 carbon sugar broken down: Into 4 carbon
sugar, NADH, ATP and Carbon dioxide.sugar, NADH, ATP and Carbon dioxide. 6. 4 carbon rearranged by enzymes. Molecules 6. 4 carbon rearranged by enzymes. Molecules
of NADH, FADH(electron carrier).of NADH, FADH(electron carrier).
Second Step: Citric Acid Cycle (Krebs Second Step: Citric Acid Cycle (Krebs Cycle)Cycle)
WhereWhere Mitochondrial matrix Mitochondrial matrix Energy YieldEnergy Yield 2 ATP and more e 2 ATP and more e--
Acetyl-CoA (2-C) combines with 4-C to form Acetyl-CoA (2-C) combines with 4-C to form 6-C CITRIC ACID6-C CITRIC ACID
Citric Acid (6-C) changed to 5-C then to a 4-C Citric Acid (6-C) changed to 5-C then to a 4-C Gives off a COGives off a CO22 molecule molecule NAD+ and FAD pick up the released eNAD+ and FAD pick up the released e--
FAD becomes FADHFAD becomes FADH22 NADNAD++ becomes NADH + H becomes NADH + H++
Cycle ALWAYS reforming a 4-C molecule Cycle ALWAYS reforming a 4-C molecule
Krebs Cycle Reactants and ProductsKrebs Cycle Reactants and Products
ReactantsReactants 2 Acetyl CoA2 Acetyl CoA
Remember when you Remember when you form a bond energy is form a bond energy is released!! This is the key!!released!! This is the key!!
ProductsProducts 2 ATP2 ATP 6 NADH (go to ETC)6 NADH (go to ETC) 2 FADH2 FADH22 (go to ETC) (go to ETC)
4 CO4 CO22 (given off as waste) (given off as waste)
Review of Mitochondria Review of Mitochondria StructureStructure
SmoothSmooth outer outer MembraneMembrane
FoldedFolded inner inner membranemembrane
Folds called Folds called CristaeCristae
Space inside Space inside cristae called the cristae called the MatrixMatrix
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Products of Kreb CycleProducts of Kreb Cycle
High energy carriers – NADH and FADH – High energy carriers – NADH and FADH – This is the main goal!!!This is the main goal!!!
Carbon DioxideCarbon Dioxide 2 ATP molecules2 ATP molecules 4 carbon molecules to start again4 carbon molecules to start again HYDROGEN IONS ARE SENT DOWN HYDROGEN IONS ARE SENT DOWN
THE ELECTRON TRANSPORT CHAIN to THE ELECTRON TRANSPORT CHAIN to make ATP.make ATP.
Diagram of the ProcessDiagram of the Process
Occurs in Cytoplasm
Occurs in Matrix
Occurs across Cristae
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Krebs CycleKrebs Cycle
Electron TransportElectron Transport
ATP synthesisATP synthesis
Electron Transport ChainElectron Transport Chain
WhereWhere inner membrane of mitochondria inner membrane of mitochondria called cristea.called cristea.
Energy YieldEnergy Yield Total of 32 ATP Total of 32 ATP OO22 combines with TWO H combines with TWO H++ to form H to form H22OO
Exhale - COExhale - CO22, H, H22O comes from cellular O comes from cellular
respirationrespiration
Electron Transport - Step 3Electron Transport - Step 3
1. Proteins inside the membrane of the mito. 1. Proteins inside the membrane of the mito. Remove electrons from NADPh and FADH.Remove electrons from NADPh and FADH.
2.2. Electrons(hydrogen) are transported down Electrons(hydrogen) are transported down the chain of the membrane to be pumped the chain of the membrane to be pumped across.across.
3.3. ATP synthase(enzyme) puts a P on ADP to ATP synthase(enzyme) puts a P on ADP to make ATP(END GOAL!!).make ATP(END GOAL!!).
4.4. Oxygen enters the cycle to pick up electrons Oxygen enters the cycle to pick up electrons and hydrogen ions to make water that and hydrogen ions to make water that leaves the cycle.leaves the cycle.
Electron Transport ChainElectron Transport Chain
Electron carriers loaded with electrons and Electron carriers loaded with electrons and protons from the Kreb’s cycle move to this protons from the Kreb’s cycle move to this chain-like a series of steps (staircase).chain-like a series of steps (staircase).
As electrons drop down stairs, energy As electrons drop down stairs, energy released to released to form a total of 32 ATP – form a total of 32 ATP – Final Goal!!Final Goal!!
Oxygen waits at bottom of staircase, picks Oxygen waits at bottom of staircase, picks up electrons and protons and in doing so up electrons and protons and in doing so becomes water becomes water
Electron Transport ChainElectron Transport Chain
Occurs in the cristae of the mitochondriaOccurs in the cristae of the mitochondria
Review of Mitochondria Review of Mitochondria StructureStructure
SmoothSmooth outer outer MembraneMembrane
FoldedFolded inner inner membranemembrane
Folds called Folds called CristaeCristae
Space inside Space inside cristae called the cristae called the MatrixMatrix
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Diagram of the ProcessDiagram of the Process
Occurs in Cytoplasm
Occurs in Matrix
Occurs across Cristae
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Review of Mitochondria Review of Mitochondria StructureStructure
SmoothSmooth outer outer MembraneMembrane
FoldedFolded inner inner membranemembrane
Folds called Folds called CristaeCristae
Space inside Space inside cristae called the cristae called the MatrixMatrix
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Electron Transport Electron Transport ChainChainSection 9-2
Electron TransportHydrogen Ion Movement
ATP Production
ATP synthase
Channel
Inner Membrane
Matrix
Intermembrane Space
Mitochondrion
PhotosynthesisWhat happens to the glucose formed in photosynthesis?
PHOTOSYNTHESIS
GLUCOSE STARCH
CELLULOSE
LIPIDS
PROTEINS
CARBON DIOXIDE AND
WATER
Required to make plant cell walls. It is made of 100s of glucose molecules bonded together.
Glucose is chemically converted to fatty acids and glycerol to make lipids, which are needed to make plant cell membranes and seed storage oils.
Is used by roots and leaves to store excess glucose in an osmotically inactive form. It is made of 100s of glucose molecules.
Using nitrate ions absorbed by plant roots, glucose is converted first to amino acids then to protein.
The carbon dioxide can be used again in photosynthesis or may diffuse out of the leaf via the stomata
respiration
ATP
Eukaryote vs Prokaryote Glycolytic pathways
Anaerobic Cellular Anaerobic Cellular RespirationRespiration
Some organisms thrive in environments with little or no Some organisms thrive in environments with little or no oxygenoxygen Marshes, bogs, gut of animals, sewage treatment pondsMarshes, bogs, gut of animals, sewage treatment ponds
No oxygen used= ‘an’aerobicNo oxygen used= ‘an’aerobic Results in no more ATPResults in no more ATP, final steps in these pathways , final steps in these pathways
serve ONLY to regenerate NAD+ so it can return to pick serve ONLY to regenerate NAD+ so it can return to pick up more electrons and hydrogens in glycolysis.up more electrons and hydrogens in glycolysis.
End products such as ethanol and COEnd products such as ethanol and CO22 (single cell fungi (single cell fungi
(yeast) in beer/bread) or lactic acid (muscle cells)(yeast) in beer/bread) or lactic acid (muscle cells)
Two Types of FermentationTwo Types of Fermentation
Alcoholic Fermentation Alcoholic Fermentation Pyruvate converted to Pyruvate converted to
ethyl alcohol and COethyl alcohol and CO22
Carried out by yeast and Carried out by yeast and some bacteriasome bacteria
Used in producing alcohol Used in producing alcohol (both consumable and for (both consumable and for ethanol), and for bakingethanol), and for baking
Lactic Acid FermentationLactic Acid Fermentation Pyruvate converted to Pyruvate converted to
lactic acidlactic acid Carried out by muscles Carried out by muscles
when working hard when working hard (muscles need ATP but (muscles need ATP but can’t get Ocan’t get O22 ) )
Causes muscle soreness Causes muscle soreness and crampsand cramps
Alcohol FermentationAlcohol Fermentation
Pyruvate
C6H12O6 → 2 C2H5OH + 2CO2 + 2 ATP Word Equation
Sugar (glucose) → Alcohol (ethanol) + Carbon Dioxide + Energy (ATP)
Alcoholic FermentationAlcoholic Fermentation
CC66HH1212OO6 6 2 C2 C22HH55OH + 2 COOH + 2 CO22
(Ethyl Alcohol or Ethanol)
As a result of Alcoholic Fermentation,
Glucose is converted into 2 molecules of Ethyl Alcohol and 2
Molecules of Carbon Dioxide.
Importance of FermentationImportance of Fermentation Alcohol Industry - almost every society Alcohol Industry - almost every society
has a fermented beverage.has a fermented beverage. Baking Industry - many breads use yeast Baking Industry - many breads use yeast
to provide bubbles to raise the dough.to provide bubbles to raise the dough.
Alcoholic FermentationAlcoholic Fermentation
Bacteria and fungi (yeast)Bacteria and fungi (yeast)
Ethyl alcohol and carbon dioxide Ethyl alcohol and carbon dioxide are the end productsare the end products
Process used to form beer, wine, Process used to form beer, wine, and other alcoholic beveragesand other alcoholic beverages
Also used to raise dough, breadAlso used to raise dough, bread
Lactic Acid FermentationLactic Acid Fermentation
Uses only Glycolysis.Uses only Glycolysis. Does Does NOTNOT require O require O22
Produces ATP when OProduces ATP when O22 is not is not available.available.
Lactic Acid FermentationLactic Acid Fermentation
Carried out by human muscle cells under Carried out by human muscle cells under oxygen debtoxygen debt..
Lactic Acid is a toxin and causes fatigue, Lactic Acid is a toxin and causes fatigue, soreness and stiffness in muscles.soreness and stiffness in muscles.
Lactic Acid FormationLactic Acid Formation
pyruvate + NADH----- lactic acid + NADpyruvate + NADH----- lactic acid + NAD++
Lactic Acid FermentationLactic Acid Fermentation
Glucose (6 carbons)
Pyruvic Acid (3C)
Pyruvic Acid (3C)2 ATP’s supply the activation
energy
4 ATP’s are produced
4 ATP Yield = 2 ATP Net Gain
2 NAD+ + 2 e- 2 NADH 2 NAD+ + 2 e-
Lactic Acid (3C)
Lactic Acid (3C)
Glycolysis
Fermentation - SummaryFermentation - Summary
Releases 2 ATP from the breakdown Releases 2 ATP from the breakdown of a glucose moleculeof a glucose molecule
Provides ATP to a cell even when OProvides ATP to a cell even when O2 2 is is
absent.absent.
Energy TallyEnergy Tally
36 ATP for aerobic vs. 2 ATP for anaerobic36 ATP for aerobic vs. 2 ATP for anaerobic
Glycolysis Glycolysis 2 ATP2 ATP
Kreb’s Kreb’s 2 ATP2 ATP
Electron TransportElectron Transport 32 ATP32 ATP 36 ATP36 ATP
Anaerobic organisms can’t be too energetic Anaerobic organisms can’t be too energetic but are important for global recycling of carbonbut are important for global recycling of carbon