Photosynthesis
Summary
TLDRIn this educational podcast, Mr. Andersen explores the vital process of photosynthesis, highlighting its importance for producing oxygen and food. He explains the roles of chloroplasts, thylakoid membranes, and the stroma in eukaryotic cells. The script delves into the light-dependent reactions occurring in the thylakoid membrane, where water is split, and ATP and NADPH are generated. It then covers the Calvin cycle, detailing how ATP and NADPH are used to convert carbon dioxide into glucose. The podcast also addresses photorespiration, a problem faced by plants in hot environments, and how some plants like CAM and C4 plants have evolved to overcome this issue.
Takeaways
- 🌿 Photosynthesis is a process that occurs in plants, algae, and some bacteria, providing oxygen and food for life on Earth.
- 🍃 The site of photosynthesis in eukaryotic cells is the chloroplast, which contains thylakoid membranes for light reactions and stroma for the Calvin cycle.
- 🌞 Light reactions take place in the thylakoid membrane, where light energy is used to generate ATP and NADPH, essential for the next stage of photosynthesis.
- 💧 The process begins with the absorption of water and carbon dioxide, and the use of light to power the production of glucose and oxygen.
- 🌱 Chlorophyll A and B, along with other pigments like carotene and xanthaphylls, work together to absorb light, primarily in the blue and red spectrums, but not green, which is reflected.
- 🔬 The equation for photosynthesis is: 6CO2 + 6H2O + light energy → C6H12O6 (glucose) + 6O2, showing the conversion of carbon dioxide and water into glucose and oxygen.
- 🔄 The Calvin cycle, also known as the light-independent reactions, uses the ATP and NADPH produced in the light reactions to fix carbon from CO2 into glucose.
- 🌡️ Photorespiration is a problem that occurs when plants don't have enough CO2, causing oxygen to enter the Calvin cycle and reduce efficiency, especially in hot conditions.
- 🌵 Solutions to photorespiration include CAM photosynthesis, used by plants like cacti and pineapples, which open their stomata at night to minimize water loss, and C4 photosynthesis, used by plants like corn, which initially convert CO2 into a 4-carbon molecule to bypass the issue.
- 🌍 Photosynthesis is a fundamental process that has been essential for life on Earth for billions of years, with adaptations like CAM and C4 pathways evolving to optimize the process in different environments.
Q & A
What are the two essential products of photosynthesis that Mr. Andersen mentions are crucial for his survival?
-The two essential products of photosynthesis mentioned by Mr. Andersen are oxygen, which we breathe, and food, which comes from the glucose produced by plants.
In which structures of eukaryotic cells does photosynthesis occur?
-Photosynthesis in eukaryotic cells occurs in the chloroplasts, which contain thylakoid membranes where the light reactions take place and the stroma where the Calvin cycle occurs.
What is the function of the thylakoid membrane in photosynthesis?
-The thylakoid membrane is where the light reactions of photosynthesis occur. It is organized in stacks called grana, and it is the site of electron transport and the production of ATP and NADPH.
What is the role of the stroma in the process of photosynthesis?
-The stroma is the liquid-filled part of the chloroplast where the Calvin cycle takes place. It is the site of carbon fixation and the synthesis of glucose from carbon dioxide.
What are the different pigments involved in photosynthesis, and how do they contribute to the process?
-The pigments involved in photosynthesis include chlorophyll A and B, carotene, and xanthophylls. They work together to absorb light, primarily in the blue and red wavelengths, and are crucial for capturing the energy needed for the light reactions.
Why are plants green, and which color of light do they reflect the most?
-Plants are green because they reflect the green light the most, which is the color they absorb the least. This is due to the pigments in the leaves, which absorb more blue and red light but reflect green.
What are the reactants and products of the photosynthesis process?
-The reactants of photosynthesis are water and carbon dioxide, while the products are glucose (or other sugars) and oxygen.
How does photorespiration affect the efficiency of photosynthesis in plants?
-Photorespiration is a process that occurs when there is not enough carbon dioxide, and oxygen can enter the Calvin cycle, leading to the production of a useless chemical that the plant must then break down. This reduces the efficiency of photosynthesis as it consumes energy without producing sugars.
What are C3, C4, and CAM plants, and how do they differ in their approach to photosynthesis?
-C3 plants are the most common type and perform photosynthesis in the Calvin cycle. C4 plants have an additional step to concentrate carbon dioxide before entering the Calvin cycle, which is more efficient in hot environments. CAM plants, like cacti, open their stomata at night to take in carbon dioxide and store it as malic acid, which they use during the day when their stomata are closed to conserve water.
What is the significance of the electron transport chain in the light reactions of photosynthesis?
-The electron transport chain in the light reactions is significant because it uses the energy from light to move electrons, which ultimately leads to the production of ATP and NADPH. These energy carriers are then used in the Calvin cycle to fix carbon dioxide into glucose.
Outlines
🌿 Introduction to Photosynthesis
Mr. Andersen introduces the topic of photosynthesis, emphasizing its importance for providing oxygen and food. He explains that photosynthesis occurs not only in plants but also in bacteria, algae, and protists. The chloroplasts in eukaryotic cells are identified as the site of photosynthesis. Key terms like thylakoid membrane, granum, and stroma are introduced, with the thylakoid membrane being the site of light reactions and the stroma the site of the Calvin cycle. The variety of pigments involved in photosynthesis, including chlorophyll A and B, carotene, and xanthaphylls, are discussed, along with their absorption spectra and the reason plants appear green, which is due to the reflection of green light.
🔬 The Light Reaction and Electron Transport Chain
This section delves into the light-dependent reactions of photosynthesis, which occur in the thylakoid membrane. The process begins with light energy being absorbed and used to move electrons through an electron transport chain, resulting in the production of NADPH. Water molecules are split to provide electrons and protons, with the latter contributing to the creation of ATP via the protein ATP synthase. The waste product of this process is oxygen, which diffuses out of the cell. The section also touches on the historical discovery of photo systems I and II and the role of rubisco in the Calvin cycle.
🌱 The Calvin Cycle and Photorespiration
The Calvin cycle, also known as the light-independent reactions, is detailed in this section. It takes place in the stroma and uses the energy from ATP and NADPH, along with carbon dioxide, to produce glucose and other sugars. The cycle involves the enzyme rubisco, which attaches carbon dioxide to a five-carbon molecule called RUBP, leading to the formation of three-carbon molecules that are then converted into usable sugars. The concept of photorespiration is introduced as a problem that arises when there is a lack of carbon dioxide, allowing oxygen to enter the Calvin cycle and produce useless compounds. Adaptations to this issue in plants living in hot environments, such as CAM and C4 photosynthesis, are discussed, highlighting strategies like opening stomata at night or converting carbon dioxide into a four-carbon molecule for later use.
Mindmap
Keywords
💡Photosynthesis
💡Chloroplasts
💡Thylakoid Membrane
💡Granum
💡Stroma
💡Pigments
💡Absorption Spectrum
💡Calvin Cycle
💡Rubisco
💡Photorespiration
💡C3, C4, and CAM Plants
Highlights
Photosynthesis is essential for producing oxygen and food.
Photosynthesis occurs not only in plants but also in bacteria, algae, and protists.
Chloroplasts are the site of photosynthesis in eukaryotic cells.
Thylakoid membranes within chloroplasts are where light reactions occur.
Granum is a stack of thylakoids involved in light reactions.
The stroma, a fluid within chloroplasts, is where the Calvin cycle takes place.
Multiple pigments work together in photosynthesis, including chlorophyll A, chlorophyll B, carotene, and xanthaphylls.
Plants reflect green light, which is why they appear green.
Photosynthesis involves a chemical reaction with water and carbon dioxide as reactants.
Plants absorb water and carbon dioxide and use light to produce glucose and oxygen.
Glucose produced by photosynthesis is used for energy and structural components like cellulose.
Photosynthesis consists of two steps: the light reaction and the Calvin cycle.
The Calvin cycle, also known as the light-independent reaction, occurs in the stroma.
Light-dependent reactions produce NADPH and ATP, which are used in the Calvin cycle.
Photosystems I and II are key components of the light-dependent reactions in the thylakoid membrane.
Water is split to produce oxygen and protons during the light-dependent reactions.
ATP synthase generates ATP by allowing protons to flow through it.
The Calvin cycle uses ATP and NADPH to fix carbon from carbon dioxide into usable molecules like G3P.
G3P can be assembled into glucose or other sugars needed by the plant.
Photorespiration is a problem for plants when carbon dioxide is scarce, leading to oxygen wastefully entering the Calvin cycle.
C3 plants are affected by photorespiration, which can occur when stomata are closed to conserve water.
CAM and C4 plants have evolved mechanisms to avoid photorespiration in hot environments.
CAM plants open their stomata at night to take in carbon dioxide and store it as malic acid.
C4 plants convert carbon dioxide into a 4-carbon molecule that can be used in the Calvin cycle without needing immediate CO2 from the atmosphere.
Corn is an example of a C4 plant that efficiently handles carbon dioxide intake.
Transcripts
Hi. It's Mr. Andersen and in this podcast I'm going to talk about photosynthesis.
I love photosynthesis because it gives me two things that I need. I need to breathe,
so it gives me oxygen. And I need to eat. And so it's going to give me food. And so
I love photosynthesis. You might think it's only found in these things, plants, but it's
also found in bacteria. It's found in algae. And so it's found in protists. It's found
everywhere. And so photosynthesis has been around a long time. It's super important that
you understand how it works. And so let's start with the site in eukaryotic cells of
photosynthesis. And that's the chloroplasts. So this is a number of cells. And you can
see how many chloroplasts we could have in a typical cell. So there's a whole bunch of
them. There are a few terms you should be familiar with. And where they are. First one
is a thylakoid membrane. Thylakoid membrane is going to be organized like this. And basically
that's where the light reaction is going to take place. If you've got a stack of thylakoids
like this together we call that a granum. The other big thing to understand photosynthesis
is that this is filled with a liquid. And that liquid is called the stroma. And that's
going to be the site of the Calvin cycle. If we were to grind up a leaf what we would
find is that there's not only one pigment, chlorophyll A that does photosynthesis. But
theres a number of them that are working together. And so if you grind up a leaf into some chromatography
paper and then you put it in a solvent, what you'll get is chromatography. It's going to
separate into all of its different parts. And so this right here would be chlorophyll
A and chlorophyll B. And this would be like carotene and xanthaphylls. And they're all
working together. You'll see this other pigments in the fall when the chlorophyll moves back
into the leaf and is reabsorbed. But if we look at what light they absorb, here's chlorophyll
A and here's B. This is what's called their absorption spectrum. And what color of light
they are able to absorb. And you can see that they absorb a lot of the blue. A lot of the
red. But they don't absorb a lot of this in the middle, this green. And so a quick question
could be what is their least favorite color, plants? And the the right answer would be
green. Because the reflect that green light. Now this is actually puzzled scientists for
a long time. And we really don't have a definitive answer as to why plants are green. Know this
that if they were black they probably would get a little bit too hot. They would absorb
too much light. And so let' start with an equation. Because this is simply a chemical
reaction. It's a chemical reaction with a number or steps. But what are the reactants?
Water and carbon dioxide. And so how does a plant grow? It's basically taking water
in from its roots and it's taking carbon dioxide in through its leaves. Through its stomata.
The other thing it needs is light. And so it's just taking these simple ingredients.
And then it's weaving those together into glucose. This monster molecule here. And then
oxygen. And so this is the food that I get. And this is the oxygen that I breathe. Now
are plants just nice? No. They're making this sugar for themselves so they can break it
down using cellular respiration. And in fact if I put this arrow in the other direction,
that becomes cellular respiration. So they're making food for themselves and they're also
going to make some of the structure. So like the cellulose in the cell walls of a plant
is made from that as well. Okay, so whenever I try to think what are the different steps
in photosynthesis? I always image this picture right here. There's photo and synthesis in
the word. Photo means light. And synthesis means to make. And so there are two steps
in photosynthesis. The light reaction. And those are going to take place in the thylakoid
membrane. And then the Calvin cycle. We used to call this the dark reactions which is a
silly term. Doesn't happen during the dark. It happen during the light. And so basically
the person who worked this all out is Melvin Calvin and so we named it after him. Where
does this take place? You guessed it. It takes place in the stroma or this liquid portion.
And so let's kind of do a cartoon version of photosynthesis. What are the reactants
again? Water, light and carbon dioxide. What are going to be the products that come out
of this? It's going to be oxygen and glucose. So let's watch what happens. In the light
dependent reaction water and light go into the thylakoid membrane and they produce two
things. They produce oxygen. Oxygen is simply a waste product. And then they're going to
produce these chemicals. NADPH and ATP. So they have energy now. Let's watch what happens
to them. Well the energy is going to transfer to the Calvin cycle where carbon dioxide comes
in and then glucose goes out. And so this is the big picture of photosynthesis. But
now let's kind of dig in a little bit deep and talk about the light reaction. Okay, so
where are we? We're in the thylakoid membrane. So we're in this membrane right here. So if
we were to zoom in to that membrane right here, that's what this diagram is. Okay. So
what are the two things coming in? Well the first one is going to be light. So light's
coming in here. Light's coming in here. What's the next things that we're going to have coming
in? And that's going to be water. Okay, so let's look at some of the other big features
in this thylalkoid membrane. So this is the outside, or the stroma. And this is going
to be the lumen or the inside. And so there's a couple of big things right here. What's
in here? Well these are basically going to be proteins with chlorophyll on the inside
of it. And so we call that whole thing together a photo system. So this first one is actually
called photo system II. And then we go to photo system I. And the reason we go backwards
is that that photo system I was discovered first. So basically what comes in? Light.
What's that light used to do? Well that light is used to power the movement of an electron
through an electron transport chain. So that electron is going through proteins, carrier
proteins. And eventually that electron is going to go to here. It's going to go to NADPH.
Because remember that's one of the products of the light dependent reaction. Okay. What
happens to the water then? So the water is going to be split right away. If you split
water what do you get? Well you get oxygen. So that's the O2 that's going to diffuse out
of a cell. And that's the oxygen that you're actually breathing right now. And then we're
going to have these protons which are simply hydrogen ions. So they're hydrogen atoms that
have lost their electron. Okay, so this is getting kind of messy. So let's look what
happens next. As that electron moves through the electron transport chain, and again it's
powered by the introduction of light here and light here. That electron is going to
be moving all the way down here and every time it goes through one of these proteins,
it's pumping protons to the insides. So it's pumping protons to the inside. Now protons
have a positive charge. So basically what's happening is that you're building up a positive
charge on the inside. So there's a positive charge in here. If you know how cellular respiration
works, you'll realize that this is the opposite of that. So now we have all of these positive
charges on the inside. Where do they go? Well there's only one hole that they can go through.
And that's is to go through this protein here. As those protons move out, they're moving
through a protein called ATP synthase. And it works almost like a little rotor. And every
time a proton goes through we make another ATP. So what have we made in the light dependent
reaction? We've made NADPH and we've made ATP. And what's nice about that is they're
now just sitting right here in the stroma and so they're able to go on to the Calvin
cycle which is going to be the next step in this process. And so who's providing the energy?
Light. Whose providing the electrons? Water. And then a waste product of that is simply
going to be oxygen. Okay. Let's go to the Calvin cycle then. So what's happening in
the Calvin cycle? You can see here's those reactants. So we've got our ATP here, ATP
here and NADPH. What are they providing? Simply energy. We also have this molecule here. It's
called RUBP. Basically it's a five carbon molecule. And then we have carbon dioxide
coming in. So it moves through the stomata of the leaf. And it's going to diffuse its
way in. Carbon dioxide is a one carbon molecule. So basically there's an enzyme here called
rubisco and it's going to attach this one carbon molecule to a five carbon molecule.
It immediately breaks into three carbon molecules. And then it gets energy from ATP and NADPH.
And when we're done it's creating this chemical down here, called G3P. What does G3P become?
Well it can be assembled quickly into glucose or sucrose or maltose or whatever they need
to do, that's going to be produced right in here by the G3P. So that's where we're synthesizing.
In other words we're taking carbon and we're fixing it. We're making it usable. Now some
of that G3P is released. But a lot of it is recycled again to make more of this RUBP.
And so that's why it's a cycle over and over again. What's the big picture? If we don't
have ATP, if we don't have NADPH, then this process is going to shut down. What's the
other thing that could shut it down? If we don't have carbon dioxide. Okay, so that's
basically photosynthesis. And again it's been working for billions of years. But there's
a slight problem. And that problem is called photorespiration. What is photorespiration?
Well photorespiration occurs only when we don't have enough carbon dioxide. So if we
don't have enough carbon dioxide, let me cross that out, well we certainly can't make our
G3P. But something worse happens. Oxygen can actually jump into the Calvin cycle. And using
rubisco can form another chemical. Now that chemical doesn't do anything. In other words
it has no purpose. And the cell actually has to break it down. And so as a result of that
plants, and we call almost all plants C3 plants. And the reason we call them C3 plants is this
G3P is going to be a 3 carbon molecule. So for these C3 plants, photorespiration is bad.
In other words, they don't get anything out of it. And so they're going to lose based
on that oxygen kind of jumping into the Calvin cycle. And so you might think evolutionarily,
why would this have even evolved? Well remember, photosynthesis shows up first. And then oxygen
in the atmosphere shows up much later. And so it wasn't a problem initially, but it became
a problem. Another question you might think is, when are we not going to have enough carbon
dioxide? When wouldn't we have carbon dioxide? Well how do they get carbon dioxide? And plant
is going to have a stomata. And it's surrounded by guard cells. And so basically when a plant
opens up its stomata, carbon dioxide can diffuse in. And so the only time the plant wouldn't
have carbon dioxide, because we have tons of carbon dioxide in the atmosphere, is when
it's actually closed. And when would it be closed in a plant? The only time it's closed
is when it's really, really hot. And a plant doesn't want to lose water. Because through
transpiration you're constantly losing water. And so if you're a plant, if it's a hot day
you have this really tough choice. If you open up your stomata, you're going to lose
water. You could shrivel up. If you close it, you can't get carbon dioxide in and then
you're going to start doing photorespiration. And so of course nature has come up with solutions
to this over time. And it's only going to be found in plants that live in really hot
environment. So here's the first solution. And this totally makes sense. This is in CAM
plants. CAM plant would be a jade plant or like a pineapple. Basically what they do is
they only open their stomata at night. And so at night they open up their stomata. And
then the carbon dioxide will come in and they'll create malic acid out of it. So they're going
to store it in vacuoles inside the cell. Okay. So now when it's day time what they can do
is they can close the stomata because they don't want to lose water. And now they can
actually take that carbon dioxide out of the malic acid and they can use it in the Calvin
cycle to make sugars. So the great thing about CAM plant is again they're only taking in
carbon dioxide at night when it's cool. And then during the day they can close their stomata
and they don't lose water. Another example of this would be in C4 plants. What they do
is instead of doing it day and night, what they'll do is they'll take that carbon dioxide
in and they'll actually use enzymes to make a 4 carbon molecule out of it. That 4 carbon
molecule will move to some cells on the inside of the leaf called the bundle sheath cells.
And then they can simply introduce carbon dioxide into the Calvin cycle here. And so
again, both of these solutions are basically taking in carbon dioxide when you can get
it. Creating a chemical out of it. And then they can introduce that chemical into the
Calvin cycle and they don't have to wait for carbon dioxide to diffuse in. Now of course
there's going to be extra steps in here so it's going to require more energy. And so
we only see this in areas where it's really, really warm. But an example of a C4 plant
that we all eat and use a lot of, in fact most of us are just made out of this stuff
is corn. And so that's photosynthesis. A simple problem is photorespiration, but I hope that's
helpful.
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