Photosynthesis

Photosynthesis

Autotrophs • Auto = self • Troph = eating • Organisms that can produce their own food (energy) from inorganic materials (sunlight)

Heterotroph • Hetero = other • Troph = eating • Organisms that cannot make its own food. Requires organic compounds (other organisms) for its principle source of food.

Chemical Energy and ATP • All cells use chemical energy carried by ATP-Adenosine triphosphate. • Cells use ATP for functions such as building molecules and moving material through active transport.

ATP • The energy carried by ATP is released when a phosphate group is removed from the molecule. • ATP become ADP (Adenosine diphosphate) • ADP can become ATP again through a series of chemical reactions.

ATP • ATP is produced during the breakdown of carbon-based molecules. • Different foods provide different amounts of ATP. • Carbohydrates (glucose) can make ~ 36 molecules of ATP • Lipids can make ~ 146 molecules

Special Creatures • Some organisms do not need sunlight and photosynthesis as a source of energy. • Some organisms live near cracks in the ocean and never see sunlight • Chemosynthesis • Process by which some organisms use chemical energy instead of light energy to make energy-storing carbon-based molecules

Photosynthetic Organisms are Producers. • Producers • Produce the chemical energy for themselves and for other organisms. • Photosynthesis • A process that captures energy from sunlight to make sugars that store chemical energy. • Chlorophyll • A molecule in chloroplasts that absorb some of the energy in visible light

Properties of Light • Organisms use only a small range of wavelengths for photosynthesis, vision, and other processes. • Most of these wavelengths are the ones we see as visible light, a small part of the electromagnetic spectrum from the sun. • Light energy is packages as photons, which vary in energy as a function of wavelength. • The shortest are gamma rays with the highest energy; longer are radio waves with the lowest energy. • Photoautotrophs use only a small range (380-750 nm) of wavelengths for photosynthesis.

From Sunlight to Photosynthesis • Pigment molecules on the thylakoid membranes absorb photons. • The chlorophylls in green leaves mask the accessory pigments until autumn when the chlorophyll content declines. • A pigment absorbs light of specific wavelengths by acting as an antenna for receiving photon energy. • Chlorophyll a and b pigments absorb blue and red, but reflect green (leaves). • Carotenoid pigments absorb blue-violet and blue-green but reflect yellow, orange, and red. • Xanthophylls reflect yellow, brown, purple, or blue light; anthocyanins reflect red and purple light in fruit and flowers; phycobilines reflect red or blue-green light and are accessory pigments found in red algae and cyanobacteria.

Harvesting the Rainbow • Violet and red light are the wavelengths best suited for photosynthesis.

Photosynthesis in Chloroplasts • Both stages of photosynthesis occur in the chloroplast. • The semifluid interior (stroma) is the site for the second series of photosynthesis reactions. • Flattened sacs, thylakoids, interconnected by channels weave through the stroma; the first reactions occur here. • In the thylakoid membranes, pigments are organized into clusters called photosystems, each consisting of 200-300 pigment molecules capable of trapping energy from the sun.

Photosynthesis in Chloroplasts • Light-dependent reactions • Convert light energy to the chemical bond energy of ATP. • Water is split to release oxygen. • NADP+ picks up electrons to become NADPH to be used later. • Light-independent reactions • Assemble sugars and other organic molecules using ATP, NADPH, and CO2.

First Stage: Light-Dependent Reaction • Capture and transfer energy. • There are two photosystems involved: photosystem II and photosystem I

Light-Dependent Reaction • Chlorophyll and other light-absorbing molecules capture energy from sunlight. • Water molecules are broken down into hydrogen ions, electrons, and oxygen gas (waste) • Sugars are NOT MADE during this part of photosynthesis Day 1

Light Dependent Reaction: Photosystem II • Chlorophyll and other light absorbing molecules absorb energy from sunlight and that energy is transferred into chloropyll. • The energy is then transferred to electrons. • 1. Energy is absorbed in sunlight • High energy electrons leave the chorophyll and enter the electron transport chain (a series of proteins in the thylakoid) • 2. Water molecules split • 3. Hydrogen ions transported

Light Dependent Reaction: Photosystem I • Chlorophyll and other light-absorbing molecules absorb sunlight and add it to the electrons from photosystem II • 4. Energy is absorbed from sunlight. Electrons are energized. • 5. NADPH produced. • In photosynthesis NADPH functions like ATP. • The molecules of NADPH go to light-independent reactions.

ATP Production • Final part of the light-reaction. • 6. Hydrogen ion diffusion • H+ ions flow through the thylakoid. • 7. ATP produced • ATP synthase take the ions as they flow and makes ATP by adding phosphate groups to ADP.

Light Dependent Reaction: Photosystem II and Photosystem I

Summary of Light-Dependent Reactions • PRODUCTS ARE: • NADPH • Used later to make sugar. • ATP • Used later to make sugar. • Oxygen • Given off as a waste.

2nd Stage: Light Independent Reaction • Uses energy from the first stage to make sugar. • Light-independent reactions take place ANY time that energy is available (it doesn’t need sunlight). • Light-independent reactions use the NADPH and ATP made during the light-dependent reactions to make sugar.

The Calvin-Benson Cycle • Uses the NADPH and ATP from the light-dependent reaction, and CO2 from the atmosphere to make simple sugars.

The Calvin-Benson Cycle • 1. Carbon dioxide added. • CO2 molecules are added to five-carbon molecules already in the Calvin Cycle (RuBP). • six-carbon molecules are formed . • 2. Three-carbon molecules formed (PGA). • ATP and NADPH is used to split the six-carbon molecules into two three-carbon molecules.

The Calvin-Benson Cycle • 3. Three-carbon molecules exit. • Most of the three-carbon molecules will stay IN the Calvin Cycle. • ONE high energy three-carbon molecule will leave the cycle. • When TWO three-carbon molecules leave the cycle, they will bond together to build a six-carbon sugar molecule. • Glucose (C6H12O6)

The Calvin-Benson Cycle • 4. Three-carbon molecules recycled (PGAL). • Energy from ATP is used to change the three-carbon molecules that stayed in the cycle to five-carbon molecules. • These five-carbon molecules stay in the Calvin Cycle. • They are added to new CO2 molecules that enter the cycle.

The Calvin-Benson Cycle

Summary of Light-Independent Reactions • PRODUCTS ARE: • Glucose • Used to store energy. • NADP+ • Return to the light-dependent reaction. • Will be changed into NADPH there. • ADP • Return to the light-dependent reaction. • Will be changed into ATP there.

Functions of Photosynthesis • Provides material for plant growth and development. • Simple sugars are bonded together to form complex sugars like cellulose and starch. • Starches store energy for the plant. • Cellulose is a major component of the cell wall. • Helps regulate the Earth’s environment. • Removes CO2 from the atmosphere.

Photosynthetic Equation • 6CO2 + 6H2O C6H12O6 + 6O2 • Light Dependent Reactions • Includes Photosystem II • Electron Transport Chain • Photosystem I • Light Independent Reactions • Includes the Calvin Cycle

Photosynthetic Equation

Photosynthesis

Photosynthesis

Presentation Transcript

PHOTOSYNTHESIS

Photosynthesis

Photosynthesis

Photosynthesis

Photosynthesis

Photosynthesis

Photosynthesis

Photosynthesis

Photosynthesis

Photosynthesis

Photosynthesis

Photosynthesis

Photosynthesis

Photosynthesis

Photosynthesis

Photosynthesis

Photosynthesis

Photosynthesis

Photosynthesis

PHOTOSYNTHESIS

Photosynthesis

PHOTOSYNTHESIS