Ever wonder how the oxygen binds to our blood cells and sent to the different parts of our body? Watch and learn with Leslie as he explains how this happens and uses the Oxygen-Dissociation Curve to describe this event.
Have fun!
Transcript of Today’s Episode
Hello and welcome to another episode of Interactive-Biology T.V. where we’re making Biology fun! My name is Leslie Samuel and in this episode, Episode 60, I’m going to be talking about hemoglobin and what’s called the oxygen-dissociation curve. So, let’s get right into it.
We’ve already done an introduction to the respiratory system and we’ve shown how the heart beats and sends the blood. When the right ventricle sends the blood, it sends it to the lungs that comes back to the left atria and then, the left ventricle pumps and that sends the blood through the rest of the body.
We’ve also looked in the lungs and seen how we have the trachea going into the bronchi and then that splits off into the bronchioles, and as you can see here, that gives us the alveoli and it’s in the alveoli where we have the exchange between the oxygen coming into the bloodstream, via the capillaries that we have here, and the carbon dioxide leaving the capillaries going into the lungs and being sent from the body.
Now, when the blood comes in here, it is picking up oxygen, and the type of blood cells that are picking up the oxygen, would be the red blood cells. Here you can see a picture of a few red blood cells, of course, it’s simplified. It’s not showing the white blood cells or anything else. It’s just showing the red blood cells and these are the blood cells that pick up that oxygen.
In the red blood cells, we have special molecule. That molecule is called hemoglobin. You can see a three-dimensional image here of the structure of hemoglobin so, this is, (let me write it here), hemoglobin. This molecule, it’s actually a protein, and this protein is the protein that is responsible for picking up the oxygen.
Now, let’s go into a little more detail. You can see here, that we have these four structures. Those four structures are called, (let’s do that in blue), those are heme groups. All right, so these are the four heme groups. The special thing about these heme groups is that those are the parts where the oxygen is attracted, so, we have O2 that actually comes and binds to the heme groups. As you would imagine since we have four heme groups, we can take a total of four oxygen molecules. So, this is one oxygen molecule here, and we can have another oxygen molecule here, here, and also here. So, this hemoglobin molecule once again, has a capacity to hold four oxygen molecules.
What’s interesting about the hemoglobin is that whenever one oxygen binds to a heme group, that causes the entire hemoglobin structure to undergo a conformational change so, basically changing the site of the molecule whenever one oxygen binds. As you can see here, this is the heme group but, there’s stuff around on it, and you can imagine that it would be relatively hard for the oxygen to get in there and find the right spot.
However, when one binds, it causes a change which opens it up a little bit to make it a little easier for another oxygen to come in and bind. And, when that other oxygen comes in and bind, it causes another conformational change, making it easier for another oxygen to come and bind and, once again, once that oxygen comes and binds here, it makes it easier for another oxygen to come in here and bind to it. So, in other words, as it starts taking up oxygen, it makes it easier for it to take up more oxygen. And then, of course, the opposite will be true. If we have a hemoglobin molecule that has four oxygen attached and, for some reason it gives up one oxygen, that’s going to cause a change that makes it a little harder for the other oxygen to bind. In other words, it becomes easier for oxygen to leave. So, as oxygen leaves, it’s easier for more to leave; as oxygen binds, it makes it easier for more oxygen to bind.
As a result of this, we get a relationship that is shown in this oxygen-dissociation curve. And, what you can see here is, (we’re going to be looking at this blue line) and, as you can see here, it’s not a linear relationship. In other words, as the amount of oxygen increases, so here, we’re showing the pressure of oxygen, as the pressure of oxygen increases in the environment that the hemoglobin is in, you’re going to get more binding, making it easier for more to bind, making it easier for more to bind, and the graph is going to increase faster as you’re going to the right where you have an increased partial pressure of oxygen.
Not a linear relationship but, as some binds it becomes easier so, more bind faster and it becomes easier and it gets faster and faster until, of course, it reaches to where it’s getting saturated and, it dies off.
Now, you might be wondering why it’s not just four-levels since we only have four binding spots for the oxygen, the four heme groups. However, this is not looking at one hemoglobin molecule. This is looking at a bunch of hemoglobin molecules in a bunch of red blood cells and, overall, as some starts binding, it makes it easier and easier so, it’s going to increase faster and faster until it reaches to the saturation and then, it’s going to slow down when it reaches its full saturation.
Also, as you come in this direction, as the pressure of oxygen decreases, and oxygen starts to leave, here it’s leaving slowly but, as it starts to leave more, it’s dropping down faster, and faster, and faster, until all of the oxygen is gone.
So, this is the oxygen-dissociation curve showing once again, as you pick up oxygen, it makes it easier for oxygen to be picked up, so here it starts slow and it goes faster and faster and faster and as you release oxygen, it makes it easier for oxygen to leave and then, that goes down faster and faster. This is called the oxygen-dissociation curve.
That’s pretty much it for this video. If you want to see more videos like this and check out the other resources we have available, visit the website at www.interactive-biology.com.
That’s it for this video and I’ll see you on the next one.
About The Author Leslie Samuel
Leslie Samuel is the creator of Interactive Biology. He created this site to help Make Biology Fun and has the goal of making this the biggest and best biology resource on the net.
Bless you for doing this, love your voice and find that you seem to make the most sense for me on YT. great job!
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thankssss
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Bless you for doing this, love your voice and find that you seem to make the most sense for me on YT. great job!
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thankssss
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Is the haemoglobin inside the red blood cell or is it just floating inside the blood plasma, if its inside the red blood cell doesn’t that lengthen the diffusion pathway making it less effective at picking up oxygen. Great video by the way it really helped.
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Is the haemoglobin inside the red blood cell or is it just floating inside the blood plasma, if its inside the red blood cell doesn’t that lengthen the diffusion pathway making it less effective at picking up oxygen. Great video by the way it really helped.
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AMAZING. Thank you.
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AMAZING. Thank you.
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Thanks for your vid! It makes so much easier to study!
Regards from Mexico city
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Thanks for your vid! It makes so much easier to study!
Regards from Mexico city
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that’s it my lecturer is a cunt
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You spelt Haemoglobin wrong.
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that’s it my lecturer is a cunt
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You spelt Haemoglobin wrong.
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This was the most useful video ever. I have recently started my degree and have never understood this concept so well as I have today! 10 star! Fantastic!!
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This was the most useful video ever. I have recently started my degree and have never understood this concept so well as I have today! 10 star! Fantastic!!
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Thank you so much!!
This is so easy to understand compared to my AS book!
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Thank you so much!!
This is so easy to understand compared to my AS book!
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Thank you so much!!
This is so easy to understand compared to my AS book!
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Spelt ‘Haemoglobin’ not ‘Hemeglobin’ apart from that very helpful
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Spelt ‘Haemoglobin’ not ‘Hemeglobin’ apart from that very helpful
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U r the BEST ! thank u
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U r the BEST ! thank u
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well he’s clearly American.
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well he’s clearly American.
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Haha yeah.
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Haha yeah.
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Brilliant video. You deserve a some sort of prize
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Brilliant video. You deserve a some sort of prize
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thank you very much
this video made my day 
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Thanks so much for clarifying cooperative binding!! You make things so clear.
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Nice audio signature, appreciate the spoken word without the hyper noise noisy music.Information theory ,noise ect. Ture pure puer spoken word lecture.
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Nice audio signature, appreciate the spoken word without the hyper noise noisy music.Information theory ,noise ect. Ture pure puer spoken word lecture.
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really great video. thank you so much for taking the time to do this. you are a great teacher!!!
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I’ve been trying to understand this stupid dissociation curve for a year from a lot of different people but somehow i understood your explanation.
Seriously you’ve helped me a lot!!
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Great video. Really helped me understand this concept.
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THIS SAVED MY GRADE!!!!!! Thank you so much Leslie!
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I go to a college in england, doing my A levels and this video really helped. thanks guys!!
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thank you. I was reading about partial pressure of gasses in blood and how that is related to H ions and bicarbonic ions but it was great to watch this now i know what they mean with conformational changes.
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would the release of oxygen from hemoglobon be consider a negative or positive feedback system?
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Does it really matter how haemoglobin is spelt? I’m American and have always spelt certain words the British way….not sure why but to me the British spelling has always seemed correct. Like if my professor writes “liters” on the board, without hesitation I write “litres”, if he writes hemo- I write haemo- and so on….I know weird.
Well anyway this video has been very helpful. Thank you very much!
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lol he sounds so happy!
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Doesn’t the 3rd conformational change make it harder for the 4th O2 do associate?
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I know I got confused too, think I worked it out:
As the conformational change changes the shape of the haemoglobin it makes it easier for O2 to attach. However FIRST the O2 has to DIFFUSE into the red blood cell before it attaches.If you have 3 O2 already in there then it cant diffuse in as the concentration of O2 is too high in the RBC. However if it was near the lungs then the O2 could diffuse in as the concentration of O2 is lower in the RBC than the surrounding enviroment.RBC=RED BLOOD CELL
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Not sure if that’s right, but it’s the only thing I could think of!
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I don’t know what’s his problem, but I love your voice
I love how easily I can understand every word you say, even if english isn’t my first language. If I have something I don’t understand, I come to your channel, because you are my favorite biology teacher online :] I can’t express how much you helped me, I have poor biology skills, but you actually made me understand it. I wish you were my teacher, not like it’s possible or something. 
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This is great! im revising for alevel biology and i was struggling with this topic, this has cleared it was up! thanks!
however did you spell haemoglobin right?? in England we spell it with an “a” before the e!!!
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Thanks, hopefully this comes up in my exam tomorrow hehe
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love your accent!
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Thanks for help on my MCAT!
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