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Jetzt kostenlos anmeldenHave you ever wondered how plants feed without a digestive system? What do plants "eat", exactly?
Unlike animals and other organisms, plants don't need to consume organic matter to produce their own. They are the "producers" of the trophic system, i.e. they are the ones that produce organic matter at the start of the food chain that other organisms consume. How do they generate organic matter then? They do this with photosynthesis!
Photosynthesis is a complex reaction by which plants generate organic matter (sugars) with the energy from sunlight from inorganic matter, namely water and CO2. Therefore, photosynthesis is a light-driven, oxidation-reduction reaction.
The glucose formed in photosynthesis provides energy for the plant and carbon molecules to make a wide array of biomolecules.
There are two stages of photosynthesis: the light-dependent reaction and the light-independent reaction. We sometimes call the light-independent reaction the ‘dark reaction’ or the ‘Calvin cycle.’
Photosynthesis takes place in the leaves, specifically in the chloroplasts from the leaves. Chloroplasts are membranous organelles specialised in photosynthetic reactions. Like mitochondria, they contain their own DNA and are thought to have evolved into organelles following the endosymbiotic theory.
Plants are not the only organisms that can do photosynthesis. Some bacteria and algae can also photosynthesise.
The endosymbiotic theory suggests that current eukaryotic cells evolved through a symbiotic relationship between archaic eukaryotic cells and certain prokaryotic cells they engulfed. Both mitochondria and chloroplasts are thought to be the remnants of this symbiotic relationship: the endosymbiotic theory states that both organelles are the remains of these initial prokaryotic organisms that were absorbed by primitive eukaryotic cells.
Leaves have several structural adaptations that allow them to perform photosynthesis efficiently. These include:
As you will see from Figure 1, leaves also have multiple cellular adaptations that allow for photosynthesis to occur. These include:
Most of the photosynthesis reaction occurs in the plant's chloroplasts. Chloroplasts contain chlorophyll, a green pigment that can ‘capture’ sunlight. Chlorophyll is found in the membrane of the thylakoid discs, which are small compartments inside the structure of the chloroplast. The light-dependent reaction takes place along this thylakoid membrane. The light-independent reaction takes place in the stroma, fluid inside the chloroplast that surrounds stacks of thylakoid discs (collectively called ‘grana’).
Below, Figure 2 outlines the general structure of a chloroplast:
Photosystems are multi-protein complexes found in the thylakoid membranes of chloroplasts in plants and some algae. They are responsible for absorbing light energy and converting it into chemical energy through the process of photosynthesis.
There are two types of photosystems:
Together, these two photosystems work in concert during the photosynthetic reaction to produce ATP and NADPH, which are necessary for the Calvin cycle or dark phase of photosynthesis. I.e. they are responsible for producing the energy that is required to produce glucose at the end of the process, which is the main goal of photosynthesis for plants.
The balanced equation for photosynthesis in plants is the following:
\(6CO_2 + 6H_2O \xrightarrow {\text{Solar energy}} C_6H_{12}O_6 + 6O_2\)
As you can see, each photosynthesis reaction needs 6 molecules of carbon dioxide (CO2) and 6 water (H2O) molecules because each glucose molecule, the sugar (i.e. organic molecule) that is produced through photosynthesis, has 6 carbon and 12 hydrogen atoms.
Simplified to be written in plain words, it is as follows:
\(\text{Carbon dioxide + Water + Solar energy} \longrightarrow \text{Glucose + Oxygen}\)
However, the equation in plain text is not totally correct, as it is not stating how many molecules of each reagent and product are needed for the reaction. The word equation is an easy way to explain the key concepts of photosynthesis: carbon dioxide and water are used, together with the energy from sunlight, to produce organic matter (glucose) and oxygen as a byproduct.
There are two main stages to photosynthesis: the light-dependent phase and the dark phase or light-independent reaction. The light-dependent phase can be further divided into 4 stages, whilst the dark phase consists of only 1 step, meaning that in total photosynthesis has 5 steps.
The first step involves the chlorophyll in the photosystem II complex (PSII) of chloroplasts absorbing light. By absorbing light the chlorophyll is absorbing energy, which ionises the chlorophyll as electrons leave it and are carried down an electron transfer chain down the thylakoid membrane.
Using the light energy absorbed by chlorophyll, the light-dependent reaction occurs. This occurs in two photosystems, which are located along the thylakoid membrane. Water splits into oxygen (O2), protons (H+) ions and electrons (e-). The electrons are then carried by plastocyanin (a copper-containing protein that mediates electron transfer) from PSII to PSI for the next part of the light reaction.
The equation for the first light-dependent reaction is:
\[2H_2O \longrightarrow O_2 + 4H^+ + 4e^-\]
In this reaction, water has been split into oxygen and hydrogen atoms (protons) and electrons which came from the hydrogen atoms.
The electrons produced in the last stage pass through PSI and are used to make NADPH (reduced NADP). NADPH is a molecule that is essential for the light-independent reaction, as it provides it with energy.
The equation for this reaction is:
\[NADP^+ + H^+ + 2e^- \longrightarrow NADPH\]
In the final stage of the light-dependent reaction, ATP is generated in the thylakoid membrane of the chloroplasts. ATP is also known as adenosine 5-triphosphate and is often referred to as the energy currency of a cell. Like NADPH, it is essential for the light-independent reaction.
The equation for this reaction is:
\[ADP + P_i \longrightarrow ATP\]
ADP is adenosine di-phosphate (which contains two phosphorus atoms), while ATP has three phosphorus atoms after the addition of inorganic phosphorus (Pi).
This occurs in the stroma of the chloroplast. Through a series of reactions, ATP and NADPH are used to convert carbon dioxide into glucose. You can find these reactions explained in the light-independent reaction article.
The overall equation for this is:
\[6CO_2 + 12NADPH + 18ATP \longrightarrow C_6H_{12}O_6 + 12 NADP^+ + 18 ADP + 18 P_i\]
The products of photosynthesis are glucose (C6H12O6) and oxygen (O2).
We can further split the process of photosynthesis and the products of each stage into the products for the light-dependent and the light-independent stages:
Photosynthesis Reactions | Products |
Photosynthesis (overall) | C6H12O6, O2 |
Light-dependent reactions | ATP, NADPH, O2, and H+ |
Light-independent reaction | Glyceraldehyde 3-phosphate (G3P), and H+ |
A limiting factor inhibits or slows the rate of a process when it is in short supply. In photosynthesis, a limiting factor would be something needed to fuel the light-dependent or light-independent reaction, so that when it is missing, the rate of photosynthesis decreases.
When all limiting factors are at optimal levels, the rate of photosynthesis will increase steadily up to a certain point before plateauing (a state of little or no change). The plateau will happen because one of these three factors will be in short supply, causing the rate of photosynthesis to stop increasing or decrease.
The law of limiting factors was proposed in 1905 by Frederick Blackman. It states that "the rate of a physiological process will be limited by whatever factor is in the shortest supply". Any change in the level of a limiting factor will affect the rate of reaction.
The rate of photosynthesis is affected by a number of factors, including:
To learn more about how these factors impact the rate of photosynthesis, check out our article Rate of Photosynthesis.
Photosynthesis takes place in the chloroplasts of the plants. Chloroplasts contain chlorophyll, a green pigment that can absorb light energy from the sun. Chlorophyll is contained in the thylakoid membrane, which is where the light-dependent reaction takes place. The light-independent reaction takes place in the stroma of the chloroplast.
The overall products of photosynthesis are glucose, oxygen, and water.
Photosynthesis is a light-driven, oxidation-reduction reaction. A shorter way to put it is that it is a type of redox reaction. This means that electrons are both lost and gained during photosynthesis. It is also important to note that photosynthesis is endergonic, meaning that it cannot occur spontaneously and needs to absorb energy - hence the need for light energy from the sun!
Photosynthesis occurs in plants through two reactions, the light-dependent reaction and the light-independent reaction. It occurs when the chloroplasts absorb light energy. This energy is then used to convert water into NADPH, ATP, and oxygen through the light-dependent reaction. The light-independent reaction occurs. This is when carbon dioxide is converted into glucose using the NADPH and ATP produced from the light-dependent reaction.
The five steps of photosynthesis cover the light reaction and the dark reactions. The five steps are:
Photosynthesis is an endothermic reaction, meaning that it requires energy to take place.
The gas that plants needs to do photosynthesis is carbon dioxide (CO2).
Flashcards in Photosynthesis27
Start learningWhat are the products of photosynthesis for the light-dependent reaction?
ATP, NADPH, O2, and H+ ions.
What are the products of photosynthesis for the light-independent reaction?
Glucose and H+ ions.
What are the three limiting factors for photosynthesis?
Light, temperature, and carbon dioxide.
On what part of the plant does photosynthesis take place?
The leaf, in the chloroplasts.
What substance found in the chloroplasts is responsible for absorbing light energy from the sun?
Chlorophyll.
What kind of reaction is photosynthesis?
A redox reaction (alternatively: a light-driven, oxidation-reduction reaction).
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