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PHOTOSYNTHESIS Energy and Life. Living things depend on Energy We need energy to play soccer, go fishing and even sleep. On a cellular level, we also need energy for active transport, growth and repair, and reproduction of cells. AUTOTROPHS & HETEROTROPHS.
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PHOTOSYNTHESISEnergy and Life Living things depend on Energy We need energy to play soccer, go fishing and even sleep. On a cellular level, we also need energy for active transport, growth and repair, and reproduction of cells.
AUTOTROPHS & HETEROTROPHS • Autotrophs: organisms that are able to produce their own food • What are some examples? • Heterotrophs: organisms that are Not able to produce their own food • Most autotrophs use PHOTOSYSTHESIS to produce their own food WHAT IS PHOTOSYNTHESIS
PHOTOSYSTHESIS- THE BIG PICTURE inputs outputs inpu
ENERGY IN THE CELL • Energy comes in many forms • Biochemical energy is stored in • CARBS AND LIPIDS Cells metabolize these compounds in a form it can use called ATP ATP is the energy currency of the cell the only energy the cell recognizes 1 MOLECULE OF C6H12O6= 90x the chemical energy of ATP
ATP AND ADP Adenosine---p-----p +energy from glucose+ p ADP Adenosine diphosphate ADP adenosine + ribose sugar+2 phosphate groups Adenosine----p----p------p ATP Adenosine triphosphate Lots of energy (originally from glucose is stored in this bond ATP adenosine+ ribose sugar +3 phosphate groups Energy stored in ATP is released when ATP is converted to ADP and a phosphate group. When the bond is broken energy is released ATP is like a fully charged battery------ ADP like a battery not fully charged
SITE OF PHOTOSYNTHESIS In addition to O2 and H2O photosynthesis also requires a pigment What is the PIGMENT found in chloroplasts that is responsible for trapping light energy? ANSWER chlorophyll There are two types of chlorophyll a (light green) and b (dark green) Plants also contain other light-absorbing pigments, such as xanthophylls, anthocyanins, and carotenoids (these are referred to as accessory pigments) we know that leaves contain these pigments because of the color of the leaves in the fall These pigments do not absorb light well in the green region of the light spectrum which is why most plants are green
SITE OF PHOTOSYNTHESIS sun • When chlorophyll absorbs light, the following occurs • Energy(light)is directly transferred to the electrons in the chlorophyll molecule • When transferred the energy level in the electron is raised (electrons get excited) • Excited electrons have HIGH ENERGY and must have a special chemical carrier called “NADPH” energy chloroplast Co2 + water Sugar and oxygen Electron chauffeur
STRUCTURE OF A CHLOROPLAST • Draw a chloroplast • Thylakoid: bag-like photosynthetic membranes • Grana: stacked thylakoids (grannum) single stack • Stroma: fluid inside the chloroplast but OUTSIDE the thylakoid membrane
PHOTOSYNTHESIS IS A BIOCHEMICAL PATHWAY Photosynthesis is broken down into 2 stages 1. Light dependent reactions 2 Light independent reactions (Calvin Cycle) Light dependent light independent reactions reactions Take place in the thylakoid membranes Take place in the stroma Occurs only in the absence of light Occurs only in light
LIGHT DEPENDENT REACTIONS LIGHT DEPENDENT REACTIONS TAKE PLACE WHERE? Chloroplast in the thykaloid REQUIRE WHAT? Sunlight, and water H2O inputs outputs • H2O • Light energy • ATP • - NADPH • O2
LIGHT DEPENDENT REACTIONS PH II • Photosystem II (PH II) Inside the thykaloid • Discovered AFTER PH I, but in the photosynthetic process • Pigments absorb light • Energy from the light “excite” electrons, increasing their energy • Excited electrons passed through the electron transport chain • The electron is passed from one molecule to another as it decreases an energy level or step, the energy given off from the electron decreasing an energy level is used to form ATP • This is the ETC
LIGHT DEPENDENT REACTIONS- PH II • Photosystem II (PH II) • One major problem with PH II is that the electrons are lost • How does PH II replenish the electrons? • By splitting the H2O molecule • Into H+ H+ ions • These ions will then be pumped back into the thylakoid re-energized by light and be carried by NADPH back to the electron transfer chain A by-product of this reaction is O2 which is then released into the atmosphere by the plants for organisms to breathe
LIGHT DEPENDENT REACTIONS– PH I • Photosystem l (PH I) • High energy electrons move through the PH II to photosystem I • Energy from these electrons transports H+ ions from the stroma to the inner thylakoid Pigments in PH I use energy from light to reenergize the electrons. These re-energized electrons are picked up by NADP+ to form NADPH (the high energy chauffeur) REMEMBER? So what is NADPH’s role in photosynthesis? IT IS THE HIGH ENERGY ELECTRON CARRIER
LIGHT DEPENDENT REACTIONS– PH I • Hydrogen ion movement • As a result of the H+ ions released during the splitting of H2O and electron transport, the inside of the thylakoid membrane becomes (+) changed while the outside is (-) charged • This difference in charges provides the energy to make ATP • ATP synthase:
LIGHT INDEPENDENT REACTIONS • Light independent reactions • Take place where? • Require what? • Also called the Calvin Cycle of “Dark Reactions” inputs outputs -- Products of light dependent rxn’s --
LIGHT INDEPENDENT REACTIONS • Calvin cycle • 6 CO2 molecules enter the cycle from the atmosphere