Professor Dave here, let's learn about photosynthesis. We talked about how cellular respiration transforms the food we eat into ATP. But what do plants do? They don't really eat in the normal sense of the word, apart from venous fly traps. As it turns out, plants are getting their energy directly from the source, the sun.
Plants use sunlight, as well as water and carbon dioxide, which are plentiful in our earthly surroundings, to produce their own nourishment through a cellular process called photosynthesis. this word makes sense because photo comes from the Greek word for light and synthesis means to build, so plants use light and small molecules to build bigger molecules that they can then metabolize to produce energy. other organisms then eat the plants, other organisms eat those organisms, so plants really are the foundation of the entire food chain. Let's learn about how photosynthesis works. Photosynthesis consists of two stages.
There are the so-called light reactions, in which solar energy is converted into chemical energy, and then there's the Calvin cycle, which uses that chemical energy to build G3P, the precursor to glucose and other molecules. Both of these stages occur inside one of the organelles found in plant cells, which are called chloroplasts, and there are around 30 to 40 of them per cell. A chloroplast has two membranes that surround a fluid called stroma, within which sacs called thylakoids are suspended.
These sacs are often stacked in columns called grana, and in the membrane of these thylakoids sits a special pigment molecule called chlorophyll. Chlorophyll can take either an A or a B form. differing only in one functional group inside the porphyrin ring, either a methyl or aldehyde group. The porphyrin ring is what gives this molecule the capacity to absorb sunlight in a unique way.
If chlorophyll absorbs a photon of a particular energy, one of its electrons jumps up to an excited state. These chlorophyll molecules sit inside of a photosystem with many other chlorophylls, and this excitation can get passed around from molecule to molecule. with one electron relaxing back to the ground state, emitting another photon that will excite an electron in another molecule, and so forth like a pinball machine.
eventually a photon may strike the reaction center complex which also contains two molecules of chlorophyll. when this happens the high-energy excited electron, rather than relaxing back down to the ground state, will instead be transferred to another molecule called the primary electron acceptor, after which an enzyme supplies the missing electron to the oxidized chlorophyll via a water molecule to get it back to normal, which is how oxygen molecules are produced. This is the first step of the light reactions. These are a series of redox reactions that occur first in photosystem II and then in photosystem I.
If they seem like they are named backwards, it's because they were named in the order that they were discovered. In photosystem II, electrons flow beginning with the primary electron acceptor through a series of compounds that are embedded in the thylakoid membrane, sort of like the electron transport chain from cellular respiration. ATP will be a byproduct of this process, due to a proton gradient and ATP synthase also just like in cellular respiration.
Now electrons will move through photosystem I, another electron transport chain. But instead of producing ATP, photosystem I will result in the conversion of nicotinamide adenine dinucleotide phosphate, or NADP+, into NADPH. So the light reactions in the thylakoid, which are summarized by the following equations, require sunlight and water among the reactants and generate oxygen, ATP, and NADPH.
NADPH as products. ATP and NADPH are then used in the Calvin cycle, which occurs in the stroma. This is where all the synthesis occurs.
Unlike the citric acid cycle, which is catabolic, the Calvin cycle is anabolic, building organic molecules from smaller components requiring energy to do so. This happens in three phases. Phase one is carbon fixation, which is catalyzed by an enzyme called Rubisco.
Rubisco captures CO2 from the atmosphere and attaches it to a five carbon sugar called ribulose bisphosphate. The resulting six carbon molecule is unstable and splits into two molecules of 3-phosphoglycerate. Phase two is reduction. Each of these molecules receives a phosphate from ATP and is then reduced by NADPH, after which it loses a phosphate to become glyceraldehyde 3-phosphate.
Some of this G3P is the output of the Calvin cycle, going on to other pathways that generate glucose and other organic compounds, and some goes back to generate more RUBP and start the cycle over again. To generate a net output of 1G3P, the cycle needs nine ATPs and six NADPHs. So to summarize, photosynthesis occurs in two phases.
In the light reactions, light and water go in and oxygen comes out, as well as the ATP and NADPH that are used in the Calvin cycle, where carbon dioxide comes in and organic products like sugars come out. In this way it's almost like the reverse of cellular respiration. they involve a series of redox reactions, the electrons just flow in opposite directions. in one a sugar is built, in the other a sugar is degraded.
and that's how plants make their own food.