cell energy ch.9. all living organisms must be able to produce energy, store the energy for future...
TRANSCRIPT
Cell energyCh.9
• All living organisms must be able to produce energy, store the energy for future use and use energy.
Cell processes that require energy
• Active transport• Movement• Cell division• Production and storage of proteins• Cells use energy to maintain
homeostasis
ATP• Molecule in your cells that is a
quick source of energy for any organelle in the cell that needs it.
• This energy is stored in the chemical bonds of
the molecule ATP
• Adenosine Triphosphate is composed of an adenosine molecule with 3 phosphate groups attached.
• AMP - adenosine monophosphate - small amount of energy
• ADP - adenosine diphosphate - more substantial amount of energy
• ATP - When bond is broken, a great amount of energy is released & the cell can use the energy for activities. ADP can then reform ATP by bonding with another phosphate group
Photosynthesis• The process plants use to trap the
sun’s energy and build carbohydrates, called glucose, that store energy.
• Occurs in 2 phases
1. Light-dependent reactions
2. Light-independent reactions
• 6CO2 + 6H2O C6H12O6 + 6O2
Light-dependent reactions
• Convert light energy into chemical energy
• ATP produced in LDR are used to fuel LIR that produce glucose
Chloroplasts
• Cell organelle where photosynthesis occurs
• Within chloroplasts, thylakoid discs contain pigments
• Most common pigment is chlorophyll• Light-dependent reactions take place
in the thylakoid discs
Chlorophyll
• Absorbs most wavelengths of light except green which it reflects, giving leaves a green appearance
Light-dependent reactions
• Requires sunlight• Sunlight strikes molecules in
thylakoid membrane & light energy is transferred to electrons
• These electrons are passed to an electron transport chain
Electron transport chain
• A series of proteins embedded in the thylakoid membrane
• Each protein passes energized electrons along from protein to protein
• At each step the electron loses energy
• ETC allows small amounts of energy to be released at time
• This energy can be used to form ATP• This energy is not wasted, the
electron is transferred to the stroma of the chloroplast
• NADP+ is used & becomes NADPH
Photolysis
• Electrons must be restored to chlorophyll because many leave with NADPH
• To replace the lost electrons, molecules of water are split through a process called photolysis
Light-independent reactions
• Does not require light• Calvin cycle• Series of reactions that use carbon
dioxide & ATP from Light-dependent Reactions to form carbohydrates
• Takes place in the stroma of the chloroplast
• We know that plants use sunlight energy to split water (H2O) into hydrogen and oxygen.
• The hydrogen is added to the carbon dioxide to make CARBOHYDRATES such as glucose.
• The oxygen produced from this splitting of water is released into our atmosphere.
• We summarise this using a chemical equation:6 CO2 + 6 H20 ------------ C6H12O6 + 6 O2
carbon water glucose oxygendioxide
Cellular Respiration
• The process by which mitochondria break down food molecules to produce ATP
3 Stages
1. Glycolysis (anaerobic)
2. Citric acid cycle (aerobic)
3. Electron Transport Chain (aerobic)
• Anaerobic – no oxygen required
• Aerobic – oxygen required
Glycolysis
• A series of chemical reactions in the cytoplasm of a cell that break down glucose into 2 molecules of pyruvic acid
• Uses 2 molecules of ATP to start & only produces 2 molecules of ATP per glucose broken down
• Not very efficient but can occur in the absence of oxygen
• Uses an electron carrier called NAD+
• NAD forms NADH when it is carrying an electron
• Following glycolysis, the pyruvic acid molecules move to the mitochondria
Citric Acid Cycle• Occurs in mitochondria
• One molecule of ATP is produced for every turn of the cycle
• 2 electron carriers are used– NAD+
– FAD
• Electron carriers pass energized electrons along to the electron transport chain in the inner membrane of the mitochondrion.
Electron Transport Chain
• NADH & FADH2 pass energized electrons from protein to protein within the membrane slowly releasing small amounts of the energy contained within the electron
• Some energy is used to form ATP & some is used to pump H+ ions into the center of the mitochondrion.
• Mitochondrion inner membrane becomes positively charged because of the high concentration of positively charged hydrogen ions.
• Exterior of membrane is negatively charged which further attracts hydrogen ions
• Inner membrane of the mitochondrion forms ATP from this electrochemical gradient of H+ ions across the membrane.
• Overall ETC produce 32 ATP molecules
Fermentation
• When your cells are without oxygen for a short period of time, an anaerobic process called fermentation follows glycolysis.
• Two major types– Lactic acid fermentation– Alcoholic fermentation